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v/thirdparty/sokol/sokol_gfx.h
Alexander Medvednikov fb7ca56d87 gg: minor fixes
2020-06-04 19:57:16 +02:00

11704 lines
470 KiB
Objective-C
Executable File

#ifndef SOKOL_GFX_INCLUDED
/*
sokol_gfx.h -- simple 3D API wrapper
Project URL: https://github.com/floooh/sokol
Do this:
#define SOKOL_IMPL
before you include this file in *one* C or C++ file to create the
implementation.
In the same place define one of the following to select the rendering
backend:
#define SOKOL_GLCORE33
#define SOKOL_GLES2
#define SOKOL_GLES3
#define SOKOL_D3D11
#define SOKOL_METAL
#define SOKOL_DUMMY_BACKEND
I.e. for the GL 3.3 Core Profile it should look like this:
#include ...
#include ...
#define SOKOL_IMPL
#define SOKOL_GLCORE33
#include "sokol_gfx.h"
The dummy backend replaces the platform-specific backend code with empty
stub functions. This is useful for writing tests that need to run on the
command line.
Optionally provide the following defines with your own implementations:
SOKOL_ASSERT(c) - your own assert macro (default: assert(c))
SOKOL_MALLOC(s) - your own malloc function (default: malloc(s))
SOKOL_FREE(p) - your own free function (default: free(p))
SOKOL_LOG(msg) - your own logging function (default: puts(msg))
SOKOL_UNREACHABLE() - a guard macro for unreachable code (default: assert(false))
SOKOL_API_DECL - public function declaration prefix (default: extern)
SOKOL_API_IMPL - public function implementation prefix (default: -)
SOKOL_TRACE_HOOKS - enable trace hook callbacks (search below for TRACE HOOKS)
If sokol_gfx.h is compiled as a DLL, define the following before
including the declaration or implementation:
SOKOL_DLL
On Windows, SOKOL_DLL will define SOKOL_API_DECL as __declspec(dllexport)
or __declspec(dllimport) as needed.
If you want to compile without deprecated structs and functions,
define:
SOKOL_NO_DEPRECATED
API usage validation macros:
SOKOL_VALIDATE_BEGIN() - begin a validation block (default:_sg_validate_begin())
SOKOL_VALIDATE(cond, err) - like assert but for API validation (default: _sg_validate(cond, err))
SOKOL_VALIDATE_END() - end a validation block, return true if all checks in block passed (default: bool _sg_validate())
If you don't want validation errors to be fatal, define SOKOL_VALIDATE_NON_FATAL,
be aware though that this may spam SOKOL_LOG messages.
Optionally define the following to force debug checks and validations
even in release mode:
SOKOL_DEBUG - by default this is defined if _DEBUG is defined
sokol_gfx DOES NOT:
===================
- create a window or the 3D-API context/device, you must do this
before sokol_gfx is initialized, and pass any required information
(like 3D device pointers) to the sokol_gfx initialization call
- present the rendered frame, how this is done exactly usually depends
on how the window and 3D-API context/device was created
- provide a unified shader language, instead 3D-API-specific shader
source-code or shader-bytecode must be provided
For complete code examples using the various backend 3D-APIs, see:
https://github.com/floooh/sokol-samples
For an optional shader-cross-compile solution, see:
https://github.com/floooh/sokol-tools/blob/master/docs/sokol-shdc.md
STEP BY STEP
============
--- to initialize sokol_gfx, after creating a window and a 3D-API
context/device, call:
sg_setup(const sg_desc*)
--- create resource objects (at least buffers, shaders and pipelines,
and optionally images and passes):
sg_buffer sg_make_buffer(const sg_buffer_desc*)
sg_image sg_make_image(const sg_image_desc*)
sg_shader sg_make_shader(const sg_shader_desc*)
sg_pipeline sg_make_pipeline(const sg_pipeline_desc*)
sg_pass sg_make_pass(const sg_pass_desc*)
--- start rendering to the default frame buffer with:
sg_begin_default_pass(const sg_pass_action* actions, int width, int height)
--- or start rendering to an offscreen framebuffer with:
sg_begin_pass(sg_pass pass, const sg_pass_action* actions)
--- set the pipeline state for the next draw call with:
sg_apply_pipeline(sg_pipeline pip)
--- fill an sg_bindings struct with the resource bindings for the next
draw call (1..N vertex buffers, 0 or 1 index buffer, 0..N image objects
to use as textures each on the vertex-shader- and fragment-shader-stage
and then call
sg_apply_bindings(const sg_bindings* bindings)
to update the resource bindings
--- optionally update shader uniform data with:
sg_apply_uniforms(sg_shader_stage stage, int ub_index, const void* data, int num_bytes)
--- kick off a draw call with:
sg_draw(int base_element, int num_elements, int num_instances)
--- finish the current rendering pass with:
sg_end_pass()
--- when done with the current frame, call
sg_commit()
--- at the end of your program, shutdown sokol_gfx with:
sg_shutdown()
--- if you need to destroy resources before sg_shutdown(), call:
sg_destroy_buffer(sg_buffer buf)
sg_destroy_image(sg_image img)
sg_destroy_shader(sg_shader shd)
sg_destroy_pipeline(sg_pipeline pip)
sg_destroy_pass(sg_pass pass)
--- to set a new viewport rectangle, call
sg_apply_viewport(int x, int y, int width, int height, bool origin_top_left)
--- to set a new scissor rect, call:
sg_apply_scissor_rect(int x, int y, int width, int height, bool origin_top_left)
both sg_apply_viewport() and sg_apply_scissor_rect() must be called
inside a rendering pass
beginning a pass will reset the viewport to the size of the framebuffer used
in the new pass,
--- to update (overwrite) the content of buffer and image resources, call:
sg_update_buffer(sg_buffer buf, const void* ptr, int num_bytes)
sg_update_image(sg_image img, const sg_image_content* content)
Buffers and images to be updated must have been created with
SG_USAGE_DYNAMIC or SG_USAGE_STREAM
Only one update per frame is allowed for buffer and image resources.
The rationale is to have a simple countermeasure to avoid the CPU
scribbling over data the GPU is currently using, or the CPU having to
wait for the GPU
Buffer and image updates can be partial, as long as a rendering
operation only references the valid (updated) data in the
buffer or image.
--- to append a chunk of data to a buffer resource, call:
int sg_append_buffer(sg_buffer buf, const void* ptr, int num_bytes)
The difference to sg_update_buffer() is that sg_append_buffer()
can be called multiple times per frame to append new data to the
buffer piece by piece, optionally interleaved with draw calls referencing
the previously written data.
sg_append_buffer() returns a byte offset to the start of the
written data, this offset can be assigned to
sg_bindings.vertex_buffer_offsets[n] or
sg_bindings.index_buffer_offset
Code example:
for (...) {
const void* data = ...;
const int num_bytes = ...;
int offset = sg_append_buffer(buf, data, num_bytes);
bindings.vertex_buffer_offsets[0] = offset;
sg_apply_pipeline(pip);
sg_apply_bindings(&bindings);
sg_apply_uniforms(...);
sg_draw(...);
}
A buffer to be used with sg_append_buffer() must have been created
with SG_USAGE_DYNAMIC or SG_USAGE_STREAM.
If the application appends more data to the buffer then fits into
the buffer, the buffer will go into the "overflow" state for the
rest of the frame.
Any draw calls attempting to render an overflown buffer will be
silently dropped (in debug mode this will also result in a
validation error).
You can also check manually if a buffer is in overflow-state by calling
bool sg_query_buffer_overflow(sg_buffer buf)
--- to check at runtime for optional features, limits and pixelformat support,
call:
sg_features sg_query_features()
sg_limits sg_query_limits()
sg_pixelformat_info sg_query_pixelformat(sg_pixel_format fmt)
--- if you need to call into the underlying 3D-API directly, you must call:
sg_reset_state_cache()
...before calling sokol_gfx functions again
--- you can inspect the original sg_desc structure handed to sg_setup()
by calling sg_query_desc(). This will return an sg_desc struct with
the default values patched in instead of any zero-initialized values
--- you can inspect various internal resource attributes via:
sg_buffer_info sg_query_buffer_info(sg_buffer buf)
sg_image_info sg_query_image_info(sg_image img)
sg_shader_info sg_query_shader_info(sg_shader shd)
sg_pipeline_info sg_query_pipeline_info(sg_pipeline pip)
sg_pass_info sg_query_pass_info(sg_pass pass)
...please note that the returned info-structs are tied quite closely
to sokol_gfx.h internals, and may change more often than other
public API functions and structs.
--- you can ask at runtime what backend sokol_gfx.h has been compiled
for, or whether the GLES3 backend had to fall back to GLES2 with:
sg_backend sg_query_backend(void)
--- you can query the default resource creation parameters through the functions
sg_buffer_desc sg_query_buffer_defaults(const sg_buffer_desc* desc)
sg_image_desc sg_query_image_defaults(const sg_image_desc* desc)
sg_shader_desc sg_query_shader_defaults(const sg_shader_desc* desc)
sg_pipeline_desc sg_query_pipeline_defaults(const sg_pipeline_desc* desc)
sg_pass_desc sg_query_pass_defaults(const sg_pass_desc* desc)
These functions take a pointer to a desc structure which may contain
zero-initialized items for default values. These zero-init values
will be replaced with their concrete values in the returned desc
struct.
BACKEND-SPECIFIC TOPICS:
========================
--- the GL backends need to know about the internal structure of uniform
blocks, and the texture sampler-name and -type:
typedef struct {
float mvp[16]; // model-view-projection matrix
float offset0[2]; // some 2D vectors
float offset1[2];
float offset2[2];
} params_t;
// uniform block structure and texture image definition in sg_shader_desc:
sg_shader_desc desc = {
// uniform block description (size and internal structure)
.vs.uniform_blocks[0] = {
.size = sizeof(params_t),
.uniforms = {
[0] = { .name="mvp", .type=SG_UNIFORMTYPE_MAT4 },
[1] = { .name="offset0", .type=SG_UNIFORMTYPE_VEC2 },
...
}
},
// one texture on the fragment-shader-stage, GLES2/WebGL needs name and image type
.fs.images[0] = { .name="tex", .type=SG_IMAGETYPE_ARRAY }
...
};
--- the Metal and D3D11 backends only need to know the size of uniform blocks,
not their internal member structure, and they only need to know
the type of a texture sampler, not its name:
sg_shader_desc desc = {
.vs.uniform_blocks[0].size = sizeof(params_t),
.fs.images[0].type = SG_IMAGETYPE_ARRAY,
...
};
--- when creating a shader object, GLES2/WebGL need to know the vertex
attribute names as used in the vertex shader:
sg_shader_desc desc = {
.attrs = {
[0] = { .name="position" },
[1] = { .name="color1" }
}
};
The vertex attribute names provided when creating a shader will be
used later in sg_create_pipeline() for matching the vertex layout
to vertex shader inputs.
--- on D3D11 you need to provide a semantic name and semantic index in the
shader description struct instead (see the D3D11 documentation on
D3D11_INPUT_ELEMENT_DESC for details):
sg_shader_desc desc = {
.attrs = {
[0] = { .sem_name="POSITION", .sem_index=0 }
[1] = { .sem_name="COLOR", .sem_index=1 }
}
};
The provided semantic information will be used later in sg_create_pipeline()
to match the vertex layout to vertex shader inputs.
--- on Metal, GL 3.3 or GLES3/WebGL2, you don't need to provide an attribute
name or semantic name, since vertex attributes can be bound by their slot index
(this is mandatory in Metal, and optional in GL):
sg_pipeline_desc desc = {
.layout = {
.attrs = {
[0] = { .format=SG_VERTEXFORMAT_FLOAT3 },
[1] = { .format=SG_VERTEXFORMAT_FLOAT4 }
}
}
};
WORKING WITH CONTEXTS
=====================
sokol-gfx allows to switch between different rendering contexts and
associate resource objects with contexts. This is useful to
create GL applications that render into multiple windows.
A rendering context keeps track of all resources created while
the context is active. When the context is destroyed, all resources
"belonging to the context" are destroyed as well.
A default context will be created and activated implicitly in
sg_setup(), and destroyed in sg_shutdown(). So for a typical application
which *doesn't* use multiple contexts, nothing changes, and calling
the context functions isn't necessary.
Three functions have been added to work with contexts:
--- sg_context sg_setup_context():
This must be called once after a GL context has been created and
made active.
--- void sg_activate_context(sg_context ctx)
This must be called after making a different GL context active.
Apart from 3D-API-specific actions, the call to sg_activate_context()
will internally call sg_reset_state_cache().
--- void sg_discard_context(sg_context ctx)
This must be called right before a GL context is destroyed and
will destroy all resources associated with the context (that
have been created while the context was active) The GL context must be
active at the time sg_discard_context(sg_context ctx) is called.
Also note that resources (buffers, images, shaders and pipelines) must
only be used or destroyed while the same GL context is active that
was also active while the resource was created (an exception is
resource sharing on GL, such resources can be used while
another context is active, but must still be destroyed under
the same context that was active during creation).
For more information, check out the multiwindow-glfw sample:
https://github.com/floooh/sokol-samples/blob/master/glfw/multiwindow-glfw.c
TRACE HOOKS:
============
sokol_gfx.h optionally allows to install "trace hook" callbacks for
each public API functions. When a public API function is called, and
a trace hook callback has been installed for this function, the
callback will be invoked with the parameters and result of the function.
This is useful for things like debugging- and profiling-tools, or
keeping track of resource creation and destruction.
To use the trace hook feature:
--- Define SOKOL_TRACE_HOOKS before including the implementation.
--- Setup an sg_trace_hooks structure with your callback function
pointers (keep all function pointers you're not interested
in zero-initialized), optionally set the user_data member
in the sg_trace_hooks struct.
--- Install the trace hooks by calling sg_install_trace_hooks(),
the return value of this function is another sg_trace_hooks
struct which contains the previously set of trace hooks.
You should keep this struct around, and call those previous
functions pointers from your own trace callbacks for proper
chaining.
As an example of how trace hooks are used, have a look at the
imgui/sokol_gfx_imgui.h header which implements a realtime
debugging UI for sokol_gfx.h on top of Dear ImGui.
A NOTE ON PORTABLE PACKED VERTEX FORMATS:
=========================================
There are two things to consider when using packed
vertex formats like UBYTE4, SHORT2, etc which need to work
across all backends:
- D3D11 can only convert *normalized* vertex formats to
floating point during vertex fetch, normalized formats
have a trailing 'N', and are "normalized" to a range
-1.0..+1.0 (for the signed formats) or 0.0..1.0 (for the
unsigned formats):
- SG_VERTEXFORMAT_BYTE4N
- SG_VERTEXFORMAT_UBYTE4N
- SG_VERTEXFORMAT_SHORT2N
- SG_VERTEXFORMAT_USHORT2N
- SG_VERTEXFORMAT_SHORT4N
- SG_VERTEXFORMAT_USHORT4N
D3D11 will not convert *non-normalized* vertex formats
to floating point vertex shader inputs, those can
only use the ivecn formats when D3D11 is used
as backend (GL and should Metal can use both formats)
- SG_VERTEXFORMAT_BYTE4,
- SG_VERTEXFORMAT_UBYTE4
- SG_VERTEXFORMAT_SHORT2
- SG_VERTEXFORMAT_SHORT4
- WebGL/GLES2 cannot use integer vertex shader inputs (int or ivecn)
- SG_VERTEXFORMAT_UINT10_N2 is not supported on WebGL/GLES2
So for a vertex input layout which works on all platforms, only use the following
vertex formats, and if needed "expand" the normalized vertex shader
inputs in the vertex shader by multiplying with 127.0, 255.0, 32767.0 or
65535.0:
- SG_VERTEXFORMAT_FLOAT,
- SG_VERTEXFORMAT_FLOAT2,
- SG_VERTEXFORMAT_FLOAT3,
- SG_VERTEXFORMAT_FLOAT4,
- SG_VERTEXFORMAT_BYTE4N,
- SG_VERTEXFORMAT_UBYTE4N,
- SG_VERTEXFORMAT_SHORT2N,
- SG_VERTEXFORMAT_USHORT2N
- SG_VERTEXFORMAT_SHORT4N,
- SG_VERTEXFORMAT_USHORT4N
TODO:
====
- talk about asynchronous resource creation
zlib/libpng license
Copyright (c) 2018 Andre Weissflog
This software is provided 'as-is', without any express or implied warranty.
In no event will the authors be held liable for any damages arising from the
use of this software.
Permission is granted to anyone to use this software for any purpose,
including commercial applications, and to alter it and redistribute it
freely, subject to the following restrictions:
1. The origin of this software must not be misrepresented; you must not
claim that you wrote the original software. If you use this software in a
product, an acknowledgment in the product documentation would be
appreciated but is not required.
2. Altered source versions must be plainly marked as such, and must not
be misrepresented as being the original software.
3. This notice may not be removed or altered from any source
distribution.
*/
#define SOKOL_GFX_INCLUDED (1)
#include <stdint.h>
#include <stdbool.h>
#ifndef SOKOL_API_DECL
#if defined(_WIN32) && defined(SOKOL_DLL) && defined(SOKOL_IMPL)
#define SOKOL_API_DECL __declspec(dllexport)
#elif defined(_WIN32) && defined(SOKOL_DLL)
#define SOKOL_API_DECL __declspec(dllimport)
#else
#define SOKOL_API_DECL extern
#endif
#endif
#ifdef __cplusplus
extern "C" {
#endif
#ifdef _MSC_VER
#pragma warning(push)
#pragma warning(disable:4201) /* nonstandard extension used: nameless struct/union */
#endif
/*
Resource id typedefs:
sg_buffer: vertex- and index-buffers
sg_image: textures and render targets
sg_shader: vertex- and fragment-shaders, uniform blocks
sg_pipeline: associated shader and vertex-layouts, and render states
sg_pass: a bundle of render targets and actions on them
sg_context: a 'context handle' for switching between 3D-API contexts
Instead of pointers, resource creation functions return a 32-bit
number which uniquely identifies the resource object.
The 32-bit resource id is split into a 16-bit pool index in the lower bits,
and a 16-bit 'unique counter' in the upper bits. The index allows fast
pool lookups, and combined with the unique-mask it allows to detect
'dangling accesses' (trying to use an object which no longer exists, and
its pool slot has been reused for a new object)
The resource ids are wrapped into a struct so that the compiler
can complain when the wrong resource type is used.
*/
typedef struct sg_buffer { uint32_t id; } sg_buffer;
typedef struct sg_image { uint32_t id; } sg_image;
typedef struct sg_shader { uint32_t id; } sg_shader;
typedef struct sg_pipeline { uint32_t id; } sg_pipeline;
typedef struct sg_pass { uint32_t id; } sg_pass;
typedef struct sg_context { uint32_t id; } sg_context;
/*
various compile-time constants
FIXME: it may make sense to convert some of those into defines so
that the user code can override them.
*/
enum {
SG_INVALID_ID = 0,
SG_NUM_SHADER_STAGES = 2,
SG_NUM_INFLIGHT_FRAMES = 2,
SG_MAX_COLOR_ATTACHMENTS = 4,
SG_MAX_SHADERSTAGE_BUFFERS = 8,
SG_MAX_SHADERSTAGE_IMAGES = 12,
SG_MAX_SHADERSTAGE_UBS = 4,
SG_MAX_UB_MEMBERS = 16,
SG_MAX_VERTEX_ATTRIBUTES = 16, /* NOTE: actual max vertex attrs can be less on GLES2, see sg_limits! */
SG_MAX_MIPMAPS = 16,
SG_MAX_TEXTUREARRAY_LAYERS = 128
};
/*
sg_backend
The active 3D-API backend, use the function sg_query_backend()
to get the currently active backend.
For returned value corresponds with the compile-time define to select
a backend, with the only exception of SOKOL_GLES3: this may
return SG_BACKEND_GLES2 if the backend has to fallback to GLES2 mode
because GLES3 isn't supported.
*/
typedef enum sg_backend {
SG_BACKEND_GLCORE33,
SG_BACKEND_GLES2,
SG_BACKEND_GLES3,
SG_BACKEND_D3D11,
SG_BACKEND_METAL_IOS,
SG_BACKEND_METAL_MACOS,
SG_BACKEND_METAL_SIMULATOR,
SG_BACKEND_DUMMY,
} sg_backend;
/*
sg_pixel_format
sokol_gfx.h basically uses the same pixel formats as WebGPU, since these
are supported on most newer GPUs. GLES2 and WebGL has a much smaller
subset of available pixel formats. Call sg_query_pixelformat() to check
at runtime if a pixel format supports the desired features.
A pixelformat name consist of three parts:
- components (R, RG, RGB or RGBA)
- bit width per component (8, 16 or 32)
- component data type:
- unsigned normalized (no postfix)
- signed normalized (SN postfix)
- unsigned integer (UI postfix)
- signed integer (SI postfix)
- float (F postfix)
Not all pixel formats can be used for everything, call sg_query_pixelformat()
to inspect the capabilities of a given pixelformat. The function returns
an sg_pixelformat_info struct with the following bool members:
- sample: the pixelformat can be sampled as texture at least with
nearest filtering
- filter: the pixelformat can be samples as texture with linear
filtering
- render: the pixelformat can be used for render targets
- blend: blending is supported when using the pixelformat for
render targets
- msaa: multisample-antiliasing is supported when using the
pixelformat for render targets
- depth: the pixelformat can be used for depth-stencil attachments
When targeting GLES2/WebGL, the only safe formats to use
as texture are SG_PIXELFORMAT_R8 and SG_PIXELFORMAT_RGBA8. For rendering
in GLES2/WebGL, only SG_PIXELFORMAT_RGBA8 is safe. All other formats
must be checked via sg_query_pixelformats().
The default pixel format for texture images is SG_PIXELFORMAT_RGBA8.
The default pixel format for render target images is platform-dependent:
- for Metal and D3D11 it is SG_PIXELFORMAT_BGRA8
- for GL backends it is SG_PIXELFORMAT_RGBA8
This is mainly because of the default framebuffer which is setup outside
of sokol_gfx.h. On some backends, using BGRA for the default frame buffer
allows more efficient frame flips. For your own offscreen-render-targets,
use whatever renderable pixel format is convenient for you.
*/
typedef enum sg_pixel_format {
_SG_PIXELFORMAT_DEFAULT, /* value 0 reserved for default-init */
SG_PIXELFORMAT_NONE,
SG_PIXELFORMAT_R8,
SG_PIXELFORMAT_R8SN,
SG_PIXELFORMAT_R8UI,
SG_PIXELFORMAT_R8SI,
SG_PIXELFORMAT_R16,
SG_PIXELFORMAT_R16SN,
SG_PIXELFORMAT_R16UI,
SG_PIXELFORMAT_R16SI,
SG_PIXELFORMAT_R16F,
SG_PIXELFORMAT_RG8,
SG_PIXELFORMAT_RG8SN,
SG_PIXELFORMAT_RG8UI,
SG_PIXELFORMAT_RG8SI,
SG_PIXELFORMAT_R32UI,
SG_PIXELFORMAT_R32SI,
SG_PIXELFORMAT_R32F,
SG_PIXELFORMAT_RG16,
SG_PIXELFORMAT_RG16SN,
SG_PIXELFORMAT_RG16UI,
SG_PIXELFORMAT_RG16SI,
SG_PIXELFORMAT_RG16F,
SG_PIXELFORMAT_RGBA8,
SG_PIXELFORMAT_RGBA8SN,
SG_PIXELFORMAT_RGBA8UI,
SG_PIXELFORMAT_RGBA8SI,
SG_PIXELFORMAT_BGRA8,
SG_PIXELFORMAT_RGB10A2,
SG_PIXELFORMAT_RG11B10F,
SG_PIXELFORMAT_RG32UI,
SG_PIXELFORMAT_RG32SI,
SG_PIXELFORMAT_RG32F,
SG_PIXELFORMAT_RGBA16,
SG_PIXELFORMAT_RGBA16SN,
SG_PIXELFORMAT_RGBA16UI,
SG_PIXELFORMAT_RGBA16SI,
SG_PIXELFORMAT_RGBA16F,
SG_PIXELFORMAT_RGBA32UI,
SG_PIXELFORMAT_RGBA32SI,
SG_PIXELFORMAT_RGBA32F,
SG_PIXELFORMAT_DEPTH,
SG_PIXELFORMAT_DEPTH_STENCIL,
SG_PIXELFORMAT_BC1_RGBA,
SG_PIXELFORMAT_BC2_RGBA,
SG_PIXELFORMAT_BC3_RGBA,
SG_PIXELFORMAT_BC4_R,
SG_PIXELFORMAT_BC4_RSN,
SG_PIXELFORMAT_BC5_RG,
SG_PIXELFORMAT_BC5_RGSN,
SG_PIXELFORMAT_BC6H_RGBF,
SG_PIXELFORMAT_BC6H_RGBUF,
SG_PIXELFORMAT_BC7_RGBA,
SG_PIXELFORMAT_PVRTC_RGB_2BPP,
SG_PIXELFORMAT_PVRTC_RGB_4BPP,
SG_PIXELFORMAT_PVRTC_RGBA_2BPP,
SG_PIXELFORMAT_PVRTC_RGBA_4BPP,
SG_PIXELFORMAT_ETC2_RGB8,
SG_PIXELFORMAT_ETC2_RGB8A1,
SG_PIXELFORMAT_ETC2_RGBA8,
SG_PIXELFORMAT_ETC2_RG11,
SG_PIXELFORMAT_ETC2_RG11SN,
_SG_PIXELFORMAT_NUM,
_SG_PIXELFORMAT_FORCE_U32 = 0x7FFFFFFF
} sg_pixel_format;
/*
Runtime information about a pixel format, returned
by sg_query_pixelformat().
*/
typedef struct sg_pixelformat_info {
bool sample; /* pixel format can be sampled in shaders */
bool filter; /* pixel format can be sampled with filtering */
bool render; /* pixel format can be used as render target */
bool blend; /* alpha-blending is supported */
bool msaa; /* pixel format can be used as MSAA render target */
bool depth; /* pixel format is a depth format */
} sg_pixelformat_info;
/*
Runtime information about available optional features,
returned by sg_query_features()
*/
typedef struct sg_features {
bool instancing;
bool origin_top_left;
bool multiple_render_targets;
bool msaa_render_targets;
bool imagetype_3d; /* creation of SG_IMAGETYPE_3D images is supported */
bool imagetype_array; /* creation of SG_IMAGETYPE_ARRAY images is supported */
bool image_clamp_to_border; /* border color and clamp-to-border UV-wrap mode is supported */
} sg_features;
/*
Runtime information about resource limits, returned by sg_query_limit()
*/
typedef struct sg_limits {
uint32_t max_image_size_2d; /* max width/height of SG_IMAGETYPE_2D images */
uint32_t max_image_size_cube; /* max width/height of SG_IMAGETYPE_CUBE images */
uint32_t max_image_size_3d; /* max width/height/depth of SG_IMAGETYPE_3D images */
uint32_t max_image_size_array;
uint32_t max_image_array_layers;
uint32_t max_vertex_attrs; /* <= SG_MAX_VERTEX_ATTRIBUTES (only on some GLES2 impls) */
} sg_limits;
/*
sg_resource_state
The current state of a resource in its resource pool.
Resources start in the INITIAL state, which means the
pool slot is unoccupied and can be allocated. When a resource is
created, first an id is allocated, and the resource pool slot
is set to state ALLOC. After allocation, the resource is
initialized, which may result in the VALID or FAILED state. The
reason why allocation and initialization are separate is because
some resource types (e.g. buffers and images) might be asynchronously
initialized by the user application. If a resource which is not
in the VALID state is attempted to be used for rendering, rendering
operations will silently be dropped.
The special INVALID state is returned in sg_query_xxx_state() if no
resource object exists for the provided resource id.
*/
typedef enum sg_resource_state {
SG_RESOURCESTATE_INITIAL,
SG_RESOURCESTATE_ALLOC,
SG_RESOURCESTATE_VALID,
SG_RESOURCESTATE_FAILED,
SG_RESOURCESTATE_INVALID,
_SG_RESOURCESTATE_FORCE_U32 = 0x7FFFFFFF
} sg_resource_state;
/*
sg_usage
A resource usage hint describing the update strategy of
buffers and images. This is used in the sg_buffer_desc.usage
and sg_image_desc.usage members when creating buffers
and images:
SG_USAGE_IMMUTABLE: the resource will never be updated with
new data, instead the data content of the
resource must be provided on creation
SG_USAGE_DYNAMIC: the resource will be updated infrequently
with new data (this could range from "once
after creation", to "quite often but not
every frame")
SG_USAGE_STREAM: the resource will be updated each frame
with new content
The rendering backends use this hint to prevent that the
CPU needs to wait for the GPU when attempting to update
a resource that might be currently accessed by the GPU.
Resource content is updated with the function sg_update_buffer() for
buffer objects, and sg_update_image() for image objects. Only
one update is allowed per frame and resource object. The
application must update all data required for rendering (this
means that the update data can be smaller than the resource size,
if only a part of the overall resource size is used for rendering,
you only need to make sure that the data that *is* used is valid.
The default usage is SG_USAGE_IMMUTABLE.
*/
typedef enum sg_usage {
_SG_USAGE_DEFAULT, /* value 0 reserved for default-init */
SG_USAGE_IMMUTABLE,
SG_USAGE_DYNAMIC,
SG_USAGE_STREAM,
_SG_USAGE_NUM,
_SG_USAGE_FORCE_U32 = 0x7FFFFFFF
} sg_usage;
/*
sg_buffer_type
This indicates whether a buffer contains vertex- or index-data,
used in the sg_buffer_desc.type member when creating a buffer.
The default value is SG_BUFFERTYPE_VERTEXBUFFER.
*/
typedef enum sg_buffer_type {
_SG_BUFFERTYPE_DEFAULT, /* value 0 reserved for default-init */
SG_BUFFERTYPE_VERTEXBUFFER,
SG_BUFFERTYPE_INDEXBUFFER,
_SG_BUFFERTYPE_NUM,
_SG_BUFFERTYPE_FORCE_U32 = 0x7FFFFFFF
} sg_buffer_type;
/*
sg_index_type
Indicates whether indexed rendering (fetching vertex-indices from an
index buffer) is used, and if yes, the index data type (16- or 32-bits).
This is used in the sg_pipeline_desc.index_type member when creating a
pipeline object.
The default index type is SG_INDEXTYPE_NONE.
*/
typedef enum sg_index_type {
_SG_INDEXTYPE_DEFAULT, /* value 0 reserved for default-init */
SG_INDEXTYPE_NONE,
SG_INDEXTYPE_UINT16,
SG_INDEXTYPE_UINT32,
_SG_INDEXTYPE_NUM,
_SG_INDEXTYPE_FORCE_U32 = 0x7FFFFFFF
} sg_index_type;
/*
sg_image_type
Indicates the basic image type (2D-texture, cubemap, 3D-texture
or 2D-array-texture). 3D- and array-textures are not supported
on the GLES2/WebGL backend. The image type is used in the
sg_image_desc.type member when creating an image.
The default image type when creating an image is SG_IMAGETYPE_2D.
*/
typedef enum sg_image_type {
_SG_IMAGETYPE_DEFAULT, /* value 0 reserved for default-init */
SG_IMAGETYPE_2D,
SG_IMAGETYPE_CUBE,
SG_IMAGETYPE_3D,
SG_IMAGETYPE_ARRAY,
_SG_IMAGETYPE_NUM,
_SG_IMAGETYPE_FORCE_U32 = 0x7FFFFFFF
} sg_image_type;
/*
sg_cube_face
The cubemap faces. Use these as indices in the sg_image_desc.content
array.
*/
typedef enum sg_cube_face {
SG_CUBEFACE_POS_X,
SG_CUBEFACE_NEG_X,
SG_CUBEFACE_POS_Y,
SG_CUBEFACE_NEG_Y,
SG_CUBEFACE_POS_Z,
SG_CUBEFACE_NEG_Z,
SG_CUBEFACE_NUM,
_SG_CUBEFACE_FORCE_U32 = 0x7FFFFFFF
} sg_cube_face;
/*
sg_shader_stage
There are 2 shader stages: vertex- and fragment-shader-stage.
Each shader stage consists of:
- one slot for a shader function (provided as source- or byte-code)
- SG_MAX_SHADERSTAGE_UBS slots for uniform blocks
- SG_MAX_SHADERSTAGE_IMAGES slots for images used as textures by
the shader function
*/
typedef enum sg_shader_stage {
SG_SHADERSTAGE_VS,
SG_SHADERSTAGE_FS,
_SG_SHADERSTAGE_FORCE_U32 = 0x7FFFFFFF
} sg_shader_stage;
/*
sg_primitive_type
This is the common subset of 3D primitive types supported across all 3D
APIs. This is used in the sg_pipeline_desc.primitive_type member when
creating a pipeline object.
The default primitive type is SG_PRIMITIVETYPE_TRIANGLES.
*/
typedef enum sg_primitive_type {
_SG_PRIMITIVETYPE_DEFAULT, /* value 0 reserved for default-init */
SG_PRIMITIVETYPE_POINTS,
SG_PRIMITIVETYPE_LINES,
SG_PRIMITIVETYPE_LINE_STRIP,
SG_PRIMITIVETYPE_TRIANGLES,
SG_PRIMITIVETYPE_TRIANGLE_STRIP,
_SG_PRIMITIVETYPE_NUM,
_SG_PRIMITIVETYPE_FORCE_U32 = 0x7FFFFFFF
} sg_primitive_type;
/*
sg_filter
The filtering mode when sampling a texture image. This is
used in the sg_image_desc.min_filter and sg_image_desc.mag_filter
members when creating an image object.
The default filter mode is SG_FILTER_NEAREST.
*/
typedef enum sg_filter {
_SG_FILTER_DEFAULT, /* value 0 reserved for default-init */
SG_FILTER_NEAREST,
SG_FILTER_LINEAR,
SG_FILTER_NEAREST_MIPMAP_NEAREST,
SG_FILTER_NEAREST_MIPMAP_LINEAR,
SG_FILTER_LINEAR_MIPMAP_NEAREST,
SG_FILTER_LINEAR_MIPMAP_LINEAR,
_SG_FILTER_NUM,
_SG_FILTER_FORCE_U32 = 0x7FFFFFFF
} sg_filter;
/*
sg_wrap
The texture coordinates wrapping mode when sampling a texture
image. This is used in the sg_image_desc.wrap_u, .wrap_v
and .wrap_w members when creating an image.
The default wrap mode is SG_WRAP_REPEAT.
NOTE: SG_WRAP_CLAMP_TO_BORDER is not supported on all backends
and platforms. To check for support, call sg_query_features()
and check the "clamp_to_border" boolean in the returned
sg_features struct.
Platforms which don't support SG_WRAP_CLAMP_TO_BORDER will silently fall back
to SG_WRAP_CLAMP_TO_EDGE without a validation error.
Platforms which support clamp-to-border are:
- all desktop GL platforms
- Metal on macOS
- D3D11
Platforms which do not support clamp-to-border:
- GLES2/3 and WebGL/WebGL2
- Metal on iOS
*/
typedef enum sg_wrap {
_SG_WRAP_DEFAULT, /* value 0 reserved for default-init */
SG_WRAP_REPEAT,
SG_WRAP_CLAMP_TO_EDGE,
SG_WRAP_CLAMP_TO_BORDER,
SG_WRAP_MIRRORED_REPEAT,
_SG_WRAP_NUM,
_SG_WRAP_FORCE_U32 = 0x7FFFFFFF
} sg_wrap;
/*
sg_border_color
The border color to use when sampling a texture, and the UV wrap
mode is SG_WRAP_CLAMP_TO_BORDER.
The default border color is SG_BORDERCOLOR_OPAQUE_BLACK
*/
typedef enum sg_border_color {
_SG_BORDERCOLOR_DEFAULT, /* value 0 reserved for default-init */
SG_BORDERCOLOR_TRANSPARENT_BLACK,
SG_BORDERCOLOR_OPAQUE_BLACK,
SG_BORDERCOLOR_OPAQUE_WHITE,
_SG_BORDERCOLOR_NUM,
_SG_BORDERCOLOR_FORCE_U32 = 0x7FFFFFFF
} sg_border_color;
/*
sg_vertex_format
The data type of a vertex component. This is used to describe
the layout of vertex data when creating a pipeline object.
*/
typedef enum sg_vertex_format {
SG_VERTEXFORMAT_INVALID,
SG_VERTEXFORMAT_FLOAT,
SG_VERTEXFORMAT_FLOAT2,
SG_VERTEXFORMAT_FLOAT3,
SG_VERTEXFORMAT_FLOAT4,
SG_VERTEXFORMAT_BYTE4,
SG_VERTEXFORMAT_BYTE4N,
SG_VERTEXFORMAT_UBYTE4,
SG_VERTEXFORMAT_UBYTE4N,
SG_VERTEXFORMAT_SHORT2,
SG_VERTEXFORMAT_SHORT2N,
SG_VERTEXFORMAT_USHORT2N,
SG_VERTEXFORMAT_SHORT4,
SG_VERTEXFORMAT_SHORT4N,
SG_VERTEXFORMAT_USHORT4N,
SG_VERTEXFORMAT_UINT10_N2,
_SG_VERTEXFORMAT_NUM,
_SG_VERTEXFORMAT_FORCE_U32 = 0x7FFFFFFF
} sg_vertex_format;
/*
sg_vertex_step
Defines whether the input pointer of a vertex input stream is advanced
'per vertex' or 'per instance'. The default step-func is
SG_VERTEXSTEP_PER_VERTEX. SG_VERTEXSTEP_PER_INSTANCE is used with
instanced-rendering.
The vertex-step is part of the vertex-layout definition
when creating pipeline objects.
*/
typedef enum sg_vertex_step {
_SG_VERTEXSTEP_DEFAULT, /* value 0 reserved for default-init */
SG_VERTEXSTEP_PER_VERTEX,
SG_VERTEXSTEP_PER_INSTANCE,
_SG_VERTEXSTEP_NUM,
_SG_VERTEXSTEP_FORCE_U32 = 0x7FFFFFFF
} sg_vertex_step;
/*
sg_uniform_type
The data type of a uniform block member. This is used to
describe the internal layout of uniform blocks when creating
a shader object.
*/
typedef enum sg_uniform_type {
SG_UNIFORMTYPE_INVALID,
SG_UNIFORMTYPE_FLOAT,
SG_UNIFORMTYPE_FLOAT2,
SG_UNIFORMTYPE_FLOAT3,
SG_UNIFORMTYPE_FLOAT4,
SG_UNIFORMTYPE_MAT4,
_SG_UNIFORMTYPE_NUM,
_SG_UNIFORMTYPE_FORCE_U32 = 0x7FFFFFFF
} sg_uniform_type;
/*
sg_cull_mode
The face-culling mode, this is used in the
sg_pipeline_desc.rasterizer.cull_mode member when creating a
pipeline object.
The default cull mode is SG_CULLMODE_NONE
*/
typedef enum sg_cull_mode {
_SG_CULLMODE_DEFAULT, /* value 0 reserved for default-init */
SG_CULLMODE_NONE,
SG_CULLMODE_FRONT,
SG_CULLMODE_BACK,
_SG_CULLMODE_NUM,
_SG_CULLMODE_FORCE_U32 = 0x7FFFFFFF
} sg_cull_mode;
/*
sg_face_winding
The vertex-winding rule that determines a front-facing primitive. This
is used in the member sg_pipeline_desc.rasterizer.face_winding
when creating a pipeline object.
The default winding is SG_FACEWINDING_CW (clockwise)
*/
typedef enum sg_face_winding {
_SG_FACEWINDING_DEFAULT, /* value 0 reserved for default-init */
SG_FACEWINDING_CCW,
SG_FACEWINDING_CW,
_SG_FACEWINDING_NUM,
_SG_FACEWINDING_FORCE_U32 = 0x7FFFFFFF
} sg_face_winding;
/*
sg_compare_func
The compare-function for depth- and stencil-ref tests.
This is used when creating pipeline objects in the members:
sg_pipeline_desc
.depth_stencil
.depth_compare_func
.stencil_front.compare_func
.stencil_back.compare_func
The default compare func for depth- and stencil-tests is
SG_COMPAREFUNC_ALWAYS.
*/
typedef enum sg_compare_func {
_SG_COMPAREFUNC_DEFAULT, /* value 0 reserved for default-init */
SG_COMPAREFUNC_NEVER,
SG_COMPAREFUNC_LESS,
SG_COMPAREFUNC_EQUAL,
SG_COMPAREFUNC_LESS_EQUAL,
SG_COMPAREFUNC_GREATER,
SG_COMPAREFUNC_NOT_EQUAL,
SG_COMPAREFUNC_GREATER_EQUAL,
SG_COMPAREFUNC_ALWAYS,
_SG_COMPAREFUNC_NUM,
_SG_COMPAREFUNC_FORCE_U32 = 0x7FFFFFFF
} sg_compare_func;
/*
sg_stencil_op
The operation performed on a currently stored stencil-value when a
comparison test passes or fails. This is used when creating a pipeline
object in the members:
sg_pipeline_desc
.depth_stencil
.stencil_front
.fail_op
.depth_fail_op
.pass_op
.stencil_back
.fail_op
.depth_fail_op
.pass_op
The default value is SG_STENCILOP_KEEP.
*/
typedef enum sg_stencil_op {
_SG_STENCILOP_DEFAULT, /* value 0 reserved for default-init */
SG_STENCILOP_KEEP,
SG_STENCILOP_ZERO,
SG_STENCILOP_REPLACE,
SG_STENCILOP_INCR_CLAMP,
SG_STENCILOP_DECR_CLAMP,
SG_STENCILOP_INVERT,
SG_STENCILOP_INCR_WRAP,
SG_STENCILOP_DECR_WRAP,
_SG_STENCILOP_NUM,
_SG_STENCILOP_FORCE_U32 = 0x7FFFFFFF
} sg_stencil_op;
/*
sg_blend_factor
The source and destination factors in blending operations.
This is used in the following members when creating a pipeline object:
sg_pipeline_desc
.blend
.src_factor_rgb
.dst_factor_rgb
.src_factor_alpha
.dst_factor_alpha
The default value is SG_BLENDFACTOR_ONE for source
factors, and SG_BLENDFACTOR_ZERO for destination factors.
*/
typedef enum sg_blend_factor {
_SG_BLENDFACTOR_DEFAULT, /* value 0 reserved for default-init */
SG_BLENDFACTOR_ZERO,
SG_BLENDFACTOR_ONE,
SG_BLENDFACTOR_SRC_COLOR,
SG_BLENDFACTOR_ONE_MINUS_SRC_COLOR,
SG_BLENDFACTOR_SRC_ALPHA,
SG_BLENDFACTOR_ONE_MINUS_SRC_ALPHA,
SG_BLENDFACTOR_DST_COLOR,
SG_BLENDFACTOR_ONE_MINUS_DST_COLOR,
SG_BLENDFACTOR_DST_ALPHA,
SG_BLENDFACTOR_ONE_MINUS_DST_ALPHA,
SG_BLENDFACTOR_SRC_ALPHA_SATURATED,
SG_BLENDFACTOR_BLEND_COLOR,
SG_BLENDFACTOR_ONE_MINUS_BLEND_COLOR,
SG_BLENDFACTOR_BLEND_ALPHA,
SG_BLENDFACTOR_ONE_MINUS_BLEND_ALPHA,
_SG_BLENDFACTOR_NUM,
_SG_BLENDFACTOR_FORCE_U32 = 0x7FFFFFFF
} sg_blend_factor;
/*
sg_blend_op
Describes how the source and destination values are combined in the
fragment blending operation. It is used in the following members when
creating a pipeline object:
sg_pipeline_desc
.blend
.op_rgb
.op_alpha
The default value is SG_BLENDOP_ADD.
*/
typedef enum sg_blend_op {
_SG_BLENDOP_DEFAULT, /* value 0 reserved for default-init */
SG_BLENDOP_ADD,
SG_BLENDOP_SUBTRACT,
SG_BLENDOP_REVERSE_SUBTRACT,
_SG_BLENDOP_NUM,
_SG_BLENDOP_FORCE_U32 = 0x7FFFFFFF
} sg_blend_op;
/*
sg_color_mask
Selects the color channels when writing a fragment color to the
framebuffer. This is used in the members
sg_pipeline_desc.blend.color_write_mask when creating a pipeline object.
The default colormask is SG_COLORMASK_RGBA (write all colors channels)
*/
typedef enum sg_color_mask {
_SG_COLORMASK_DEFAULT = 0, /* value 0 reserved for default-init */
SG_COLORMASK_NONE = (0x10), /* special value for 'all channels disabled */
SG_COLORMASK_R = (1<<0),
SG_COLORMASK_G = (1<<1),
SG_COLORMASK_B = (1<<2),
SG_COLORMASK_A = (1<<3),
SG_COLORMASK_RGB = 0x7,
SG_COLORMASK_RGBA = 0xF,
_SG_COLORMASK_FORCE_U32 = 0x7FFFFFFF
} sg_color_mask;
/*
sg_action
Defines what action should be performed at the start of a render pass:
SG_ACTION_CLEAR: clear the render target image
SG_ACTION_LOAD: load the previous content of the render target image
SG_ACTION_DONTCARE: leave the render target image content undefined
This is used in the sg_pass_action structure.
The default action for all pass attachments is SG_ACTION_CLEAR, with the
clear color rgba = {0.5f, 0.5f, 0.5f, 1.0f], depth=1.0 and stencil=0.
If you want to override the default behaviour, it is important to not
only set the clear color, but the 'action' field as well (as long as this
is in its _SG_ACTION_DEFAULT, the value fields will be ignored).
*/
typedef enum sg_action {
_SG_ACTION_DEFAULT,
SG_ACTION_CLEAR,
SG_ACTION_LOAD,
SG_ACTION_DONTCARE,
_SG_ACTION_NUM,
_SG_ACTION_FORCE_U32 = 0x7FFFFFFF
} sg_action;
/*
sg_pass_action
The sg_pass_action struct defines the actions to be performed
at the start of a rendering pass in the functions sg_begin_pass()
and sg_begin_default_pass().
A separate action and clear values can be defined for each
color attachment, and for the depth-stencil attachment.
The default clear values are defined by the macros:
- SG_DEFAULT_CLEAR_RED: 0.5f
- SG_DEFAULT_CLEAR_GREEN: 0.5f
- SG_DEFAULT_CLEAR_BLUE: 0.5f
- SG_DEFAULT_CLEAR_ALPHA: 1.0f
- SG_DEFAULT_CLEAR_DEPTH: 1.0f
- SG_DEFAULT_CLEAR_STENCIL: 0
*/
typedef struct sg_color_attachment_action {
sg_action action;
float val[4];
} sg_color_attachment_action;
typedef struct sg_depth_attachment_action {
sg_action action;
float val;
} sg_depth_attachment_action;
typedef struct sg_stencil_attachment_action {
sg_action action;
uint8_t val;
} sg_stencil_attachment_action;
typedef struct sg_pass_action {
uint32_t _start_canary;
sg_color_attachment_action colors[SG_MAX_COLOR_ATTACHMENTS];
sg_depth_attachment_action depth;
sg_stencil_attachment_action stencil;
uint32_t _end_canary;
} sg_pass_action;
/*
sg_bindings
The sg_bindings structure defines the resource binding slots
of the sokol_gfx render pipeline, used as argument to the
sg_apply_bindings() function.
A resource binding struct contains:
- 1..N vertex buffers
- 0..N vertex buffer offsets
- 0..1 index buffers
- 0..1 index buffer offsets
- 0..N vertex shader stage images
- 0..N fragment shader stage images
The max number of vertex buffer and shader stage images
are defined by the SG_MAX_SHADERSTAGE_BUFFERS and
SG_MAX_SHADERSTAGE_IMAGES configuration constants.
The optional buffer offsets can be used to group different chunks
of vertex- and/or index-data into the same buffer objects.
*/
typedef struct sg_bindings {
uint32_t _start_canary;
sg_buffer vertex_buffers[SG_MAX_SHADERSTAGE_BUFFERS];
int vertex_buffer_offsets[SG_MAX_SHADERSTAGE_BUFFERS];
sg_buffer index_buffer;
int index_buffer_offset;
sg_image vs_images[SG_MAX_SHADERSTAGE_IMAGES];
sg_image fs_images[SG_MAX_SHADERSTAGE_IMAGES];
uint32_t _end_canary;
} sg_bindings;
/*
sg_buffer_desc
Creation parameters for sg_buffer objects, used in the
sg_make_buffer() call.
The default configuration is:
.size: 0 (this *must* be set to a valid size in bytes)
.type: SG_BUFFERTYPE_VERTEXBUFFER
.usage: SG_USAGE_IMMUTABLE
.content 0
.label 0 (optional string label for trace hooks)
The dbg_label will be ignored by sokol_gfx.h, it is only useful
when hooking into sg_make_buffer() or sg_init_buffer() via
the sg_install_trace_hook
ADVANCED TOPIC: Injecting native 3D-API buffers:
The following struct members allow to inject your own GL, Metal
or D3D11 buffers into sokol_gfx:
.gl_buffers[SG_NUM_INFLIGHT_FRAMES]
.mtl_buffers[SG_NUM_INFLIGHT_FRAMES]
.d3d11_buffer
You must still provide all other members except the .content member, and
these must match the creation parameters of the native buffers you
provide. For SG_USAGE_IMMUTABLE, only provide a single native 3D-API
buffer, otherwise you need to provide SG_NUM_INFLIGHT_FRAMES buffers
(only for GL and Metal, not D3D11). Providing multiple buffers for GL and
Metal is necessary because sokol_gfx will rotate through them when
calling sg_update_buffer() to prevent lock-stalls.
Note that it is expected that immutable injected buffer have already been
initialized with content, and the .content member must be 0!
Also you need to call sg_reset_state_cache() after calling native 3D-API
functions, and before calling any sokol_gfx function.
*/
typedef struct sg_buffer_desc {
uint32_t _start_canary;
int size;
sg_buffer_type type;
sg_usage usage;
const void* content;
const char* label;
/* GL specific */
uint32_t gl_buffers[SG_NUM_INFLIGHT_FRAMES];
/* Metal specific */
const void* mtl_buffers[SG_NUM_INFLIGHT_FRAMES];
/* D3D11 specific */
const void* d3d11_buffer;
uint32_t _end_canary;
} sg_buffer_desc;
/*
sg_subimage_content
Pointer to and size of a subimage-surface data, this is
used to describe the initial content of immutable-usage images,
or for updating a dynamic- or stream-usage images.
For 3D- or array-textures, one sg_subimage_content item
describes an entire mipmap level consisting of all array- or
3D-slices of the mipmap level. It is only possible to update
an entire mipmap level, not parts of it.
*/
typedef struct sg_subimage_content {
const void* ptr; /* pointer to subimage data */
int size; /* size in bytes of pointed-to subimage data */
} sg_subimage_content;
/*
sg_image_content
Defines the content of an image through a 2D array
of sg_subimage_content structs. The first array dimension
is the cubemap face, and the second array dimension the
mipmap level.
*/
typedef struct sg_image_content {
sg_subimage_content subimage[SG_CUBEFACE_NUM][SG_MAX_MIPMAPS];
} sg_image_content;
/*
sg_image_desc
Creation parameters for sg_image objects, used in the
sg_make_image() call.
The default configuration is:
.type: SG_IMAGETYPE_2D
.render_target: false
.width 0 (must be set to >0)
.height 0 (must be set to >0)
.depth/.layers: 1
.num_mipmaps: 1
.usage: SG_USAGE_IMMUTABLE
.pixel_format: SG_PIXELFORMAT_RGBA8 for textures, backend-dependent
for render targets (RGBA8 or BGRA8)
.sample_count: 1 (only used in render_targets)
.min_filter: SG_FILTER_NEAREST
.mag_filter: SG_FILTER_NEAREST
.wrap_u: SG_WRAP_REPEAT
.wrap_v: SG_WRAP_REPEAT
.wrap_w: SG_WRAP_REPEAT (only SG_IMAGETYPE_3D)
.border_color SG_BORDERCOLOR_OPAQUE_BLACK
.max_anisotropy 1 (must be 1..16)
.min_lod 0.0f
.max_lod FLT_MAX
.content an sg_image_content struct to define the initial content
.label 0 (optional string label for trace hooks)
SG_IMAGETYPE_ARRAY and SG_IMAGETYPE_3D are not supported on
WebGL/GLES2, use sg_query_features().imagetype_array and
sg_query_features().imagetype_3d at runtime to check
if array- and 3D-textures are supported.
Images with usage SG_USAGE_IMMUTABLE must be fully initialized by
providing a valid .content member which points to
initialization data.
ADVANCED TOPIC: Injecting native 3D-API textures:
The following struct members allow to inject your own GL, Metal
or D3D11 textures into sokol_gfx:
.gl_textures[SG_NUM_INFLIGHT_FRAMES]
.mtl_textures[SG_NUM_INFLIGHT_FRAMES]
.d3d11_texture
The same rules apply as for injecting native buffers
(see sg_buffer_desc documentation for more details).
*/
typedef struct sg_image_desc {
uint32_t _start_canary;
sg_image_type type;
bool render_target;
int width;
int height;
union {
int depth;
int layers;
};
int num_mipmaps;
sg_usage usage;
sg_pixel_format pixel_format;
int sample_count;
sg_filter min_filter;
sg_filter mag_filter;
sg_wrap wrap_u;
sg_wrap wrap_v;
sg_wrap wrap_w;
sg_border_color border_color;
uint32_t max_anisotropy;
float min_lod;
float max_lod;
sg_image_content content;
const char* label;
/* GL specific */
uint32_t gl_textures[SG_NUM_INFLIGHT_FRAMES];
/* Metal specific */
const void* mtl_textures[SG_NUM_INFLIGHT_FRAMES];
/* D3D11 specific */
const void* d3d11_texture;
uint32_t _end_canary;
} sg_image_desc;
/*
sg_shader_desc
The structure sg_shader_desc defines all creation parameters
for shader programs, used as input to the sg_make_shader() function:
- reflection information for vertex attributes (vertex shader inputs):
- vertex attribute name (required for GLES2, optional for GLES3 and GL)
- a semantic name and index (required for D3D11)
- for each vertex- and fragment-shader-stage:
- the shader source or bytecode
- an optional entry function name
- reflection info for each uniform block used by the shader stage:
- the size of the uniform block in bytes
- reflection info for each uniform block member (only required for GL backends):
- member name
- member type (SG_UNIFORMTYPE_xxx)
- if the member is an array, the number of array items
- reflection info for the texture images used by the shader stage:
- the image type (SG_IMAGETYPE_xxx)
- the name of the texture sampler (required for GLES2, optional everywhere else)
For all GL backends, shader source-code must be provided. For D3D11 and Metal,
either shader source-code or byte-code can be provided.
For D3D11, if source code is provided, the d3dcompiler_47.dll will be loaded
on demand. If this fails, shader creation will fail.
*/
typedef struct sg_shader_attr_desc {
const char* name; /* GLSL vertex attribute name (only required for GLES2) */
const char* sem_name; /* HLSL semantic name */
int sem_index; /* HLSL semantic index */
} sg_shader_attr_desc;
typedef struct sg_shader_uniform_desc {
const char* name;
sg_uniform_type type;
int array_count;
} sg_shader_uniform_desc;
typedef struct sg_shader_uniform_block_desc {
int size;
sg_shader_uniform_desc uniforms[SG_MAX_UB_MEMBERS];
} sg_shader_uniform_block_desc;
typedef struct sg_shader_image_desc {
const char* name;
sg_image_type type;
} sg_shader_image_desc;
typedef struct sg_shader_stage_desc {
const char* source;
const uint8_t* byte_code;
int byte_code_size;
const char* entry;
sg_shader_uniform_block_desc uniform_blocks[SG_MAX_SHADERSTAGE_UBS];
sg_shader_image_desc images[SG_MAX_SHADERSTAGE_IMAGES];
} sg_shader_stage_desc;
typedef struct sg_shader_desc {
uint32_t _start_canary;
sg_shader_attr_desc attrs[SG_MAX_VERTEX_ATTRIBUTES];
sg_shader_stage_desc vs;
sg_shader_stage_desc fs;
const char* label;
uint32_t _end_canary;
} sg_shader_desc;
/*
sg_pipeline_desc
The sg_pipeline_desc struct defines all creation parameters
for an sg_pipeline object, used as argument to the
sg_make_pipeline() function:
- the vertex layout for all input vertex buffers
- a shader object
- the 3D primitive type (points, lines, triangles, ...)
- the index type (none, 16- or 32-bit)
- depth-stencil state
- alpha-blending state
- rasterizer state
If the vertex data has no gaps between vertex components, you can omit
the .layout.buffers[].stride and layout.attrs[].offset items (leave them
default-initialized to 0), sokol will then compute the offsets and strides
from the vertex component formats (.layout.attrs[].offset). Please note
that ALL vertex attribute offsets must be 0 in order for the the
automatic offset computation to kick in.
The default configuration is as follows:
.layout:
.buffers[]: vertex buffer layouts
.stride: 0 (if no stride is given it will be computed)
.step_func SG_VERTEXSTEP_PER_VERTEX
.step_rate 1
.attrs[]: vertex attribute declarations
.buffer_index 0 the vertex buffer bind slot
.offset 0 (offsets can be omitted if the vertex layout has no gaps)
.format SG_VERTEXFORMAT_INVALID (must be initialized!)
.shader: 0 (must be intilized with a valid sg_shader id!)
.primitive_type: SG_PRIMITIVETYPE_TRIANGLES
.index_type: SG_INDEXTYPE_NONE
.depth_stencil:
.stencil_front, .stencil_back:
.fail_op: SG_STENCILOP_KEEP
.depth_fail_op: SG_STENCILOP_KEEP
.pass_op: SG_STENCILOP_KEEP
.compare_func SG_COMPAREFUNC_ALWAYS
.depth_compare_func: SG_COMPAREFUNC_ALWAYS
.depth_write_enabled: false
.stencil_enabled: false
.stencil_read_mask: 0
.stencil_write_mask: 0
.stencil_ref: 0
.blend:
.enabled: false
.src_factor_rgb: SG_BLENDFACTOR_ONE
.dst_factor_rgb: SG_BLENDFACTOR_ZERO
.op_rgb: SG_BLENDOP_ADD
.src_factor_alpha: SG_BLENDFACTOR_ONE
.dst_factor_alpha: SG_BLENDFACTOR_ZERO
.op_alpha: SG_BLENDOP_ADD
.color_write_mask: SG_COLORMASK_RGBA
.color_attachment_count 1
.color_format SG_PIXELFORMAT_RGBA8
.depth_format SG_PIXELFORMAT_DEPTHSTENCIL
.blend_color: { 0.0f, 0.0f, 0.0f, 0.0f }
.rasterizer:
.alpha_to_coverage_enabled: false
.cull_mode: SG_CULLMODE_NONE
.face_winding: SG_FACEWINDING_CW
.sample_count: 1
.depth_bias: 0.0f
.depth_bias_slope_scale: 0.0f
.depth_bias_clamp: 0.0f
.label 0 (optional string label for trace hooks)
*/
typedef struct sg_buffer_layout_desc {
int stride;
sg_vertex_step step_func;
int step_rate;
} sg_buffer_layout_desc;
typedef struct sg_vertex_attr_desc {
int buffer_index;
int offset;
sg_vertex_format format;
} sg_vertex_attr_desc;
typedef struct sg_layout_desc {
sg_buffer_layout_desc buffers[SG_MAX_SHADERSTAGE_BUFFERS];
sg_vertex_attr_desc attrs[SG_MAX_VERTEX_ATTRIBUTES];
} sg_layout_desc;
typedef struct sg_stencil_state {
sg_stencil_op fail_op;
sg_stencil_op depth_fail_op;
sg_stencil_op pass_op;
sg_compare_func compare_func;
} sg_stencil_state;
typedef struct sg_depth_stencil_state {
sg_stencil_state stencil_front;
sg_stencil_state stencil_back;
sg_compare_func depth_compare_func;
bool depth_write_enabled;
bool stencil_enabled;
uint8_t stencil_read_mask;
uint8_t stencil_write_mask;
uint8_t stencil_ref;
} sg_depth_stencil_state;
typedef struct sg_blend_state {
bool enabled;
sg_blend_factor src_factor_rgb;
sg_blend_factor dst_factor_rgb;
sg_blend_op op_rgb;
sg_blend_factor src_factor_alpha;
sg_blend_factor dst_factor_alpha;
sg_blend_op op_alpha;
uint8_t color_write_mask;
int color_attachment_count;
sg_pixel_format color_format;
sg_pixel_format depth_format;
float blend_color[4];
} sg_blend_state;
typedef struct sg_rasterizer_state {
bool alpha_to_coverage_enabled;
sg_cull_mode cull_mode;
sg_face_winding face_winding;
int sample_count;
float depth_bias;
float depth_bias_slope_scale;
float depth_bias_clamp;
} sg_rasterizer_state;
typedef struct sg_pipeline_desc {
uint32_t _start_canary;
sg_layout_desc layout;
sg_shader shader;
sg_primitive_type primitive_type;
sg_index_type index_type;
sg_depth_stencil_state depth_stencil;
sg_blend_state blend;
sg_rasterizer_state rasterizer;
const char* label;
uint32_t _end_canary;
} sg_pipeline_desc;
/*
sg_pass_desc
Creation parameters for an sg_pass object, used as argument
to the sg_make_pass() function.
A pass object contains 1..4 color-attachments and none, or one,
depth-stencil-attachment. Each attachment consists of
an image, and two additional indices describing
which subimage the pass will render: one mipmap index, and
if the image is a cubemap, array-texture or 3D-texture, the
face-index, array-layer or depth-slice.
Pass images must fulfill the following requirements:
All images must have:
- been created as render target (sg_image_desc.render_target = true)
- the same size
- the same sample count
In addition, all color-attachment images must have the same
pixel format.
*/
typedef struct sg_attachment_desc {
sg_image image;
int mip_level;
union {
int face;
int layer;
int slice;
};
} sg_attachment_desc;
typedef struct sg_pass_desc {
uint32_t _start_canary;
sg_attachment_desc color_attachments[SG_MAX_COLOR_ATTACHMENTS];
sg_attachment_desc depth_stencil_attachment;
const char* label;
uint32_t _end_canary;
} sg_pass_desc;
/*
sg_trace_hooks
Installable callback functions to keep track of the sokol_gfx calls,
this is useful for debugging, or keeping track of resource creation
and destruction.
Trace hooks are installed with sg_install_trace_hooks(), this returns
another sg_trace_hooks struct with the previous set of
trace hook function pointers. These should be invoked by the
new trace hooks to form a proper call chain.
*/
typedef struct sg_trace_hooks {
void* user_data;
void (*reset_state_cache)(void* user_data);
void (*make_buffer)(const sg_buffer_desc* desc, sg_buffer result, void* user_data);
void (*make_image)(const sg_image_desc* desc, sg_image result, void* user_data);
void (*make_shader)(const sg_shader_desc* desc, sg_shader result, void* user_data);
void (*make_pipeline)(const sg_pipeline_desc* desc, sg_pipeline result, void* user_data);
void (*make_pass)(const sg_pass_desc* desc, sg_pass result, void* user_data);
void (*destroy_buffer)(sg_buffer buf, void* user_data);
void (*destroy_image)(sg_image img, void* user_data);
void (*destroy_shader)(sg_shader shd, void* user_data);
void (*destroy_pipeline)(sg_pipeline pip, void* user_data);
void (*destroy_pass)(sg_pass pass, void* user_data);
void (*update_buffer)(sg_buffer buf, const void* data_ptr, int data_size, void* user_data);
void (*update_image)(sg_image img, const sg_image_content* data, void* user_data);
void (*append_buffer)(sg_buffer buf, const void* data_ptr, int data_size, int result, void* user_data);
void (*begin_default_pass)(const sg_pass_action* pass_action, int width, int height, void* user_data);
void (*begin_pass)(sg_pass pass, const sg_pass_action* pass_action, void* user_data);
void (*apply_viewport)(int x, int y, int width, int height, bool origin_top_left, void* user_data);
void (*apply_scissor_rect)(int x, int y, int width, int height, bool origin_top_left, void* user_data);
void (*apply_pipeline)(sg_pipeline pip, void* user_data);
void (*apply_bindings)(const sg_bindings* bindings, void* user_data);
void (*apply_uniforms)(sg_shader_stage stage, int ub_index, const void* data, int num_bytes, void* user_data);
void (*draw)(int base_element, int num_elements, int num_instances, void* user_data);
void (*end_pass)(void* user_data);
void (*commit)(void* user_data);
void (*alloc_buffer)(sg_buffer result, void* user_data);
void (*alloc_image)(sg_image result, void* user_data);
void (*alloc_shader)(sg_shader result, void* user_data);
void (*alloc_pipeline)(sg_pipeline result, void* user_data);
void (*alloc_pass)(sg_pass result, void* user_data);
void (*init_buffer)(sg_buffer buf_id, const sg_buffer_desc* desc, void* user_data);
void (*init_image)(sg_image img_id, const sg_image_desc* desc, void* user_data);
void (*init_shader)(sg_shader shd_id, const sg_shader_desc* desc, void* user_data);
void (*init_pipeline)(sg_pipeline pip_id, const sg_pipeline_desc* desc, void* user_data);
void (*init_pass)(sg_pass pass_id, const sg_pass_desc* desc, void* user_data);
void (*fail_buffer)(sg_buffer buf_id, void* user_data);
void (*fail_image)(sg_image img_id, void* user_data);
void (*fail_shader)(sg_shader shd_id, void* user_data);
void (*fail_pipeline)(sg_pipeline pip_id, void* user_data);
void (*fail_pass)(sg_pass pass_id, void* user_data);
void (*push_debug_group)(const char* name, void* user_data);
void (*pop_debug_group)(void* user_data);
void (*err_buffer_pool_exhausted)(void* user_data);
void (*err_image_pool_exhausted)(void* user_data);
void (*err_shader_pool_exhausted)(void* user_data);
void (*err_pipeline_pool_exhausted)(void* user_data);
void (*err_pass_pool_exhausted)(void* user_data);
void (*err_context_mismatch)(void* user_data);
void (*err_pass_invalid)(void* user_data);
void (*err_draw_invalid)(void* user_data);
void (*err_bindings_invalid)(void* user_data);
} sg_trace_hooks;
/*
sg_buffer_info
sg_image_info
sg_shader_info
sg_pipeline_info
sg_pass_info
These structs contain various internal resource attributes which
might be useful for debug-inspection. Please don't rely on the
actual content of those structs too much, as they are quite closely
tied to sokol_gfx.h internals and may change more frequently than
the other public API elements.
The *_info structs are used as the return values of the following functions:
sg_query_buffer_info()
sg_query_image_info()
sg_query_shader_info()
sg_query_pipeline_info()
sg_query_pass_info()
*/
typedef struct sg_slot_info {
sg_resource_state state; /* the current state of this resource slot */
uint32_t res_id; /* type-neutral resource if (e.g. sg_buffer.id) */
uint32_t ctx_id; /* the context this resource belongs to */
} sg_slot_info;
typedef struct sg_buffer_info {
sg_slot_info slot; /* resource pool slot info */
uint32_t update_frame_index; /* frame index of last sg_update_buffer() */
uint32_t append_frame_index; /* frame index of last sg_append_buffer() */
int append_pos; /* current position in buffer for sg_append_buffer() */
bool append_overflow; /* is buffer in overflow state (due to sg_append_buffer) */
int num_slots; /* number of renaming-slots for dynamically updated buffers */
int active_slot; /* currently active write-slot for dynamically updated buffers */
} sg_buffer_info;
typedef struct sg_image_info {
sg_slot_info slot; /* resource pool slot info */
uint32_t upd_frame_index; /* frame index of last sg_update_image() */
int num_slots; /* number of renaming-slots for dynamically updated images */
int active_slot; /* currently active write-slot for dynamically updated images */
} sg_image_info;
typedef struct sg_shader_info {
sg_slot_info slot; /* resoure pool slot info */
} sg_shader_info;
typedef struct sg_pipeline_info {
sg_slot_info slot; /* resource pool slot info */
} sg_pipeline_info;
typedef struct sg_pass_info {
sg_slot_info slot; /* resource pool slot info */
} sg_pass_info;
/*
sg_desc
The sg_desc struct contains configuration values for sokol_gfx,
it is used as parameter to the sg_setup() call.
The default configuration is:
.buffer_pool_size: 128
.image_pool_size: 128
.shader_pool_size: 32
.pipeline_pool_size: 64
.pass_pool_size: 16
.context_pool_size: 16
GL specific:
.gl_force_gles2
if this is true the GL backend will act in "GLES2 fallback mode" even
when compiled with SOKOL_GLES3, this is useful to fall back
to traditional WebGL if a browser doesn't support a WebGL2 context
Metal specific:
(NOTE: All Objective-C object references are transferred through
a bridged (const void*) to sokol_gfx, which will use a unretained
bridged cast (__bridged id<xxx>) to retrieve the Objective-C
references back. Since the bridge cast is unretained, the caller
must hold a strong reference to the Objective-C object for the
duration of the sokol_gfx call!
.mtl_device
a pointer to the MTLDevice object
.mtl_renderpass_descriptor_cb
a C callback function to obtain the MTLRenderPassDescriptor for the
current frame when rendering to the default framebuffer, will be called
in sg_begin_default_pass()
.mtl_drawable_cb
a C callback function to obtain a MTLDrawable for the current
frame when rendering to the default framebuffer, will be called in
sg_end_pass() of the default pass
.mtl_global_uniform_buffer_size
the size of the global uniform buffer in bytes, this must be big
enough to hold all uniform block updates for a single frame,
the default value is 4 MByte (4 * 1024 * 1024)
.mtl_sampler_cache_size
the number of slots in the sampler cache, the Metal backend
will share texture samplers with the same state in this
cache, the default value is 64
D3D11 specific:
.d3d11_device
a pointer to the ID3D11Device object, this must have been created
before sg_setup() is called
.d3d11_device_context
a pointer to the ID3D11DeviceContext object
.d3d11_render_target_view_cb
a C callback function to obtain a pointer to the current
ID3D11RenderTargetView object of the default framebuffer,
this function will be called in sg_begin_pass() when rendering
to the default framebuffer
.d3d11_depth_stencil_view_cb
a C callback function to obtain a pointer to the current
ID3D11DepthStencilView object of the default framebuffer,
this function will be called in sg_begin_pass() when rendering
to the default framebuffer
*/
typedef struct sg_desc {
uint32_t _start_canary;
int buffer_pool_size;
int image_pool_size;
int shader_pool_size;
int pipeline_pool_size;
int pass_pool_size;
int context_pool_size;
/* GL specific */
bool gl_force_gles2;
/* Metal-specific */
const void* mtl_device;
const void* (*mtl_renderpass_descriptor_cb)(void);
const void* (*mtl_drawable_cb)(void);
int mtl_global_uniform_buffer_size;
int mtl_sampler_cache_size;
/* D3D11-specific */
const void* d3d11_device;
const void* d3d11_device_context;
const void* (*d3d11_render_target_view_cb)(void);
const void* (*d3d11_depth_stencil_view_cb)(void);
uint32_t _end_canary;
} sg_desc;
/* setup and misc functions */
SOKOL_API_DECL void sg_setup(const sg_desc* desc);
SOKOL_API_DECL void sg_shutdown(void);
SOKOL_API_DECL bool sg_isvalid(void);
SOKOL_API_DECL void sg_reset_state_cache(void);
SOKOL_API_DECL sg_trace_hooks sg_install_trace_hooks(const sg_trace_hooks* trace_hooks);
SOKOL_API_DECL void sg_push_debug_group(const char* name);
SOKOL_API_DECL void sg_pop_debug_group(void);
/* resource creation, destruction and updating */
SOKOL_API_DECL sg_buffer sg_make_buffer(const sg_buffer_desc* desc);
SOKOL_API_DECL sg_image sg_make_image(const sg_image_desc* desc);
SOKOL_API_DECL sg_shader sg_make_shader(const sg_shader_desc* desc);
SOKOL_API_DECL sg_pipeline sg_make_pipeline(const sg_pipeline_desc* desc);
SOKOL_API_DECL sg_pass sg_make_pass(const sg_pass_desc* desc);
SOKOL_API_DECL void sg_destroy_buffer(sg_buffer buf);
SOKOL_API_DECL void sg_destroy_image(sg_image img);
SOKOL_API_DECL void sg_destroy_shader(sg_shader shd);
SOKOL_API_DECL void sg_destroy_pipeline(sg_pipeline pip);
SOKOL_API_DECL void sg_destroy_pass(sg_pass pass);
SOKOL_API_DECL void sg_update_buffer(sg_buffer buf, const void* data_ptr, int data_size);
SOKOL_API_DECL void sg_update_image(sg_image img, const sg_image_content* data);
SOKOL_API_DECL int sg_append_buffer(sg_buffer buf, const void* data_ptr, int data_size);
SOKOL_API_DECL bool sg_query_buffer_overflow(sg_buffer buf);
/* rendering functions */
SOKOL_API_DECL void sg_begin_default_pass(const sg_pass_action* pass_action, int width, int height);
SOKOL_API_DECL void sg_begin_pass(sg_pass pass, const sg_pass_action* pass_action);
SOKOL_API_DECL void sg_apply_viewport(int x, int y, int width, int height, bool origin_top_left);
SOKOL_API_DECL void sg_apply_scissor_rect(int x, int y, int width, int height, bool origin_top_left);
SOKOL_API_DECL void sg_apply_pipeline(sg_pipeline pip);
SOKOL_API_DECL void sg_apply_bindings(const sg_bindings* bindings);
SOKOL_API_DECL void sg_apply_uniforms(sg_shader_stage stage, int ub_index, const void* data, int num_bytes);
SOKOL_API_DECL void sg_draw(int base_element, int num_elements, int num_instances);
SOKOL_API_DECL void sg_end_pass(void);
SOKOL_API_DECL void sg_commit(void);
/* getting information */
SOKOL_API_DECL sg_desc sg_query_desc(void);
SOKOL_API_DECL sg_backend sg_query_backend(void);
SOKOL_API_DECL sg_features sg_query_features(void);
SOKOL_API_DECL sg_limits sg_query_limits(void);
SOKOL_API_DECL sg_pixelformat_info sg_query_pixelformat(sg_pixel_format fmt);
/* get current state of a resource (INITIAL, ALLOC, VALID, FAILED, INVALID) */
SOKOL_API_DECL sg_resource_state sg_query_buffer_state(sg_buffer buf);
SOKOL_API_DECL sg_resource_state sg_query_image_state(sg_image img);
SOKOL_API_DECL sg_resource_state sg_query_shader_state(sg_shader shd);
SOKOL_API_DECL sg_resource_state sg_query_pipeline_state(sg_pipeline pip);
SOKOL_API_DECL sg_resource_state sg_query_pass_state(sg_pass pass);
/* get runtime information about a resource */
SOKOL_API_DECL sg_buffer_info sg_query_buffer_info(sg_buffer buf);
SOKOL_API_DECL sg_image_info sg_query_image_info(sg_image img);
SOKOL_API_DECL sg_shader_info sg_query_shader_info(sg_shader shd);
SOKOL_API_DECL sg_pipeline_info sg_query_pipeline_info(sg_pipeline pip);
SOKOL_API_DECL sg_pass_info sg_query_pass_info(sg_pass pass);
/* get resource creation desc struct with their default values replaced */
SOKOL_API_DECL sg_buffer_desc sg_query_buffer_defaults(const sg_buffer_desc* desc);
SOKOL_API_DECL sg_image_desc sg_query_image_defaults(const sg_image_desc* desc);
SOKOL_API_DECL sg_shader_desc sg_query_shader_defaults(const sg_shader_desc* desc);
SOKOL_API_DECL sg_pipeline_desc sg_query_pipeline_defaults(const sg_pipeline_desc* desc);
SOKOL_API_DECL sg_pass_desc sg_query_pass_defaults(const sg_pass_desc* desc);
/* separate resource allocation and initialization (for async setup) */
SOKOL_API_DECL sg_buffer sg_alloc_buffer(void);
SOKOL_API_DECL sg_image sg_alloc_image(void);
SOKOL_API_DECL sg_shader sg_alloc_shader(void);
SOKOL_API_DECL sg_pipeline sg_alloc_pipeline(void);
SOKOL_API_DECL sg_pass sg_alloc_pass(void);
SOKOL_API_DECL void sg_init_buffer(sg_buffer buf_id, const sg_buffer_desc* desc);
SOKOL_API_DECL void sg_init_image(sg_image img_id, const sg_image_desc* desc);
SOKOL_API_DECL void sg_init_shader(sg_shader shd_id, const sg_shader_desc* desc);
SOKOL_API_DECL void sg_init_pipeline(sg_pipeline pip_id, const sg_pipeline_desc* desc);
SOKOL_API_DECL void sg_init_pass(sg_pass pass_id, const sg_pass_desc* desc);
SOKOL_API_DECL void sg_fail_buffer(sg_buffer buf_id);
SOKOL_API_DECL void sg_fail_image(sg_image img_id);
SOKOL_API_DECL void sg_fail_shader(sg_shader shd_id);
SOKOL_API_DECL void sg_fail_pipeline(sg_pipeline pip_id);
SOKOL_API_DECL void sg_fail_pass(sg_pass pass_id);
/* rendering contexts (optional) */
SOKOL_API_DECL sg_context sg_setup_context(void);
SOKOL_API_DECL void sg_activate_context(sg_context ctx_id);
SOKOL_API_DECL void sg_discard_context(sg_context ctx_id);
#ifdef _MSC_VER
#pragma warning(pop)
#endif
#ifdef __cplusplus
} /* extern "C" */
#endif
#endif // SOKOL_GFX_INCLUDED
/*--- IMPLEMENTATION ---------------------------------------------------------*/
#ifdef SOKOL_IMPL
#define SOKOL_GFX_IMPL_INCLUDED (1)
#if !(defined(SOKOL_GLCORE33)||defined(SOKOL_GLES2)||defined(SOKOL_GLES3)||defined(SOKOL_D3D11)||defined(SOKOL_METAL)||defined(SOKOL_DUMMY_BACKEND))
#error "Please select a backend with SOKOL_GLCORE33, SOKOL_GLES2, SOKOL_GLES3, SOKOL_D3D11, SOKOL_METAL or SOKOL_DUMMY_BACKEND"
#endif
#include <string.h> /* memset */
#include <float.h> /* FLT_MAX */
#ifndef SOKOL_API_IMPL
#define SOKOL_API_IMPL
#endif
#ifndef SOKOL_DEBUG
#ifndef NDEBUG
#define SOKOL_DEBUG (1)
#endif
#endif
#ifndef SOKOL_ASSERT
#include <assert.h>
#define SOKOL_ASSERT(c) assert(c)
#endif
#ifndef SOKOL_VALIDATE_BEGIN
#define SOKOL_VALIDATE_BEGIN() _sg_validate_begin()
#endif
#ifndef SOKOL_VALIDATE
#define SOKOL_VALIDATE(cond, err) _sg_validate((cond), err)
#endif
#ifndef SOKOL_VALIDATE_END
#define SOKOL_VALIDATE_END() _sg_validate_end()
#endif
#ifndef SOKOL_UNREACHABLE
#define SOKOL_UNREACHABLE SOKOL_ASSERT(false)
#endif
#ifndef SOKOL_MALLOC
#include <stdlib.h>
#define SOKOL_MALLOC(s) malloc(s)
#define SOKOL_FREE(p) free(p)
#endif
#ifndef SOKOL_LOG
#ifdef SOKOL_DEBUG
#include <stdio.h>
#define SOKOL_LOG(s) { SOKOL_ASSERT(s); puts(s); }
#else
#define SOKOL_LOG(s)
#endif
#endif
#ifndef _SOKOL_PRIVATE
#if defined(__GNUC__)
#define _SOKOL_PRIVATE __attribute__((unused)) static
#else
#define _SOKOL_PRIVATE static
#endif
#endif
#ifndef _SOKOL_UNUSED
#define _SOKOL_UNUSED(x) (void)(x)
#endif
#if defined(SOKOL_TRACE_HOOKS)
#define _SG_TRACE_ARGS(fn, ...) if (_sg.hooks.fn) { _sg.hooks.fn(__VA_ARGS__, _sg.hooks.user_data); }
#define _SG_TRACE_NOARGS(fn) if (_sg.hooks.fn) { _sg.hooks.fn(_sg.hooks.user_data); }
#else
#define _SG_TRACE_ARGS(fn, ...)
#define _SG_TRACE_NOARGS(fn)
#endif
/* default clear values */
#ifndef SG_DEFAULT_CLEAR_RED
#define SG_DEFAULT_CLEAR_RED (0.5f)
#endif
#ifndef SG_DEFAULT_CLEAR_GREEN
#define SG_DEFAULT_CLEAR_GREEN (0.5f)
#endif
#ifndef SG_DEFAULT_CLEAR_BLUE
#define SG_DEFAULT_CLEAR_BLUE (0.5f)
#endif
#ifndef SG_DEFAULT_CLEAR_ALPHA
#define SG_DEFAULT_CLEAR_ALPHA (1.0f)
#endif
#ifndef SG_DEFAULT_CLEAR_DEPTH
#define SG_DEFAULT_CLEAR_DEPTH (1.0f)
#endif
#ifndef SG_DEFAULT_CLEAR_STENCIL
#define SG_DEFAULT_CLEAR_STENCIL (0)
#endif
#ifdef _MSC_VER
#pragma warning(push)
#pragma warning(disable:4201) /* nonstandard extension used: nameless struct/union */
#pragma warning(disable:4115) /* named type definition in parentheses */
#pragma warning(disable:4505) /* unreferenced local function has been removed */
#endif
#if defined(SOKOL_GLCORE33) || defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
#ifndef GL_UNSIGNED_INT_2_10_10_10_REV
#define GL_UNSIGNED_INT_2_10_10_10_REV 0x8368
#endif
#ifndef GL_UNSIGNED_INT_24_8
#define GL_UNSIGNED_INT_24_8 0x84FA
#endif
#ifndef GL_TEXTURE_MAX_ANISOTROPY_EXT
#define GL_TEXTURE_MAX_ANISOTROPY_EXT 0x84FE
#endif
#ifndef GL_MAX_TEXTURE_MAX_ANISOTROPY_EXT
#define GL_MAX_TEXTURE_MAX_ANISOTROPY_EXT 0x84FF
#endif
#ifndef GL_COMPRESSED_RGBA_S3TC_DXT1_EXT
#define GL_COMPRESSED_RGBA_S3TC_DXT1_EXT 0x83F1
#endif
#ifndef GL_COMPRESSED_RGBA_S3TC_DXT3_EXT
#define GL_COMPRESSED_RGBA_S3TC_DXT3_EXT 0x83F2
#endif
#ifndef GL_COMPRESSED_RGBA_S3TC_DXT5_EXT
#define GL_COMPRESSED_RGBA_S3TC_DXT5_EXT 0x83F3
#endif
#ifndef GL_COMPRESSED_RED_RGTC1
#define GL_COMPRESSED_RED_RGTC1 0x8DBB
#endif
#ifndef GL_COMPRESSED_SIGNED_RED_RGTC1
#define GL_COMPRESSED_SIGNED_RED_RGTC1 0x8DBC
#endif
#ifndef GL_COMPRESSED_RED_GREEN_RGTC2
#define GL_COMPRESSED_RED_GREEN_RGTC2 0x8DBD
#endif
#ifndef GL_COMPRESSED_SIGNED_RED_GREEN_RGTC2
#define GL_COMPRESSED_SIGNED_RED_GREEN_RGTC2 0x8DBE
#endif
#ifndef GL_COMPRESSED_RGBA_BPTC_UNORM_ARB
#define GL_COMPRESSED_RGBA_BPTC_UNORM_ARB 0x8E8C
#endif
#ifndef GL_COMPRESSED_SRGB_ALPHA_BPTC_UNORM_ARB
#define GL_COMPRESSED_SRGB_ALPHA_BPTC_UNORM_ARB 0x8E8D
#endif
#ifndef GL_COMPRESSED_RGB_BPTC_SIGNED_FLOAT_ARB
#define GL_COMPRESSED_RGB_BPTC_SIGNED_FLOAT_ARB 0x8E8E
#endif
#ifndef GL_COMPRESSED_RGB_BPTC_UNSIGNED_FLOAT_ARB
#define GL_COMPRESSED_RGB_BPTC_UNSIGNED_FLOAT_ARB 0x8E8F
#endif
#ifndef GL_COMPRESSED_RGB_PVRTC_2BPPV1_IMG
#define GL_COMPRESSED_RGB_PVRTC_2BPPV1_IMG 0x8C01
#endif
#ifndef GL_COMPRESSED_RGB_PVRTC_4BPPV1_IMG
#define GL_COMPRESSED_RGB_PVRTC_4BPPV1_IMG 0x8C00
#endif
#ifndef GL_COMPRESSED_RGBA_PVRTC_2BPPV1_IMG
#define GL_COMPRESSED_RGBA_PVRTC_2BPPV1_IMG 0x8C03
#endif
#ifndef GL_COMPRESSED_RGBA_PVRTC_4BPPV1_IMG
#define GL_COMPRESSED_RGBA_PVRTC_4BPPV1_IMG 0x8C02
#endif
#ifndef GL_COMPRESSED_RGB8_ETC2
#define GL_COMPRESSED_RGB8_ETC2 0x9274
#endif
#ifndef GL_COMPRESSED_RGBA8_ETC2_EAC
#define GL_COMPRESSED_RGBA8_ETC2_EAC 0x9278
#endif
#ifndef GL_COMPRESSED_RGB8_PUNCHTHROUGH_ALPHA1_ETC2
#define GL_COMPRESSED_RGB8_PUNCHTHROUGH_ALPHA1_ETC2 0x9276
#endif
#ifndef GL_COMPRESSED_RG11_EAC
#define GL_COMPRESSED_RG11_EAC 0x9272
#endif
#ifndef GL_COMPRESSED_SIGNED_RG11_EAC
#define GL_COMPRESSED_SIGNED_RG11_EAC 0x9273
#endif
#ifndef GL_DEPTH24_STENCIL8
#define GL_DEPTH24_STENCIL8 0x88F0
#endif
#ifndef GL_HALF_FLOAT
#define GL_HALF_FLOAT 0x140B
#endif
#ifndef GL_DEPTH_STENCIL
#define GL_DEPTH_STENCIL 0x84F9
#endif
#ifndef GL_LUMINANCE
#define GL_LUMINANCE 0x1909
#endif
#ifdef SOKOL_GLES2
# ifdef GL_ANGLE_instanced_arrays
# define SOKOL_INSTANCING_ENABLED
# define glDrawArraysInstanced(mode, first, count, instancecount) glDrawArraysInstancedANGLE(mode, first, count, instancecount)
# define glDrawElementsInstanced(mode, count, type, indices, instancecount) glDrawElementsInstancedANGLE(mode, count, type, indices, instancecount)
# define glVertexAttribDivisor(index, divisor) glVertexAttribDivisorANGLE(index, divisor)
# elif defined(GL_EXT_draw_instanced) && defined(GL_EXT_instanced_arrays)
# define SOKOL_INSTANCING_ENABLED
# define glDrawArraysInstanced(mode, first, count, instancecount) glDrawArraysInstancedEXT(mode, first, count, instancecount)
# define glDrawElementsInstanced(mode, count, type, indices, instancecount) glDrawElementsInstancedEXT(mode, count, type, indices, instancecount)
# define glVertexAttribDivisor(index, divisor) glVertexAttribDivisorEXT(index, divisor)
# else
# define SOKOL_GLES2_INSTANCING_ERROR "Select GL_ANGLE_instanced_arrays or (GL_EXT_draw_instanced & GL_EXT_instanced_arrays) to enable instancing in GLES2"
# define glDrawArraysInstanced(mode, first, count, instancecount) SOKOL_ASSERT(0 && SOKOL_GLES2_INSTANCING_ERROR)
# define glDrawElementsInstanced(mode, count, type, indices, instancecount) SOKOL_ASSERT(0 && SOKOL_GLES2_INSTANCING_ERROR)
# define glVertexAttribDivisor(index, divisor) SOKOL_ASSERT(0 && SOKOL_GLES2_INSTANCING_ERROR)
# endif
#else
# define SOKOL_INSTANCING_ENABLED
#endif
#define _SG_GL_CHECK_ERROR() { SOKOL_ASSERT(glGetError() == GL_NO_ERROR); }
#elif defined(SOKOL_D3D11)
#ifndef D3D11_NO_HELPERS
#define D3D11_NO_HELPERS
#endif
#ifndef CINTERFACE
#define CINTERFACE
#endif
#ifndef COBJMACROS
#define COBJMACROS
#endif
#ifndef WIN32_LEAN_AND_MEAN
#define WIN32_LEAN_AND_MEAN
#endif
#include <windows.h>
#include <d3d11.h>
#include <d3dcompiler.h>
#if (defined(WINAPI_FAMILY_PARTITION) && !WINAPI_FAMILY_PARTITION(WINAPI_PARTITION_DESKTOP))
#pragma comment (lib, "WindowsApp.lib")
#else
#pragma comment (lib, "user32.lib")
#pragma comment (lib, "dxgi.lib")
#pragma comment (lib, "d3d11.lib")
#pragma comment (lib, "dxguid.lib")
#endif
#elif defined(SOKOL_METAL)
#if !__has_feature(objc_arc)
#error "Please enable ARC when using the Metal backend"
#endif
#include <TargetConditionals.h>
#import <Metal/Metal.h>
#if defined(TARGET_OS_IPHONE) && !TARGET_OS_IPHONE
#define _SG_TARGET_MACOS (1)
#else
#define _SG_TARGET_IOS (1)
#if defined(TARGET_IPHONE_SIMULATOR) && TARGET_IPHONE_SIMULATOR
#define _SG_TARGET_IOS_SIMULATOR (1)
#endif
#endif
#endif
/*=== PRIVATE DECLS ==========================================================*/
/* resource pool slots */
typedef struct {
uint32_t id;
uint32_t ctx_id;
sg_resource_state state;
} _sg_slot_t;
/* constants */
enum {
_SG_STRING_SIZE = 16,
_SG_SLOT_SHIFT = 16,
_SG_SLOT_MASK = (1<<_SG_SLOT_SHIFT)-1,
_SG_MAX_POOL_SIZE = (1<<_SG_SLOT_SHIFT),
_SG_DEFAULT_BUFFER_POOL_SIZE = 128,
_SG_DEFAULT_IMAGE_POOL_SIZE = 128,
_SG_DEFAULT_SHADER_POOL_SIZE = 32,
_SG_DEFAULT_PIPELINE_POOL_SIZE = 64,
_SG_DEFAULT_PASS_POOL_SIZE = 16,
_SG_DEFAULT_CONTEXT_POOL_SIZE = 16,
_SG_MTL_DEFAULT_UB_SIZE = 4 * 1024 * 1024,
_SG_MTL_DEFAULT_SAMPLER_CACHE_CAPACITY = 64,
};
/* fixed-size string */
typedef struct {
char buf[_SG_STRING_SIZE];
} _sg_str_t;
/* helper macros */
#define _sg_def(val, def) (((val) == 0) ? (def) : (val))
#define _sg_def_flt(val, def) (((val) == 0.0f) ? (def) : (val))
#define _sg_min(a,b) ((a<b)?a:b)
#define _sg_max(a,b) ((a>b)?a:b)
#define _sg_clamp(v,v0,v1) ((v<v0)?(v0):((v>v1)?(v1):(v)))
#define _sg_fequal(val,cmp,delta) (((val-cmp)> -delta)&&((val-cmp)<delta))
/*=== DUMMY BACKEND DECLARATIONS =============================================*/
#if defined(SOKOL_DUMMY_BACKEND)
typedef struct {
_sg_slot_t slot;
int size;
int append_pos;
bool append_overflow;
sg_buffer_type type;
sg_usage usage;
uint32_t update_frame_index;
uint32_t append_frame_index;
int num_slots;
int active_slot;
} _sg_buffer_t;
typedef struct {
_sg_slot_t slot;
sg_image_type type;
bool render_target;
int width;
int height;
int depth;
int num_mipmaps;
sg_usage usage;
sg_pixel_format pixel_format;
int sample_count;
sg_filter min_filter;
sg_filter mag_filter;
sg_wrap wrap_u;
sg_wrap wrap_v;
sg_wrap wrap_w;
uint32_t max_anisotropy;
uint32_t upd_frame_index;
int num_slots;
int active_slot;
} _sg_image_t;
typedef struct {
int size;
} _sg_uniform_block_t;
typedef struct {
sg_image_type type;
} _sg_shader_image_t;
typedef struct {
int num_uniform_blocks;
int num_images;
_sg_uniform_block_t uniform_blocks[SG_MAX_SHADERSTAGE_UBS];
_sg_shader_image_t images[SG_MAX_SHADERSTAGE_IMAGES];
} _sg_shader_stage_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_stage_t stage[SG_NUM_SHADER_STAGES];
} _sg_shader_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_t* shader;
sg_shader shader_id;
bool vertex_layout_valid[SG_MAX_SHADERSTAGE_BUFFERS];
int color_attachment_count;
sg_pixel_format color_format;
sg_pixel_format depth_format;
int sample_count;
float depth_bias;
float depth_bias_slope_scale;
float depth_bias_clamp;
sg_index_type index_type;
float blend_color[4];
} _sg_pipeline_t;
typedef struct {
_sg_image_t* image;
sg_image image_id;
int mip_level;
int slice;
} _sg_attachment_t;
typedef struct {
_sg_slot_t slot;
int num_color_atts;
_sg_attachment_t color_atts[SG_MAX_COLOR_ATTACHMENTS];
_sg_attachment_t ds_att;
} _sg_pass_t;
typedef struct {
_sg_slot_t slot;
} _sg_context_t;
/*== GL BACKEND DECLARATIONS =================================================*/
#elif defined(SOKOL_GLCORE33) || defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
typedef struct {
_sg_slot_t slot;
int size;
int append_pos;
bool append_overflow;
sg_buffer_type type;
sg_usage usage;
uint32_t update_frame_index;
uint32_t append_frame_index;
int num_slots;
int active_slot;
GLuint gl_buf[SG_NUM_INFLIGHT_FRAMES];
bool ext_buffers; /* if true, external buffers were injected with sg_buffer_desc.gl_buffers */
} _sg_buffer_t;
typedef struct {
_sg_slot_t slot;
sg_image_type type;
bool render_target;
int width;
int height;
int depth;
int num_mipmaps;
sg_usage usage;
sg_pixel_format pixel_format;
int sample_count;
sg_filter min_filter;
sg_filter mag_filter;
sg_wrap wrap_u;
sg_wrap wrap_v;
sg_wrap wrap_w;
sg_border_color border_color;
uint32_t max_anisotropy;
GLenum gl_target;
GLuint gl_depth_render_buffer;
GLuint gl_msaa_render_buffer;
uint32_t upd_frame_index;
int num_slots;
int active_slot;
GLuint gl_tex[SG_NUM_INFLIGHT_FRAMES];
bool ext_textures; /* if true, external textures were injected with sg_image_desc.gl_textures */
} _sg_image_t;
typedef struct {
GLint gl_loc;
sg_uniform_type type;
uint8_t count;
uint16_t offset;
} _sg_uniform_t;
typedef struct {
int size;
int num_uniforms;
_sg_uniform_t uniforms[SG_MAX_UB_MEMBERS];
} _sg_uniform_block_t;
typedef struct {
sg_image_type type;
GLint gl_loc;
int gl_tex_slot;
} _sg_shader_image_t;
typedef struct {
_sg_str_t name;
} _sg_shader_attr_t;
typedef struct {
int num_uniform_blocks;
int num_images;
_sg_uniform_block_t uniform_blocks[SG_MAX_SHADERSTAGE_UBS];
_sg_shader_image_t images[SG_MAX_SHADERSTAGE_IMAGES];
} _sg_shader_stage_t;
typedef struct {
_sg_slot_t slot;
GLuint gl_prog;
_sg_shader_attr_t attrs[SG_MAX_VERTEX_ATTRIBUTES];
_sg_shader_stage_t stage[SG_NUM_SHADER_STAGES];
} _sg_shader_t;
typedef struct {
int8_t vb_index; /* -1 if attr is not enabled */
int8_t divisor; /* -1 if not initialized */
uint8_t stride;
uint8_t size;
uint8_t normalized;
int offset;
GLenum type;
} _sg_gl_attr_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_t* shader;
sg_shader shader_id;
sg_primitive_type primitive_type;
sg_index_type index_type;
bool vertex_layout_valid[SG_MAX_SHADERSTAGE_BUFFERS];
int color_attachment_count;
sg_pixel_format color_format;
sg_pixel_format depth_format;
int sample_count;
_sg_gl_attr_t gl_attrs[SG_MAX_VERTEX_ATTRIBUTES];
sg_depth_stencil_state depth_stencil;
sg_blend_state blend;
sg_rasterizer_state rast;
} _sg_pipeline_t;
typedef struct {
_sg_image_t* image;
sg_image image_id;
int mip_level;
int slice;
GLuint gl_msaa_resolve_buffer;
} _sg_attachment_t;
typedef struct {
_sg_slot_t slot;
GLuint gl_fb;
int num_color_atts;
_sg_attachment_t color_atts[SG_MAX_COLOR_ATTACHMENTS];
_sg_attachment_t ds_att;
} _sg_pass_t;
typedef struct {
_sg_slot_t slot;
#if !defined(SOKOL_GLES2)
GLuint vao;
#endif
GLuint default_framebuffer;
} _sg_context_t;
typedef struct {
_sg_gl_attr_t gl_attr;
GLuint gl_vbuf;
} _sg_gl_cache_attr_t;
typedef struct {
GLenum target;
GLuint texture;
} _sg_gl_texture_bind_slot;
typedef struct {
sg_depth_stencil_state ds;
sg_blend_state blend;
sg_rasterizer_state rast;
bool polygon_offset_enabled;
_sg_gl_cache_attr_t attrs[SG_MAX_VERTEX_ATTRIBUTES];
GLuint vertex_buffer;
GLuint index_buffer;
GLuint stored_vertex_buffer;
GLuint stored_index_buffer;
_sg_gl_texture_bind_slot textures[SG_MAX_SHADERSTAGE_IMAGES];
_sg_gl_texture_bind_slot stored_texture;
int cur_ib_offset;
GLenum cur_primitive_type;
GLenum cur_index_type;
_sg_pipeline_t* cur_pipeline;
sg_pipeline cur_pipeline_id;
} _sg_gl_state_cache_t;
typedef struct {
bool valid;
bool gles2;
bool in_pass;
int cur_pass_width;
int cur_pass_height;
_sg_context_t* cur_context;
_sg_pass_t* cur_pass;
sg_pass cur_pass_id;
_sg_gl_state_cache_t cache;
bool ext_anisotropic;
GLint max_anisotropy;
GLint max_combined_texture_image_units;
} _sg_gl_backend_t;
/*== D3D11 BACKEND DECLARATIONS ==============================================*/
#elif defined(SOKOL_D3D11)
typedef struct {
_sg_slot_t slot;
int size;
int append_pos;
bool append_overflow;
sg_buffer_type type;
sg_usage usage;
uint32_t update_frame_index;
uint32_t append_frame_index;
ID3D11Buffer* d3d11_buf;
} _sg_buffer_t;
typedef struct {
_sg_slot_t slot;
sg_image_type type;
bool render_target;
int width;
int height;
int depth;
int num_mipmaps;
sg_usage usage;
sg_pixel_format pixel_format;
int sample_count;
sg_filter min_filter;
sg_filter mag_filter;
sg_wrap wrap_u;
sg_wrap wrap_v;
sg_wrap wrap_w;
sg_border_color border_color;
uint32_t max_anisotropy;
uint32_t upd_frame_index;
DXGI_FORMAT d3d11_format;
ID3D11Texture2D* d3d11_tex2d;
ID3D11Texture3D* d3d11_tex3d;
ID3D11Texture2D* d3d11_texds;
ID3D11Texture2D* d3d11_texmsaa;
ID3D11ShaderResourceView* d3d11_srv;
ID3D11SamplerState* d3d11_smp;
} _sg_image_t;
typedef struct {
int size;
} _sg_uniform_block_t;
typedef struct {
sg_image_type type;
} _sg_shader_image_t;
typedef struct {
_sg_str_t sem_name;
int sem_index;
} _sg_shader_attr_t;
typedef struct {
int num_uniform_blocks;
int num_images;
_sg_shader_attr_t attrs[SG_MAX_VERTEX_ATTRIBUTES];
_sg_uniform_block_t uniform_blocks[SG_MAX_SHADERSTAGE_UBS];
_sg_shader_image_t images[SG_MAX_SHADERSTAGE_IMAGES];
ID3D11Buffer* d3d11_cbs[SG_MAX_SHADERSTAGE_UBS];
} _sg_shader_stage_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_attr_t attrs[SG_MAX_VERTEX_ATTRIBUTES];
_sg_shader_stage_t stage[SG_NUM_SHADER_STAGES];
ID3D11VertexShader* d3d11_vs;
ID3D11PixelShader* d3d11_fs;
void* d3d11_vs_blob;
int d3d11_vs_blob_length;
} _sg_shader_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_t* shader;
sg_shader shader_id;
sg_index_type index_type;
bool vertex_layout_valid[SG_MAX_SHADERSTAGE_BUFFERS];
int color_attachment_count;
sg_pixel_format color_format;
sg_pixel_format depth_format;
int sample_count;
float blend_color[4];
UINT d3d11_stencil_ref;
UINT d3d11_vb_strides[SG_MAX_SHADERSTAGE_BUFFERS];
D3D_PRIMITIVE_TOPOLOGY d3d11_topology;
DXGI_FORMAT d3d11_index_format;
ID3D11InputLayout* d3d11_il;
ID3D11RasterizerState* d3d11_rs;
ID3D11DepthStencilState* d3d11_dss;
ID3D11BlendState* d3d11_bs;
} _sg_pipeline_t;
typedef struct {
_sg_image_t* image;
sg_image image_id;
int mip_level;
int slice;
} _sg_attachment_t;
typedef struct {
_sg_slot_t slot;
int num_color_atts;
_sg_attachment_t color_atts[SG_MAX_COLOR_ATTACHMENTS];
_sg_attachment_t ds_att;
ID3D11RenderTargetView* d3d11_rtvs[SG_MAX_COLOR_ATTACHMENTS];
ID3D11DepthStencilView* d3d11_dsv;
} _sg_pass_t;
typedef struct {
_sg_slot_t slot;
} _sg_context_t;
typedef struct {
bool valid;
ID3D11Device* dev;
ID3D11DeviceContext* ctx;
const void* (*rtv_cb)(void);
const void* (*dsv_cb)(void);
bool in_pass;
bool use_indexed_draw;
int cur_width;
int cur_height;
int num_rtvs;
_sg_pass_t* cur_pass;
sg_pass cur_pass_id;
_sg_pipeline_t* cur_pipeline;
sg_pipeline cur_pipeline_id;
ID3D11RenderTargetView* cur_rtvs[SG_MAX_COLOR_ATTACHMENTS];
ID3D11DepthStencilView* cur_dsv;
/* on-demand loaded d3dcompiler_47.dll handles */
HINSTANCE d3dcompiler_dll;
bool d3dcompiler_dll_load_failed;
pD3DCompile D3DCompile_func;
/* the following arrays are used for unbinding resources, they will always contain zeroes */
ID3D11RenderTargetView* zero_rtvs[SG_MAX_COLOR_ATTACHMENTS];
ID3D11Buffer* zero_vbs[SG_MAX_SHADERSTAGE_BUFFERS];
UINT zero_vb_offsets[SG_MAX_SHADERSTAGE_BUFFERS];
UINT zero_vb_strides[SG_MAX_SHADERSTAGE_BUFFERS];
ID3D11Buffer* zero_cbs[SG_MAX_SHADERSTAGE_UBS];
ID3D11ShaderResourceView* zero_srvs[SG_MAX_SHADERSTAGE_IMAGES];
ID3D11SamplerState* zero_smps[SG_MAX_SHADERSTAGE_IMAGES];
/* global subresourcedata array for texture updates */
D3D11_SUBRESOURCE_DATA subres_data[SG_MAX_MIPMAPS * SG_MAX_TEXTUREARRAY_LAYERS];
} _sg_d3d11_backend_t;
/*=== METAL BACKEND DECLARATIONS =============================================*/
#elif defined(SOKOL_METAL)
enum {
#if defined(_SG_TARGET_MACOS)
_SG_MTL_UB_ALIGN = 256,
#else
_SG_MTL_UB_ALIGN = 16,
#endif
_SG_MTL_INVALID_SLOT_INDEX = 0
};
/* note that there's a free-standing _sg_mtl_idpool NSMutableArray,
this can't be part of a C struct before Xcode10.x
*/
typedef struct {
uint32_t frame_index; /* frame index at which it is safe to release this resource */
uint32_t slot_index;
} _sg_mtl_release_item_t;
typedef struct {
uint32_t num_slots;
uint32_t free_queue_top;
uint32_t* free_queue;
uint32_t release_queue_front;
uint32_t release_queue_back;
_sg_mtl_release_item_t* release_queue;
} _sg_mtl_idpool_t;
/* Metal sampler cache */
typedef struct {
sg_filter min_filter;
sg_filter mag_filter;
sg_wrap wrap_u;
sg_wrap wrap_v;
sg_wrap wrap_w;
sg_border_color border_color;
uint32_t max_anisotropy;
int min_lod; /* orig min/max_lod is float, this is int(min/max_lod*1000.0) */
int max_lod;
uint32_t mtl_sampler_state;
} _sg_mtl_sampler_cache_item_t;
typedef struct {
int capacity;
int num_items;
_sg_mtl_sampler_cache_item_t* items;
} _sg_mtl_sampler_cache_t;
typedef struct {
_sg_slot_t slot;
int size;
int append_pos;
bool append_overflow;
sg_buffer_type type;
sg_usage usage;
uint32_t update_frame_index;
uint32_t append_frame_index;
int num_slots;
int active_slot;
uint32_t mtl_buf[SG_NUM_INFLIGHT_FRAMES]; /* index intp _sg_mtl_pool */
} _sg_buffer_t;
typedef struct {
_sg_slot_t slot;
sg_image_type type;
bool render_target;
int width;
int height;
int depth;
int num_mipmaps;
sg_usage usage;
sg_pixel_format pixel_format;
int sample_count;
sg_filter min_filter;
sg_filter mag_filter;
sg_wrap wrap_u;
sg_wrap wrap_v;
sg_wrap wrap_w;
uint32_t max_anisotropy;
uint32_t upd_frame_index;
int num_slots;
int active_slot;
uint32_t mtl_tex[SG_NUM_INFLIGHT_FRAMES];
uint32_t mtl_depth_tex;
uint32_t mtl_msaa_tex;
uint32_t mtl_sampler_state;
} _sg_image_t;
typedef struct {
int size;
} _sg_uniform_block_t;
typedef struct {
sg_image_type type;
} _sg_shader_image_t;
typedef struct {
int num_uniform_blocks;
int num_images;
_sg_uniform_block_t uniform_blocks[SG_MAX_SHADERSTAGE_UBS];
_sg_shader_image_t images[SG_MAX_SHADERSTAGE_IMAGES];
uint32_t mtl_lib;
uint32_t mtl_func;
} _sg_shader_stage_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_stage_t stage[SG_NUM_SHADER_STAGES];
} _sg_shader_t;
typedef struct {
_sg_slot_t slot;
_sg_shader_t* shader;
sg_shader shader_id;
bool vertex_layout_valid[SG_MAX_SHADERSTAGE_BUFFERS];
int color_attachment_count;
sg_pixel_format color_format;
sg_pixel_format depth_format;
int sample_count;
float depth_bias;
float depth_bias_slope_scale;
float depth_bias_clamp;
MTLPrimitiveType mtl_prim_type;
sg_index_type index_type;
NSUInteger mtl_index_size;
MTLIndexType mtl_index_type;
MTLCullMode mtl_cull_mode;
MTLWinding mtl_winding;
float blend_color[4];
uint32_t mtl_stencil_ref;
uint32_t mtl_rps;
uint32_t mtl_dss;
} _sg_pipeline_t;
typedef struct {
_sg_image_t* image;
sg_image image_id;
int mip_level;
int slice;
} _sg_attachment_t;
typedef struct {
_sg_slot_t slot;
int num_color_atts;
_sg_attachment_t color_atts[SG_MAX_COLOR_ATTACHMENTS];
_sg_attachment_t ds_att;
} _sg_pass_t;
typedef struct {
_sg_slot_t slot;
} _sg_context_t;
/* resouce binding state cache */
typedef struct {
const _sg_pipeline_t* cur_pipeline;
sg_pipeline cur_pipeline_id;
const _sg_buffer_t* cur_indexbuffer;
int cur_indexbuffer_offset;
sg_buffer cur_indexbuffer_id;
const _sg_buffer_t* cur_vertexbuffers[SG_MAX_SHADERSTAGE_BUFFERS];
int cur_vertexbuffer_offsets[SG_MAX_SHADERSTAGE_BUFFERS];
sg_buffer cur_vertexbuffer_ids[SG_MAX_SHADERSTAGE_BUFFERS];
const _sg_image_t* cur_vs_images[SG_MAX_SHADERSTAGE_IMAGES];
sg_image cur_vs_image_ids[SG_MAX_SHADERSTAGE_IMAGES];
const _sg_image_t* cur_fs_images[SG_MAX_SHADERSTAGE_IMAGES];
sg_image cur_fs_image_ids[SG_MAX_SHADERSTAGE_IMAGES];
} _sg_mtl_state_cache_t;
typedef struct {
bool valid;
const void*(*renderpass_descriptor_cb)(void);
const void*(*drawable_cb)(void);
uint32_t frame_index;
uint32_t cur_frame_rotate_index;
uint32_t ub_size;
uint32_t cur_ub_offset;
uint8_t* cur_ub_base_ptr;
bool in_pass;
bool pass_valid;
int cur_width;
int cur_height;
_sg_mtl_state_cache_t state_cache;
_sg_mtl_sampler_cache_t sampler_cache;
_sg_mtl_idpool_t idpool;
} _sg_mtl_backend_t;
/* keep Objective-C 'smart data' in a separate static objects, these can't be in a C struct until Xcode10 or so */
static NSMutableArray* _sg_mtl_idpool;
static id<MTLDevice> _sg_mtl_device;
static id<MTLCommandQueue> _sg_mtl_cmd_queue;
static id<MTLCommandBuffer> _sg_mtl_cmd_buffer;
static id<MTLBuffer> _sg_mtl_uniform_buffers[SG_NUM_INFLIGHT_FRAMES];
static id<MTLRenderCommandEncoder> _sg_mtl_cmd_encoder;
static dispatch_semaphore_t _sg_mtl_sem;
#endif /* SOKOL_METAL */
/*=== RESOURCE POOL DECLARATIONS =============================================*/
/* this *MUST* remain 0 */
#define _SG_INVALID_SLOT_INDEX (0)
typedef struct {
int size;
int queue_top;
uint32_t* gen_ctrs;
int* free_queue;
} _sg_pool_t;
typedef struct {
_sg_pool_t buffer_pool;
_sg_pool_t image_pool;
_sg_pool_t shader_pool;
_sg_pool_t pipeline_pool;
_sg_pool_t pass_pool;
_sg_pool_t context_pool;
_sg_buffer_t* buffers;
_sg_image_t* images;
_sg_shader_t* shaders;
_sg_pipeline_t* pipelines;
_sg_pass_t* passes;
_sg_context_t* contexts;
} _sg_pools_t;
/*=== VALIDATION LAYER DECLARATIONS ==========================================*/
typedef enum {
/* special case 'validation was successful' */
_SG_VALIDATE_SUCCESS,
/* buffer creation */
_SG_VALIDATE_BUFFERDESC_CANARY,
_SG_VALIDATE_BUFFERDESC_SIZE,
_SG_VALIDATE_BUFFERDESC_CONTENT,
_SG_VALIDATE_BUFFERDESC_NO_CONTENT,
/* image creation */
_SG_VALIDATE_IMAGEDESC_CANARY,
_SG_VALIDATE_IMAGEDESC_WIDTH,
_SG_VALIDATE_IMAGEDESC_HEIGHT,
_SG_VALIDATE_IMAGEDESC_RT_PIXELFORMAT,
_SG_VALIDATE_IMAGEDESC_NONRT_PIXELFORMAT,
_SG_VALIDATE_IMAGEDESC_MSAA_BUT_NO_RT,
_SG_VALIDATE_IMAGEDESC_NO_MSAA_RT_SUPPORT,
_SG_VALIDATE_IMAGEDESC_RT_IMMUTABLE,
_SG_VALIDATE_IMAGEDESC_RT_NO_CONTENT,
_SG_VALIDATE_IMAGEDESC_CONTENT,
_SG_VALIDATE_IMAGEDESC_NO_CONTENT,
/* shader creation */
_SG_VALIDATE_SHADERDESC_CANARY,
_SG_VALIDATE_SHADERDESC_SOURCE,
_SG_VALIDATE_SHADERDESC_BYTECODE,
_SG_VALIDATE_SHADERDESC_SOURCE_OR_BYTECODE,
_SG_VALIDATE_SHADERDESC_NO_BYTECODE_SIZE,
_SG_VALIDATE_SHADERDESC_NO_CONT_UBS,
_SG_VALIDATE_SHADERDESC_NO_CONT_IMGS,
_SG_VALIDATE_SHADERDESC_NO_CONT_UB_MEMBERS,
_SG_VALIDATE_SHADERDESC_NO_UB_MEMBERS,
_SG_VALIDATE_SHADERDESC_UB_MEMBER_NAME,
_SG_VALIDATE_SHADERDESC_UB_SIZE_MISMATCH,
_SG_VALIDATE_SHADERDESC_IMG_NAME,
_SG_VALIDATE_SHADERDESC_ATTR_NAMES,
_SG_VALIDATE_SHADERDESC_ATTR_SEMANTICS,
_SG_VALIDATE_SHADERDESC_ATTR_STRING_TOO_LONG,
/* pipeline creation */
_SG_VALIDATE_PIPELINEDESC_CANARY,
_SG_VALIDATE_PIPELINEDESC_SHADER,
_SG_VALIDATE_PIPELINEDESC_NO_ATTRS,
_SG_VALIDATE_PIPELINEDESC_LAYOUT_STRIDE4,
_SG_VALIDATE_PIPELINEDESC_ATTR_NAME,
_SG_VALIDATE_PIPELINEDESC_ATTR_SEMANTICS,
/* pass creation */
_SG_VALIDATE_PASSDESC_CANARY,
_SG_VALIDATE_PASSDESC_NO_COLOR_ATTS,
_SG_VALIDATE_PASSDESC_NO_CONT_COLOR_ATTS,
_SG_VALIDATE_PASSDESC_IMAGE,
_SG_VALIDATE_PASSDESC_MIPLEVEL,
_SG_VALIDATE_PASSDESC_FACE,
_SG_VALIDATE_PASSDESC_LAYER,
_SG_VALIDATE_PASSDESC_SLICE,
_SG_VALIDATE_PASSDESC_IMAGE_NO_RT,
_SG_VALIDATE_PASSDESC_COLOR_PIXELFORMATS,
_SG_VALIDATE_PASSDESC_COLOR_INV_PIXELFORMAT,
_SG_VALIDATE_PASSDESC_DEPTH_INV_PIXELFORMAT,
_SG_VALIDATE_PASSDESC_IMAGE_SIZES,
_SG_VALIDATE_PASSDESC_IMAGE_SAMPLE_COUNTS,
/* sg_begin_pass validation */
_SG_VALIDATE_BEGINPASS_PASS,
_SG_VALIDATE_BEGINPASS_IMAGE,
/* sg_apply_pipeline validation */
_SG_VALIDATE_APIP_PIPELINE_VALID_ID,
_SG_VALIDATE_APIP_PIPELINE_EXISTS,
_SG_VALIDATE_APIP_PIPELINE_VALID,
_SG_VALIDATE_APIP_SHADER_EXISTS,
_SG_VALIDATE_APIP_SHADER_VALID,
_SG_VALIDATE_APIP_ATT_COUNT,
_SG_VALIDATE_APIP_COLOR_FORMAT,
_SG_VALIDATE_APIP_DEPTH_FORMAT,
_SG_VALIDATE_APIP_SAMPLE_COUNT,
/* sg_apply_bindings validation */
_SG_VALIDATE_ABND_PIPELINE,
_SG_VALIDATE_ABND_PIPELINE_EXISTS,
_SG_VALIDATE_ABND_PIPELINE_VALID,
_SG_VALIDATE_ABND_VBS,
_SG_VALIDATE_ABND_VB_EXISTS,
_SG_VALIDATE_ABND_VB_TYPE,
_SG_VALIDATE_ABND_VB_OVERFLOW,
_SG_VALIDATE_ABND_NO_IB,
_SG_VALIDATE_ABND_IB,
_SG_VALIDATE_ABND_IB_EXISTS,
_SG_VALIDATE_ABND_IB_TYPE,
_SG_VALIDATE_ABND_IB_OVERFLOW,
_SG_VALIDATE_ABND_VS_IMGS,
_SG_VALIDATE_ABND_VS_IMG_EXISTS,
_SG_VALIDATE_ABND_VS_IMG_TYPES,
_SG_VALIDATE_ABND_FS_IMGS,
_SG_VALIDATE_ABND_FS_IMG_EXISTS,
_SG_VALIDATE_ABND_FS_IMG_TYPES,
/* sg_apply_uniforms validation */
_SG_VALIDATE_AUB_NO_PIPELINE,
_SG_VALIDATE_AUB_NO_UB_AT_SLOT,
_SG_VALIDATE_AUB_SIZE,
/* sg_update_buffer validation */
_SG_VALIDATE_UPDATEBUF_USAGE,
_SG_VALIDATE_UPDATEBUF_SIZE,
_SG_VALIDATE_UPDATEBUF_ONCE,
_SG_VALIDATE_UPDATEBUF_APPEND,
/* sg_append_buffer validation */
_SG_VALIDATE_APPENDBUF_USAGE,
_SG_VALIDATE_APPENDBUF_SIZE,
_SG_VALIDATE_APPENDBUF_UPDATE,
/* sg_update_image validation */
_SG_VALIDATE_UPDIMG_USAGE,
_SG_VALIDATE_UPDIMG_NOTENOUGHDATA,
_SG_VALIDATE_UPDIMG_SIZE,
_SG_VALIDATE_UPDIMG_COMPRESSED,
_SG_VALIDATE_UPDIMG_ONCE
} _sg_validate_error_t;
/*=== GENERIC BACKEND STATE ==================================================*/
typedef struct {
bool valid;
sg_desc desc; /* original desc with default values patched in */
uint32_t frame_index;
sg_context active_context;
sg_pass cur_pass;
sg_pipeline cur_pipeline;
bool pass_valid;
bool bindings_valid;
bool next_draw_valid;
#if defined(SOKOL_DEBUG)
_sg_validate_error_t validate_error;
#endif
_sg_pools_t pools;
sg_backend backend;
sg_features features;
sg_limits limits;
sg_pixelformat_info formats[_SG_PIXELFORMAT_NUM];
#if defined(SOKOL_GLCORE33) || defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
_sg_gl_backend_t gl;
#elif defined(SOKOL_METAL)
_sg_mtl_backend_t mtl;
#elif defined(SOKOL_D3D11)
_sg_d3d11_backend_t d3d11;
#endif
#if defined(SOKOL_TRACE_HOOKS)
sg_trace_hooks hooks;
#endif
} _sg_state_t;
static _sg_state_t _sg;
/*-- helper functions --------------------------------------------------------*/
_SOKOL_PRIVATE bool _sg_strempty(const _sg_str_t* str) {
return 0 == str->buf[0];
}
_SOKOL_PRIVATE const char* _sg_strptr(const _sg_str_t* str) {
return &str->buf[0];
}
_SOKOL_PRIVATE void _sg_strcpy(_sg_str_t* dst, const char* src) {
SOKOL_ASSERT(dst);
if (src) {
#if defined(_MSC_VER)
strncpy_s(dst->buf, _SG_STRING_SIZE, src, (_SG_STRING_SIZE-1));
#else
strncpy(dst->buf, src, _SG_STRING_SIZE);
#endif
dst->buf[_SG_STRING_SIZE-1] = 0;
}
else {
memset(dst->buf, 0, _SG_STRING_SIZE);
}
}
/* return byte size of a vertex format */
_SOKOL_PRIVATE int _sg_vertexformat_bytesize(sg_vertex_format fmt) {
switch (fmt) {
case SG_VERTEXFORMAT_FLOAT: return 4;
case SG_VERTEXFORMAT_FLOAT2: return 8;
case SG_VERTEXFORMAT_FLOAT3: return 12;
case SG_VERTEXFORMAT_FLOAT4: return 16;
case SG_VERTEXFORMAT_BYTE4: return 4;
case SG_VERTEXFORMAT_BYTE4N: return 4;
case SG_VERTEXFORMAT_UBYTE4: return 4;
case SG_VERTEXFORMAT_UBYTE4N: return 4;
case SG_VERTEXFORMAT_SHORT2: return 4;
case SG_VERTEXFORMAT_SHORT2N: return 4;
case SG_VERTEXFORMAT_USHORT2N: return 4;
case SG_VERTEXFORMAT_SHORT4: return 8;
case SG_VERTEXFORMAT_SHORT4N: return 8;
case SG_VERTEXFORMAT_USHORT4N: return 8;
case SG_VERTEXFORMAT_UINT10_N2: return 4;
case SG_VERTEXFORMAT_INVALID: return 0;
default:
SOKOL_UNREACHABLE;
return -1;
}
}
/* return the byte size of a shader uniform */
_SOKOL_PRIVATE int _sg_uniform_size(sg_uniform_type type, int count) {
switch (type) {
case SG_UNIFORMTYPE_INVALID: return 0;
case SG_UNIFORMTYPE_FLOAT: return 4 * count;
case SG_UNIFORMTYPE_FLOAT2: return 8 * count;
case SG_UNIFORMTYPE_FLOAT3: return 12 * count; /* FIXME: std140??? */
case SG_UNIFORMTYPE_FLOAT4: return 16 * count;
case SG_UNIFORMTYPE_MAT4: return 64 * count;
default:
SOKOL_UNREACHABLE;
return -1;
}
}
/* the default color pixelformat for render targets */
_SOKOL_PRIVATE sg_pixel_format _sg_default_rendertarget_colorformat(void) {
#if defined(SOKOL_METAL) || defined(SOKOL_D3D11)
return SG_PIXELFORMAT_BGRA8;
#else
return SG_PIXELFORMAT_RGBA8;
#endif
}
_SOKOL_PRIVATE sg_pixel_format _sg_default_rendertarget_depthformat(void) {
return SG_PIXELFORMAT_DEPTH_STENCIL;
}
/* return true if pixel format is a compressed format */
_SOKOL_PRIVATE bool _sg_is_compressed_pixel_format(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_BC1_RGBA:
case SG_PIXELFORMAT_BC2_RGBA:
case SG_PIXELFORMAT_BC3_RGBA:
case SG_PIXELFORMAT_BC4_R:
case SG_PIXELFORMAT_BC4_RSN:
case SG_PIXELFORMAT_BC5_RG:
case SG_PIXELFORMAT_BC5_RGSN:
case SG_PIXELFORMAT_BC6H_RGBF:
case SG_PIXELFORMAT_BC6H_RGBUF:
case SG_PIXELFORMAT_BC7_RGBA:
case SG_PIXELFORMAT_PVRTC_RGB_2BPP:
case SG_PIXELFORMAT_PVRTC_RGB_4BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP:
case SG_PIXELFORMAT_ETC2_RGB8:
case SG_PIXELFORMAT_ETC2_RGB8A1:
case SG_PIXELFORMAT_ETC2_RGBA8:
case SG_PIXELFORMAT_ETC2_RG11:
case SG_PIXELFORMAT_ETC2_RG11SN:
return true;
default:
return false;
}
}
/* return true if pixel format is a valid render target format */
_SOKOL_PRIVATE bool _sg_is_valid_rendertarget_color_format(sg_pixel_format fmt) {
const int fmt_index = (int) fmt;
SOKOL_ASSERT((fmt_index >= 0) && (fmt_index < _SG_PIXELFORMAT_NUM));
return _sg.formats[fmt_index].render && !_sg.formats[fmt_index].depth;
}
/* return true if pixel format is a valid depth format */
_SOKOL_PRIVATE bool _sg_is_valid_rendertarget_depth_format(sg_pixel_format fmt) {
const int fmt_index = (int) fmt;
SOKOL_ASSERT((fmt_index >= 0) && (fmt_index < _SG_PIXELFORMAT_NUM));
return _sg.formats[fmt_index].render && _sg.formats[fmt_index].depth;
}
/* return true if pixel format is a depth-stencil format */
_SOKOL_PRIVATE bool _sg_is_depth_stencil_format(sg_pixel_format fmt) {
return (SG_PIXELFORMAT_DEPTH_STENCIL == fmt);
}
/* return the bytes-per-pixel for a pixel format */
_SOKOL_PRIVATE int _sg_pixelformat_bytesize(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_R8:
case SG_PIXELFORMAT_R8SN:
case SG_PIXELFORMAT_R8UI:
case SG_PIXELFORMAT_R8SI:
return 1;
case SG_PIXELFORMAT_R16:
case SG_PIXELFORMAT_R16SN:
case SG_PIXELFORMAT_R16UI:
case SG_PIXELFORMAT_R16SI:
case SG_PIXELFORMAT_R16F:
case SG_PIXELFORMAT_RG8:
case SG_PIXELFORMAT_RG8SN:
case SG_PIXELFORMAT_RG8UI:
case SG_PIXELFORMAT_RG8SI:
return 2;
case SG_PIXELFORMAT_R32UI:
case SG_PIXELFORMAT_R32SI:
case SG_PIXELFORMAT_R32F:
case SG_PIXELFORMAT_RG16:
case SG_PIXELFORMAT_RG16SN:
case SG_PIXELFORMAT_RG16UI:
case SG_PIXELFORMAT_RG16SI:
case SG_PIXELFORMAT_RG16F:
case SG_PIXELFORMAT_RGBA8:
case SG_PIXELFORMAT_RGBA8SN:
case SG_PIXELFORMAT_RGBA8UI:
case SG_PIXELFORMAT_RGBA8SI:
case SG_PIXELFORMAT_BGRA8:
case SG_PIXELFORMAT_RGB10A2:
case SG_PIXELFORMAT_RG11B10F:
return 4;
case SG_PIXELFORMAT_RG32UI:
case SG_PIXELFORMAT_RG32SI:
case SG_PIXELFORMAT_RG32F:
case SG_PIXELFORMAT_RGBA16:
case SG_PIXELFORMAT_RGBA16SN:
case SG_PIXELFORMAT_RGBA16UI:
case SG_PIXELFORMAT_RGBA16SI:
case SG_PIXELFORMAT_RGBA16F:
return 8;
case SG_PIXELFORMAT_RGBA32UI:
case SG_PIXELFORMAT_RGBA32SI:
case SG_PIXELFORMAT_RGBA32F:
return 16;
default:
SOKOL_UNREACHABLE;
return 0;
}
}
/* return row pitch for an image
see ComputePitch in https://github.com/microsoft/DirectXTex/blob/master/DirectXTex/DirectXTexUtil.cpp
*/
_SOKOL_PRIVATE int _sg_row_pitch(sg_pixel_format fmt, int width) {
int pitch;
switch (fmt) {
case SG_PIXELFORMAT_BC1_RGBA:
case SG_PIXELFORMAT_BC4_R:
case SG_PIXELFORMAT_BC4_RSN:
case SG_PIXELFORMAT_ETC2_RGB8:
case SG_PIXELFORMAT_ETC2_RGB8A1:
pitch = ((width + 3) / 4) * 8;
pitch = pitch < 8 ? 8 : pitch;
break;
case SG_PIXELFORMAT_BC2_RGBA:
case SG_PIXELFORMAT_BC3_RGBA:
case SG_PIXELFORMAT_BC5_RG:
case SG_PIXELFORMAT_BC5_RGSN:
case SG_PIXELFORMAT_BC6H_RGBF:
case SG_PIXELFORMAT_BC6H_RGBUF:
case SG_PIXELFORMAT_BC7_RGBA:
case SG_PIXELFORMAT_ETC2_RGBA8:
case SG_PIXELFORMAT_ETC2_RG11:
case SG_PIXELFORMAT_ETC2_RG11SN:
pitch = ((width + 3) / 4) * 16;
pitch = pitch < 16 ? 16 : pitch;
break;
case SG_PIXELFORMAT_PVRTC_RGB_4BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP:
{
const int block_size = 4*4;
const int bpp = 4;
int width_blocks = width / 4;
width_blocks = width_blocks < 2 ? 2 : width_blocks;
pitch = width_blocks * ((block_size * bpp) / 8);
}
break;
case SG_PIXELFORMAT_PVRTC_RGB_2BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP:
{
const int block_size = 8*4;
const int bpp = 2;
int width_blocks = width / 4;
width_blocks = width_blocks < 2 ? 2 : width_blocks;
pitch = width_blocks * ((block_size * bpp) / 8);
}
break;
default:
pitch = width * _sg_pixelformat_bytesize(fmt);
break;
}
return pitch;
}
/* return pitch of a 2D subimage / texture slice
see ComputePitch in https://github.com/microsoft/DirectXTex/blob/master/DirectXTex/DirectXTexUtil.cpp
*/
_SOKOL_PRIVATE int _sg_surface_pitch(sg_pixel_format fmt, int width, int height) {
int num_rows = 0;
switch (fmt) {
case SG_PIXELFORMAT_BC1_RGBA:
case SG_PIXELFORMAT_BC4_R:
case SG_PIXELFORMAT_BC4_RSN:
case SG_PIXELFORMAT_ETC2_RGB8:
case SG_PIXELFORMAT_ETC2_RGB8A1:
case SG_PIXELFORMAT_ETC2_RGBA8:
case SG_PIXELFORMAT_ETC2_RG11:
case SG_PIXELFORMAT_ETC2_RG11SN:
case SG_PIXELFORMAT_BC2_RGBA:
case SG_PIXELFORMAT_BC3_RGBA:
case SG_PIXELFORMAT_BC5_RG:
case SG_PIXELFORMAT_BC5_RGSN:
case SG_PIXELFORMAT_BC6H_RGBF:
case SG_PIXELFORMAT_BC6H_RGBUF:
case SG_PIXELFORMAT_BC7_RGBA:
case SG_PIXELFORMAT_PVRTC_RGB_4BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP:
case SG_PIXELFORMAT_PVRTC_RGB_2BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP:
num_rows = ((height + 3) / 4);
break;
default:
num_rows = height;
break;
}
if (num_rows < 1) {
num_rows = 1;
}
return num_rows * _sg_row_pitch(fmt, width);
}
/* capability table pixel format helper functions */
_SOKOL_PRIVATE void _sg_pixelformat_all(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->filter = true;
pfi->blend = true;
pfi->render = true;
pfi->msaa = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_s(sg_pixelformat_info* pfi) {
pfi->sample = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_sf(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->filter = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_sr(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->render = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_srmd(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->render = true;
pfi->msaa = true;
pfi->depth = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_srm(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->render = true;
pfi->msaa = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_sfrm(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->filter = true;
pfi->render = true;
pfi->msaa = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_sbrm(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->blend = true;
pfi->render = true;
pfi->msaa = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_sbr(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->blend = true;
pfi->render = true;
}
_SOKOL_PRIVATE void _sg_pixelformat_sfbr(sg_pixelformat_info* pfi) {
pfi->sample = true;
pfi->filter = true;
pfi->blend = true;
pfi->render = true;
}
/* resolve pass action defaults into a new pass action struct */
_SOKOL_PRIVATE void _sg_resolve_default_pass_action(const sg_pass_action* from, sg_pass_action* to) {
SOKOL_ASSERT(from && to);
*to = *from;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
if (to->colors[i].action == _SG_ACTION_DEFAULT) {
to->colors[i].action = SG_ACTION_CLEAR;
to->colors[i].val[0] = SG_DEFAULT_CLEAR_RED;
to->colors[i].val[1] = SG_DEFAULT_CLEAR_GREEN;
to->colors[i].val[2] = SG_DEFAULT_CLEAR_BLUE;
to->colors[i].val[3] = SG_DEFAULT_CLEAR_ALPHA;
}
}
if (to->depth.action == _SG_ACTION_DEFAULT) {
to->depth.action = SG_ACTION_CLEAR;
to->depth.val = SG_DEFAULT_CLEAR_DEPTH;
}
if (to->stencil.action == _SG_ACTION_DEFAULT) {
to->stencil.action = SG_ACTION_CLEAR;
to->stencil.val = SG_DEFAULT_CLEAR_STENCIL;
}
}
/*== DUMMY BACKEND IMPL ======================================================*/
#if defined(SOKOL_DUMMY_BACKEND)
_SOKOL_PRIVATE void _sg_setup_backend(const sg_desc* desc) {
SOKOL_ASSERT(desc);
_SOKOL_UNUSED(desc);
_sg.backend = SG_BACKEND_DUMMY;
for (int i = SG_PIXELFORMAT_R8; i < SG_PIXELFORMAT_BC1_RGBA; i++) {
_sg.formats[i].sample = true;
_sg.formats[i].filter = true;
_sg.formats[i].render = true;
_sg.formats[i].blend = true;
_sg.formats[i].msaa = true;
}
_sg.formats[SG_PIXELFORMAT_DEPTH].depth = true;
_sg.formats[SG_PIXELFORMAT_DEPTH_STENCIL].depth = true;
}
_SOKOL_PRIVATE void _sg_discard_backend(void) {
/* empty */
}
_SOKOL_PRIVATE void _sg_reset_state_cache(void) {
/* empty*/
}
_SOKOL_PRIVATE sg_resource_state _sg_create_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
}
_SOKOL_PRIVATE void _sg_activate_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_buffer(_sg_buffer_t* buf, const sg_buffer_desc* desc) {
SOKOL_ASSERT(buf && desc);
buf->size = desc->size;
buf->append_pos = 0;
buf->append_overflow = false;
buf->type = desc->type;
buf->usage = desc->usage;
buf->update_frame_index = 0;
buf->append_frame_index = 0;
buf->num_slots = (buf->usage == SG_USAGE_IMMUTABLE) ? 1 : SG_NUM_INFLIGHT_FRAMES;
buf->active_slot = 0;
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_buffer(_sg_buffer_t* buf) {
SOKOL_ASSERT(buf);
_SOKOL_UNUSED(buf);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_image(_sg_image_t* img, const sg_image_desc* desc) {
SOKOL_ASSERT(img && desc);
img->type = desc->type;
img->render_target = desc->render_target;
img->width = desc->width;
img->height = desc->height;
img->depth = desc->depth;
img->num_mipmaps = desc->num_mipmaps;
img->usage = desc->usage;
img->pixel_format = desc->pixel_format;
img->sample_count = desc->sample_count;
img->min_filter = desc->min_filter;
img->mag_filter = desc->mag_filter;
img->wrap_u = desc->wrap_u;
img->wrap_v = desc->wrap_v;
img->wrap_w = desc->wrap_w;
img->max_anisotropy = desc->max_anisotropy;
img->upd_frame_index = 0;
img->num_slots = (img->usage == SG_USAGE_IMMUTABLE) ? 1 :SG_NUM_INFLIGHT_FRAMES;
img->active_slot = 0;
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_image(_sg_image_t* img) {
SOKOL_ASSERT(img);
_SOKOL_UNUSED(img);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_shader(_sg_shader_t* shd, const sg_shader_desc* desc) {
SOKOL_ASSERT(shd && desc);
/* uniform block sizes and image types */
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const sg_shader_stage_desc* stage_desc = (stage_index == SG_SHADERSTAGE_VS) ? &desc->vs : &desc->fs;
_sg_shader_stage_t* stage = &shd->stage[stage_index];
SOKOL_ASSERT(stage->num_uniform_blocks == 0);
for (int ub_index = 0; ub_index < SG_MAX_SHADERSTAGE_UBS; ub_index++) {
const sg_shader_uniform_block_desc* ub_desc = &stage_desc->uniform_blocks[ub_index];
if (0 == ub_desc->size) {
break;
}
_sg_uniform_block_t* ub = &stage->uniform_blocks[ub_index];
ub->size = ub_desc->size;
stage->num_uniform_blocks++;
}
SOKOL_ASSERT(stage->num_images == 0);
for (int img_index = 0; img_index < SG_MAX_SHADERSTAGE_IMAGES; img_index++) {
const sg_shader_image_desc* img_desc = &stage_desc->images[img_index];
if (img_desc->type == _SG_IMAGETYPE_DEFAULT) {
break;
}
stage->images[img_index].type = img_desc->type;
stage->num_images++;
}
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_shader(_sg_shader_t* shd) {
SOKOL_ASSERT(shd);
_SOKOL_UNUSED(shd);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pipeline(_sg_pipeline_t* pip, _sg_shader_t* shd, const sg_pipeline_desc* desc) {
SOKOL_ASSERT(pip && desc);
pip->shader = shd;
pip->shader_id = desc->shader;
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
const sg_vertex_attr_desc* a_desc = &desc->layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
break;
}
SOKOL_ASSERT((a_desc->buffer_index >= 0) && (a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS));
pip->vertex_layout_valid[a_desc->buffer_index] = true;
}
pip->color_attachment_count = desc->blend.color_attachment_count;
pip->color_format = desc->blend.color_format;
pip->depth_format = desc->blend.depth_format;
pip->sample_count = desc->rasterizer.sample_count;
pip->depth_bias = desc->rasterizer.depth_bias;
pip->depth_bias_slope_scale = desc->rasterizer.depth_bias_slope_scale;
pip->depth_bias_clamp = desc->rasterizer.depth_bias_clamp;
pip->index_type = desc->index_type;
for (int i = 0; i < 4; i++) {
pip->blend_color[i] = desc->blend.blend_color[i];
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
_SOKOL_UNUSED(pip);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pass(_sg_pass_t* pass, _sg_image_t** att_images, const sg_pass_desc* desc) {
SOKOL_ASSERT(pass && desc);
SOKOL_ASSERT(att_images && att_images[0]);
/* copy image pointers and desc attributes */
const sg_attachment_desc* att_desc;
_sg_attachment_t* att;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
SOKOL_ASSERT(0 == pass->color_atts[i].image);
att_desc = &desc->color_attachments[i];
if (att_desc->image.id != SG_INVALID_ID) {
pass->num_color_atts++;
SOKOL_ASSERT(att_images[i] && (att_images[i]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_color_format(att_images[i]->pixel_format));
att = &pass->color_atts[i];
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[i];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
}
}
SOKOL_ASSERT(0 == pass->ds_att.image);
att_desc = &desc->depth_stencil_attachment;
const int ds_img_index = SG_MAX_COLOR_ATTACHMENTS;
if (att_desc->image.id != SG_INVALID_ID) {
SOKOL_ASSERT(att_images[ds_img_index] && (att_images[ds_img_index]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_depth_format(att_images[ds_img_index]->pixel_format));
att = &pass->ds_att;
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[ds_img_index];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pass(_sg_pass_t* pass) {
SOKOL_ASSERT(pass);
_SOKOL_UNUSED(pass);
}
_SOKOL_PRIVATE void _sg_begin_pass(_sg_pass_t* pass, const sg_pass_action* action, int w, int h) {
SOKOL_ASSERT(action);
_SOKOL_UNUSED(pass);
_SOKOL_UNUSED(action);
_SOKOL_UNUSED(w);
_SOKOL_UNUSED(h);
}
_SOKOL_PRIVATE void _sg_end_pass(void) {
/* empty */
}
_SOKOL_PRIVATE void _sg_commit(void) {
/* empty */
}
_SOKOL_PRIVATE void _sg_apply_viewport(int x, int y, int w, int h, bool origin_top_left) {
_SOKOL_UNUSED(x);
_SOKOL_UNUSED(y);
_SOKOL_UNUSED(w);
_SOKOL_UNUSED(h);
_SOKOL_UNUSED(origin_top_left);
}
_SOKOL_PRIVATE void _sg_apply_scissor_rect(int x, int y, int w, int h, bool origin_top_left) {
_SOKOL_UNUSED(x);
_SOKOL_UNUSED(y);
_SOKOL_UNUSED(w);
_SOKOL_UNUSED(h);
_SOKOL_UNUSED(origin_top_left);
}
_SOKOL_PRIVATE void _sg_apply_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
_SOKOL_UNUSED(pip);
}
_SOKOL_PRIVATE void _sg_apply_bindings(
_sg_pipeline_t* pip,
_sg_buffer_t** vbs, const int* vb_offsets, int num_vbs,
_sg_buffer_t* ib, int ib_offset,
_sg_image_t** vs_imgs, int num_vs_imgs,
_sg_image_t** fs_imgs, int num_fs_imgs)
{
SOKOL_ASSERT(pip);
SOKOL_ASSERT(vbs && vb_offsets);
SOKOL_ASSERT(vs_imgs);
SOKOL_ASSERT(fs_imgs);
_SOKOL_UNUSED(pip);
_SOKOL_UNUSED(vbs); _SOKOL_UNUSED(vb_offsets); _SOKOL_UNUSED(num_vbs);
_SOKOL_UNUSED(ib); _SOKOL_UNUSED(ib_offset);
_SOKOL_UNUSED(vs_imgs); _SOKOL_UNUSED(num_vs_imgs);
_SOKOL_UNUSED(fs_imgs); _SOKOL_UNUSED(num_fs_imgs);
}
_SOKOL_PRIVATE void _sg_apply_uniforms(sg_shader_stage stage_index, int ub_index, const void* data, int num_bytes) {
SOKOL_ASSERT(data && (num_bytes > 0));
SOKOL_ASSERT((stage_index >= 0) && ((int)stage_index < SG_NUM_SHADER_STAGES));
SOKOL_ASSERT((ub_index >= 0) && (ub_index < SG_MAX_SHADERSTAGE_UBS));
_SOKOL_UNUSED(stage_index);
_SOKOL_UNUSED(ub_index);
_SOKOL_UNUSED(data);
_SOKOL_UNUSED(num_bytes);
}
_SOKOL_PRIVATE void _sg_draw(int base_element, int num_elements, int num_instances) {
_SOKOL_UNUSED(base_element);
_SOKOL_UNUSED(num_elements);
_SOKOL_UNUSED(num_instances);
}
_SOKOL_PRIVATE void _sg_update_buffer(_sg_buffer_t* buf, const void* data, int data_size) {
SOKOL_ASSERT(buf && data && (data_size > 0));
_SOKOL_UNUSED(data);
_SOKOL_UNUSED(data_size);
if (++buf->active_slot >= buf->num_slots) {
buf->active_slot = 0;
}
}
_SOKOL_PRIVATE void _sg_append_buffer(_sg_buffer_t* buf, const void* data, int data_size, bool new_frame) {
SOKOL_ASSERT(buf && data && (data_size > 0));
_SOKOL_UNUSED(data);
_SOKOL_UNUSED(data_size);
if (new_frame) {
if (++buf->active_slot >= buf->num_slots) {
buf->active_slot = 0;
}
}
}
_SOKOL_PRIVATE void _sg_update_image(_sg_image_t* img, const sg_image_content* data) {
SOKOL_ASSERT(img && data);
_SOKOL_UNUSED(data);
if (++img->active_slot >= img->num_slots) {
img->active_slot = 0;
}
}
/*== GL BACKEND ==============================================================*/
#elif defined(SOKOL_GLCORE33) || defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
/*-- type translation --------------------------------------------------------*/
_SOKOL_PRIVATE GLenum _sg_gl_buffer_target(sg_buffer_type t) {
switch (t) {
case SG_BUFFERTYPE_VERTEXBUFFER: return GL_ARRAY_BUFFER;
case SG_BUFFERTYPE_INDEXBUFFER: return GL_ELEMENT_ARRAY_BUFFER;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_texture_target(sg_image_type t) {
switch (t) {
case SG_IMAGETYPE_2D: return GL_TEXTURE_2D;
case SG_IMAGETYPE_CUBE: return GL_TEXTURE_CUBE_MAP;
#if !defined(SOKOL_GLES2)
case SG_IMAGETYPE_3D: return GL_TEXTURE_3D;
case SG_IMAGETYPE_ARRAY: return GL_TEXTURE_2D_ARRAY;
#endif
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_usage(sg_usage u) {
switch (u) {
case SG_USAGE_IMMUTABLE: return GL_STATIC_DRAW;
case SG_USAGE_DYNAMIC: return GL_DYNAMIC_DRAW;
case SG_USAGE_STREAM: return GL_STREAM_DRAW;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_shader_stage(sg_shader_stage stage) {
switch (stage) {
case SG_SHADERSTAGE_VS: return GL_VERTEX_SHADER;
case SG_SHADERSTAGE_FS: return GL_FRAGMENT_SHADER;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLint _sg_gl_vertexformat_size(sg_vertex_format fmt) {
switch (fmt) {
case SG_VERTEXFORMAT_FLOAT: return 1;
case SG_VERTEXFORMAT_FLOAT2: return 2;
case SG_VERTEXFORMAT_FLOAT3: return 3;
case SG_VERTEXFORMAT_FLOAT4: return 4;
case SG_VERTEXFORMAT_BYTE4: return 4;
case SG_VERTEXFORMAT_BYTE4N: return 4;
case SG_VERTEXFORMAT_UBYTE4: return 4;
case SG_VERTEXFORMAT_UBYTE4N: return 4;
case SG_VERTEXFORMAT_SHORT2: return 2;
case SG_VERTEXFORMAT_SHORT2N: return 2;
case SG_VERTEXFORMAT_USHORT2N: return 2;
case SG_VERTEXFORMAT_SHORT4: return 4;
case SG_VERTEXFORMAT_SHORT4N: return 4;
case SG_VERTEXFORMAT_USHORT4N: return 4;
case SG_VERTEXFORMAT_UINT10_N2: return 4;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_vertexformat_type(sg_vertex_format fmt) {
switch (fmt) {
case SG_VERTEXFORMAT_FLOAT:
case SG_VERTEXFORMAT_FLOAT2:
case SG_VERTEXFORMAT_FLOAT3:
case SG_VERTEXFORMAT_FLOAT4:
return GL_FLOAT;
case SG_VERTEXFORMAT_BYTE4:
case SG_VERTEXFORMAT_BYTE4N:
return GL_BYTE;
case SG_VERTEXFORMAT_UBYTE4:
case SG_VERTEXFORMAT_UBYTE4N:
return GL_UNSIGNED_BYTE;
case SG_VERTEXFORMAT_SHORT2:
case SG_VERTEXFORMAT_SHORT2N:
case SG_VERTEXFORMAT_SHORT4:
case SG_VERTEXFORMAT_SHORT4N:
return GL_SHORT;
case SG_VERTEXFORMAT_USHORT2N:
case SG_VERTEXFORMAT_USHORT4N:
return GL_UNSIGNED_SHORT;
case SG_VERTEXFORMAT_UINT10_N2:
return GL_UNSIGNED_INT_2_10_10_10_REV;
default:
SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLboolean _sg_gl_vertexformat_normalized(sg_vertex_format fmt) {
switch (fmt) {
case SG_VERTEXFORMAT_BYTE4N:
case SG_VERTEXFORMAT_UBYTE4N:
case SG_VERTEXFORMAT_SHORT2N:
case SG_VERTEXFORMAT_USHORT2N:
case SG_VERTEXFORMAT_SHORT4N:
case SG_VERTEXFORMAT_USHORT4N:
case SG_VERTEXFORMAT_UINT10_N2:
return GL_TRUE;
default:
return GL_FALSE;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_primitive_type(sg_primitive_type t) {
switch (t) {
case SG_PRIMITIVETYPE_POINTS: return GL_POINTS;
case SG_PRIMITIVETYPE_LINES: return GL_LINES;
case SG_PRIMITIVETYPE_LINE_STRIP: return GL_LINE_STRIP;
case SG_PRIMITIVETYPE_TRIANGLES: return GL_TRIANGLES;
case SG_PRIMITIVETYPE_TRIANGLE_STRIP: return GL_TRIANGLE_STRIP;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_index_type(sg_index_type t) {
switch (t) {
case SG_INDEXTYPE_NONE: return 0;
case SG_INDEXTYPE_UINT16: return GL_UNSIGNED_SHORT;
case SG_INDEXTYPE_UINT32: return GL_UNSIGNED_INT;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_compare_func(sg_compare_func cmp) {
switch (cmp) {
case SG_COMPAREFUNC_NEVER: return GL_NEVER;
case SG_COMPAREFUNC_LESS: return GL_LESS;
case SG_COMPAREFUNC_EQUAL: return GL_EQUAL;
case SG_COMPAREFUNC_LESS_EQUAL: return GL_LEQUAL;
case SG_COMPAREFUNC_GREATER: return GL_GREATER;
case SG_COMPAREFUNC_NOT_EQUAL: return GL_NOTEQUAL;
case SG_COMPAREFUNC_GREATER_EQUAL: return GL_GEQUAL;
case SG_COMPAREFUNC_ALWAYS: return GL_ALWAYS;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_stencil_op(sg_stencil_op op) {
switch (op) {
case SG_STENCILOP_KEEP: return GL_KEEP;
case SG_STENCILOP_ZERO: return GL_ZERO;
case SG_STENCILOP_REPLACE: return GL_REPLACE;
case SG_STENCILOP_INCR_CLAMP: return GL_INCR;
case SG_STENCILOP_DECR_CLAMP: return GL_DECR;
case SG_STENCILOP_INVERT: return GL_INVERT;
case SG_STENCILOP_INCR_WRAP: return GL_INCR_WRAP;
case SG_STENCILOP_DECR_WRAP: return GL_DECR_WRAP;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_blend_factor(sg_blend_factor f) {
switch (f) {
case SG_BLENDFACTOR_ZERO: return GL_ZERO;
case SG_BLENDFACTOR_ONE: return GL_ONE;
case SG_BLENDFACTOR_SRC_COLOR: return GL_SRC_COLOR;
case SG_BLENDFACTOR_ONE_MINUS_SRC_COLOR: return GL_ONE_MINUS_SRC_COLOR;
case SG_BLENDFACTOR_SRC_ALPHA: return GL_SRC_ALPHA;
case SG_BLENDFACTOR_ONE_MINUS_SRC_ALPHA: return GL_ONE_MINUS_SRC_ALPHA;
case SG_BLENDFACTOR_DST_COLOR: return GL_DST_COLOR;
case SG_BLENDFACTOR_ONE_MINUS_DST_COLOR: return GL_ONE_MINUS_DST_COLOR;
case SG_BLENDFACTOR_DST_ALPHA: return GL_DST_ALPHA;
case SG_BLENDFACTOR_ONE_MINUS_DST_ALPHA: return GL_ONE_MINUS_DST_ALPHA;
case SG_BLENDFACTOR_SRC_ALPHA_SATURATED: return GL_SRC_ALPHA_SATURATE;
case SG_BLENDFACTOR_BLEND_COLOR: return GL_CONSTANT_COLOR;
case SG_BLENDFACTOR_ONE_MINUS_BLEND_COLOR: return GL_ONE_MINUS_CONSTANT_COLOR;
case SG_BLENDFACTOR_BLEND_ALPHA: return GL_CONSTANT_ALPHA;
case SG_BLENDFACTOR_ONE_MINUS_BLEND_ALPHA: return GL_ONE_MINUS_CONSTANT_ALPHA;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_blend_op(sg_blend_op op) {
switch (op) {
case SG_BLENDOP_ADD: return GL_FUNC_ADD;
case SG_BLENDOP_SUBTRACT: return GL_FUNC_SUBTRACT;
case SG_BLENDOP_REVERSE_SUBTRACT: return GL_FUNC_REVERSE_SUBTRACT;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_filter(sg_filter f) {
switch (f) {
case SG_FILTER_NEAREST: return GL_NEAREST;
case SG_FILTER_LINEAR: return GL_LINEAR;
case SG_FILTER_NEAREST_MIPMAP_NEAREST: return GL_NEAREST_MIPMAP_NEAREST;
case SG_FILTER_NEAREST_MIPMAP_LINEAR: return GL_NEAREST_MIPMAP_LINEAR;
case SG_FILTER_LINEAR_MIPMAP_NEAREST: return GL_LINEAR_MIPMAP_NEAREST;
case SG_FILTER_LINEAR_MIPMAP_LINEAR: return GL_LINEAR_MIPMAP_LINEAR;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_wrap(sg_wrap w) {
switch (w) {
case SG_WRAP_CLAMP_TO_EDGE: return GL_CLAMP_TO_EDGE;
#if defined(SOKOL_GLCORE33)
case SG_WRAP_CLAMP_TO_BORDER: return GL_CLAMP_TO_BORDER;
#else
case SG_WRAP_CLAMP_TO_BORDER: return GL_CLAMP_TO_EDGE;
#endif
case SG_WRAP_REPEAT: return GL_REPEAT;
case SG_WRAP_MIRRORED_REPEAT: return GL_MIRRORED_REPEAT;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_teximage_type(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_R8:
case SG_PIXELFORMAT_R8UI:
case SG_PIXELFORMAT_RG8:
case SG_PIXELFORMAT_RG8UI:
case SG_PIXELFORMAT_RGBA8:
case SG_PIXELFORMAT_RGBA8UI:
case SG_PIXELFORMAT_BGRA8:
return GL_UNSIGNED_BYTE;
case SG_PIXELFORMAT_R8SN:
case SG_PIXELFORMAT_R8SI:
case SG_PIXELFORMAT_RG8SN:
case SG_PIXELFORMAT_RG8SI:
case SG_PIXELFORMAT_RGBA8SN:
case SG_PIXELFORMAT_RGBA8SI:
return GL_BYTE;
case SG_PIXELFORMAT_R16:
case SG_PIXELFORMAT_R16UI:
case SG_PIXELFORMAT_RG16:
case SG_PIXELFORMAT_RG16UI:
case SG_PIXELFORMAT_RGBA16:
case SG_PIXELFORMAT_RGBA16UI:
return GL_UNSIGNED_SHORT;
case SG_PIXELFORMAT_R16SN:
case SG_PIXELFORMAT_R16SI:
case SG_PIXELFORMAT_RG16SN:
case SG_PIXELFORMAT_RG16SI:
case SG_PIXELFORMAT_RGBA16SN:
case SG_PIXELFORMAT_RGBA16SI:
return GL_SHORT;
case SG_PIXELFORMAT_R16F:
case SG_PIXELFORMAT_RG16F:
case SG_PIXELFORMAT_RGBA16F:
return GL_HALF_FLOAT;
case SG_PIXELFORMAT_R32UI:
case SG_PIXELFORMAT_RG32UI:
case SG_PIXELFORMAT_RGBA32UI:
return GL_UNSIGNED_INT;
case SG_PIXELFORMAT_R32SI:
case SG_PIXELFORMAT_RG32SI:
case SG_PIXELFORMAT_RGBA32SI:
return GL_INT;
case SG_PIXELFORMAT_R32F:
case SG_PIXELFORMAT_RG32F:
case SG_PIXELFORMAT_RGBA32F:
return GL_FLOAT;
#if !defined(SOKOL_GLES2)
case SG_PIXELFORMAT_RGB10A2:
return GL_UNSIGNED_INT_2_10_10_10_REV;
case SG_PIXELFORMAT_RG11B10F:
return GL_UNSIGNED_INT_10F_11F_11F_REV;
#endif
case SG_PIXELFORMAT_DEPTH:
return GL_UNSIGNED_SHORT;
case SG_PIXELFORMAT_DEPTH_STENCIL:
return GL_UNSIGNED_INT_24_8;
default:
SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_teximage_format(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_R8:
case SG_PIXELFORMAT_R8SN:
case SG_PIXELFORMAT_R16:
case SG_PIXELFORMAT_R16SN:
case SG_PIXELFORMAT_R16F:
case SG_PIXELFORMAT_R32F:
#if defined(SOKOL_GLES2)
return GL_LUMINANCE;
#else
if (_sg.gl.gles2) {
return GL_LUMINANCE;
}
else {
return GL_RED;
}
#endif
#if !defined(SOKOL_GLES2)
case SG_PIXELFORMAT_R8UI:
case SG_PIXELFORMAT_R8SI:
case SG_PIXELFORMAT_R16UI:
case SG_PIXELFORMAT_R16SI:
case SG_PIXELFORMAT_R32UI:
case SG_PIXELFORMAT_R32SI:
return GL_RED_INTEGER;
case SG_PIXELFORMAT_RG8:
case SG_PIXELFORMAT_RG8SN:
case SG_PIXELFORMAT_RG16:
case SG_PIXELFORMAT_RG16SN:
case SG_PIXELFORMAT_RG16F:
case SG_PIXELFORMAT_RG32F:
return GL_RG;
case SG_PIXELFORMAT_RG8UI:
case SG_PIXELFORMAT_RG8SI:
case SG_PIXELFORMAT_RG16UI:
case SG_PIXELFORMAT_RG16SI:
case SG_PIXELFORMAT_RG32UI:
case SG_PIXELFORMAT_RG32SI:
return GL_RG_INTEGER;
#endif
case SG_PIXELFORMAT_RGBA8:
case SG_PIXELFORMAT_RGBA8SN:
case SG_PIXELFORMAT_RGBA16:
case SG_PIXELFORMAT_RGBA16SN:
case SG_PIXELFORMAT_RGBA16F:
case SG_PIXELFORMAT_RGBA32F:
case SG_PIXELFORMAT_RGB10A2:
return GL_RGBA;
#if !defined(SOKOL_GLES2)
case SG_PIXELFORMAT_RGBA8UI:
case SG_PIXELFORMAT_RGBA8SI:
case SG_PIXELFORMAT_RGBA16UI:
case SG_PIXELFORMAT_RGBA16SI:
case SG_PIXELFORMAT_RGBA32UI:
case SG_PIXELFORMAT_RGBA32SI:
return GL_RGBA_INTEGER;
#endif
case SG_PIXELFORMAT_RG11B10F:
return GL_RGB;
case SG_PIXELFORMAT_DEPTH:
return GL_DEPTH_COMPONENT;
case SG_PIXELFORMAT_DEPTH_STENCIL:
return GL_DEPTH_STENCIL;
case SG_PIXELFORMAT_BC1_RGBA:
return GL_COMPRESSED_RGBA_S3TC_DXT1_EXT;
case SG_PIXELFORMAT_BC2_RGBA:
return GL_COMPRESSED_RGBA_S3TC_DXT3_EXT;
case SG_PIXELFORMAT_BC3_RGBA:
return GL_COMPRESSED_RGBA_S3TC_DXT5_EXT;
case SG_PIXELFORMAT_BC4_R:
return GL_COMPRESSED_RED_RGTC1;
case SG_PIXELFORMAT_BC4_RSN:
return GL_COMPRESSED_SIGNED_RED_RGTC1;
case SG_PIXELFORMAT_BC5_RG:
return GL_COMPRESSED_RED_GREEN_RGTC2;
case SG_PIXELFORMAT_BC5_RGSN:
return GL_COMPRESSED_SIGNED_RED_GREEN_RGTC2;
case SG_PIXELFORMAT_BC6H_RGBF:
return GL_COMPRESSED_RGB_BPTC_SIGNED_FLOAT_ARB;
case SG_PIXELFORMAT_BC6H_RGBUF:
return GL_COMPRESSED_RGB_BPTC_UNSIGNED_FLOAT_ARB;
case SG_PIXELFORMAT_BC7_RGBA:
return GL_COMPRESSED_RGBA_BPTC_UNORM_ARB;
case SG_PIXELFORMAT_PVRTC_RGB_2BPP:
return GL_COMPRESSED_RGB_PVRTC_2BPPV1_IMG;
case SG_PIXELFORMAT_PVRTC_RGB_4BPP:
return GL_COMPRESSED_RGB_PVRTC_4BPPV1_IMG;
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP:
return GL_COMPRESSED_RGBA_PVRTC_2BPPV1_IMG;
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP:
return GL_COMPRESSED_RGBA_PVRTC_4BPPV1_IMG;
case SG_PIXELFORMAT_ETC2_RGB8:
return GL_COMPRESSED_RGB8_ETC2;
case SG_PIXELFORMAT_ETC2_RGB8A1:
return GL_COMPRESSED_RGB8_PUNCHTHROUGH_ALPHA1_ETC2;
case SG_PIXELFORMAT_ETC2_RGBA8:
return GL_COMPRESSED_RGBA8_ETC2_EAC;
case SG_PIXELFORMAT_ETC2_RG11:
return GL_COMPRESSED_RG11_EAC;
case SG_PIXELFORMAT_ETC2_RG11SN:
return GL_COMPRESSED_SIGNED_RG11_EAC;
default:
SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_teximage_internal_format(sg_pixel_format fmt) {
#if defined(SOKOL_GLES2)
return _sg_gl_teximage_format(fmt);
#else
if (_sg.gl.gles2) {
return _sg_gl_teximage_format(fmt);
}
else {
switch (fmt) {
case SG_PIXELFORMAT_R8: return GL_R8;
case SG_PIXELFORMAT_R8SN: return GL_R8_SNORM;
case SG_PIXELFORMAT_R8UI: return GL_R8UI;
case SG_PIXELFORMAT_R8SI: return GL_R8I;
#if !defined(SOKOL_GLES3)
case SG_PIXELFORMAT_R16: return GL_R16;
case SG_PIXELFORMAT_R16SN: return GL_R16_SNORM;
#endif
case SG_PIXELFORMAT_R16UI: return GL_R16UI;
case SG_PIXELFORMAT_R16SI: return GL_R16I;
case SG_PIXELFORMAT_R16F: return GL_R16F;
case SG_PIXELFORMAT_RG8: return GL_RG8;
case SG_PIXELFORMAT_RG8SN: return GL_RG8_SNORM;
case SG_PIXELFORMAT_RG8UI: return GL_RG8UI;
case SG_PIXELFORMAT_RG8SI: return GL_RG8I;
case SG_PIXELFORMAT_R32UI: return GL_R32UI;
case SG_PIXELFORMAT_R32SI: return GL_R32I;
case SG_PIXELFORMAT_R32F: return GL_R32F;
#if !defined(SOKOL_GLES3)
case SG_PIXELFORMAT_RG16: return GL_RG16;
case SG_PIXELFORMAT_RG16SN: return GL_RG16_SNORM;
#endif
case SG_PIXELFORMAT_RG16UI: return GL_RG16UI;
case SG_PIXELFORMAT_RG16SI: return GL_RG16I;
case SG_PIXELFORMAT_RG16F: return GL_RG16F;
case SG_PIXELFORMAT_RGBA8: return GL_RGBA8;
case SG_PIXELFORMAT_RGBA8SN: return GL_RGBA8_SNORM;
case SG_PIXELFORMAT_RGBA8UI: return GL_RGBA8UI;
case SG_PIXELFORMAT_RGBA8SI: return GL_RGBA8I;
case SG_PIXELFORMAT_RGB10A2: return GL_RGB10_A2;
case SG_PIXELFORMAT_RG11B10F: return GL_R11F_G11F_B10F;
case SG_PIXELFORMAT_RG32UI: return GL_RG32UI;
case SG_PIXELFORMAT_RG32SI: return GL_RG32I;
case SG_PIXELFORMAT_RG32F: return GL_RG32F;
#if !defined(SOKOL_GLES3)
case SG_PIXELFORMAT_RGBA16: return GL_RGBA16;
case SG_PIXELFORMAT_RGBA16SN: return GL_RGBA16_SNORM;
#endif
case SG_PIXELFORMAT_RGBA16UI: return GL_RGBA16UI;
case SG_PIXELFORMAT_RGBA16SI: return GL_RGBA16I;
case SG_PIXELFORMAT_RGBA16F: return GL_RGBA16F;
case SG_PIXELFORMAT_RGBA32UI: return GL_RGBA32UI;
case SG_PIXELFORMAT_RGBA32SI: return GL_RGBA32I;
case SG_PIXELFORMAT_RGBA32F: return GL_RGBA32F;
case SG_PIXELFORMAT_DEPTH: return GL_DEPTH_COMPONENT16;
case SG_PIXELFORMAT_DEPTH_STENCIL: return GL_DEPTH24_STENCIL8;
case SG_PIXELFORMAT_BC1_RGBA: return GL_COMPRESSED_RGBA_S3TC_DXT1_EXT;
case SG_PIXELFORMAT_BC2_RGBA: return GL_COMPRESSED_RGBA_S3TC_DXT3_EXT;
case SG_PIXELFORMAT_BC3_RGBA: return GL_COMPRESSED_RGBA_S3TC_DXT5_EXT;
case SG_PIXELFORMAT_BC4_R: return GL_COMPRESSED_RED_RGTC1;
case SG_PIXELFORMAT_BC4_RSN: return GL_COMPRESSED_SIGNED_RED_RGTC1;
case SG_PIXELFORMAT_BC5_RG: return GL_COMPRESSED_RED_GREEN_RGTC2;
case SG_PIXELFORMAT_BC5_RGSN: return GL_COMPRESSED_SIGNED_RED_GREEN_RGTC2;
case SG_PIXELFORMAT_BC6H_RGBF: return GL_COMPRESSED_RGB_BPTC_SIGNED_FLOAT_ARB;
case SG_PIXELFORMAT_BC6H_RGBUF: return GL_COMPRESSED_RGB_BPTC_UNSIGNED_FLOAT_ARB;
case SG_PIXELFORMAT_BC7_RGBA: return GL_COMPRESSED_RGBA_BPTC_UNORM_ARB;
case SG_PIXELFORMAT_PVRTC_RGB_2BPP: return GL_COMPRESSED_RGB_PVRTC_2BPPV1_IMG;
case SG_PIXELFORMAT_PVRTC_RGB_4BPP: return GL_COMPRESSED_RGB_PVRTC_4BPPV1_IMG;
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP: return GL_COMPRESSED_RGBA_PVRTC_2BPPV1_IMG;
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP: return GL_COMPRESSED_RGBA_PVRTC_4BPPV1_IMG;
case SG_PIXELFORMAT_ETC2_RGB8: return GL_COMPRESSED_RGB8_ETC2;
case SG_PIXELFORMAT_ETC2_RGB8A1: return GL_COMPRESSED_RGB8_PUNCHTHROUGH_ALPHA1_ETC2;
case SG_PIXELFORMAT_ETC2_RGBA8: return GL_COMPRESSED_RGBA8_ETC2_EAC;
case SG_PIXELFORMAT_ETC2_RG11: return GL_COMPRESSED_RG11_EAC;
case SG_PIXELFORMAT_ETC2_RG11SN: return GL_COMPRESSED_SIGNED_RG11_EAC;
default: SOKOL_UNREACHABLE; return 0;
}
}
#endif
}
_SOKOL_PRIVATE GLenum _sg_gl_cubeface_target(int face_index) {
switch (face_index) {
case 0: return GL_TEXTURE_CUBE_MAP_POSITIVE_X;
case 1: return GL_TEXTURE_CUBE_MAP_NEGATIVE_X;
case 2: return GL_TEXTURE_CUBE_MAP_POSITIVE_Y;
case 3: return GL_TEXTURE_CUBE_MAP_NEGATIVE_Y;
case 4: return GL_TEXTURE_CUBE_MAP_POSITIVE_Z;
case 5: return GL_TEXTURE_CUBE_MAP_NEGATIVE_Z;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE GLenum _sg_gl_depth_attachment_format(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_DEPTH: return GL_DEPTH_COMPONENT16;
case SG_PIXELFORMAT_DEPTH_STENCIL: return GL_DEPTH24_STENCIL8;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE void _sg_gl_init_attr(_sg_gl_attr_t* attr) {
attr->vb_index = -1;
attr->divisor = -1;
}
_SOKOL_PRIVATE void _sg_gl_init_stencil_state(sg_stencil_state* s) {
SOKOL_ASSERT(s);
s->fail_op = SG_STENCILOP_KEEP;
s->depth_fail_op = SG_STENCILOP_KEEP;
s->pass_op = SG_STENCILOP_KEEP;
s->compare_func = SG_COMPAREFUNC_ALWAYS;
}
_SOKOL_PRIVATE void _sg_gl_init_depth_stencil_state(sg_depth_stencil_state* s) {
SOKOL_ASSERT(s);
_sg_gl_init_stencil_state(&s->stencil_front);
_sg_gl_init_stencil_state(&s->stencil_back);
s->depth_compare_func = SG_COMPAREFUNC_ALWAYS;
}
_SOKOL_PRIVATE void _sg_gl_init_blend_state(sg_blend_state* s) {
SOKOL_ASSERT(s);
s->src_factor_rgb = SG_BLENDFACTOR_ONE;
s->dst_factor_rgb = SG_BLENDFACTOR_ZERO;
s->op_rgb = SG_BLENDOP_ADD;
s->src_factor_alpha = SG_BLENDFACTOR_ONE;
s->dst_factor_alpha = SG_BLENDFACTOR_ZERO;
s->op_alpha = SG_BLENDOP_ADD;
s->color_write_mask = SG_COLORMASK_RGBA;
}
_SOKOL_PRIVATE void _sg_gl_init_rasterizer_state(sg_rasterizer_state* s) {
SOKOL_ASSERT(s);
s->cull_mode = SG_CULLMODE_NONE;
s->face_winding = SG_FACEWINDING_CW;
s->sample_count = 1;
}
/* see: https://www.khronos.org/registry/OpenGL-Refpages/es3.0/html/glTexImage2D.xhtml */
_SOKOL_PRIVATE void _sg_gl_init_pixelformats(bool has_bgra) {
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R8]);
}
else {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R8]);
}
#else
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R8]);
#endif
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R8SN]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R8UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R8SI]);
#if !defined(SOKOL_GLES3)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R16]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R16SN]);
#endif
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R16UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R16SI]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG8]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RG8SN]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG8UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG8SI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_R32UI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_R32SI]);
#if !defined(SOKOL_GLES3)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG16]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG16SN]);
#endif
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG16UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG16SI]);
}
#endif
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA8]);
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RGBA8SN]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA8UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA8SI]);
}
#endif
if (has_bgra) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_BGRA8]);
}
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGB10A2]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RG11B10F]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG32UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG32SI]);
#if !defined(SOKOL_GLES3)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16SN]);
#endif
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA16UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA16SI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA32UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA32SI]);
}
#endif
// FIXME: WEBGL_depth_texture extension?
_sg_pixelformat_srmd(&_sg.formats[SG_PIXELFORMAT_DEPTH]);
_sg_pixelformat_srmd(&_sg.formats[SG_PIXELFORMAT_DEPTH_STENCIL]);
}
/* FIXME: OES_half_float_blend */
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_half_float(bool has_colorbuffer_half_float, bool has_texture_half_float_linear) {
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
if (has_texture_half_float_linear) {
if (has_colorbuffer_half_float) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R16F]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG16F]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
else {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R16F]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RG16F]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
}
else {
if (has_colorbuffer_half_float) {
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_R16F]);
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_RG16F]);
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
else {
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_R16F]);
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_RG16F]);
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
}
}
else {
#endif
/* GLES2 can only render to RGBA, and there's no RG format */
if (has_texture_half_float_linear) {
if (has_colorbuffer_half_float) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
else {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R16F]);
}
else {
if (has_colorbuffer_half_float) {
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
else {
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
}
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_R16F]);
}
#if !defined(SOKOL_GLES2)
}
#endif
}
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_float(bool has_colorbuffer_float, bool has_texture_float_linear, bool has_float_blend) {
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
if (has_texture_float_linear) {
if (has_colorbuffer_float) {
if (has_float_blend) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R32F]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG32F]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
else {
_sg_pixelformat_sfrm(&_sg.formats[SG_PIXELFORMAT_R32F]);
_sg_pixelformat_sfrm(&_sg.formats[SG_PIXELFORMAT_RG32F]);
_sg_pixelformat_sfrm(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
}
else {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R32F]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RG32F]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
}
else {
if (has_colorbuffer_float) {
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_R32F]);
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_RG32F]);
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
else {
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_R32F]);
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_RG32F]);
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
}
}
else {
#endif
/* GLES2 can only render to RGBA, and there's no RG format */
if (has_texture_float_linear) {
if (has_colorbuffer_float) {
if (has_float_blend) {
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
else {
_sg_pixelformat_sfrm(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
}
else {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_R32F]);
}
else {
if (has_colorbuffer_float) {
_sg_pixelformat_sbrm(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
else {
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
}
_sg_pixelformat_s(&_sg.formats[SG_PIXELFORMAT_R32F]);
}
#if !defined(SOKOL_GLES2)
}
#endif
}
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_s3tc(void) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC1_RGBA]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC2_RGBA]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC3_RGBA]);
}
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_rgtc(void) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC4_R]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC4_RSN]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC5_RG]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC5_RGSN]);
}
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_bptc(void) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC6H_RGBF]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC6H_RGBUF]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC7_RGBA]);
}
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_pvrtc(void) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGB_2BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGB_4BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGBA_2BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGBA_4BPP]);
}
_SOKOL_PRIVATE void _sg_gl_init_pixelformats_etc2(void) {
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RGB8]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RGB8A1]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RGBA8]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RG11]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RG11SN]);
}
_SOKOL_PRIVATE void _sg_gl_init_limits(void) {
_SG_GL_CHECK_ERROR();
GLint gl_int;
glGetIntegerv(GL_MAX_TEXTURE_SIZE, &gl_int);
_SG_GL_CHECK_ERROR();
_sg.limits.max_image_size_2d = gl_int;
_sg.limits.max_image_size_array = gl_int;
glGetIntegerv(GL_MAX_CUBE_MAP_TEXTURE_SIZE, &gl_int);
_SG_GL_CHECK_ERROR();
_sg.limits.max_image_size_cube = gl_int;
glGetIntegerv(GL_MAX_VERTEX_ATTRIBS, &gl_int);
_SG_GL_CHECK_ERROR();
if (gl_int > SG_MAX_VERTEX_ATTRIBUTES) {
gl_int = SG_MAX_VERTEX_ATTRIBUTES;
}
_sg.limits.max_vertex_attrs = gl_int;
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
glGetIntegerv(GL_MAX_3D_TEXTURE_SIZE, &gl_int);
_SG_GL_CHECK_ERROR();
_sg.limits.max_image_size_3d = gl_int;
glGetIntegerv(GL_MAX_ARRAY_TEXTURE_LAYERS, &gl_int);
_SG_GL_CHECK_ERROR();
_sg.limits.max_image_array_layers = gl_int;
}
#endif
if (_sg.gl.ext_anisotropic) {
glGetIntegerv(GL_MAX_TEXTURE_MAX_ANISOTROPY_EXT, &gl_int);
_SG_GL_CHECK_ERROR();
_sg.gl.max_anisotropy = gl_int;
}
else {
_sg.gl.max_anisotropy = 1;
}
glGetIntegerv(GL_MAX_COMBINED_TEXTURE_IMAGE_UNITS, &gl_int);
_SG_GL_CHECK_ERROR();
_sg.gl.max_combined_texture_image_units = gl_int;
}
#if defined(SOKOL_GLCORE33)
_SOKOL_PRIVATE void _sg_gl_init_caps_glcore33(void) {
_sg.backend = SG_BACKEND_GLCORE33;
_sg.features.origin_top_left = false;
_sg.features.instancing = true;
_sg.features.multiple_render_targets = true;
_sg.features.msaa_render_targets = true;
_sg.features.imagetype_3d = true;
_sg.features.imagetype_array = true;
_sg.features.image_clamp_to_border = true;
/* scan extensions */
bool has_s3tc = false; /* BC1..BC3 */
bool has_rgtc = false; /* BC4 and BC5 */
bool has_bptc = false; /* BC6H and BC7 */
bool has_pvrtc = false;
bool has_etc2 = false;
GLint num_ext = 0;
glGetIntegerv(GL_NUM_EXTENSIONS, &num_ext);
for (int i = 0; i < num_ext; i++) {
const char* ext = (const char*) glGetStringi(GL_EXTENSIONS, i);
if (ext) {
if (strstr(ext, "_texture_compression_s3tc")) {
has_s3tc = true;
}
else if (strstr(ext, "_texture_compression_rgtc")) {
has_rgtc = true;
}
else if (strstr(ext, "_texture_compression_bptc")) {
has_bptc = true;
}
else if (strstr(ext, "_texture_compression_pvrtc")) {
has_pvrtc = true;
}
else if (strstr(ext, "_ES3_compatibility")) {
has_etc2 = true;
}
else if (strstr(ext, "_texture_filter_anisotropic")) {
_sg.gl.ext_anisotropic = true;
}
}
}
/* limits */
_sg_gl_init_limits();
/* pixel formats */
const bool has_bgra = false; /* not a bug */
const bool has_colorbuffer_float = true;
const bool has_colorbuffer_half_float = true;
const bool has_texture_float_linear = true; /* FIXME??? */
const bool has_texture_half_float_linear = true;
const bool has_float_blend = true;
_sg_gl_init_pixelformats(has_bgra);
_sg_gl_init_pixelformats_float(has_colorbuffer_float, has_texture_float_linear, has_float_blend);
_sg_gl_init_pixelformats_half_float(has_colorbuffer_half_float, has_texture_half_float_linear);
if (has_s3tc) {
_sg_gl_init_pixelformats_s3tc();
}
if (has_rgtc) {
_sg_gl_init_pixelformats_rgtc();
}
if (has_bptc) {
_sg_gl_init_pixelformats_bptc();
}
if (has_pvrtc) {
_sg_gl_init_pixelformats_pvrtc();
}
if (has_etc2) {
_sg_gl_init_pixelformats_etc2();
}
}
#endif
#if defined(SOKOL_GLES3)
_SOKOL_PRIVATE void _sg_gl_init_caps_gles3(void) {
_sg.backend = SG_BACKEND_GLES3;
_sg.features.origin_top_left = false;
_sg.features.instancing = true;
_sg.features.multiple_render_targets = true;
_sg.features.msaa_render_targets = true;
_sg.features.imagetype_3d = true;
_sg.features.imagetype_array = true;
_sg.features.image_clamp_to_border = false;
bool has_s3tc = false; /* BC1..BC3 */
bool has_rgtc = false; /* BC4 and BC5 */
bool has_bptc = false; /* BC6H and BC7 */
bool has_pvrtc = false;
#if defined(__EMSCRIPTEN__)
bool has_etc2 = false;
#else
bool has_etc2 = true;
#endif
bool has_colorbuffer_float = false;
bool has_colorbuffer_half_float = false;
bool has_texture_float_linear = false;
bool has_float_blend = false;
GLint num_ext = 0;
glGetIntegerv(GL_NUM_EXTENSIONS, &num_ext);
for (int i = 0; i < num_ext; i++) {
const char* ext = (const char*) glGetStringi(GL_EXTENSIONS, i);
if (ext) {
if (strstr(ext, "_texture_compression_s3tc")) {
has_s3tc = true;
}
else if (strstr(ext, "_compressed_texture_s3tc")) {
has_s3tc = true;
}
else if (strstr(ext, "_texture_compression_rgtc")) {
has_rgtc = true;
}
else if (strstr(ext, "_texture_compression_bptc")) {
has_bptc = true;
}
else if (strstr(ext, "_texture_compression_pvrtc")) {
has_pvrtc = true;
}
else if (strstr(ext, "_compressed_texture_etc")) {
has_etc2 = true;
}
else if (strstr(ext, "_color_buffer_float")) {
has_colorbuffer_float = true;
}
else if (strstr(ext, "_color_buffer_half_float")) {
has_colorbuffer_half_float = true;
}
else if (strstr(ext, "_texture_float_linear")) {
has_texture_float_linear = true;
}
else if (strstr(ext, "_float_blend")) {
has_float_blend = true;
}
else if (strstr(ext, "_texture_filter_anisotropic")) {
_sg.gl.ext_anisotropic = true;
}
}
}
/* limits */
_sg_gl_init_limits();
/* pixel formats */
const bool has_texture_half_float_linear = true;
const bool has_bgra = false; /* not a bug */
_sg_gl_init_pixelformats(has_bgra);
_sg_gl_init_pixelformats_float(has_colorbuffer_float, has_texture_float_linear, has_float_blend);
_sg_gl_init_pixelformats_half_float(has_colorbuffer_half_float, has_texture_half_float_linear);
if (has_s3tc) {
_sg_gl_init_pixelformats_s3tc();
}
if (has_rgtc) {
_sg_gl_init_pixelformats_rgtc();
}
if (has_bptc) {
_sg_gl_init_pixelformats_bptc();
}
if (has_pvrtc) {
_sg_gl_init_pixelformats_pvrtc();
}
if (has_etc2) {
_sg_gl_init_pixelformats_etc2();
}
}
#endif
#if defined(SOKOL_GLES3) || defined(SOKOL_GLES2)
_SOKOL_PRIVATE void _sg_gl_init_caps_gles2(void) {
_sg.backend = SG_BACKEND_GLES2;
bool has_s3tc = false; /* BC1..BC3 */
bool has_rgtc = false; /* BC4 and BC5 */
bool has_bptc = false; /* BC6H and BC7 */
bool has_pvrtc = false;
bool has_etc2 = false;
bool has_texture_float = false;
bool has_texture_float_linear = false;
bool has_colorbuffer_float = false;
bool has_float_blend = false;
bool has_instancing = false;
const char* ext = (const char*) glGetString(GL_EXTENSIONS);
if (ext) {
has_s3tc = strstr(ext, "_texture_compression_s3tc") || strstr(ext, "_compressed_texture_s3tc");
has_rgtc = strstr(ext, "_texture_compression_rgtc");
has_bptc = strstr(ext, "_texture_compression_bptc");
has_pvrtc = strstr(ext, "_texture_compression_pvrtc");
has_etc2 = strstr(ext, "_compressed_texture_etc");
has_texture_float = strstr(ext, "_texture_float");
has_texture_float_linear = strstr(ext, "_texture_float_linear");
has_colorbuffer_float = strstr(ext, "_color_buffer_float");
has_float_blend = strstr(ext, "_float_blend");
/* don't bother with half_float support on WebGL1
has_texture_half_float = strstr(ext, "_texture_half_float");
has_texture_half_float_linear = strstr(ext, "_texture_half_float_linear");
has_colorbuffer_half_float = strstr(ext, "_color_buffer_half_float");
*/
has_instancing = strstr(ext, "_instanced_arrays");
_sg.gl.ext_anisotropic = strstr(ext, "ext_anisotropic");
}
_sg.features.origin_top_left = false;
#if defined(SOKOL_INSTANCING_ENABLED)
_sg.features.instancing = has_instancing;
#endif
_sg.features.multiple_render_targets = false;
_sg.features.msaa_render_targets = false;
_sg.features.imagetype_3d = false;
_sg.features.imagetype_array = false;
_sg.features.image_clamp_to_border = false;
/* limits */
_sg_gl_init_limits();
/* pixel formats */
const bool has_bgra = false; /* not a bug */
const bool has_texture_half_float = false;
const bool has_texture_half_float_linear = false;
const bool has_colorbuffer_half_float = false;
_sg_gl_init_pixelformats(has_bgra);
if (has_texture_float) {
_sg_gl_init_pixelformats_float(has_colorbuffer_float, has_texture_float_linear, has_float_blend);
}
if (has_texture_half_float) {
_sg_gl_init_pixelformats_half_float(has_colorbuffer_half_float, has_texture_half_float_linear);
}
if (has_s3tc) {
_sg_gl_init_pixelformats_s3tc();
}
if (has_rgtc) {
_sg_gl_init_pixelformats_rgtc();
}
if (has_bptc) {
_sg_gl_init_pixelformats_bptc();
}
if (has_pvrtc) {
_sg_gl_init_pixelformats_pvrtc();
}
if (has_etc2) {
_sg_gl_init_pixelformats_etc2();
}
/* GLES2 doesn't allow multi-sampled render targets at all */
for (int i = 0; i < _SG_PIXELFORMAT_NUM; i++) {
_sg.formats[i].msaa = false;
}
}
#endif
/*-- state cache implementation ----------------------------------------------*/
_SOKOL_PRIVATE void _sg_gl_clear_buffer_bindings(bool force) {
if (force || (_sg.gl.cache.vertex_buffer != 0)) {
glBindBuffer(GL_ARRAY_BUFFER, 0);
_sg.gl.cache.vertex_buffer = 0;
}
if (force || (_sg.gl.cache.index_buffer != 0)) {
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0);
_sg.gl.cache.index_buffer = 0;
}
}
_SOKOL_PRIVATE void _sg_gl_bind_buffer(GLenum target, GLuint buffer) {
SOKOL_ASSERT((GL_ARRAY_BUFFER == target) || (GL_ELEMENT_ARRAY_BUFFER == target));
if (target == GL_ARRAY_BUFFER) {
if (_sg.gl.cache.vertex_buffer != buffer) {
_sg.gl.cache.vertex_buffer = buffer;
glBindBuffer(target, buffer);
}
}
else {
if (_sg.gl.cache.index_buffer != buffer) {
_sg.gl.cache.index_buffer = buffer;
glBindBuffer(target, buffer);
}
}
}
_SOKOL_PRIVATE void _sg_gl_store_buffer_binding(GLenum target) {
if (target == GL_ARRAY_BUFFER) {
_sg.gl.cache.stored_vertex_buffer = _sg.gl.cache.vertex_buffer;
}
else {
_sg.gl.cache.stored_index_buffer = _sg.gl.cache.index_buffer;
}
}
_SOKOL_PRIVATE void _sg_gl_restore_buffer_binding(GLenum target) {
if (target == GL_ARRAY_BUFFER) {
_sg_gl_bind_buffer(target, _sg.gl.cache.stored_vertex_buffer);
}
else {
_sg_gl_bind_buffer(target, _sg.gl.cache.stored_index_buffer);
}
}
_SOKOL_PRIVATE void _sg_gl_clear_texture_bindings(bool force) {
for (int i = 0; (i < SG_MAX_SHADERSTAGE_IMAGES) && (i < _sg.gl.max_combined_texture_image_units); i++) {
if (force || (_sg.gl.cache.textures[i].texture != 0)) {
glActiveTexture(GL_TEXTURE0 + i);
glBindTexture(GL_TEXTURE_2D, 0);
glBindTexture(GL_TEXTURE_CUBE_MAP, 0);
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
glBindTexture(GL_TEXTURE_3D, 0);
glBindTexture(GL_TEXTURE_2D_ARRAY, 0);
}
#endif
_sg.gl.cache.textures[i].target = 0;
_sg.gl.cache.textures[i].texture = 0;
}
}
}
_SOKOL_PRIVATE void _sg_gl_bind_texture(int slot_index, GLenum target, GLuint texture) {
/* it's valid to call this function with target=0 and/or texture=0
target=0 will unbind the previous binding, texture=0 will clear
the new binding
*/
SOKOL_ASSERT(slot_index < SG_MAX_SHADERSTAGE_IMAGES);
if (slot_index >= _sg.gl.max_combined_texture_image_units) {
return;
}
_sg_gl_texture_bind_slot* slot = &_sg.gl.cache.textures[slot_index];
if ((slot->target != target) || (slot->texture != texture)) {
glActiveTexture(GL_TEXTURE0 + slot_index);
/* if the target has changed, clear the previous binding on that target */
if ((target != slot->target) && (slot->target != 0)) {
glBindTexture(slot->target, 0);
}
/* apply new binding (texture can be 0 to unbind) */
if (target != 0) {
glBindTexture(target, texture);
}
slot->target = target;
slot->texture = texture;
}
}
_SOKOL_PRIVATE void _sg_gl_store_texture_binding(int slot_index) {
SOKOL_ASSERT(slot_index < SG_MAX_SHADERSTAGE_IMAGES);
_sg.gl.cache.stored_texture = _sg.gl.cache.textures[slot_index];
}
_SOKOL_PRIVATE void _sg_gl_restore_texture_binding(int slot_index) {
SOKOL_ASSERT(slot_index < SG_MAX_SHADERSTAGE_IMAGES);
const _sg_gl_texture_bind_slot* slot = &_sg.gl.cache.stored_texture;
_sg_gl_bind_texture(slot_index, slot->target, slot->texture);
}
_SOKOL_PRIVATE void _sg_gl_reset_state_cache(void) {
_SG_GL_CHECK_ERROR();
memset(&_sg.gl.cache, 0, sizeof(_sg.gl.cache));
_sg_gl_clear_buffer_bindings(true);
_SG_GL_CHECK_ERROR();
_sg_gl_clear_texture_bindings(true);
_SG_GL_CHECK_ERROR();
for (uint32_t i = 0; i < _sg.limits.max_vertex_attrs; i++) {
_sg_gl_init_attr(&_sg.gl.cache.attrs[i].gl_attr);
glDisableVertexAttribArray(i);
_SG_GL_CHECK_ERROR();
}
_sg.gl.cache.cur_primitive_type = GL_TRIANGLES;
/* depth-stencil state */
_sg_gl_init_depth_stencil_state(&_sg.gl.cache.ds);
glEnable(GL_DEPTH_TEST);
glDepthFunc(GL_ALWAYS);
glDepthMask(GL_FALSE);
glDisable(GL_STENCIL_TEST);
glStencilFunc(GL_ALWAYS, 0, 0);
glStencilOp(GL_KEEP, GL_KEEP, GL_KEEP);
glStencilMask(0);
/* blend state */
_sg_gl_init_blend_state(&_sg.gl.cache.blend);
glDisable(GL_BLEND);
glBlendFuncSeparate(GL_ONE, GL_ZERO, GL_ONE, GL_ZERO);
glBlendEquationSeparate(GL_FUNC_ADD, GL_FUNC_ADD);
glColorMask(GL_TRUE, GL_TRUE, GL_TRUE, GL_TRUE);
glBlendColor(0.0f, 0.0f, 0.0f, 0.0f);
/* rasterizer state */
_sg_gl_init_rasterizer_state(&_sg.gl.cache.rast);
glPolygonOffset(0.0f, 0.0f);
glDisable(GL_POLYGON_OFFSET_FILL);
glDisable(GL_CULL_FACE);
glFrontFace(GL_CW);
glCullFace(GL_BACK);
glEnable(GL_SCISSOR_TEST);
glDisable(GL_SAMPLE_ALPHA_TO_COVERAGE);
glEnable(GL_DITHER);
glDisable(GL_POLYGON_OFFSET_FILL);
#if defined(SOKOL_GLCORE33)
glEnable(GL_MULTISAMPLE);
glEnable(GL_PROGRAM_POINT_SIZE);
#endif
}
/*-- main GL backend state and functions -------------------------------------*/
_SOKOL_PRIVATE void _sg_setup_backend(const sg_desc* desc) {
/* assumes that _sg.gl is already zero-initialized */
_sg.gl.valid = true;
#if defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
_sg.gl.gles2 = desc->gl_force_gles2;
#else
_SOKOL_UNUSED(desc);
_sg.gl.gles2 = false;
#endif
/* clear initial GL error state */
#if defined(SOKOL_DEBUG)
while (glGetError() != GL_NO_ERROR);
#endif
#if defined(SOKOL_GLCORE33)
_sg_gl_init_caps_glcore33();
#elif defined(SOKOL_GLES3)
if (_sg.gl.gles2) {
_sg_gl_init_caps_gles2();
}
else {
_sg_gl_init_caps_gles3();
}
#else
_sg_gl_init_caps_gles2();
#endif
}
_SOKOL_PRIVATE void _sg_discard_backend(void) {
SOKOL_ASSERT(_sg.gl.valid);
_sg.gl.valid = false;
}
_SOKOL_PRIVATE void _sg_reset_state_cache(void) {
if (_sg.gl.cur_context) {
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
_SG_GL_CHECK_ERROR();
glBindVertexArray(_sg.gl.cur_context->vao);
_SG_GL_CHECK_ERROR();
}
#endif
_sg_gl_reset_state_cache();
}
}
_SOKOL_PRIVATE void _sg_activate_context(_sg_context_t* ctx) {
SOKOL_ASSERT(_sg.gl.valid);
/* NOTE: ctx can be 0 to unset the current context */
_sg.gl.cur_context = ctx;
_sg_reset_state_cache();
}
/*-- GL backend resource creation and destruction ----------------------------*/
_SOKOL_PRIVATE sg_resource_state _sg_create_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
SOKOL_ASSERT(0 == ctx->default_framebuffer);
_SG_GL_CHECK_ERROR();
glGetIntegerv(GL_FRAMEBUFFER_BINDING, (GLint*)&ctx->default_framebuffer);
_SG_GL_CHECK_ERROR();
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
SOKOL_ASSERT(0 == ctx->vao);
glGenVertexArrays(1, &ctx->vao);
glBindVertexArray(ctx->vao);
_SG_GL_CHECK_ERROR();
}
#endif
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
if (ctx->vao) {
glDeleteVertexArrays(1, &ctx->vao);
}
_SG_GL_CHECK_ERROR();
}
#endif
}
_SOKOL_PRIVATE sg_resource_state _sg_create_buffer(_sg_buffer_t* buf, const sg_buffer_desc* desc) {
SOKOL_ASSERT(buf && desc);
_SG_GL_CHECK_ERROR();
buf->size = desc->size;
buf->append_pos = 0;
buf->append_overflow = false;
buf->type = desc->type;
buf->usage = desc->usage;
buf->update_frame_index = 0;
buf->append_frame_index = 0;
buf->num_slots = (buf->usage == SG_USAGE_IMMUTABLE) ? 1 : SG_NUM_INFLIGHT_FRAMES;
buf->active_slot = 0;
buf->ext_buffers = (0 != desc->gl_buffers[0]);
GLenum gl_target = _sg_gl_buffer_target(buf->type);
GLenum gl_usage = _sg_gl_usage(buf->usage);
for (int slot = 0; slot < buf->num_slots; slot++) {
GLuint gl_buf = 0;
if (buf->ext_buffers) {
SOKOL_ASSERT(desc->gl_buffers[slot]);
gl_buf = desc->gl_buffers[slot];
}
else {
glGenBuffers(1, &gl_buf);
_sg_gl_store_buffer_binding(gl_target);
_sg_gl_bind_buffer(gl_target, gl_buf);
glBufferData(gl_target, buf->size, 0, gl_usage);
if (buf->usage == SG_USAGE_IMMUTABLE) {
SOKOL_ASSERT(desc->content);
glBufferSubData(gl_target, 0, buf->size, desc->content);
}
_sg_gl_restore_buffer_binding(gl_target);
}
buf->gl_buf[slot] = gl_buf;
}
_SG_GL_CHECK_ERROR();
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_buffer(_sg_buffer_t* buf) {
SOKOL_ASSERT(buf);
_SG_GL_CHECK_ERROR();
if (!buf->ext_buffers) {
for (int slot = 0; slot < buf->num_slots; slot++) {
if (buf->gl_buf[slot]) {
glDeleteBuffers(1, &buf->gl_buf[slot]);
}
}
_SG_GL_CHECK_ERROR();
}
}
_SOKOL_PRIVATE bool _sg_gl_supported_texture_format(sg_pixel_format fmt) {
const int fmt_index = (int) fmt;
SOKOL_ASSERT((fmt_index > SG_PIXELFORMAT_NONE) && (fmt_index < _SG_PIXELFORMAT_NUM));
return _sg.formats[fmt_index].sample;
}
_SOKOL_PRIVATE sg_resource_state _sg_create_image(_sg_image_t* img, const sg_image_desc* desc) {
SOKOL_ASSERT(img && desc);
_SG_GL_CHECK_ERROR();
img->type = desc->type;
img->render_target = desc->render_target;
img->width = desc->width;
img->height = desc->height;
img->depth = desc->depth;
img->num_mipmaps = desc->num_mipmaps;
img->usage = desc->usage;
img->pixel_format = desc->pixel_format;
img->sample_count = desc->sample_count;
img->min_filter = desc->min_filter;
img->mag_filter = desc->mag_filter;
img->wrap_u = desc->wrap_u;
img->wrap_v = desc->wrap_v;
img->wrap_w = desc->wrap_w;
img->border_color = desc->border_color;
img->max_anisotropy = desc->max_anisotropy;
img->upd_frame_index = 0;
/* check if texture format is support */
if (!_sg_gl_supported_texture_format(img->pixel_format)) {
SOKOL_LOG("texture format not supported by GL context\n");
return SG_RESOURCESTATE_FAILED;
}
/* check for optional texture types */
if ((img->type == SG_IMAGETYPE_3D) && !_sg.features.imagetype_3d) {
SOKOL_LOG("3D textures not supported by GL context\n");
return SG_RESOURCESTATE_FAILED;
}
if ((img->type == SG_IMAGETYPE_ARRAY) && !_sg.features.imagetype_array) {
SOKOL_LOG("array textures not supported by GL context\n");
return SG_RESOURCESTATE_FAILED;
}
/* create 1 or 2 GL textures, depending on requested update strategy */
img->num_slots = (img->usage == SG_USAGE_IMMUTABLE) ? 1 : SG_NUM_INFLIGHT_FRAMES;
img->active_slot = 0;
img->ext_textures = (0 != desc->gl_textures[0]);
#if !defined(SOKOL_GLES2)
bool msaa = false;
if (!_sg.gl.gles2) {
msaa = (img->sample_count > 1) && (_sg.features.msaa_render_targets);
}
#endif
if (_sg_is_valid_rendertarget_depth_format(img->pixel_format)) {
/* special case depth-stencil-buffer? */
SOKOL_ASSERT((img->usage == SG_USAGE_IMMUTABLE) && (img->num_slots == 1));
SOKOL_ASSERT(!img->ext_textures); /* cannot provide external texture for depth images */
glGenRenderbuffers(1, &img->gl_depth_render_buffer);
glBindRenderbuffer(GL_RENDERBUFFER, img->gl_depth_render_buffer);
GLenum gl_depth_format = _sg_gl_depth_attachment_format(img->pixel_format);
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2 && msaa) {
glRenderbufferStorageMultisample(GL_RENDERBUFFER, img->sample_count, gl_depth_format, img->width, img->height);
}
else
#endif
{
glRenderbufferStorage(GL_RENDERBUFFER, gl_depth_format, img->width, img->height);
}
}
else {
/* regular color texture */
img->gl_target = _sg_gl_texture_target(img->type);
const GLenum gl_internal_format = _sg_gl_teximage_internal_format(img->pixel_format);
/* if this is a MSAA render target, need to create a separate render buffer */
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2 && img->render_target && msaa) {
glGenRenderbuffers(1, &img->gl_msaa_render_buffer);
glBindRenderbuffer(GL_RENDERBUFFER, img->gl_msaa_render_buffer);
glRenderbufferStorageMultisample(GL_RENDERBUFFER, img->sample_count, gl_internal_format, img->width, img->height);
}
#endif
if (img->ext_textures) {
/* inject externally GL textures */
for (int slot = 0; slot < img->num_slots; slot++) {
SOKOL_ASSERT(desc->gl_textures[slot]);
img->gl_tex[slot] = desc->gl_textures[slot];
}
}
else {
/* create our own GL texture(s) */
const GLenum gl_format = _sg_gl_teximage_format(img->pixel_format);
const bool is_compressed = _sg_is_compressed_pixel_format(img->pixel_format);
for (int slot = 0; slot < img->num_slots; slot++) {
glGenTextures(1, &img->gl_tex[slot]);
_sg_gl_store_texture_binding(0);
_sg_gl_bind_texture(0, img->gl_target, img->gl_tex[slot]);
GLenum gl_min_filter = _sg_gl_filter(img->min_filter);
GLenum gl_mag_filter = _sg_gl_filter(img->mag_filter);
glTexParameteri(img->gl_target, GL_TEXTURE_MIN_FILTER, gl_min_filter);
glTexParameteri(img->gl_target, GL_TEXTURE_MAG_FILTER, gl_mag_filter);
if (_sg.gl.ext_anisotropic && (img->max_anisotropy > 1)) {
GLint max_aniso = (GLint) img->max_anisotropy;
if (max_aniso > _sg.gl.max_anisotropy) {
max_aniso = _sg.gl.max_anisotropy;
}
glTexParameteri(img->gl_target, GL_TEXTURE_MAX_ANISOTROPY_EXT, max_aniso);
}
if (img->type == SG_IMAGETYPE_CUBE) {
glTexParameteri(img->gl_target, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(img->gl_target, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
}
else {
glTexParameteri(img->gl_target, GL_TEXTURE_WRAP_S, _sg_gl_wrap(img->wrap_u));
glTexParameteri(img->gl_target, GL_TEXTURE_WRAP_T, _sg_gl_wrap(img->wrap_v));
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2 && (img->type == SG_IMAGETYPE_3D)) {
glTexParameteri(img->gl_target, GL_TEXTURE_WRAP_R, _sg_gl_wrap(img->wrap_w));
}
#endif
#if defined(SOKOL_GLCORE33)
float border[4];
switch (img->border_color) {
case SG_BORDERCOLOR_TRANSPARENT_BLACK:
border[0] = 0.0f; border[1] = 0.0f; border[2] = 0.0f; border[3] = 0.0f;
break;
case SG_BORDERCOLOR_OPAQUE_WHITE:
border[0] = 1.0f; border[1] = 1.0f; border[2] = 1.0f; border[3] = 1.0f;
break;
default:
border[0] = 0.0f; border[1] = 0.0f; border[2] = 0.0f; border[3] = 1.0f;
break;
}
glTexParameterfv(img->gl_target, GL_TEXTURE_BORDER_COLOR, border);
#endif
}
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
/* GL spec has strange defaults for mipmap min/max lod: -1000 to +1000 */
const float min_lod = _sg_clamp(desc->min_lod, 0.0f, 1000.0f);
const float max_lod = _sg_clamp(desc->max_lod, 0.0f, 1000.0f);
glTexParameterf(img->gl_target, GL_TEXTURE_MIN_LOD, min_lod);
glTexParameterf(img->gl_target, GL_TEXTURE_MAX_LOD, max_lod);
}
#endif
const int num_faces = img->type == SG_IMAGETYPE_CUBE ? 6 : 1;
int data_index = 0;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int mip_index = 0; mip_index < img->num_mipmaps; mip_index++, data_index++) {
GLenum gl_img_target = img->gl_target;
if (SG_IMAGETYPE_CUBE == img->type) {
gl_img_target = _sg_gl_cubeface_target(face_index);
}
const GLvoid* data_ptr = desc->content.subimage[face_index][mip_index].ptr;
const int data_size = desc->content.subimage[face_index][mip_index].size;
int mip_width = img->width >> mip_index;
if (mip_width == 0) {
mip_width = 1;
}
int mip_height = img->height >> mip_index;
if (mip_height == 0) {
mip_height = 1;
}
if ((SG_IMAGETYPE_2D == img->type) || (SG_IMAGETYPE_CUBE == img->type)) {
if (is_compressed) {
glCompressedTexImage2D(gl_img_target, mip_index, gl_internal_format,
mip_width, mip_height, 0, data_size, data_ptr);
}
else {
const GLenum gl_type = _sg_gl_teximage_type(img->pixel_format);
glTexImage2D(gl_img_target, mip_index, gl_internal_format,
mip_width, mip_height, 0, gl_format, gl_type, data_ptr);
}
}
#if !defined(SOKOL_GLES2)
else if (!_sg.gl.gles2 && ((SG_IMAGETYPE_3D == img->type) || (SG_IMAGETYPE_ARRAY == img->type))) {
int mip_depth = img->depth;
if (SG_IMAGETYPE_3D == img->type) {
mip_depth >>= mip_index;
}
if (mip_depth == 0) {
mip_depth = 1;
}
if (is_compressed) {
glCompressedTexImage3D(gl_img_target, mip_index, gl_internal_format,
mip_width, mip_height, mip_depth, 0, data_size, data_ptr);
}
else {
const GLenum gl_type = _sg_gl_teximage_type(img->pixel_format);
glTexImage3D(gl_img_target, mip_index, gl_internal_format,
mip_width, mip_height, mip_depth, 0, gl_format, gl_type, data_ptr);
}
}
#endif
}
}
_sg_gl_restore_texture_binding(0);
}
}
}
_SG_GL_CHECK_ERROR();
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_image(_sg_image_t* img) {
SOKOL_ASSERT(img);
_SG_GL_CHECK_ERROR();
if (!img->ext_textures) {
for (int slot = 0; slot < img->num_slots; slot++) {
if (img->gl_tex[slot]) {
glDeleteTextures(1, &img->gl_tex[slot]);
}
}
}
if (img->gl_depth_render_buffer) {
glDeleteRenderbuffers(1, &img->gl_depth_render_buffer);
}
if (img->gl_msaa_render_buffer) {
glDeleteRenderbuffers(1, &img->gl_msaa_render_buffer);
}
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE GLuint _sg_gl_compile_shader(sg_shader_stage stage, const char* src) {
SOKOL_ASSERT(src);
_SG_GL_CHECK_ERROR();
GLuint gl_shd = glCreateShader(_sg_gl_shader_stage(stage));
glShaderSource(gl_shd, 1, &src, 0);
glCompileShader(gl_shd);
GLint compile_status = 0;
glGetShaderiv(gl_shd, GL_COMPILE_STATUS, &compile_status);
if (!compile_status) {
/* compilation failed, log error and delete shader */
GLint log_len = 0;
glGetShaderiv(gl_shd, GL_INFO_LOG_LENGTH, &log_len);
if (log_len > 0) {
GLchar* log_buf = (GLchar*) SOKOL_MALLOC(log_len);
glGetShaderInfoLog(gl_shd, log_len, &log_len, log_buf);
SOKOL_LOG(log_buf);
SOKOL_FREE(log_buf);
}
glDeleteShader(gl_shd);
gl_shd = 0;
}
_SG_GL_CHECK_ERROR();
return gl_shd;
}
_SOKOL_PRIVATE sg_resource_state _sg_create_shader(_sg_shader_t* shd, const sg_shader_desc* desc) {
SOKOL_ASSERT(shd && desc);
SOKOL_ASSERT(!shd->gl_prog);
_SG_GL_CHECK_ERROR();
/* copy vertex attribute names over, these are required for GLES2, and optional for GLES3 and GL3.x */
for (int i = 0; i < SG_MAX_VERTEX_ATTRIBUTES; i++) {
_sg_strcpy(&shd->attrs[i].name, desc->attrs[i].name);
}
GLuint gl_vs = _sg_gl_compile_shader(SG_SHADERSTAGE_VS, desc->vs.source);
GLuint gl_fs = _sg_gl_compile_shader(SG_SHADERSTAGE_FS, desc->fs.source);
if (!(gl_vs && gl_fs)) {
return SG_RESOURCESTATE_FAILED;
}
GLuint gl_prog = glCreateProgram();
glAttachShader(gl_prog, gl_vs);
glAttachShader(gl_prog, gl_fs);
glLinkProgram(gl_prog);
glDeleteShader(gl_vs);
glDeleteShader(gl_fs);
_SG_GL_CHECK_ERROR();
GLint link_status;
glGetProgramiv(gl_prog, GL_LINK_STATUS, &link_status);
if (!link_status) {
GLint log_len = 0;
glGetProgramiv(gl_prog, GL_INFO_LOG_LENGTH, &log_len);
if (log_len > 0) {
GLchar* log_buf = (GLchar*) SOKOL_MALLOC(log_len);
glGetProgramInfoLog(gl_prog, log_len, &log_len, log_buf);
SOKOL_LOG(log_buf);
SOKOL_FREE(log_buf);
}
glDeleteProgram(gl_prog);
return SG_RESOURCESTATE_FAILED;
}
shd->gl_prog = gl_prog;
/* resolve uniforms */
_SG_GL_CHECK_ERROR();
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const sg_shader_stage_desc* stage_desc = (stage_index == SG_SHADERSTAGE_VS)? &desc->vs : &desc->fs;
_sg_shader_stage_t* stage = &shd->stage[stage_index];
SOKOL_ASSERT(stage->num_uniform_blocks == 0);
for (int ub_index = 0; ub_index < SG_MAX_SHADERSTAGE_UBS; ub_index++) {
const sg_shader_uniform_block_desc* ub_desc = &stage_desc->uniform_blocks[ub_index];
if (0 == ub_desc->size) {
break;
}
_sg_uniform_block_t* ub = &stage->uniform_blocks[ub_index];
ub->size = ub_desc->size;
SOKOL_ASSERT(ub->num_uniforms == 0);
int cur_uniform_offset = 0;
for (int u_index = 0; u_index < SG_MAX_UB_MEMBERS; u_index++) {
const sg_shader_uniform_desc* u_desc = &ub_desc->uniforms[u_index];
if (u_desc->type == SG_UNIFORMTYPE_INVALID) {
break;
}
_sg_uniform_t* u = &ub->uniforms[u_index];
u->type = u_desc->type;
u->count = (uint8_t) u_desc->array_count;
u->offset = (uint16_t) cur_uniform_offset;
cur_uniform_offset += _sg_uniform_size(u->type, u->count);
if (u_desc->name) {
u->gl_loc = glGetUniformLocation(gl_prog, u_desc->name);
}
else {
u->gl_loc = u_index;
}
ub->num_uniforms++;
}
SOKOL_ASSERT(ub_desc->size == cur_uniform_offset);
stage->num_uniform_blocks++;
}
}
/* resolve image locations */
_SG_GL_CHECK_ERROR();
int gl_tex_slot = 0;
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const sg_shader_stage_desc* stage_desc = (stage_index == SG_SHADERSTAGE_VS)? &desc->vs : &desc->fs;
_sg_shader_stage_t* stage = &shd->stage[stage_index];
SOKOL_ASSERT(stage->num_images == 0);
for (int img_index = 0; img_index < SG_MAX_SHADERSTAGE_IMAGES; img_index++) {
const sg_shader_image_desc* img_desc = &stage_desc->images[img_index];
if (img_desc->type == _SG_IMAGETYPE_DEFAULT) {
break;
}
_sg_shader_image_t* img = &stage->images[img_index];
img->type = img_desc->type;
img->gl_loc = img_index;
if (img_desc->name) {
img->gl_loc = glGetUniformLocation(gl_prog, img_desc->name);
}
if (img->gl_loc != -1) {
img->gl_tex_slot = gl_tex_slot++;
}
else {
img->gl_tex_slot = -1;
}
stage->num_images++;
}
}
_SG_GL_CHECK_ERROR();
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_shader(_sg_shader_t* shd) {
SOKOL_ASSERT(shd);
_SG_GL_CHECK_ERROR();
if (shd->gl_prog) {
glDeleteProgram(shd->gl_prog);
}
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pipeline(_sg_pipeline_t* pip, _sg_shader_t* shd, const sg_pipeline_desc* desc) {
SOKOL_ASSERT(pip && shd && desc);
SOKOL_ASSERT(!pip->shader && pip->shader_id.id == SG_INVALID_ID);
SOKOL_ASSERT(desc->shader.id == shd->slot.id);
SOKOL_ASSERT(shd->gl_prog);
pip->shader = shd;
pip->shader_id = desc->shader;
pip->primitive_type = desc->primitive_type;
pip->index_type = desc->index_type;
pip->color_attachment_count = desc->blend.color_attachment_count;
pip->color_format = desc->blend.color_format;
pip->depth_format = desc->blend.depth_format;
pip->sample_count = desc->rasterizer.sample_count;
pip->depth_stencil = desc->depth_stencil;
pip->blend = desc->blend;
pip->rast = desc->rasterizer;
/* resolve vertex attributes */
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
pip->gl_attrs[attr_index].vb_index = -1;
}
for (uint32_t attr_index = 0; attr_index < _sg.limits.max_vertex_attrs; attr_index++) {
const sg_vertex_attr_desc* a_desc = &desc->layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
break;
}
SOKOL_ASSERT((a_desc->buffer_index >= 0) && (a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS));
const sg_buffer_layout_desc* l_desc = &desc->layout.buffers[a_desc->buffer_index];
const sg_vertex_step step_func = l_desc->step_func;
const int step_rate = l_desc->step_rate;
GLint attr_loc = attr_index;
if (!_sg_strempty(&shd->attrs[attr_index].name)) {
attr_loc = glGetAttribLocation(pip->shader->gl_prog, _sg_strptr(&shd->attrs[attr_index].name));
}
SOKOL_ASSERT(attr_loc < (GLint)_sg.limits.max_vertex_attrs);
if (attr_loc != -1) {
_sg_gl_attr_t* gl_attr = &pip->gl_attrs[attr_loc];
SOKOL_ASSERT(gl_attr->vb_index == -1);
gl_attr->vb_index = (int8_t) a_desc->buffer_index;
if (step_func == SG_VERTEXSTEP_PER_VERTEX) {
gl_attr->divisor = 0;
}
else {
gl_attr->divisor = (int8_t) step_rate;
}
SOKOL_ASSERT(l_desc->stride > 0);
gl_attr->stride = (uint8_t) l_desc->stride;
gl_attr->offset = a_desc->offset;
gl_attr->size = (uint8_t) _sg_gl_vertexformat_size(a_desc->format);
gl_attr->type = _sg_gl_vertexformat_type(a_desc->format);
gl_attr->normalized = _sg_gl_vertexformat_normalized(a_desc->format);
pip->vertex_layout_valid[a_desc->buffer_index] = true;
}
else {
SOKOL_LOG("Vertex attribute not found in shader: ");
SOKOL_LOG(_sg_strptr(&shd->attrs[attr_index].name));
}
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
/* empty */
}
/*
_sg_create_pass
att_imgs must point to a _sg_image* att_imgs[SG_MAX_COLOR_ATTACHMENTS+1] array,
first entries are the color attachment images (or nullptr), last entry
is the depth-stencil image (or nullptr).
*/
_SOKOL_PRIVATE sg_resource_state _sg_create_pass(_sg_pass_t* pass, _sg_image_t** att_images, const sg_pass_desc* desc) {
SOKOL_ASSERT(pass && att_images && desc);
SOKOL_ASSERT(att_images && att_images[0]);
_SG_GL_CHECK_ERROR();
/* copy image pointers and desc attributes */
const sg_attachment_desc* att_desc;
_sg_attachment_t* att;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
SOKOL_ASSERT(0 == pass->color_atts[i].image);
att_desc = &desc->color_attachments[i];
if (att_desc->image.id != SG_INVALID_ID) {
pass->num_color_atts++;
SOKOL_ASSERT(att_images[i] && (att_images[i]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_color_format(att_images[i]->pixel_format));
att = &pass->color_atts[i];
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[i];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
}
}
SOKOL_ASSERT(0 == pass->ds_att.image);
att_desc = &desc->depth_stencil_attachment;
const int ds_img_index = SG_MAX_COLOR_ATTACHMENTS;
if (att_desc->image.id != SG_INVALID_ID) {
SOKOL_ASSERT(att_images[ds_img_index] && (att_images[ds_img_index]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_depth_format(att_images[ds_img_index]->pixel_format));
att = &pass->ds_att;
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[ds_img_index];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
}
/* store current framebuffer binding (restored at end of function) */
GLuint gl_orig_fb;
glGetIntegerv(GL_FRAMEBUFFER_BINDING, (GLint*)&gl_orig_fb);
/* create a framebuffer object */
glGenFramebuffers(1, &pass->gl_fb);
glBindFramebuffer(GL_FRAMEBUFFER, pass->gl_fb);
/* attach msaa render buffer or textures */
const bool is_msaa = (0 != att_images[0]->gl_msaa_render_buffer);
if (is_msaa) {
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
const _sg_image_t* att_img = pass->color_atts[i].image;
if (att_img) {
const GLuint gl_render_buffer = att_img->gl_msaa_render_buffer;
SOKOL_ASSERT(gl_render_buffer);
glFramebufferRenderbuffer(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0+i, GL_RENDERBUFFER, gl_render_buffer);
}
}
}
else {
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
const _sg_image_t* att_img = pass->color_atts[i].image;
const int mip_level = pass->color_atts[i].mip_level;
const int slice = pass->color_atts[i].slice;
if (att_img) {
const GLuint gl_tex = att_img->gl_tex[0];
SOKOL_ASSERT(gl_tex);
const GLenum gl_att = GL_COLOR_ATTACHMENT0 + i;
switch (att_img->type) {
case SG_IMAGETYPE_2D:
glFramebufferTexture2D(GL_FRAMEBUFFER, gl_att, GL_TEXTURE_2D, gl_tex, mip_level);
break;
case SG_IMAGETYPE_CUBE:
glFramebufferTexture2D(GL_FRAMEBUFFER, gl_att, _sg_gl_cubeface_target(slice), gl_tex, mip_level);
break;
default:
/* 3D- or array-texture */
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
glFramebufferTextureLayer(GL_FRAMEBUFFER, gl_att, gl_tex, mip_level, slice);
}
#endif
break;
}
}
}
}
/* attach depth-stencil buffer to framebuffer */
if (pass->ds_att.image) {
const GLuint gl_render_buffer = pass->ds_att.image->gl_depth_render_buffer;
SOKOL_ASSERT(gl_render_buffer);
glFramebufferRenderbuffer(GL_FRAMEBUFFER, GL_DEPTH_ATTACHMENT, GL_RENDERBUFFER, gl_render_buffer);
if (_sg_is_depth_stencil_format(pass->ds_att.image->pixel_format)) {
glFramebufferRenderbuffer(GL_FRAMEBUFFER, GL_STENCIL_ATTACHMENT, GL_RENDERBUFFER, gl_render_buffer);
}
}
/* check if framebuffer is complete */
if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE) {
SOKOL_LOG("Framebuffer completeness check failed!\n");
return SG_RESOURCESTATE_FAILED;
}
/* create MSAA resolve framebuffers if necessary */
if (is_msaa) {
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
att = &pass->color_atts[i];
if (att->image) {
SOKOL_ASSERT(0 == att->gl_msaa_resolve_buffer);
glGenFramebuffers(1, &att->gl_msaa_resolve_buffer);
glBindFramebuffer(GL_FRAMEBUFFER, att->gl_msaa_resolve_buffer);
const GLuint gl_tex = att->image->gl_tex[0];
SOKOL_ASSERT(gl_tex);
switch (att->image->type) {
case SG_IMAGETYPE_2D:
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0,
GL_TEXTURE_2D, gl_tex, att->mip_level);
break;
case SG_IMAGETYPE_CUBE:
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0,
_sg_gl_cubeface_target(att->slice), gl_tex, att->mip_level);
break;
default:
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
glFramebufferTextureLayer(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, gl_tex, att->mip_level, att->slice);
}
#endif
break;
}
/* check if framebuffer is complete */
if (glCheckFramebufferStatus(GL_FRAMEBUFFER) != GL_FRAMEBUFFER_COMPLETE) {
SOKOL_LOG("Framebuffer completeness check failed (msaa resolve buffer)!\n");
return SG_RESOURCESTATE_FAILED;
}
}
}
}
/* restore original framebuffer binding */
glBindFramebuffer(GL_FRAMEBUFFER, gl_orig_fb);
_SG_GL_CHECK_ERROR();
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pass(_sg_pass_t* pass) {
SOKOL_ASSERT(pass);
_SG_GL_CHECK_ERROR();
if (0 != pass->gl_fb) {
glDeleteFramebuffers(1, &pass->gl_fb);
}
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
if (pass->color_atts[i].gl_msaa_resolve_buffer) {
glDeleteFramebuffers(1, &pass->color_atts[i].gl_msaa_resolve_buffer);
}
}
if (pass->ds_att.gl_msaa_resolve_buffer) {
glDeleteFramebuffers(1, &pass->ds_att.gl_msaa_resolve_buffer);
}
_SG_GL_CHECK_ERROR();
}
/*-- GL backend rendering functions ------------------------------------------*/
_SOKOL_PRIVATE void _sg_begin_pass(_sg_pass_t* pass, const sg_pass_action* action, int w, int h) {
/* FIXME: what if a texture used as render target is still bound, should we
unbind all currently bound textures in begin pass? */
SOKOL_ASSERT(action);
SOKOL_ASSERT(!_sg.gl.in_pass);
_SG_GL_CHECK_ERROR();
_sg.gl.in_pass = true;
_sg.gl.cur_pass = pass; /* can be 0 */
if (pass) {
_sg.gl.cur_pass_id.id = pass->slot.id;
}
else {
_sg.gl.cur_pass_id.id = SG_INVALID_ID;
}
_sg.gl.cur_pass_width = w;
_sg.gl.cur_pass_height = h;
if (pass) {
/* offscreen pass */
SOKOL_ASSERT(pass->gl_fb);
glBindFramebuffer(GL_FRAMEBUFFER, pass->gl_fb);
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2) {
GLenum att[SG_MAX_COLOR_ATTACHMENTS] = {
GL_COLOR_ATTACHMENT0,
GL_COLOR_ATTACHMENT1,
GL_COLOR_ATTACHMENT2,
GL_COLOR_ATTACHMENT3
};
int num_attrs = 0;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
if (pass->color_atts[num_attrs].image) {
num_attrs++;
}
else {
break;
}
}
glDrawBuffers(num_attrs, att);
}
#endif
}
else {
/* default pass */
SOKOL_ASSERT(_sg.gl.cur_context);
glBindFramebuffer(GL_FRAMEBUFFER, _sg.gl.cur_context->default_framebuffer);
}
glViewport(0, 0, w, h);
glScissor(0, 0, w, h);
bool need_pip_cache_flush = false;
if (_sg.gl.cache.blend.color_write_mask != SG_COLORMASK_RGBA) {
need_pip_cache_flush = true;
_sg.gl.cache.blend.color_write_mask = SG_COLORMASK_RGBA;
glColorMask(GL_TRUE, GL_TRUE, GL_TRUE, GL_TRUE);
}
if (!_sg.gl.cache.ds.depth_write_enabled) {
need_pip_cache_flush = true;
_sg.gl.cache.ds.depth_write_enabled = true;
glDepthMask(GL_TRUE);
}
if (_sg.gl.cache.ds.depth_compare_func != SG_COMPAREFUNC_ALWAYS) {
need_pip_cache_flush = true;
_sg.gl.cache.ds.depth_compare_func = SG_COMPAREFUNC_ALWAYS;
glDepthFunc(GL_ALWAYS);
}
if (_sg.gl.cache.ds.stencil_write_mask != 0xFF) {
need_pip_cache_flush = true;
_sg.gl.cache.ds.stencil_write_mask = 0xFF;
glStencilMask(0xFF);
}
if (need_pip_cache_flush) {
/* we messed with the state cache directly, need to clear cached
pipeline to force re-evaluation in next sg_apply_pipeline() */
_sg.gl.cache.cur_pipeline = 0;
_sg.gl.cache.cur_pipeline_id.id = SG_INVALID_ID;
}
bool use_mrt_clear = (0 != pass);
#if defined(SOKOL_GLES2)
use_mrt_clear = false;
#else
if (_sg.gl.gles2) {
use_mrt_clear = false;
}
#endif
if (!use_mrt_clear) {
GLbitfield clear_mask = 0;
if (action->colors[0].action == SG_ACTION_CLEAR) {
clear_mask |= GL_COLOR_BUFFER_BIT;
const float* c = action->colors[0].val;
glClearColor(c[0], c[1], c[2], c[3]);
}
if (action->depth.action == SG_ACTION_CLEAR) {
clear_mask |= GL_DEPTH_BUFFER_BIT;
#ifdef SOKOL_GLCORE33
glClearDepth(action->depth.val);
#else
glClearDepthf(action->depth.val);
#endif
}
if (action->stencil.action == SG_ACTION_CLEAR) {
clear_mask |= GL_STENCIL_BUFFER_BIT;
glClearStencil(action->stencil.val);
}
if (0 != clear_mask) {
glClear(clear_mask);
}
}
#if !defined SOKOL_GLES2
else {
SOKOL_ASSERT(pass);
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
if (pass->color_atts[i].image) {
if (action->colors[i].action == SG_ACTION_CLEAR) {
glClearBufferfv(GL_COLOR, i, action->colors[i].val);
}
}
else {
break;
}
}
if (pass->ds_att.image) {
if ((action->depth.action == SG_ACTION_CLEAR) && (action->stencil.action == SG_ACTION_CLEAR)) {
glClearBufferfi(GL_DEPTH_STENCIL, 0, action->depth.val, action->stencil.val);
}
else if (action->depth.action == SG_ACTION_CLEAR) {
glClearBufferfv(GL_DEPTH, 0, &action->depth.val);
}
else if (action->stencil.action == SG_ACTION_CLEAR) {
GLuint val = action->stencil.val;
glClearBufferuiv(GL_STENCIL, 0, &val);
}
}
}
#endif
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE void _sg_end_pass(void) {
SOKOL_ASSERT(_sg.gl.in_pass);
_SG_GL_CHECK_ERROR();
/* if this was an offscreen pass, and MSAA rendering was used, need
to resolve into the pass images */
#if !defined(SOKOL_GLES2)
if (!_sg.gl.gles2 && _sg.gl.cur_pass) {
/* check if the pass object is still valid */
const _sg_pass_t* pass = _sg.gl.cur_pass;
SOKOL_ASSERT(pass->slot.id == _sg.gl.cur_pass_id.id);
bool is_msaa = (0 != _sg.gl.cur_pass->color_atts[0].gl_msaa_resolve_buffer);
if (is_msaa) {
SOKOL_ASSERT(pass->gl_fb);
glBindFramebuffer(GL_READ_FRAMEBUFFER, pass->gl_fb);
SOKOL_ASSERT(pass->color_atts[0].image);
const int w = pass->color_atts[0].image->width;
const int h = pass->color_atts[0].image->height;
for (int att_index = 0; att_index < SG_MAX_COLOR_ATTACHMENTS; att_index++) {
const _sg_attachment_t* att = &pass->color_atts[att_index];
if (att->image) {
SOKOL_ASSERT(att->gl_msaa_resolve_buffer);
glBindFramebuffer(GL_DRAW_FRAMEBUFFER, att->gl_msaa_resolve_buffer);
glReadBuffer(GL_COLOR_ATTACHMENT0 + att_index);
const GLenum gl_att = GL_COLOR_ATTACHMENT0;
glDrawBuffers(1, &gl_att);
glBlitFramebuffer(0, 0, w, h, 0, 0, w, h, GL_COLOR_BUFFER_BIT, GL_NEAREST);
}
else {
break;
}
}
}
}
#endif
_sg.gl.cur_pass = 0;
_sg.gl.cur_pass_id.id = SG_INVALID_ID;
_sg.gl.cur_pass_width = 0;
_sg.gl.cur_pass_height = 0;
SOKOL_ASSERT(_sg.gl.cur_context);
glBindFramebuffer(GL_FRAMEBUFFER, _sg.gl.cur_context->default_framebuffer);
_sg.gl.in_pass = false;
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE void _sg_apply_viewport(int x, int y, int w, int h, bool origin_top_left) {
SOKOL_ASSERT(_sg.gl.in_pass);
y = origin_top_left ? (_sg.gl.cur_pass_height - (y+h)) : y;
glViewport(x, y, w, h);
}
_SOKOL_PRIVATE void _sg_apply_scissor_rect(int x, int y, int w, int h, bool origin_top_left) {
SOKOL_ASSERT(_sg.gl.in_pass);
y = origin_top_left ? (_sg.gl.cur_pass_height - (y+h)) : y;
glScissor(x, y, w, h);
}
_SOKOL_PRIVATE void _sg_apply_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
SOKOL_ASSERT(pip->shader);
_SG_GL_CHECK_ERROR();
if ((_sg.gl.cache.cur_pipeline != pip) || (_sg.gl.cache.cur_pipeline_id.id != pip->slot.id)) {
_sg.gl.cache.cur_pipeline = pip;
_sg.gl.cache.cur_pipeline_id.id = pip->slot.id;
_sg.gl.cache.cur_primitive_type = _sg_gl_primitive_type(pip->primitive_type);
_sg.gl.cache.cur_index_type = _sg_gl_index_type(pip->index_type);
/* update depth-stencil state */
const sg_depth_stencil_state* new_ds = &pip->depth_stencil;
sg_depth_stencil_state* cache_ds = &_sg.gl.cache.ds;
if (new_ds->depth_compare_func != cache_ds->depth_compare_func) {
cache_ds->depth_compare_func = new_ds->depth_compare_func;
glDepthFunc(_sg_gl_compare_func(new_ds->depth_compare_func));
}
if (new_ds->depth_write_enabled != cache_ds->depth_write_enabled) {
cache_ds->depth_write_enabled = new_ds->depth_write_enabled;
glDepthMask(new_ds->depth_write_enabled);
}
if (new_ds->stencil_enabled != cache_ds->stencil_enabled) {
cache_ds->stencil_enabled = new_ds->stencil_enabled;
if (new_ds->stencil_enabled) glEnable(GL_STENCIL_TEST);
else glDisable(GL_STENCIL_TEST);
}
if (new_ds->stencil_write_mask != cache_ds->stencil_write_mask) {
cache_ds->stencil_write_mask = new_ds->stencil_write_mask;
glStencilMask(new_ds->stencil_write_mask);
}
for (int i = 0; i < 2; i++) {
const sg_stencil_state* new_ss = (i==0)? &new_ds->stencil_front : &new_ds->stencil_back;
sg_stencil_state* cache_ss = (i==0)? &cache_ds->stencil_front : &cache_ds->stencil_back;
GLenum gl_face = (i==0)? GL_FRONT : GL_BACK;
if ((new_ss->compare_func != cache_ss->compare_func) ||
(new_ds->stencil_read_mask != cache_ds->stencil_read_mask) ||
(new_ds->stencil_ref != cache_ds->stencil_ref))
{
cache_ss->compare_func = new_ss->compare_func;
glStencilFuncSeparate(gl_face,
_sg_gl_compare_func(new_ss->compare_func),
new_ds->stencil_ref,
new_ds->stencil_read_mask);
}
if ((new_ss->fail_op != cache_ss->fail_op) ||
(new_ss->depth_fail_op != cache_ss->depth_fail_op) ||
(new_ss->pass_op != cache_ss->pass_op))
{
cache_ss->fail_op = new_ss->fail_op;
cache_ss->depth_fail_op = new_ss->depth_fail_op;
cache_ss->pass_op = new_ss->pass_op;
glStencilOpSeparate(gl_face,
_sg_gl_stencil_op(new_ss->fail_op),
_sg_gl_stencil_op(new_ss->depth_fail_op),
_sg_gl_stencil_op(new_ss->pass_op));
}
}
cache_ds->stencil_read_mask = new_ds->stencil_read_mask;
cache_ds->stencil_ref = new_ds->stencil_ref;
/* update blend state */
const sg_blend_state* new_b = &pip->blend;
sg_blend_state* cache_b = &_sg.gl.cache.blend;
if (new_b->enabled != cache_b->enabled) {
cache_b->enabled = new_b->enabled;
if (new_b->enabled) glEnable(GL_BLEND);
else glDisable(GL_BLEND);
}
if ((new_b->src_factor_rgb != cache_b->src_factor_rgb) ||
(new_b->dst_factor_rgb != cache_b->dst_factor_rgb) ||
(new_b->src_factor_alpha != cache_b->src_factor_alpha) ||
(new_b->dst_factor_alpha != cache_b->dst_factor_alpha))
{
cache_b->src_factor_rgb = new_b->src_factor_rgb;
cache_b->dst_factor_rgb = new_b->dst_factor_rgb;
cache_b->src_factor_alpha = new_b->src_factor_alpha;
cache_b->dst_factor_alpha = new_b->dst_factor_alpha;
glBlendFuncSeparate(_sg_gl_blend_factor(new_b->src_factor_rgb),
_sg_gl_blend_factor(new_b->dst_factor_rgb),
_sg_gl_blend_factor(new_b->src_factor_alpha),
_sg_gl_blend_factor(new_b->dst_factor_alpha));
}
if ((new_b->op_rgb != cache_b->op_rgb) || (new_b->op_alpha != cache_b->op_alpha)) {
cache_b->op_rgb = new_b->op_rgb;
cache_b->op_alpha = new_b->op_alpha;
glBlendEquationSeparate(_sg_gl_blend_op(new_b->op_rgb), _sg_gl_blend_op(new_b->op_alpha));
}
if (new_b->color_write_mask != cache_b->color_write_mask) {
cache_b->color_write_mask = new_b->color_write_mask;
glColorMask((new_b->color_write_mask & SG_COLORMASK_R) != 0,
(new_b->color_write_mask & SG_COLORMASK_G) != 0,
(new_b->color_write_mask & SG_COLORMASK_B) != 0,
(new_b->color_write_mask & SG_COLORMASK_A) != 0);
}
if (!_sg_fequal(new_b->blend_color[0], cache_b->blend_color[0], 0.0001f) ||
!_sg_fequal(new_b->blend_color[1], cache_b->blend_color[1], 0.0001f) ||
!_sg_fequal(new_b->blend_color[2], cache_b->blend_color[2], 0.0001f) ||
!_sg_fequal(new_b->blend_color[3], cache_b->blend_color[3], 0.0001f))
{
const float* bc = new_b->blend_color;
for (int i=0; i<4; i++) {
cache_b->blend_color[i] = bc[i];
}
glBlendColor(bc[0], bc[1], bc[2], bc[3]);
}
/* update rasterizer state */
const sg_rasterizer_state* new_r = &pip->rast;
sg_rasterizer_state* cache_r = &_sg.gl.cache.rast;
if (new_r->cull_mode != cache_r->cull_mode) {
cache_r->cull_mode = new_r->cull_mode;
if (SG_CULLMODE_NONE == new_r->cull_mode) {
glDisable(GL_CULL_FACE);
}
else {
glEnable(GL_CULL_FACE);
GLenum gl_mode = (SG_CULLMODE_FRONT == new_r->cull_mode) ? GL_FRONT : GL_BACK;
glCullFace(gl_mode);
}
}
if (new_r->face_winding != cache_r->face_winding) {
cache_r->face_winding = new_r->face_winding;
GLenum gl_winding = (SG_FACEWINDING_CW == new_r->face_winding) ? GL_CW : GL_CCW;
glFrontFace(gl_winding);
}
if (new_r->alpha_to_coverage_enabled != cache_r->alpha_to_coverage_enabled) {
cache_r->alpha_to_coverage_enabled = new_r->alpha_to_coverage_enabled;
if (new_r->alpha_to_coverage_enabled) glEnable(GL_SAMPLE_ALPHA_TO_COVERAGE);
else glDisable(GL_SAMPLE_ALPHA_TO_COVERAGE);
}
#ifdef SOKOL_GLCORE33
if (new_r->sample_count != cache_r->sample_count) {
cache_r->sample_count = new_r->sample_count;
if (new_r->sample_count > 1) glEnable(GL_MULTISAMPLE);
else glDisable(GL_MULTISAMPLE);
}
#endif
if (!_sg_fequal(new_r->depth_bias, cache_r->depth_bias, 0.000001f) ||
!_sg_fequal(new_r->depth_bias_slope_scale, cache_r->depth_bias_slope_scale, 0.000001f))
{
/* according to ANGLE's D3D11 backend:
D3D11 SlopeScaledDepthBias ==> GL polygonOffsetFactor
D3D11 DepthBias ==> GL polygonOffsetUnits
DepthBiasClamp has no meaning on GL
*/
cache_r->depth_bias = new_r->depth_bias;
cache_r->depth_bias_slope_scale = new_r->depth_bias_slope_scale;
glPolygonOffset(new_r->depth_bias_slope_scale, new_r->depth_bias);
bool po_enabled = true;
if (_sg_fequal(new_r->depth_bias, 0.0f, 0.000001f) &&
_sg_fequal(new_r->depth_bias_slope_scale, 0.0f, 0.000001f))
{
po_enabled = false;
}
if (po_enabled != _sg.gl.cache.polygon_offset_enabled) {
_sg.gl.cache.polygon_offset_enabled = po_enabled;
if (po_enabled) glEnable(GL_POLYGON_OFFSET_FILL);
else glDisable(GL_POLYGON_OFFSET_FILL);
}
}
/* bind shader program */
glUseProgram(pip->shader->gl_prog);
}
}
_SOKOL_PRIVATE void _sg_apply_bindings(
_sg_pipeline_t* pip,
_sg_buffer_t** vbs, const int* vb_offsets, int num_vbs,
_sg_buffer_t* ib, int ib_offset,
_sg_image_t** vs_imgs, int num_vs_imgs,
_sg_image_t** fs_imgs, int num_fs_imgs)
{
SOKOL_ASSERT(pip);
_SOKOL_UNUSED(num_fs_imgs);
_SOKOL_UNUSED(num_vs_imgs);
_SOKOL_UNUSED(num_vbs);
_SG_GL_CHECK_ERROR();
/* bind textures */
_SG_GL_CHECK_ERROR();
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const _sg_shader_stage_t* stage = &pip->shader->stage[stage_index];
_sg_image_t** imgs = (stage_index == SG_SHADERSTAGE_VS)? vs_imgs : fs_imgs;
SOKOL_ASSERT(((stage_index == SG_SHADERSTAGE_VS)? num_vs_imgs : num_fs_imgs) == stage->num_images);
for (int img_index = 0; img_index < stage->num_images; img_index++) {
const _sg_shader_image_t* shd_img = &stage->images[img_index];
if (shd_img->gl_loc != -1) {
_sg_image_t* img = imgs[img_index];
const GLuint gl_tex = img->gl_tex[img->active_slot];
SOKOL_ASSERT(img && img->gl_target);
SOKOL_ASSERT((shd_img->gl_tex_slot != -1) && gl_tex);
glUniform1i(shd_img->gl_loc, shd_img->gl_tex_slot);
_sg_gl_bind_texture(shd_img->gl_tex_slot, img->gl_target, gl_tex);
}
}
}
_SG_GL_CHECK_ERROR();
/* index buffer (can be 0) */
const GLuint gl_ib = ib ? ib->gl_buf[ib->active_slot] : 0;
_sg_gl_bind_buffer(GL_ELEMENT_ARRAY_BUFFER, gl_ib);
_sg.gl.cache.cur_ib_offset = ib_offset;
/* vertex attributes */
for (uint32_t attr_index = 0; attr_index < _sg.limits.max_vertex_attrs; attr_index++) {
_sg_gl_attr_t* attr = &pip->gl_attrs[attr_index];
_sg_gl_cache_attr_t* cache_attr = &_sg.gl.cache.attrs[attr_index];
bool cache_attr_dirty = false;
int vb_offset = 0;
GLuint gl_vb = 0;
if (attr->vb_index >= 0) {
/* attribute is enabled */
SOKOL_ASSERT(attr->vb_index < num_vbs);
_sg_buffer_t* vb = vbs[attr->vb_index];
SOKOL_ASSERT(vb);
gl_vb = vb->gl_buf[vb->active_slot];
vb_offset = vb_offsets[attr->vb_index] + attr->offset;
if ((gl_vb != cache_attr->gl_vbuf) ||
(attr->size != cache_attr->gl_attr.size) ||
(attr->type != cache_attr->gl_attr.type) ||
(attr->normalized != cache_attr->gl_attr.normalized) ||
(attr->stride != cache_attr->gl_attr.stride) ||
(vb_offset != cache_attr->gl_attr.offset) ||
(cache_attr->gl_attr.divisor != attr->divisor))
{
_sg_gl_bind_buffer(GL_ARRAY_BUFFER, gl_vb);
glVertexAttribPointer(attr_index, attr->size, attr->type,
attr->normalized, attr->stride,
(const GLvoid*)(GLintptr)vb_offset);
#ifdef SOKOL_INSTANCING_ENABLED
if (_sg.features.instancing) {
glVertexAttribDivisor(attr_index, attr->divisor);
}
#endif
cache_attr_dirty = true;
}
if (cache_attr->gl_attr.vb_index == -1) {
glEnableVertexAttribArray(attr_index);
cache_attr_dirty = true;
}
}
else {
/* attribute is disabled */
if (cache_attr->gl_attr.vb_index != -1) {
glDisableVertexAttribArray(attr_index);
cache_attr_dirty = true;
}
}
if (cache_attr_dirty) {
cache_attr->gl_attr = *attr;
cache_attr->gl_attr.offset = vb_offset;
cache_attr->gl_vbuf = gl_vb;
}
}
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE void _sg_apply_uniforms(sg_shader_stage stage_index, int ub_index, const void* data, int num_bytes) {
_SOKOL_UNUSED(num_bytes);
SOKOL_ASSERT(data && (num_bytes > 0));
SOKOL_ASSERT((stage_index >= 0) && ((int)stage_index < SG_NUM_SHADER_STAGES));
SOKOL_ASSERT(_sg.gl.cache.cur_pipeline);
SOKOL_ASSERT(_sg.gl.cache.cur_pipeline->slot.id == _sg.gl.cache.cur_pipeline_id.id);
SOKOL_ASSERT(_sg.gl.cache.cur_pipeline->shader->slot.id == _sg.gl.cache.cur_pipeline->shader_id.id);
_sg_shader_stage_t* stage = &_sg.gl.cache.cur_pipeline->shader->stage[stage_index];
SOKOL_ASSERT(ub_index < stage->num_uniform_blocks);
_sg_uniform_block_t* ub = &stage->uniform_blocks[ub_index];
SOKOL_ASSERT(ub->size == num_bytes);
for (int u_index = 0; u_index < ub->num_uniforms; u_index++) {
_sg_uniform_t* u = &ub->uniforms[u_index];
SOKOL_ASSERT(u->type != SG_UNIFORMTYPE_INVALID);
if (u->gl_loc == -1) {
continue;
}
GLfloat* ptr = (GLfloat*) (((uint8_t*)data) + u->offset);
switch (u->type) {
case SG_UNIFORMTYPE_INVALID:
break;
case SG_UNIFORMTYPE_FLOAT:
glUniform1fv(u->gl_loc, u->count, ptr);
break;
case SG_UNIFORMTYPE_FLOAT2:
glUniform2fv(u->gl_loc, u->count, ptr);
break;
case SG_UNIFORMTYPE_FLOAT3:
glUniform3fv(u->gl_loc, u->count, ptr);
break;
case SG_UNIFORMTYPE_FLOAT4:
glUniform4fv(u->gl_loc, u->count, ptr);
break;
case SG_UNIFORMTYPE_MAT4:
glUniformMatrix4fv(u->gl_loc, u->count, GL_FALSE, ptr);
break;
default:
SOKOL_UNREACHABLE;
break;
}
}
}
_SOKOL_PRIVATE void _sg_draw(int base_element, int num_elements, int num_instances) {
const GLenum i_type = _sg.gl.cache.cur_index_type;
const GLenum p_type = _sg.gl.cache.cur_primitive_type;
if (0 != i_type) {
/* indexed rendering */
const int i_size = (i_type == GL_UNSIGNED_SHORT) ? 2 : 4;
const int ib_offset = _sg.gl.cache.cur_ib_offset;
const GLvoid* indices = (const GLvoid*)(GLintptr)(base_element*i_size+ib_offset);
if (num_instances == 1) {
glDrawElements(p_type, num_elements, i_type, indices);
}
else {
if (_sg.features.instancing) {
glDrawElementsInstanced(p_type, num_elements, i_type, indices, num_instances);
}
}
}
else {
/* non-indexed rendering */
if (num_instances == 1) {
glDrawArrays(p_type, base_element, num_elements);
}
else {
if (_sg.features.instancing) {
glDrawArraysInstanced(p_type, base_element, num_elements, num_instances);
}
}
}
}
_SOKOL_PRIVATE void _sg_commit(void) {
SOKOL_ASSERT(!_sg.gl.in_pass);
/* "soft" clear bindings (only those that are actually bound) */
_sg_gl_clear_buffer_bindings(false);
_sg_gl_clear_texture_bindings(false);
}
_SOKOL_PRIVATE void _sg_update_buffer(_sg_buffer_t* buf, const void* data_ptr, int data_size) {
SOKOL_ASSERT(buf && data_ptr && (data_size > 0));
/* only one update per buffer per frame allowed */
if (++buf->active_slot >= buf->num_slots) {
buf->active_slot = 0;
}
GLenum gl_tgt = _sg_gl_buffer_target(buf->type);
SOKOL_ASSERT(buf->active_slot < SG_NUM_INFLIGHT_FRAMES);
GLuint gl_buf = buf->gl_buf[buf->active_slot];
SOKOL_ASSERT(gl_buf);
_SG_GL_CHECK_ERROR();
_sg_gl_store_buffer_binding(gl_tgt);
_sg_gl_bind_buffer(gl_tgt, gl_buf);
glBufferSubData(gl_tgt, 0, data_size, data_ptr);
_sg_gl_restore_buffer_binding(gl_tgt);
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE void _sg_append_buffer(_sg_buffer_t* buf, const void* data_ptr, int data_size, bool new_frame) {
SOKOL_ASSERT(buf && data_ptr && (data_size > 0));
if (new_frame) {
if (++buf->active_slot >= buf->num_slots) {
buf->active_slot = 0;
}
}
GLenum gl_tgt = _sg_gl_buffer_target(buf->type);
SOKOL_ASSERT(buf->active_slot < SG_NUM_INFLIGHT_FRAMES);
GLuint gl_buf = buf->gl_buf[buf->active_slot];
SOKOL_ASSERT(gl_buf);
_SG_GL_CHECK_ERROR();
_sg_gl_store_buffer_binding(gl_tgt);
_sg_gl_bind_buffer(gl_tgt, gl_buf);
glBufferSubData(gl_tgt, buf->append_pos, data_size, data_ptr);
_sg_gl_restore_buffer_binding(gl_tgt);
_SG_GL_CHECK_ERROR();
}
_SOKOL_PRIVATE void _sg_update_image(_sg_image_t* img, const sg_image_content* data) {
SOKOL_ASSERT(img && data);
/* only one update per image per frame allowed */
if (++img->active_slot >= img->num_slots) {
img->active_slot = 0;
}
SOKOL_ASSERT(img->active_slot < SG_NUM_INFLIGHT_FRAMES);
SOKOL_ASSERT(0 != img->gl_tex[img->active_slot]);
_sg_gl_store_texture_binding(0);
_sg_gl_bind_texture(0, img->gl_target, img->gl_tex[img->active_slot]);
const GLenum gl_img_format = _sg_gl_teximage_format(img->pixel_format);
const GLenum gl_img_type = _sg_gl_teximage_type(img->pixel_format);
const int num_faces = img->type == SG_IMAGETYPE_CUBE ? 6 : 1;
const int num_mips = img->num_mipmaps;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int mip_index = 0; mip_index < num_mips; mip_index++) {
GLenum gl_img_target = img->gl_target;
if (SG_IMAGETYPE_CUBE == img->type) {
gl_img_target = _sg_gl_cubeface_target(face_index);
}
const GLvoid* data_ptr = data->subimage[face_index][mip_index].ptr;
int mip_width = img->width >> mip_index;
if (mip_width == 0) {
mip_width = 1;
}
int mip_height = img->height >> mip_index;
if (mip_height == 0) {
mip_height = 1;
}
if ((SG_IMAGETYPE_2D == img->type) || (SG_IMAGETYPE_CUBE == img->type)) {
glTexSubImage2D(gl_img_target, mip_index,
0, 0,
mip_width, mip_height,
gl_img_format, gl_img_type,
data_ptr);
}
#if !defined(SOKOL_GLES2)
else if (!_sg.gl.gles2 && ((SG_IMAGETYPE_3D == img->type) || (SG_IMAGETYPE_ARRAY == img->type))) {
int mip_depth = img->depth >> mip_index;
if (mip_depth == 0) {
mip_depth = 1;
}
glTexSubImage3D(gl_img_target, mip_index,
0, 0, 0,
mip_width, mip_height, mip_depth,
gl_img_format, gl_img_type,
data_ptr);
}
#endif
}
}
_sg_gl_restore_texture_binding(0);
}
/*== D3D11 BACKEND IMPLEMENTATION ============================================*/
#elif defined(SOKOL_D3D11)
/*-- enum translation functions ----------------------------------------------*/
_SOKOL_PRIVATE D3D11_USAGE _sg_d3d11_usage(sg_usage usg) {
switch (usg) {
case SG_USAGE_IMMUTABLE:
return D3D11_USAGE_IMMUTABLE;
case SG_USAGE_DYNAMIC:
case SG_USAGE_STREAM:
return D3D11_USAGE_DYNAMIC;
default:
SOKOL_UNREACHABLE;
return (D3D11_USAGE) 0;
}
}
_SOKOL_PRIVATE UINT _sg_d3d11_cpu_access_flags(sg_usage usg) {
switch (usg) {
case SG_USAGE_IMMUTABLE:
return 0;
case SG_USAGE_DYNAMIC:
case SG_USAGE_STREAM:
return D3D11_CPU_ACCESS_WRITE;
default:
SOKOL_UNREACHABLE;
return 0;
}
}
_SOKOL_PRIVATE DXGI_FORMAT _sg_d3d11_pixel_format(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_R8: return DXGI_FORMAT_R8_UNORM;
case SG_PIXELFORMAT_R8SN: return DXGI_FORMAT_R8_SNORM;
case SG_PIXELFORMAT_R8UI: return DXGI_FORMAT_R8_UINT;
case SG_PIXELFORMAT_R8SI: return DXGI_FORMAT_R8_SINT;
case SG_PIXELFORMAT_R16: return DXGI_FORMAT_R16_UNORM;
case SG_PIXELFORMAT_R16SN: return DXGI_FORMAT_R16_SNORM;
case SG_PIXELFORMAT_R16UI: return DXGI_FORMAT_R16_UINT;
case SG_PIXELFORMAT_R16SI: return DXGI_FORMAT_R16_SINT;
case SG_PIXELFORMAT_R16F: return DXGI_FORMAT_R16_FLOAT;
case SG_PIXELFORMAT_RG8: return DXGI_FORMAT_R8G8_UNORM;
case SG_PIXELFORMAT_RG8SN: return DXGI_FORMAT_R8G8_SNORM;
case SG_PIXELFORMAT_RG8UI: return DXGI_FORMAT_R8G8_UINT;
case SG_PIXELFORMAT_RG8SI: return DXGI_FORMAT_R8G8_SINT;
case SG_PIXELFORMAT_R32UI: return DXGI_FORMAT_R32_UINT;
case SG_PIXELFORMAT_R32SI: return DXGI_FORMAT_R32_SINT;
case SG_PIXELFORMAT_R32F: return DXGI_FORMAT_R32_FLOAT;
case SG_PIXELFORMAT_RG16: return DXGI_FORMAT_R16G16_UNORM;
case SG_PIXELFORMAT_RG16SN: return DXGI_FORMAT_R16G16_SNORM;
case SG_PIXELFORMAT_RG16UI: return DXGI_FORMAT_R16G16_UINT;
case SG_PIXELFORMAT_RG16SI: return DXGI_FORMAT_R16G16_SINT;
case SG_PIXELFORMAT_RG16F: return DXGI_FORMAT_R16G16_FLOAT;
case SG_PIXELFORMAT_RGBA8: return DXGI_FORMAT_R8G8B8A8_UNORM;
case SG_PIXELFORMAT_RGBA8SN: return DXGI_FORMAT_R8G8B8A8_SNORM;
case SG_PIXELFORMAT_RGBA8UI: return DXGI_FORMAT_R8G8B8A8_UINT;
case SG_PIXELFORMAT_RGBA8SI: return DXGI_FORMAT_R8G8B8A8_SINT;
case SG_PIXELFORMAT_BGRA8: return DXGI_FORMAT_B8G8R8A8_UNORM;
case SG_PIXELFORMAT_RGB10A2: return DXGI_FORMAT_R10G10B10A2_UNORM;
case SG_PIXELFORMAT_RG11B10F: return DXGI_FORMAT_R11G11B10_FLOAT;
case SG_PIXELFORMAT_RG32UI: return DXGI_FORMAT_R32G32_UINT;
case SG_PIXELFORMAT_RG32SI: return DXGI_FORMAT_R32G32_SINT;
case SG_PIXELFORMAT_RG32F: return DXGI_FORMAT_R32G32_FLOAT;
case SG_PIXELFORMAT_RGBA16: return DXGI_FORMAT_R16G16B16A16_UNORM;
case SG_PIXELFORMAT_RGBA16SN: return DXGI_FORMAT_R16G16B16A16_SNORM;
case SG_PIXELFORMAT_RGBA16UI: return DXGI_FORMAT_R16G16B16A16_UINT;
case SG_PIXELFORMAT_RGBA16SI: return DXGI_FORMAT_R16G16B16A16_SINT;
case SG_PIXELFORMAT_RGBA16F: return DXGI_FORMAT_R16G16B16A16_FLOAT;
case SG_PIXELFORMAT_RGBA32UI: return DXGI_FORMAT_R32G32B32A32_UINT;
case SG_PIXELFORMAT_RGBA32SI: return DXGI_FORMAT_R32G32B32A32_SINT;
case SG_PIXELFORMAT_RGBA32F: return DXGI_FORMAT_R32G32B32A32_FLOAT;
case SG_PIXELFORMAT_DEPTH: return DXGI_FORMAT_D32_FLOAT;
case SG_PIXELFORMAT_DEPTH_STENCIL: return DXGI_FORMAT_D24_UNORM_S8_UINT;
case SG_PIXELFORMAT_BC1_RGBA: return DXGI_FORMAT_BC1_UNORM;
case SG_PIXELFORMAT_BC2_RGBA: return DXGI_FORMAT_BC2_UNORM;
case SG_PIXELFORMAT_BC3_RGBA: return DXGI_FORMAT_BC3_UNORM;
case SG_PIXELFORMAT_BC4_R: return DXGI_FORMAT_BC4_UNORM;
case SG_PIXELFORMAT_BC4_RSN: return DXGI_FORMAT_BC4_SNORM;
case SG_PIXELFORMAT_BC5_RG: return DXGI_FORMAT_BC5_UNORM;
case SG_PIXELFORMAT_BC5_RGSN: return DXGI_FORMAT_BC5_SNORM;
case SG_PIXELFORMAT_BC6H_RGBF: return DXGI_FORMAT_BC6H_SF16;
case SG_PIXELFORMAT_BC6H_RGBUF: return DXGI_FORMAT_BC6H_UF16;
case SG_PIXELFORMAT_BC7_RGBA: return DXGI_FORMAT_BC7_UNORM;
default: return DXGI_FORMAT_UNKNOWN;
};
}
_SOKOL_PRIVATE D3D11_PRIMITIVE_TOPOLOGY _sg_d3d11_primitive_topology(sg_primitive_type prim_type) {
switch (prim_type) {
case SG_PRIMITIVETYPE_POINTS: return D3D11_PRIMITIVE_TOPOLOGY_POINTLIST;
case SG_PRIMITIVETYPE_LINES: return D3D11_PRIMITIVE_TOPOLOGY_LINELIST;
case SG_PRIMITIVETYPE_LINE_STRIP: return D3D11_PRIMITIVE_TOPOLOGY_LINESTRIP;
case SG_PRIMITIVETYPE_TRIANGLES: return D3D11_PRIMITIVE_TOPOLOGY_TRIANGLELIST;
case SG_PRIMITIVETYPE_TRIANGLE_STRIP: return D3D11_PRIMITIVE_TOPOLOGY_TRIANGLESTRIP;
default: SOKOL_UNREACHABLE; return (D3D11_PRIMITIVE_TOPOLOGY) 0;
}
}
_SOKOL_PRIVATE DXGI_FORMAT _sg_d3d11_index_format(sg_index_type index_type) {
switch (index_type) {
case SG_INDEXTYPE_NONE: return DXGI_FORMAT_UNKNOWN;
case SG_INDEXTYPE_UINT16: return DXGI_FORMAT_R16_UINT;
case SG_INDEXTYPE_UINT32: return DXGI_FORMAT_R32_UINT;
default: SOKOL_UNREACHABLE; return (DXGI_FORMAT) 0;
}
}
_SOKOL_PRIVATE D3D11_FILTER _sg_d3d11_filter(sg_filter min_f, sg_filter mag_f, uint32_t max_anisotropy) {
if (max_anisotropy > 1) {
return D3D11_FILTER_ANISOTROPIC;
}
else if (mag_f == SG_FILTER_NEAREST) {
switch (min_f) {
case SG_FILTER_NEAREST:
case SG_FILTER_NEAREST_MIPMAP_NEAREST:
return D3D11_FILTER_MIN_MAG_MIP_POINT;
case SG_FILTER_LINEAR:
case SG_FILTER_LINEAR_MIPMAP_NEAREST:
return D3D11_FILTER_MIN_LINEAR_MAG_MIP_POINT;
case SG_FILTER_NEAREST_MIPMAP_LINEAR:
return D3D11_FILTER_MIN_MAG_POINT_MIP_LINEAR;
case SG_FILTER_LINEAR_MIPMAP_LINEAR:
return D3D11_FILTER_MIN_LINEAR_MAG_POINT_MIP_LINEAR;
default:
SOKOL_UNREACHABLE; break;
}
}
else if (mag_f == SG_FILTER_LINEAR) {
switch (min_f) {
case SG_FILTER_NEAREST:
case SG_FILTER_NEAREST_MIPMAP_NEAREST:
return D3D11_FILTER_MIN_POINT_MAG_LINEAR_MIP_POINT;
case SG_FILTER_LINEAR:
case SG_FILTER_LINEAR_MIPMAP_NEAREST:
return D3D11_FILTER_MIN_MAG_LINEAR_MIP_POINT;
case SG_FILTER_NEAREST_MIPMAP_LINEAR:
return D3D11_FILTER_MIN_POINT_MAG_MIP_LINEAR;
case SG_FILTER_LINEAR_MIPMAP_LINEAR:
return D3D11_FILTER_MIN_MAG_MIP_LINEAR;
default:
SOKOL_UNREACHABLE; break;
}
}
/* invalid value for mag filter */
SOKOL_UNREACHABLE;
return D3D11_FILTER_MIN_MAG_MIP_POINT;
}
_SOKOL_PRIVATE D3D11_TEXTURE_ADDRESS_MODE _sg_d3d11_address_mode(sg_wrap m) {
switch (m) {
case SG_WRAP_REPEAT: return D3D11_TEXTURE_ADDRESS_WRAP;
case SG_WRAP_CLAMP_TO_EDGE: return D3D11_TEXTURE_ADDRESS_CLAMP;
case SG_WRAP_CLAMP_TO_BORDER: return D3D11_TEXTURE_ADDRESS_BORDER;
case SG_WRAP_MIRRORED_REPEAT: return D3D11_TEXTURE_ADDRESS_MIRROR;
default: SOKOL_UNREACHABLE; return (D3D11_TEXTURE_ADDRESS_MODE) 0;
}
}
_SOKOL_PRIVATE DXGI_FORMAT _sg_d3d11_vertex_format(sg_vertex_format fmt) {
switch (fmt) {
case SG_VERTEXFORMAT_FLOAT: return DXGI_FORMAT_R32_FLOAT;
case SG_VERTEXFORMAT_FLOAT2: return DXGI_FORMAT_R32G32_FLOAT;
case SG_VERTEXFORMAT_FLOAT3: return DXGI_FORMAT_R32G32B32_FLOAT;
case SG_VERTEXFORMAT_FLOAT4: return DXGI_FORMAT_R32G32B32A32_FLOAT;
case SG_VERTEXFORMAT_BYTE4: return DXGI_FORMAT_R8G8B8A8_SINT;
case SG_VERTEXFORMAT_BYTE4N: return DXGI_FORMAT_R8G8B8A8_SNORM;
case SG_VERTEXFORMAT_UBYTE4: return DXGI_FORMAT_R8G8B8A8_UINT;
case SG_VERTEXFORMAT_UBYTE4N: return DXGI_FORMAT_R8G8B8A8_UNORM;
case SG_VERTEXFORMAT_SHORT2: return DXGI_FORMAT_R16G16_SINT;
case SG_VERTEXFORMAT_SHORT2N: return DXGI_FORMAT_R16G16_SNORM;
case SG_VERTEXFORMAT_USHORT2N: return DXGI_FORMAT_R16G16_UNORM;
case SG_VERTEXFORMAT_SHORT4: return DXGI_FORMAT_R16G16B16A16_SINT;
case SG_VERTEXFORMAT_SHORT4N: return DXGI_FORMAT_R16G16B16A16_SNORM;
case SG_VERTEXFORMAT_USHORT4N: return DXGI_FORMAT_R16G16B16A16_UNORM;
case SG_VERTEXFORMAT_UINT10_N2: return DXGI_FORMAT_R10G10B10A2_UNORM;
default: SOKOL_UNREACHABLE; return (DXGI_FORMAT) 0;
}
}
_SOKOL_PRIVATE D3D11_INPUT_CLASSIFICATION _sg_d3d11_input_classification(sg_vertex_step step) {
switch (step) {
case SG_VERTEXSTEP_PER_VERTEX: return D3D11_INPUT_PER_VERTEX_DATA;
case SG_VERTEXSTEP_PER_INSTANCE: return D3D11_INPUT_PER_INSTANCE_DATA;
default: SOKOL_UNREACHABLE; return (D3D11_INPUT_CLASSIFICATION) 0;
}
}
_SOKOL_PRIVATE D3D11_CULL_MODE _sg_d3d11_cull_mode(sg_cull_mode m) {
switch (m) {
case SG_CULLMODE_NONE: return D3D11_CULL_NONE;
case SG_CULLMODE_FRONT: return D3D11_CULL_FRONT;
case SG_CULLMODE_BACK: return D3D11_CULL_BACK;
default: SOKOL_UNREACHABLE; return (D3D11_CULL_MODE) 0;
}
}
_SOKOL_PRIVATE D3D11_COMPARISON_FUNC _sg_d3d11_compare_func(sg_compare_func f) {
switch (f) {
case SG_COMPAREFUNC_NEVER: return D3D11_COMPARISON_NEVER;
case SG_COMPAREFUNC_LESS: return D3D11_COMPARISON_LESS;
case SG_COMPAREFUNC_EQUAL: return D3D11_COMPARISON_EQUAL;
case SG_COMPAREFUNC_LESS_EQUAL: return D3D11_COMPARISON_LESS_EQUAL;
case SG_COMPAREFUNC_GREATER: return D3D11_COMPARISON_GREATER;
case SG_COMPAREFUNC_NOT_EQUAL: return D3D11_COMPARISON_NOT_EQUAL;
case SG_COMPAREFUNC_GREATER_EQUAL: return D3D11_COMPARISON_GREATER_EQUAL;
case SG_COMPAREFUNC_ALWAYS: return D3D11_COMPARISON_ALWAYS;
default: SOKOL_UNREACHABLE; return (D3D11_COMPARISON_FUNC) 0;
}
}
_SOKOL_PRIVATE D3D11_STENCIL_OP _sg_d3d11_stencil_op(sg_stencil_op op) {
switch (op) {
case SG_STENCILOP_KEEP: return D3D11_STENCIL_OP_KEEP;
case SG_STENCILOP_ZERO: return D3D11_STENCIL_OP_ZERO;
case SG_STENCILOP_REPLACE: return D3D11_STENCIL_OP_REPLACE;
case SG_STENCILOP_INCR_CLAMP: return D3D11_STENCIL_OP_INCR_SAT;
case SG_STENCILOP_DECR_CLAMP: return D3D11_STENCIL_OP_DECR_SAT;
case SG_STENCILOP_INVERT: return D3D11_STENCIL_OP_INVERT;
case SG_STENCILOP_INCR_WRAP: return D3D11_STENCIL_OP_INCR;
case SG_STENCILOP_DECR_WRAP: return D3D11_STENCIL_OP_DECR;
default: SOKOL_UNREACHABLE; return (D3D11_STENCIL_OP) 0;
}
}
_SOKOL_PRIVATE D3D11_BLEND _sg_d3d11_blend_factor(sg_blend_factor f) {
switch (f) {
case SG_BLENDFACTOR_ZERO: return D3D11_BLEND_ZERO;
case SG_BLENDFACTOR_ONE: return D3D11_BLEND_ONE;
case SG_BLENDFACTOR_SRC_COLOR: return D3D11_BLEND_SRC_COLOR;
case SG_BLENDFACTOR_ONE_MINUS_SRC_COLOR: return D3D11_BLEND_INV_SRC_COLOR;
case SG_BLENDFACTOR_SRC_ALPHA: return D3D11_BLEND_SRC_ALPHA;
case SG_BLENDFACTOR_ONE_MINUS_SRC_ALPHA: return D3D11_BLEND_INV_SRC_ALPHA;
case SG_BLENDFACTOR_DST_COLOR: return D3D11_BLEND_DEST_COLOR;
case SG_BLENDFACTOR_ONE_MINUS_DST_COLOR: return D3D11_BLEND_INV_DEST_COLOR;
case SG_BLENDFACTOR_DST_ALPHA: return D3D11_BLEND_DEST_ALPHA;
case SG_BLENDFACTOR_ONE_MINUS_DST_ALPHA: return D3D11_BLEND_INV_DEST_ALPHA;
case SG_BLENDFACTOR_SRC_ALPHA_SATURATED: return D3D11_BLEND_SRC_ALPHA_SAT;
case SG_BLENDFACTOR_BLEND_COLOR: return D3D11_BLEND_BLEND_FACTOR;
case SG_BLENDFACTOR_ONE_MINUS_BLEND_COLOR: return D3D11_BLEND_INV_BLEND_FACTOR;
case SG_BLENDFACTOR_BLEND_ALPHA: return D3D11_BLEND_BLEND_FACTOR;
case SG_BLENDFACTOR_ONE_MINUS_BLEND_ALPHA: return D3D11_BLEND_INV_BLEND_FACTOR;
default: SOKOL_UNREACHABLE; return (D3D11_BLEND) 0;
}
}
_SOKOL_PRIVATE D3D11_BLEND_OP _sg_d3d11_blend_op(sg_blend_op op) {
switch (op) {
case SG_BLENDOP_ADD: return D3D11_BLEND_OP_ADD;
case SG_BLENDOP_SUBTRACT: return D3D11_BLEND_OP_SUBTRACT;
case SG_BLENDOP_REVERSE_SUBTRACT: return D3D11_BLEND_OP_REV_SUBTRACT;
default: SOKOL_UNREACHABLE; return (D3D11_BLEND_OP) 0;
}
}
_SOKOL_PRIVATE UINT8 _sg_d3d11_color_write_mask(sg_color_mask m) {
UINT8 res = 0;
if (m & SG_COLORMASK_R) {
res |= D3D11_COLOR_WRITE_ENABLE_RED;
}
if (m & SG_COLORMASK_G) {
res |= D3D11_COLOR_WRITE_ENABLE_GREEN;
}
if (m & SG_COLORMASK_B) {
res |= D3D11_COLOR_WRITE_ENABLE_BLUE;
}
if (m & SG_COLORMASK_A) {
res |= D3D11_COLOR_WRITE_ENABLE_ALPHA;
}
return res;
}
/* see: https://docs.microsoft.com/en-us/windows/win32/direct3d11/overviews-direct3d-11-resources-limits#resource-limits-for-feature-level-11-hardware */
_SOKOL_PRIVATE void _sg_d3d11_init_caps(void) {
_sg.backend = SG_BACKEND_D3D11;
_sg.features.instancing = true;
_sg.features.origin_top_left = true;
_sg.features.multiple_render_targets = true;
_sg.features.msaa_render_targets = true;
_sg.features.imagetype_3d = true;
_sg.features.imagetype_array = true;
_sg.features.image_clamp_to_border = true;
_sg.limits.max_image_size_2d = 16 * 1024;
_sg.limits.max_image_size_cube = 16 * 1024;
_sg.limits.max_image_size_3d = 2 * 1024;
_sg.limits.max_image_size_array = 16 * 1024;
_sg.limits.max_image_array_layers = 2 * 1024;
_sg.limits.max_vertex_attrs = SG_MAX_VERTEX_ATTRIBUTES;
/* see: https://docs.microsoft.com/en-us/windows/win32/api/d3d11/ne-d3d11-d3d11_format_support */
UINT dxgi_fmt_caps = 0;
for (int fmt = (SG_PIXELFORMAT_NONE+1); fmt < _SG_PIXELFORMAT_NUM; fmt++) {
DXGI_FORMAT dxgi_fmt = _sg_d3d11_pixel_format((sg_pixel_format)fmt);
HRESULT hr = ID3D11Device_CheckFormatSupport(_sg.d3d11.dev, dxgi_fmt, &dxgi_fmt_caps);
SOKOL_ASSERT(SUCCEEDED(hr));
sg_pixelformat_info* info = &_sg.formats[fmt];
info->sample = 0 != (dxgi_fmt_caps & D3D11_FORMAT_SUPPORT_TEXTURE2D);
info->filter = 0 != (dxgi_fmt_caps & D3D11_FORMAT_SUPPORT_SHADER_SAMPLE);
info->render = 0 != (dxgi_fmt_caps & D3D11_FORMAT_SUPPORT_RENDER_TARGET);
info->blend = 0 != (dxgi_fmt_caps & D3D11_FORMAT_SUPPORT_BLENDABLE);
info->msaa = 0 != (dxgi_fmt_caps & D3D11_FORMAT_SUPPORT_MULTISAMPLE_RENDERTARGET);
info->depth = 0 != (dxgi_fmt_caps & D3D11_FORMAT_SUPPORT_DEPTH_STENCIL);
if (info->depth) {
info->render = true;
}
}
}
_SOKOL_PRIVATE void _sg_setup_backend(const sg_desc* desc) {
/* assume _sg.d3d11 already is zero-initialized */
SOKOL_ASSERT(desc);
SOKOL_ASSERT(desc->d3d11_device);
SOKOL_ASSERT(desc->d3d11_device_context);
SOKOL_ASSERT(desc->d3d11_render_target_view_cb);
SOKOL_ASSERT(desc->d3d11_depth_stencil_view_cb);
SOKOL_ASSERT(desc->d3d11_render_target_view_cb != desc->d3d11_depth_stencil_view_cb);
_sg.d3d11.valid = true;
_sg.d3d11.dev = (ID3D11Device*) desc->d3d11_device;
_sg.d3d11.ctx = (ID3D11DeviceContext*) desc->d3d11_device_context;
_sg.d3d11.rtv_cb = desc->d3d11_render_target_view_cb;
_sg.d3d11.dsv_cb = desc->d3d11_depth_stencil_view_cb;
_sg_d3d11_init_caps();
}
_SOKOL_PRIVATE void _sg_discard_backend(void) {
SOKOL_ASSERT(_sg.d3d11.valid);
_sg.d3d11.valid = false;
}
_SOKOL_PRIVATE void _sg_d3d11_clear_state(void) {
/* clear all the device context state, so that resource refs don't keep stuck in the d3d device context */
ID3D11DeviceContext_OMSetRenderTargets(_sg.d3d11.ctx, SG_MAX_COLOR_ATTACHMENTS, _sg.d3d11.zero_rtvs, NULL);
ID3D11DeviceContext_RSSetState(_sg.d3d11.ctx, NULL);
ID3D11DeviceContext_OMSetDepthStencilState(_sg.d3d11.ctx, NULL, 0);
ID3D11DeviceContext_OMSetBlendState(_sg.d3d11.ctx, NULL, NULL, 0xFFFFFFFF);
ID3D11DeviceContext_IASetVertexBuffers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_BUFFERS, _sg.d3d11.zero_vbs, _sg.d3d11.zero_vb_strides, _sg.d3d11.zero_vb_offsets);
ID3D11DeviceContext_IASetIndexBuffer(_sg.d3d11.ctx, NULL, DXGI_FORMAT_UNKNOWN, 0);
ID3D11DeviceContext_IASetInputLayout(_sg.d3d11.ctx, NULL);
ID3D11DeviceContext_VSSetShader(_sg.d3d11.ctx, NULL, NULL, 0);
ID3D11DeviceContext_PSSetShader(_sg.d3d11.ctx, NULL, NULL, 0);
ID3D11DeviceContext_VSSetConstantBuffers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_UBS, _sg.d3d11.zero_cbs);
ID3D11DeviceContext_PSSetConstantBuffers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_UBS, _sg.d3d11.zero_cbs);
ID3D11DeviceContext_VSSetShaderResources(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, _sg.d3d11.zero_srvs);
ID3D11DeviceContext_PSSetShaderResources(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, _sg.d3d11.zero_srvs);
ID3D11DeviceContext_VSSetSamplers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, _sg.d3d11.zero_smps);
ID3D11DeviceContext_PSSetSamplers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, _sg.d3d11.zero_smps);
}
_SOKOL_PRIVATE void _sg_reset_state_cache(void) {
/* just clear the d3d11 device context state */
_sg_d3d11_clear_state();
}
_SOKOL_PRIVATE void _sg_activate_context(_sg_context_t* ctx) {
_SOKOL_UNUSED(ctx);
_sg_reset_state_cache();
}
_SOKOL_PRIVATE sg_resource_state _sg_create_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
/* empty */
}
_SOKOL_PRIVATE sg_resource_state _sg_create_buffer(_sg_buffer_t* buf, const sg_buffer_desc* desc) {
SOKOL_ASSERT(buf && desc);
SOKOL_ASSERT(!buf->d3d11_buf);
buf->size = desc->size;
buf->append_pos = 0;
buf->append_overflow = false;
buf->type = desc->type;
buf->usage = desc->usage;
buf->update_frame_index = 0;
buf->append_frame_index = 0;
const bool injected = (0 != desc->d3d11_buffer);
if (injected) {
buf->d3d11_buf = (ID3D11Buffer*) desc->d3d11_buffer;
ID3D11Buffer_AddRef(buf->d3d11_buf);
}
else {
D3D11_BUFFER_DESC d3d11_desc;
memset(&d3d11_desc, 0, sizeof(d3d11_desc));
d3d11_desc.ByteWidth = buf->size;
d3d11_desc.Usage = _sg_d3d11_usage(buf->usage);
d3d11_desc.BindFlags = buf->type == SG_BUFFERTYPE_VERTEXBUFFER ? D3D11_BIND_VERTEX_BUFFER : D3D11_BIND_INDEX_BUFFER;
d3d11_desc.CPUAccessFlags = _sg_d3d11_cpu_access_flags(buf->usage);
D3D11_SUBRESOURCE_DATA* init_data_ptr = 0;
D3D11_SUBRESOURCE_DATA init_data;
memset(&init_data, 0, sizeof(init_data));
if (buf->usage == SG_USAGE_IMMUTABLE) {
SOKOL_ASSERT(desc->content);
init_data.pSysMem = desc->content;
init_data_ptr = &init_data;
}
HRESULT hr = ID3D11Device_CreateBuffer(_sg.d3d11.dev, &d3d11_desc, init_data_ptr, &buf->d3d11_buf);
_SOKOL_UNUSED(hr);
SOKOL_ASSERT(SUCCEEDED(hr) && buf->d3d11_buf);
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_buffer(_sg_buffer_t* buf) {
SOKOL_ASSERT(buf);
if (buf->d3d11_buf) {
ID3D11Buffer_Release(buf->d3d11_buf);
}
}
_SOKOL_PRIVATE void _sg_d3d11_fill_subres_data(const _sg_image_t* img, const sg_image_content* content) {
const int num_faces = (img->type == SG_IMAGETYPE_CUBE) ? 6:1;
const int num_slices = (img->type == SG_IMAGETYPE_ARRAY) ? img->depth:1;
int subres_index = 0;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int slice_index = 0; slice_index < num_slices; slice_index++) {
for (int mip_index = 0; mip_index < img->num_mipmaps; mip_index++, subres_index++) {
SOKOL_ASSERT(subres_index < (SG_MAX_MIPMAPS * SG_MAX_TEXTUREARRAY_LAYERS));
D3D11_SUBRESOURCE_DATA* subres_data = &_sg.d3d11.subres_data[subres_index];
const int mip_width = ((img->width>>mip_index)>0) ? img->width>>mip_index : 1;
const int mip_height = ((img->height>>mip_index)>0) ? img->height>>mip_index : 1;
const sg_subimage_content* subimg_content = &(content->subimage[face_index][mip_index]);
const int slice_size = subimg_content->size / num_slices;
const int slice_offset = slice_size * slice_index;
const uint8_t* ptr = (const uint8_t*) subimg_content->ptr;
subres_data->pSysMem = ptr + slice_offset;
subres_data->SysMemPitch = _sg_row_pitch(img->pixel_format, mip_width);
if (img->type == SG_IMAGETYPE_3D) {
/* FIXME? const int mip_depth = ((img->depth>>mip_index)>0) ? img->depth>>mip_index : 1; */
subres_data->SysMemSlicePitch = _sg_surface_pitch(img->pixel_format, mip_width, mip_height);
}
else {
subres_data->SysMemSlicePitch = 0;
}
}
}
}
}
_SOKOL_PRIVATE sg_resource_state _sg_create_image(_sg_image_t* img, const sg_image_desc* desc) {
SOKOL_ASSERT(img && desc);
SOKOL_ASSERT(!img->d3d11_tex2d && !img->d3d11_tex3d && !img->d3d11_texds && !img->d3d11_texmsaa);
SOKOL_ASSERT(!img->d3d11_srv && !img->d3d11_smp);
HRESULT hr;
img->type = desc->type;
img->render_target = desc->render_target;
img->width = desc->width;
img->height = desc->height;
img->depth = desc->depth;
img->num_mipmaps = desc->num_mipmaps;
img->usage = desc->usage;
img->pixel_format = desc->pixel_format;
img->sample_count = desc->sample_count;
img->min_filter = desc->min_filter;
img->mag_filter = desc->mag_filter;
img->wrap_u = desc->wrap_u;
img->wrap_v = desc->wrap_v;
img->wrap_w = desc->wrap_w;
img->border_color = desc->border_color;
img->max_anisotropy = desc->max_anisotropy;
img->upd_frame_index = 0;
const bool injected = (0 != desc->d3d11_texture);
const bool msaa = (img->sample_count > 1);
/* special case depth-stencil buffer? */
if (_sg_is_valid_rendertarget_depth_format(img->pixel_format)) {
/* create only a depth-texture */
SOKOL_ASSERT(!injected);
img->d3d11_format = _sg_d3d11_pixel_format(img->pixel_format);
if (img->d3d11_format == DXGI_FORMAT_UNKNOWN) {
SOKOL_LOG("trying to create a D3D11 depth-texture with unsupported pixel format\n");
return SG_RESOURCESTATE_FAILED;
}
D3D11_TEXTURE2D_DESC d3d11_desc;
memset(&d3d11_desc, 0, sizeof(d3d11_desc));
d3d11_desc.Width = img->width;
d3d11_desc.Height = img->height;
d3d11_desc.MipLevels = 1;
d3d11_desc.ArraySize = 1;
d3d11_desc.Format = img->d3d11_format;
d3d11_desc.Usage = D3D11_USAGE_DEFAULT;
d3d11_desc.BindFlags = D3D11_BIND_DEPTH_STENCIL;
d3d11_desc.SampleDesc.Count = img->sample_count;
d3d11_desc.SampleDesc.Quality = msaa ? D3D11_STANDARD_MULTISAMPLE_PATTERN : 0;
hr = ID3D11Device_CreateTexture2D(_sg.d3d11.dev, &d3d11_desc, NULL, &img->d3d11_texds);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_texds);
}
else {
/* create (or inject) color texture */
/* prepare initial content pointers */
D3D11_SUBRESOURCE_DATA* init_data = 0;
if (!injected && (img->usage == SG_USAGE_IMMUTABLE) && !img->render_target) {
_sg_d3d11_fill_subres_data(img, &desc->content);
init_data = _sg.d3d11.subres_data;
}
if (img->type != SG_IMAGETYPE_3D) {
/* 2D-, cube- or array-texture */
/* if this is an MSAA render target, the following texture will be the 'resolve-texture' */
D3D11_TEXTURE2D_DESC d3d11_tex_desc;
memset(&d3d11_tex_desc, 0, sizeof(d3d11_tex_desc));
d3d11_tex_desc.Width = img->width;
d3d11_tex_desc.Height = img->height;
d3d11_tex_desc.MipLevels = img->num_mipmaps;
switch (img->type) {
case SG_IMAGETYPE_ARRAY: d3d11_tex_desc.ArraySize = img->depth; break;
case SG_IMAGETYPE_CUBE: d3d11_tex_desc.ArraySize = 6; break;
default: d3d11_tex_desc.ArraySize = 1; break;
}
d3d11_tex_desc.BindFlags = D3D11_BIND_SHADER_RESOURCE;
if (img->render_target) {
img->d3d11_format = _sg_d3d11_pixel_format(img->pixel_format);
d3d11_tex_desc.Format = img->d3d11_format;
d3d11_tex_desc.Usage = D3D11_USAGE_DEFAULT;
if (!msaa) {
d3d11_tex_desc.BindFlags |= D3D11_BIND_RENDER_TARGET;
}
d3d11_tex_desc.CPUAccessFlags = 0;
}
else {
img->d3d11_format = _sg_d3d11_pixel_format(img->pixel_format);
d3d11_tex_desc.Format = img->d3d11_format;
d3d11_tex_desc.Usage = _sg_d3d11_usage(img->usage);
d3d11_tex_desc.CPUAccessFlags = _sg_d3d11_cpu_access_flags(img->usage);
}
if (img->d3d11_format == DXGI_FORMAT_UNKNOWN) {
/* trying to create a texture format that's not supported by D3D */
SOKOL_LOG("trying to create a D3D11 texture with unsupported pixel format\n");
return SG_RESOURCESTATE_FAILED;
}
d3d11_tex_desc.SampleDesc.Count = 1;
d3d11_tex_desc.SampleDesc.Quality = 0;
d3d11_tex_desc.MiscFlags = (img->type == SG_IMAGETYPE_CUBE) ? D3D11_RESOURCE_MISC_TEXTURECUBE : 0;
if (injected) {
img->d3d11_tex2d = (ID3D11Texture2D*) desc->d3d11_texture;
ID3D11Texture2D_AddRef(img->d3d11_tex2d);
}
else {
hr = ID3D11Device_CreateTexture2D(_sg.d3d11.dev, &d3d11_tex_desc, init_data, &img->d3d11_tex2d);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_tex2d);
}
/* shader-resource-view */
D3D11_SHADER_RESOURCE_VIEW_DESC d3d11_srv_desc;
memset(&d3d11_srv_desc, 0, sizeof(d3d11_srv_desc));
d3d11_srv_desc.Format = d3d11_tex_desc.Format;
switch (img->type) {
case SG_IMAGETYPE_2D:
d3d11_srv_desc.ViewDimension = D3D11_SRV_DIMENSION_TEXTURE2D;
d3d11_srv_desc.Texture2D.MipLevels = img->num_mipmaps;
break;
case SG_IMAGETYPE_CUBE:
d3d11_srv_desc.ViewDimension = D3D11_SRV_DIMENSION_TEXTURECUBE;
d3d11_srv_desc.TextureCube.MipLevels = img->num_mipmaps;
break;
case SG_IMAGETYPE_ARRAY:
d3d11_srv_desc.ViewDimension = D3D11_SRV_DIMENSION_TEXTURE2DARRAY;
d3d11_srv_desc.Texture2DArray.MipLevels = img->num_mipmaps;
d3d11_srv_desc.Texture2DArray.ArraySize = img->depth;
break;
default:
SOKOL_UNREACHABLE; break;
}
hr = ID3D11Device_CreateShaderResourceView(_sg.d3d11.dev, (ID3D11Resource*)img->d3d11_tex2d, &d3d11_srv_desc, &img->d3d11_srv);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_srv);
}
else {
/* 3D texture */
D3D11_TEXTURE3D_DESC d3d11_tex_desc;
memset(&d3d11_tex_desc, 0, sizeof(d3d11_tex_desc));
d3d11_tex_desc.Width = img->width;
d3d11_tex_desc.Height = img->height;
d3d11_tex_desc.Depth = img->depth;
d3d11_tex_desc.MipLevels = img->num_mipmaps;
d3d11_tex_desc.BindFlags = D3D11_BIND_SHADER_RESOURCE;
if (img->render_target) {
img->d3d11_format = _sg_d3d11_pixel_format(img->pixel_format);
d3d11_tex_desc.Format = img->d3d11_format;
d3d11_tex_desc.Usage = D3D11_USAGE_DEFAULT;
if (!msaa) {
d3d11_tex_desc.BindFlags |= D3D11_BIND_RENDER_TARGET;
}
d3d11_tex_desc.CPUAccessFlags = 0;
}
else {
img->d3d11_format = _sg_d3d11_pixel_format(img->pixel_format);
d3d11_tex_desc.Format = img->d3d11_format;
d3d11_tex_desc.Usage = _sg_d3d11_usage(img->usage);
d3d11_tex_desc.CPUAccessFlags = _sg_d3d11_cpu_access_flags(img->usage);
}
if (img->d3d11_format == DXGI_FORMAT_UNKNOWN) {
/* trying to create a texture format that's not supported by D3D */
SOKOL_LOG("trying to create a D3D11 texture with unsupported pixel format\n");
return SG_RESOURCESTATE_FAILED;
}
if (injected) {
img->d3d11_tex3d = (ID3D11Texture3D*) desc->d3d11_texture;
ID3D11Texture3D_AddRef(img->d3d11_tex3d);
}
else {
hr = ID3D11Device_CreateTexture3D(_sg.d3d11.dev, &d3d11_tex_desc, init_data, &img->d3d11_tex3d);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_tex3d);
}
/* shader resource view for 3d texture */
D3D11_SHADER_RESOURCE_VIEW_DESC d3d11_srv_desc;
memset(&d3d11_srv_desc, 0, sizeof(d3d11_srv_desc));
d3d11_srv_desc.Format = d3d11_tex_desc.Format;
d3d11_srv_desc.ViewDimension = D3D11_SRV_DIMENSION_TEXTURE3D;
d3d11_srv_desc.Texture3D.MipLevels = img->num_mipmaps;
hr = ID3D11Device_CreateShaderResourceView(_sg.d3d11.dev, (ID3D11Resource*)img->d3d11_tex3d, &d3d11_srv_desc, &img->d3d11_srv);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_srv);
}
/* also need to create a separate MSAA render target texture? */
if (msaa) {
D3D11_TEXTURE2D_DESC d3d11_tex_desc;
memset(&d3d11_tex_desc, 0, sizeof(d3d11_tex_desc));
d3d11_tex_desc.Width = img->width;
d3d11_tex_desc.Height = img->height;
d3d11_tex_desc.MipLevels = 1;
d3d11_tex_desc.ArraySize = 1;
d3d11_tex_desc.Format = img->d3d11_format;
d3d11_tex_desc.Usage = D3D11_USAGE_DEFAULT;
d3d11_tex_desc.BindFlags = D3D11_BIND_RENDER_TARGET;
d3d11_tex_desc.CPUAccessFlags = 0;
d3d11_tex_desc.SampleDesc.Count = img->sample_count;
d3d11_tex_desc.SampleDesc.Quality = (UINT)D3D11_STANDARD_MULTISAMPLE_PATTERN;
hr = ID3D11Device_CreateTexture2D(_sg.d3d11.dev, &d3d11_tex_desc, NULL, &img->d3d11_texmsaa);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_texmsaa);
}
/* sampler state object, note D3D11 implements an internal shared-pool for sampler objects */
D3D11_SAMPLER_DESC d3d11_smp_desc;
memset(&d3d11_smp_desc, 0, sizeof(d3d11_smp_desc));
d3d11_smp_desc.Filter = _sg_d3d11_filter(img->min_filter, img->mag_filter, img->max_anisotropy);
d3d11_smp_desc.AddressU = _sg_d3d11_address_mode(img->wrap_u);
d3d11_smp_desc.AddressV = _sg_d3d11_address_mode(img->wrap_v);
d3d11_smp_desc.AddressW = _sg_d3d11_address_mode(img->wrap_w);
switch (img->border_color) {
case SG_BORDERCOLOR_TRANSPARENT_BLACK:
/* all 0.0f */
break;
case SG_BORDERCOLOR_OPAQUE_WHITE:
for (int i = 0; i < 4; i++) {
d3d11_smp_desc.BorderColor[i] = 1.0f;
}
break;
default:
/* opaque black */
d3d11_smp_desc.BorderColor[3] = 1.0f;
break;
}
d3d11_smp_desc.MaxAnisotropy = img->max_anisotropy;
d3d11_smp_desc.ComparisonFunc = D3D11_COMPARISON_NEVER;
d3d11_smp_desc.MinLOD = desc->min_lod;
d3d11_smp_desc.MaxLOD = desc->max_lod;
hr = ID3D11Device_CreateSamplerState(_sg.d3d11.dev, &d3d11_smp_desc, &img->d3d11_smp);
SOKOL_ASSERT(SUCCEEDED(hr) && img->d3d11_smp);
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_image(_sg_image_t* img) {
SOKOL_ASSERT(img);
if (img->d3d11_tex2d) {
ID3D11Texture2D_Release(img->d3d11_tex2d);
}
if (img->d3d11_tex3d) {
ID3D11Texture3D_Release(img->d3d11_tex3d);
}
if (img->d3d11_texds) {
ID3D11Texture2D_Release(img->d3d11_texds);
}
if (img->d3d11_texmsaa) {
ID3D11Texture2D_Release(img->d3d11_texmsaa);
}
if (img->d3d11_srv) {
ID3D11ShaderResourceView_Release(img->d3d11_srv);
}
if (img->d3d11_smp) {
ID3D11SamplerState_Release(img->d3d11_smp);
}
}
_SOKOL_PRIVATE bool _sg_d3d11_load_d3dcompiler_dll(void) {
/* on UWP, don't do anything (not tested) */
#if (defined(WINAPI_FAMILY_PARTITION) && !WINAPI_FAMILY_PARTITION(WINAPI_PARTITION_DESKTOP))
return true;
#else
/* load DLL on demand */
if ((0 == _sg.d3d11.d3dcompiler_dll) && !_sg.d3d11.d3dcompiler_dll_load_failed) {
_sg.d3d11.d3dcompiler_dll = LoadLibraryA("d3dcompiler_47.dll");
if (0 == _sg.d3d11.d3dcompiler_dll) {
/* don't attempt to load missing DLL in the future */
SOKOL_LOG("failed to load d3dcompiler_47.dll!\n");
_sg.d3d11.d3dcompiler_dll_load_failed = true;
return false;
}
/* look up function pointers */
_sg.d3d11.D3DCompile_func = (pD3DCompile) GetProcAddress(_sg.d3d11.d3dcompiler_dll, "D3DCompile");
SOKOL_ASSERT(_sg.d3d11.D3DCompile_func);
}
return 0 != _sg.d3d11.d3dcompiler_dll;
#endif
}
#if (defined(WINAPI_FAMILY_PARTITION) && !WINAPI_FAMILY_PARTITION(WINAPI_PARTITION_DESKTOP))
#define _sg_d3d11_D3DCompile D3DCompile
#else
#define _sg_d3d11_D3DCompile _sg.d3d11.D3DCompile_func
#endif
_SOKOL_PRIVATE ID3DBlob* _sg_d3d11_compile_shader(const sg_shader_stage_desc* stage_desc, const char* target) {
if (!_sg_d3d11_load_d3dcompiler_dll()) {
return NULL;
}
ID3DBlob* output = NULL;
ID3DBlob* errors = NULL;
_sg_d3d11_D3DCompile(
stage_desc->source, /* pSrcData */
strlen(stage_desc->source), /* SrcDataSize */
NULL, /* pSourceName */
NULL, /* pDefines */
NULL, /* pInclude */
stage_desc->entry ? stage_desc->entry : "main", /* pEntryPoint */
target, /* pTarget (vs_5_0 or ps_5_0) */
D3DCOMPILE_PACK_MATRIX_COLUMN_MAJOR | D3DCOMPILE_OPTIMIZATION_LEVEL3, /* Flags1 */
0, /* Flags2 */
&output, /* ppCode */
&errors); /* ppErrorMsgs */
if (errors) {
SOKOL_LOG((LPCSTR)ID3D10Blob_GetBufferPointer(errors));
ID3D10Blob_Release(errors); errors = NULL;
return NULL;
}
return output;
}
#define _sg_d3d11_roundup(val, round_to) (((val)+((round_to)-1))&~((round_to)-1))
_SOKOL_PRIVATE sg_resource_state _sg_create_shader(_sg_shader_t* shd, const sg_shader_desc* desc) {
SOKOL_ASSERT(shd && desc);
SOKOL_ASSERT(!shd->d3d11_vs && !shd->d3d11_fs && !shd->d3d11_vs_blob);
HRESULT hr;
sg_resource_state result = SG_RESOURCESTATE_FAILED;
/* copy vertex attribute semantic names and indices */
for (int i = 0; i < SG_MAX_VERTEX_ATTRIBUTES; i++) {
_sg_strcpy(&shd->attrs[i].sem_name, desc->attrs[i].sem_name);
shd->attrs[i].sem_index = desc->attrs[i].sem_index;
}
/* shader stage uniform blocks and image slots */
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const sg_shader_stage_desc* stage_desc = (stage_index == SG_SHADERSTAGE_VS) ? &desc->vs : &desc->fs;
_sg_shader_stage_t* stage = &shd->stage[stage_index];
SOKOL_ASSERT(stage->num_uniform_blocks == 0);
for (int ub_index = 0; ub_index < SG_MAX_SHADERSTAGE_UBS; ub_index++) {
const sg_shader_uniform_block_desc* ub_desc = &stage_desc->uniform_blocks[ub_index];
if (0 == ub_desc->size) {
break;
}
_sg_uniform_block_t* ub = &stage->uniform_blocks[ub_index];
ub->size = ub_desc->size;
/* create a D3D constant buffer */
SOKOL_ASSERT(!stage->d3d11_cbs[ub_index]);
D3D11_BUFFER_DESC cb_desc;
memset(&cb_desc, 0, sizeof(cb_desc));
cb_desc.ByteWidth = _sg_d3d11_roundup(ub->size, 16);
cb_desc.Usage = D3D11_USAGE_DEFAULT;
cb_desc.BindFlags = D3D11_BIND_CONSTANT_BUFFER;
hr = ID3D11Device_CreateBuffer(_sg.d3d11.dev, &cb_desc, NULL, &stage->d3d11_cbs[ub_index]);
SOKOL_ASSERT(SUCCEEDED(hr) && stage->d3d11_cbs[ub_index]);
stage->num_uniform_blocks++;
}
SOKOL_ASSERT(stage->num_images == 0);
for (int img_index = 0; img_index < SG_MAX_SHADERSTAGE_IMAGES; img_index++) {
const sg_shader_image_desc* img_desc = &stage_desc->images[img_index];
if (img_desc->type == _SG_IMAGETYPE_DEFAULT) {
break;
}
stage->images[img_index].type = img_desc->type;
stage->num_images++;
}
}
const void* vs_ptr = 0, *fs_ptr = 0;
SIZE_T vs_length = 0, fs_length = 0;
ID3DBlob* vs_blob = 0, *fs_blob = 0;
if (desc->vs.byte_code && desc->fs.byte_code) {
/* create from byte code */
vs_ptr = desc->vs.byte_code;
fs_ptr = desc->fs.byte_code;
vs_length = desc->vs.byte_code_size;
fs_length = desc->fs.byte_code_size;
}
else {
/* compile shader code */
vs_blob = _sg_d3d11_compile_shader(&desc->vs, "vs_5_0");
fs_blob = _sg_d3d11_compile_shader(&desc->fs, "ps_5_0");
if (vs_blob && fs_blob) {
vs_ptr = ID3D10Blob_GetBufferPointer(vs_blob);
vs_length = ID3D10Blob_GetBufferSize(vs_blob);
fs_ptr = ID3D10Blob_GetBufferPointer(fs_blob);
fs_length = ID3D10Blob_GetBufferSize(fs_blob);
}
}
if (vs_ptr && fs_ptr && (vs_length > 0) && (fs_length > 0)) {
/* create the D3D vertex- and pixel-shader objects */
hr = ID3D11Device_CreateVertexShader(_sg.d3d11.dev, vs_ptr, vs_length, NULL, &shd->d3d11_vs);
SOKOL_ASSERT(SUCCEEDED(hr) && shd->d3d11_vs);
hr = ID3D11Device_CreatePixelShader(_sg.d3d11.dev, fs_ptr, fs_length, NULL, &shd->d3d11_fs);
SOKOL_ASSERT(SUCCEEDED(hr) && shd->d3d11_fs);
/* need to store the vertex shader byte code, this is needed later in sg_create_pipeline */
shd->d3d11_vs_blob_length = (int)vs_length;
shd->d3d11_vs_blob = SOKOL_MALLOC((int)vs_length);
SOKOL_ASSERT(shd->d3d11_vs_blob);
memcpy(shd->d3d11_vs_blob, vs_ptr, vs_length);
result = SG_RESOURCESTATE_VALID;
}
if (vs_blob) {
ID3D10Blob_Release(vs_blob); vs_blob = 0;
}
if (fs_blob) {
ID3D10Blob_Release(fs_blob); fs_blob = 0;
}
return result;
}
_SOKOL_PRIVATE void _sg_destroy_shader(_sg_shader_t* shd) {
SOKOL_ASSERT(shd);
if (shd->d3d11_vs) {
ID3D11VertexShader_Release(shd->d3d11_vs);
}
if (shd->d3d11_fs) {
ID3D11PixelShader_Release(shd->d3d11_fs);
}
if (shd->d3d11_vs_blob) {
SOKOL_FREE(shd->d3d11_vs_blob);
}
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
_sg_shader_stage_t* stage = &shd->stage[stage_index];
for (int ub_index = 0; ub_index < stage->num_uniform_blocks; ub_index++) {
if (stage->d3d11_cbs[ub_index]) {
ID3D11Buffer_Release(stage->d3d11_cbs[ub_index]);
}
}
}
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pipeline(_sg_pipeline_t* pip, _sg_shader_t* shd, const sg_pipeline_desc* desc) {
SOKOL_ASSERT(pip && shd && desc);
SOKOL_ASSERT(desc->shader.id == shd->slot.id);
SOKOL_ASSERT(shd->slot.state == SG_RESOURCESTATE_VALID);
SOKOL_ASSERT(shd->d3d11_vs_blob && shd->d3d11_vs_blob_length > 0);
SOKOL_ASSERT(!pip->d3d11_il && !pip->d3d11_rs && !pip->d3d11_dss && !pip->d3d11_bs);
HRESULT hr;
pip->shader = shd;
pip->shader_id = desc->shader;
pip->index_type = desc->index_type;
pip->color_attachment_count = desc->blend.color_attachment_count;
pip->color_format = desc->blend.color_format;
pip->depth_format = desc->blend.depth_format;
pip->sample_count = desc->rasterizer.sample_count;
pip->d3d11_index_format = _sg_d3d11_index_format(pip->index_type);
pip->d3d11_topology = _sg_d3d11_primitive_topology(desc->primitive_type);
for (int i = 0; i < 4; i++) {
pip->blend_color[i] = desc->blend.blend_color[i];
}
pip->d3d11_stencil_ref = desc->depth_stencil.stencil_ref;
/* create input layout object */
D3D11_INPUT_ELEMENT_DESC d3d11_comps[SG_MAX_VERTEX_ATTRIBUTES];
memset(d3d11_comps, 0, sizeof(d3d11_comps));
int attr_index = 0;
for (; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
const sg_vertex_attr_desc* a_desc = &desc->layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
break;
}
SOKOL_ASSERT((a_desc->buffer_index >= 0) && (a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS));
const sg_buffer_layout_desc* l_desc = &desc->layout.buffers[a_desc->buffer_index];
const sg_vertex_step step_func = l_desc->step_func;
const int step_rate = l_desc->step_rate;
D3D11_INPUT_ELEMENT_DESC* d3d11_comp = &d3d11_comps[attr_index];
d3d11_comp->SemanticName = _sg_strptr(&shd->attrs[attr_index].sem_name);
d3d11_comp->SemanticIndex = shd->attrs[attr_index].sem_index;
d3d11_comp->Format = _sg_d3d11_vertex_format(a_desc->format);
d3d11_comp->InputSlot = a_desc->buffer_index;
d3d11_comp->AlignedByteOffset = a_desc->offset;
d3d11_comp->InputSlotClass = _sg_d3d11_input_classification(step_func);
if (SG_VERTEXSTEP_PER_INSTANCE == step_func) {
d3d11_comp->InstanceDataStepRate = step_rate;
}
pip->vertex_layout_valid[a_desc->buffer_index] = true;
}
for (int layout_index = 0; layout_index < SG_MAX_SHADERSTAGE_BUFFERS; layout_index++) {
if (pip->vertex_layout_valid[layout_index]) {
const sg_buffer_layout_desc* l_desc = &desc->layout.buffers[layout_index];
SOKOL_ASSERT(l_desc->stride > 0);
pip->d3d11_vb_strides[layout_index] = l_desc->stride;
}
else {
pip->d3d11_vb_strides[layout_index] = 0;
}
}
hr = ID3D11Device_CreateInputLayout(_sg.d3d11.dev,
d3d11_comps, /* pInputElementDesc */
attr_index, /* NumElements */
shd->d3d11_vs_blob, /* pShaderByteCodeWithInputSignature */
shd->d3d11_vs_blob_length, /* BytecodeLength */
&pip->d3d11_il);
SOKOL_ASSERT(SUCCEEDED(hr) && pip->d3d11_il);
/* create rasterizer state */
D3D11_RASTERIZER_DESC rs_desc;
memset(&rs_desc, 0, sizeof(rs_desc));
rs_desc.FillMode = D3D11_FILL_SOLID;
rs_desc.CullMode = _sg_d3d11_cull_mode(desc->rasterizer.cull_mode);
rs_desc.FrontCounterClockwise = desc->rasterizer.face_winding == SG_FACEWINDING_CCW;
rs_desc.DepthBias = (INT) desc->rasterizer.depth_bias;
rs_desc.DepthBiasClamp = desc->rasterizer.depth_bias_clamp;
rs_desc.SlopeScaledDepthBias = desc->rasterizer.depth_bias_slope_scale;
rs_desc.DepthClipEnable = TRUE;
rs_desc.ScissorEnable = TRUE;
rs_desc.MultisampleEnable = desc->rasterizer.sample_count > 1;
rs_desc.AntialiasedLineEnable = FALSE;
hr = ID3D11Device_CreateRasterizerState(_sg.d3d11.dev, &rs_desc, &pip->d3d11_rs);
SOKOL_ASSERT(SUCCEEDED(hr) && pip->d3d11_rs);
/* create depth-stencil state */
D3D11_DEPTH_STENCIL_DESC dss_desc;
memset(&dss_desc, 0, sizeof(dss_desc));
dss_desc.DepthEnable = TRUE;
dss_desc.DepthWriteMask = desc->depth_stencil.depth_write_enabled ? D3D11_DEPTH_WRITE_MASK_ALL : D3D11_DEPTH_WRITE_MASK_ZERO;
dss_desc.DepthFunc = _sg_d3d11_compare_func(desc->depth_stencil.depth_compare_func);
dss_desc.StencilEnable = desc->depth_stencil.stencil_enabled;
dss_desc.StencilReadMask = desc->depth_stencil.stencil_read_mask;
dss_desc.StencilWriteMask = desc->depth_stencil.stencil_write_mask;
const sg_stencil_state* sf = &desc->depth_stencil.stencil_front;
dss_desc.FrontFace.StencilFailOp = _sg_d3d11_stencil_op(sf->fail_op);
dss_desc.FrontFace.StencilDepthFailOp = _sg_d3d11_stencil_op(sf->depth_fail_op);
dss_desc.FrontFace.StencilPassOp = _sg_d3d11_stencil_op(sf->pass_op);
dss_desc.FrontFace.StencilFunc = _sg_d3d11_compare_func(sf->compare_func);
const sg_stencil_state* sb = &desc->depth_stencil.stencil_back;
dss_desc.BackFace.StencilFailOp = _sg_d3d11_stencil_op(sb->fail_op);
dss_desc.BackFace.StencilDepthFailOp = _sg_d3d11_stencil_op(sb->depth_fail_op);
dss_desc.BackFace.StencilPassOp = _sg_d3d11_stencil_op(sb->pass_op);
dss_desc.BackFace.StencilFunc = _sg_d3d11_compare_func(sb->compare_func);
hr = ID3D11Device_CreateDepthStencilState(_sg.d3d11.dev, &dss_desc, &pip->d3d11_dss);
SOKOL_ASSERT(SUCCEEDED(hr) && pip->d3d11_dss);
/* create blend state */
D3D11_BLEND_DESC bs_desc;
memset(&bs_desc, 0, sizeof(bs_desc));
bs_desc.AlphaToCoverageEnable = desc->rasterizer.alpha_to_coverage_enabled;
bs_desc.IndependentBlendEnable = FALSE;
bs_desc.RenderTarget[0].BlendEnable = desc->blend.enabled;
bs_desc.RenderTarget[0].SrcBlend = _sg_d3d11_blend_factor(desc->blend.src_factor_rgb);
bs_desc.RenderTarget[0].DestBlend = _sg_d3d11_blend_factor(desc->blend.dst_factor_rgb);
bs_desc.RenderTarget[0].BlendOp = _sg_d3d11_blend_op(desc->blend.op_rgb);
bs_desc.RenderTarget[0].SrcBlendAlpha = _sg_d3d11_blend_factor(desc->blend.src_factor_alpha);
bs_desc.RenderTarget[0].DestBlendAlpha = _sg_d3d11_blend_factor(desc->blend.dst_factor_alpha);
bs_desc.RenderTarget[0].BlendOpAlpha = _sg_d3d11_blend_op(desc->blend.op_alpha);
bs_desc.RenderTarget[0].RenderTargetWriteMask = _sg_d3d11_color_write_mask((sg_color_mask)desc->blend.color_write_mask);
hr = ID3D11Device_CreateBlendState(_sg.d3d11.dev, &bs_desc, &pip->d3d11_bs);
SOKOL_ASSERT(SUCCEEDED(hr) && pip->d3d11_bs);
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
if (pip->d3d11_il) {
ID3D11InputLayout_Release(pip->d3d11_il);
}
if (pip->d3d11_rs) {
ID3D11RasterizerState_Release(pip->d3d11_rs);
}
if (pip->d3d11_dss) {
ID3D11DepthStencilState_Release(pip->d3d11_dss);
}
if (pip->d3d11_bs) {
ID3D11BlendState_Release(pip->d3d11_bs);
}
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pass(_sg_pass_t* pass, _sg_image_t** att_images, const sg_pass_desc* desc) {
SOKOL_ASSERT(pass && desc);
SOKOL_ASSERT(att_images && att_images[0]);
SOKOL_ASSERT(_sg.d3d11.dev);
const sg_attachment_desc* att_desc;
_sg_attachment_t* att;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
SOKOL_ASSERT(0 == pass->color_atts[i].image);
SOKOL_ASSERT(pass->d3d11_rtvs[i] == 0);
att_desc = &desc->color_attachments[i];
if (att_desc->image.id != SG_INVALID_ID) {
pass->num_color_atts++;
SOKOL_ASSERT(att_images[i] && (att_images[i]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_color_format(att_images[i]->pixel_format));
att = &pass->color_atts[i];
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[i];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
/* create D3D11 render-target-view */
ID3D11Resource* d3d11_res = 0;
const bool is_msaa = att->image->sample_count > 1;
D3D11_RENDER_TARGET_VIEW_DESC d3d11_rtv_desc;
memset(&d3d11_rtv_desc, 0, sizeof(d3d11_rtv_desc));
d3d11_rtv_desc.Format = att->image->d3d11_format;
if ((att->image->type == SG_IMAGETYPE_2D) || is_msaa) {
if (is_msaa) {
d3d11_res = (ID3D11Resource*) att->image->d3d11_texmsaa;
d3d11_rtv_desc.ViewDimension = D3D11_RTV_DIMENSION_TEXTURE2DMS;
}
else {
d3d11_res = (ID3D11Resource*) att->image->d3d11_tex2d;
d3d11_rtv_desc.ViewDimension = D3D11_RTV_DIMENSION_TEXTURE2D;
d3d11_rtv_desc.Texture2D.MipSlice = att->mip_level;
}
}
else if ((att->image->type == SG_IMAGETYPE_CUBE) || (att->image->type == SG_IMAGETYPE_ARRAY)) {
d3d11_res = (ID3D11Resource*) att->image->d3d11_tex2d;
d3d11_rtv_desc.ViewDimension = D3D11_RTV_DIMENSION_TEXTURE2DARRAY;
d3d11_rtv_desc.Texture2DArray.MipSlice = att->mip_level;
d3d11_rtv_desc.Texture2DArray.FirstArraySlice = att->slice;
d3d11_rtv_desc.Texture2DArray.ArraySize = 1;
}
else {
SOKOL_ASSERT(att->image->type == SG_IMAGETYPE_3D);
d3d11_res = (ID3D11Resource*) att->image->d3d11_tex3d;
d3d11_rtv_desc.ViewDimension = D3D11_RTV_DIMENSION_TEXTURE3D;
d3d11_rtv_desc.Texture3D.MipSlice = att->mip_level;
d3d11_rtv_desc.Texture3D.FirstWSlice = att->slice;
d3d11_rtv_desc.Texture3D.WSize = 1;
}
SOKOL_ASSERT(d3d11_res);
HRESULT hr = ID3D11Device_CreateRenderTargetView(_sg.d3d11.dev, d3d11_res, &d3d11_rtv_desc, &pass->d3d11_rtvs[i]);
_SOKOL_UNUSED(hr);
SOKOL_ASSERT(SUCCEEDED(hr) && pass->d3d11_rtvs[i]);
}
}
/* optional depth-stencil image */
SOKOL_ASSERT(0 == pass->ds_att.image);
SOKOL_ASSERT(pass->d3d11_dsv == 0);
att_desc = &desc->depth_stencil_attachment;
const int ds_img_index = SG_MAX_COLOR_ATTACHMENTS;
if (att_desc->image.id != SG_INVALID_ID) {
SOKOL_ASSERT(att_images[ds_img_index] && (att_images[ds_img_index]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_depth_format(att_images[ds_img_index]->pixel_format));
att = &pass->ds_att;
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[ds_img_index];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
/* create D3D11 depth-stencil-view */
D3D11_DEPTH_STENCIL_VIEW_DESC d3d11_dsv_desc;
memset(&d3d11_dsv_desc, 0, sizeof(d3d11_dsv_desc));
d3d11_dsv_desc.Format = att->image->d3d11_format;
const bool is_msaa = att->image->sample_count > 1;
if (is_msaa) {
d3d11_dsv_desc.ViewDimension = D3D11_DSV_DIMENSION_TEXTURE2DMS;
}
else {
d3d11_dsv_desc.ViewDimension = D3D11_DSV_DIMENSION_TEXTURE2D;
}
ID3D11Resource* d3d11_res = (ID3D11Resource*) att->image->d3d11_texds;
SOKOL_ASSERT(d3d11_res);
HRESULT hr = ID3D11Device_CreateDepthStencilView(_sg.d3d11.dev, d3d11_res, &d3d11_dsv_desc, &pass->d3d11_dsv);
_SOKOL_UNUSED(hr);
SOKOL_ASSERT(SUCCEEDED(hr) && pass->d3d11_dsv);
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pass(_sg_pass_t* pass) {
SOKOL_ASSERT(pass);
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
if (pass->d3d11_rtvs[i]) {
ID3D11RenderTargetView_Release(pass->d3d11_rtvs[i]);
}
}
if (pass->d3d11_dsv) {
ID3D11DepthStencilView_Release(pass->d3d11_dsv);
}
}
_SOKOL_PRIVATE void _sg_begin_pass(_sg_pass_t* pass, const sg_pass_action* action, int w, int h) {
SOKOL_ASSERT(action);
SOKOL_ASSERT(!_sg.d3d11.in_pass);
_sg.d3d11.in_pass = true;
_sg.d3d11.cur_width = w;
_sg.d3d11.cur_height = h;
if (pass) {
_sg.d3d11.cur_pass = pass;
_sg.d3d11.cur_pass_id.id = pass->slot.id;
_sg.d3d11.num_rtvs = 0;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
_sg.d3d11.cur_rtvs[i] = pass->d3d11_rtvs[i];
if (_sg.d3d11.cur_rtvs[i]) {
_sg.d3d11.num_rtvs++;
}
}
_sg.d3d11.cur_dsv = pass->d3d11_dsv;
}
else {
/* render to default frame buffer */
_sg.d3d11.cur_pass = 0;
_sg.d3d11.cur_pass_id.id = SG_INVALID_ID;
_sg.d3d11.num_rtvs = 1;
_sg.d3d11.cur_rtvs[0] = (ID3D11RenderTargetView*) _sg.d3d11.rtv_cb();
for (int i = 1; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
_sg.d3d11.cur_rtvs[i] = 0;
}
_sg.d3d11.cur_dsv = (ID3D11DepthStencilView*) _sg.d3d11.dsv_cb();
SOKOL_ASSERT(_sg.d3d11.cur_rtvs[0] && _sg.d3d11.cur_dsv);
}
/* apply the render-target- and depth-stencil-views */
ID3D11DeviceContext_OMSetRenderTargets(_sg.d3d11.ctx, SG_MAX_COLOR_ATTACHMENTS, _sg.d3d11.cur_rtvs, _sg.d3d11.cur_dsv);
/* set viewport and scissor rect to cover whole screen */
D3D11_VIEWPORT vp;
memset(&vp, 0, sizeof(vp));
vp.Width = (FLOAT) w;
vp.Height = (FLOAT) h;
vp.MaxDepth = 1.0f;
ID3D11DeviceContext_RSSetViewports(_sg.d3d11.ctx, 1, &vp);
D3D11_RECT rect;
rect.left = 0;
rect.top = 0;
rect.right = w;
rect.bottom = h;
ID3D11DeviceContext_RSSetScissorRects(_sg.d3d11.ctx, 1, &rect);
/* perform clear action */
for (int i = 0; i < _sg.d3d11.num_rtvs; i++) {
if (action->colors[i].action == SG_ACTION_CLEAR) {
ID3D11DeviceContext_ClearRenderTargetView(_sg.d3d11.ctx, _sg.d3d11.cur_rtvs[i], action->colors[i].val);
}
}
UINT ds_flags = 0;
if (action->depth.action == SG_ACTION_CLEAR) {
ds_flags |= D3D11_CLEAR_DEPTH;
}
if (action->stencil.action == SG_ACTION_CLEAR) {
ds_flags |= D3D11_CLEAR_STENCIL;
}
if ((0 != ds_flags) && _sg.d3d11.cur_dsv) {
ID3D11DeviceContext_ClearDepthStencilView(_sg.d3d11.ctx, _sg.d3d11.cur_dsv, ds_flags, action->depth.val, action->stencil.val);
}
}
/* D3D11CalcSubresource only exists for C++ */
_SOKOL_PRIVATE UINT _sg_d3d11_calcsubresource(UINT mip_slice, UINT array_slice, UINT mip_levels) {
return mip_slice + array_slice * mip_levels;
}
_SOKOL_PRIVATE void _sg_end_pass(void) {
SOKOL_ASSERT(_sg.d3d11.in_pass && _sg.d3d11.ctx);
_sg.d3d11.in_pass = false;
/* need to resolve MSAA render target into texture? */
if (_sg.d3d11.cur_pass) {
SOKOL_ASSERT(_sg.d3d11.cur_pass->slot.id == _sg.d3d11.cur_pass_id.id);
for (int i = 0; i < _sg.d3d11.num_rtvs; i++) {
_sg_attachment_t* att = &_sg.d3d11.cur_pass->color_atts[i];
SOKOL_ASSERT(att->image && (att->image->slot.id == att->image_id.id));
if (att->image->sample_count > 1) {
/* FIXME: support MSAA resolve into 3D texture */
SOKOL_ASSERT(att->image->d3d11_tex2d && att->image->d3d11_texmsaa && !att->image->d3d11_tex3d);
SOKOL_ASSERT(DXGI_FORMAT_UNKNOWN != att->image->d3d11_format);
const _sg_image_t* img = att->image;
UINT dst_subres = _sg_d3d11_calcsubresource(att->mip_level, att->slice, img->num_mipmaps);
ID3D11DeviceContext_ResolveSubresource(_sg.d3d11.ctx,
(ID3D11Resource*) img->d3d11_tex2d, /* pDstResource */
dst_subres, /* DstSubresource */
(ID3D11Resource*) img->d3d11_texmsaa, /* pSrcResource */
0, /* SrcSubresource */
img->d3d11_format);
}
}
}
_sg.d3d11.cur_pass = 0;
_sg.d3d11.cur_pass_id.id = SG_INVALID_ID;
_sg.d3d11.cur_pipeline = 0;
_sg.d3d11.cur_pipeline_id.id = SG_INVALID_ID;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
_sg.d3d11.cur_rtvs[i] = 0;
}
_sg.d3d11.cur_dsv = 0;
_sg_d3d11_clear_state();
}
_SOKOL_PRIVATE void _sg_apply_viewport(int x, int y, int w, int h, bool origin_top_left) {
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(_sg.d3d11.in_pass);
D3D11_VIEWPORT vp;
vp.TopLeftX = (FLOAT) x;
vp.TopLeftY = (FLOAT) (origin_top_left ? y : (_sg.d3d11.cur_height - (y + h)));
vp.Width = (FLOAT) w;
vp.Height = (FLOAT) h;
vp.MinDepth = 0.0f;
vp.MaxDepth = 1.0f;
ID3D11DeviceContext_RSSetViewports(_sg.d3d11.ctx, 1, &vp);
}
_SOKOL_PRIVATE void _sg_apply_scissor_rect(int x, int y, int w, int h, bool origin_top_left) {
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(_sg.d3d11.in_pass);
D3D11_RECT rect;
rect.left = x;
rect.top = (origin_top_left ? y : (_sg.d3d11.cur_height - (y + h)));
rect.right = x + w;
rect.bottom = origin_top_left ? (y + h) : (_sg.d3d11.cur_height - y);
ID3D11DeviceContext_RSSetScissorRects(_sg.d3d11.ctx, 1, &rect);
}
_SOKOL_PRIVATE void _sg_apply_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
SOKOL_ASSERT(pip->shader);
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(_sg.d3d11.in_pass);
SOKOL_ASSERT(pip->d3d11_rs && pip->d3d11_bs && pip->d3d11_dss && pip->d3d11_il);
_sg.d3d11.cur_pipeline = pip;
_sg.d3d11.cur_pipeline_id.id = pip->slot.id;
_sg.d3d11.use_indexed_draw = (pip->d3d11_index_format != DXGI_FORMAT_UNKNOWN);
ID3D11DeviceContext_RSSetState(_sg.d3d11.ctx, pip->d3d11_rs);
ID3D11DeviceContext_OMSetDepthStencilState(_sg.d3d11.ctx, pip->d3d11_dss, pip->d3d11_stencil_ref);
ID3D11DeviceContext_OMSetBlendState(_sg.d3d11.ctx, pip->d3d11_bs, pip->blend_color, 0xFFFFFFFF);
ID3D11DeviceContext_IASetPrimitiveTopology(_sg.d3d11.ctx, pip->d3d11_topology);
ID3D11DeviceContext_IASetInputLayout(_sg.d3d11.ctx, pip->d3d11_il);
ID3D11DeviceContext_VSSetShader(_sg.d3d11.ctx, pip->shader->d3d11_vs, NULL, 0);
ID3D11DeviceContext_VSSetConstantBuffers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_UBS, pip->shader->stage[SG_SHADERSTAGE_VS].d3d11_cbs);
ID3D11DeviceContext_PSSetShader(_sg.d3d11.ctx, pip->shader->d3d11_fs, NULL, 0);
ID3D11DeviceContext_PSSetConstantBuffers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_UBS, pip->shader->stage[SG_SHADERSTAGE_FS].d3d11_cbs);
}
_SOKOL_PRIVATE void _sg_apply_bindings(
_sg_pipeline_t* pip,
_sg_buffer_t** vbs, const int* vb_offsets, int num_vbs,
_sg_buffer_t* ib, int ib_offset,
_sg_image_t** vs_imgs, int num_vs_imgs,
_sg_image_t** fs_imgs, int num_fs_imgs)
{
SOKOL_ASSERT(pip);
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(_sg.d3d11.in_pass);
/* gather all the D3D11 resources into arrays */
ID3D11Buffer* d3d11_ib = ib ? ib->d3d11_buf : 0;
ID3D11Buffer* d3d11_vbs[SG_MAX_SHADERSTAGE_BUFFERS];
UINT d3d11_vb_offsets[SG_MAX_SHADERSTAGE_BUFFERS];
ID3D11ShaderResourceView* d3d11_vs_srvs[SG_MAX_SHADERSTAGE_IMAGES];
ID3D11SamplerState* d3d11_vs_smps[SG_MAX_SHADERSTAGE_IMAGES];
ID3D11ShaderResourceView* d3d11_fs_srvs[SG_MAX_SHADERSTAGE_IMAGES];
ID3D11SamplerState* d3d11_fs_smps[SG_MAX_SHADERSTAGE_IMAGES];
int i;
for (i = 0; i < num_vbs; i++) {
SOKOL_ASSERT(vbs[i]->d3d11_buf);
d3d11_vbs[i] = vbs[i]->d3d11_buf;
d3d11_vb_offsets[i] = vb_offsets[i];
}
for (; i < SG_MAX_SHADERSTAGE_BUFFERS; i++) {
d3d11_vbs[i] = 0;
d3d11_vb_offsets[i] = 0;
}
for (i = 0; i < num_vs_imgs; i++) {
SOKOL_ASSERT(vs_imgs[i]->d3d11_srv);
SOKOL_ASSERT(vs_imgs[i]->d3d11_smp);
d3d11_vs_srvs[i] = vs_imgs[i]->d3d11_srv;
d3d11_vs_smps[i] = vs_imgs[i]->d3d11_smp;
}
for (; i < SG_MAX_SHADERSTAGE_IMAGES; i++) {
d3d11_vs_srvs[i] = 0;
d3d11_vs_smps[i] = 0;
}
for (i = 0; i < num_fs_imgs; i++) {
SOKOL_ASSERT(fs_imgs[i]->d3d11_srv);
SOKOL_ASSERT(fs_imgs[i]->d3d11_smp);
d3d11_fs_srvs[i] = fs_imgs[i]->d3d11_srv;
d3d11_fs_smps[i] = fs_imgs[i]->d3d11_smp;
}
for (; i < SG_MAX_SHADERSTAGE_IMAGES; i++) {
d3d11_fs_srvs[i] = 0;
d3d11_fs_smps[i] = 0;
}
ID3D11DeviceContext_IASetVertexBuffers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_BUFFERS, d3d11_vbs, pip->d3d11_vb_strides, d3d11_vb_offsets);
ID3D11DeviceContext_IASetIndexBuffer(_sg.d3d11.ctx, d3d11_ib, pip->d3d11_index_format, ib_offset);
ID3D11DeviceContext_VSSetShaderResources(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, d3d11_vs_srvs);
ID3D11DeviceContext_VSSetSamplers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, d3d11_vs_smps);
ID3D11DeviceContext_PSSetShaderResources(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, d3d11_fs_srvs);
ID3D11DeviceContext_PSSetSamplers(_sg.d3d11.ctx, 0, SG_MAX_SHADERSTAGE_IMAGES, d3d11_fs_smps);
}
_SOKOL_PRIVATE void _sg_apply_uniforms(sg_shader_stage stage_index, int ub_index, const void* data, int num_bytes) {
_SOKOL_UNUSED(num_bytes);
SOKOL_ASSERT(_sg.d3d11.ctx && _sg.d3d11.in_pass);
SOKOL_ASSERT(data && (num_bytes > 0));
SOKOL_ASSERT((stage_index >= 0) && ((int)stage_index < SG_NUM_SHADER_STAGES));
SOKOL_ASSERT((ub_index >= 0) && (ub_index < SG_MAX_SHADERSTAGE_UBS));
SOKOL_ASSERT(_sg.d3d11.cur_pipeline && _sg.d3d11.cur_pipeline->slot.id == _sg.d3d11.cur_pipeline_id.id);
SOKOL_ASSERT(_sg.d3d11.cur_pipeline->shader && _sg.d3d11.cur_pipeline->shader->slot.id == _sg.d3d11.cur_pipeline->shader_id.id);
SOKOL_ASSERT(ub_index < _sg.d3d11.cur_pipeline->shader->stage[stage_index].num_uniform_blocks);
SOKOL_ASSERT(num_bytes == _sg.d3d11.cur_pipeline->shader->stage[stage_index].uniform_blocks[ub_index].size);
ID3D11Buffer* cb = _sg.d3d11.cur_pipeline->shader->stage[stage_index].d3d11_cbs[ub_index];
SOKOL_ASSERT(cb);
ID3D11DeviceContext_UpdateSubresource(_sg.d3d11.ctx, (ID3D11Resource*)cb, 0, NULL, data, 0, 0);
}
_SOKOL_PRIVATE void _sg_draw(int base_element, int num_elements, int num_instances) {
SOKOL_ASSERT(_sg.d3d11.in_pass);
if (_sg.d3d11.use_indexed_draw) {
if (1 == num_instances) {
ID3D11DeviceContext_DrawIndexed(_sg.d3d11.ctx, num_elements, base_element, 0);
}
else {
ID3D11DeviceContext_DrawIndexedInstanced(_sg.d3d11.ctx, num_elements, num_instances, base_element, 0, 0);
}
}
else {
if (1 == num_instances) {
ID3D11DeviceContext_Draw(_sg.d3d11.ctx, num_elements, base_element);
}
else {
ID3D11DeviceContext_DrawInstanced(_sg.d3d11.ctx, num_elements, num_instances, base_element, 0);
}
}
}
_SOKOL_PRIVATE void _sg_commit(void) {
SOKOL_ASSERT(!_sg.d3d11.in_pass);
}
_SOKOL_PRIVATE void _sg_update_buffer(_sg_buffer_t* buf, const void* data_ptr, int data_size) {
SOKOL_ASSERT(buf && data_ptr && (data_size > 0));
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(buf->d3d11_buf);
D3D11_MAPPED_SUBRESOURCE d3d11_msr;
HRESULT hr = ID3D11DeviceContext_Map(_sg.d3d11.ctx, (ID3D11Resource*)buf->d3d11_buf, 0, D3D11_MAP_WRITE_DISCARD, 0, &d3d11_msr);
_SOKOL_UNUSED(hr);
SOKOL_ASSERT(SUCCEEDED(hr));
memcpy(d3d11_msr.pData, data_ptr, data_size);
ID3D11DeviceContext_Unmap(_sg.d3d11.ctx, (ID3D11Resource*)buf->d3d11_buf, 0);
}
_SOKOL_PRIVATE void _sg_append_buffer(_sg_buffer_t* buf, const void* data_ptr, int data_size, bool new_frame) {
SOKOL_ASSERT(buf && data_ptr && (data_size > 0));
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(buf->d3d11_buf);
D3D11_MAP map_type = new_frame ? D3D11_MAP_WRITE_DISCARD : D3D11_MAP_WRITE_NO_OVERWRITE;
D3D11_MAPPED_SUBRESOURCE d3d11_msr;
HRESULT hr = ID3D11DeviceContext_Map(_sg.d3d11.ctx, (ID3D11Resource*)buf->d3d11_buf, 0, map_type, 0, &d3d11_msr);
_SOKOL_UNUSED(hr);
SOKOL_ASSERT(SUCCEEDED(hr));
uint8_t* dst_ptr = (uint8_t*)d3d11_msr.pData + buf->append_pos;
memcpy(dst_ptr, data_ptr, data_size);
ID3D11DeviceContext_Unmap(_sg.d3d11.ctx, (ID3D11Resource*)buf->d3d11_buf, 0);
}
_SOKOL_PRIVATE void _sg_update_image(_sg_image_t* img, const sg_image_content* data) {
SOKOL_ASSERT(img && data);
SOKOL_ASSERT(_sg.d3d11.ctx);
SOKOL_ASSERT(img->d3d11_tex2d || img->d3d11_tex3d);
ID3D11Resource* d3d11_res = 0;
if (img->d3d11_tex3d) {
d3d11_res = (ID3D11Resource*) img->d3d11_tex3d;
}
else {
d3d11_res = (ID3D11Resource*) img->d3d11_tex2d;
}
SOKOL_ASSERT(d3d11_res);
const int num_faces = (img->type == SG_IMAGETYPE_CUBE) ? 6:1;
const int num_slices = (img->type == SG_IMAGETYPE_ARRAY) ? img->depth:1;
int subres_index = 0;
HRESULT hr;
D3D11_MAPPED_SUBRESOURCE d3d11_msr;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int slice_index = 0; slice_index < num_slices; slice_index++) {
for (int mip_index = 0; mip_index < img->num_mipmaps; mip_index++, subres_index++) {
SOKOL_ASSERT(subres_index < (SG_MAX_MIPMAPS * SG_MAX_TEXTUREARRAY_LAYERS));
const int mip_width = ((img->width>>mip_index)>0) ? img->width>>mip_index : 1;
const int mip_height = ((img->height>>mip_index)>0) ? img->height>>mip_index : 1;
const int src_pitch = _sg_row_pitch(img->pixel_format, mip_width);
const sg_subimage_content* subimg_content = &(data->subimage[face_index][mip_index]);
const int slice_size = subimg_content->size / num_slices;
const int slice_offset = slice_size * slice_index;
const uint8_t* slice_ptr = ((const uint8_t*)subimg_content->ptr) + slice_offset;
hr = ID3D11DeviceContext_Map(_sg.d3d11.ctx, d3d11_res, subres_index, D3D11_MAP_WRITE_DISCARD, 0, &d3d11_msr);
SOKOL_ASSERT(SUCCEEDED(hr));
/* FIXME: need to handle difference in depth-pitch for 3D textures as well! */
if (src_pitch == (int)d3d11_msr.RowPitch) {
memcpy(d3d11_msr.pData, slice_ptr, slice_size);
}
else {
SOKOL_ASSERT(src_pitch < (int)d3d11_msr.RowPitch);
const uint8_t* src_ptr = slice_ptr;
uint8_t* dst_ptr = (uint8_t*) d3d11_msr.pData;
for (int row_index = 0; row_index < mip_height; row_index++) {
memcpy(dst_ptr, src_ptr, src_pitch);
src_ptr += src_pitch;
dst_ptr += d3d11_msr.RowPitch;
}
}
ID3D11DeviceContext_Unmap(_sg.d3d11.ctx, d3d11_res, subres_index);
}
}
}
}
/*== METAL BACKEND IMPLEMENTATION ============================================*/
#elif defined(SOKOL_METAL)
/*-- enum translation functions ----------------------------------------------*/
_SOKOL_PRIVATE MTLLoadAction _sg_mtl_load_action(sg_action a) {
switch (a) {
case SG_ACTION_CLEAR: return MTLLoadActionClear;
case SG_ACTION_LOAD: return MTLLoadActionLoad;
case SG_ACTION_DONTCARE: return MTLLoadActionDontCare;
default: SOKOL_UNREACHABLE; return (MTLLoadAction)0;
}
}
_SOKOL_PRIVATE MTLResourceOptions _sg_mtl_buffer_resource_options(sg_usage usg) {
switch (usg) {
case SG_USAGE_IMMUTABLE:
return MTLResourceStorageModeShared;
case SG_USAGE_DYNAMIC:
case SG_USAGE_STREAM:
#if defined(_SG_TARGET_MACOS)
return MTLCPUCacheModeWriteCombined|MTLResourceStorageModeManaged;
#else
return MTLCPUCacheModeWriteCombined;
#endif
default:
SOKOL_UNREACHABLE;
return 0;
}
}
_SOKOL_PRIVATE MTLVertexStepFunction _sg_mtl_step_function(sg_vertex_step step) {
switch (step) {
case SG_VERTEXSTEP_PER_VERTEX: return MTLVertexStepFunctionPerVertex;
case SG_VERTEXSTEP_PER_INSTANCE: return MTLVertexStepFunctionPerInstance;
default: SOKOL_UNREACHABLE; return (MTLVertexStepFunction)0;
}
}
_SOKOL_PRIVATE MTLVertexFormat _sg_mtl_vertex_format(sg_vertex_format fmt) {
switch (fmt) {
case SG_VERTEXFORMAT_FLOAT: return MTLVertexFormatFloat;
case SG_VERTEXFORMAT_FLOAT2: return MTLVertexFormatFloat2;
case SG_VERTEXFORMAT_FLOAT3: return MTLVertexFormatFloat3;
case SG_VERTEXFORMAT_FLOAT4: return MTLVertexFormatFloat4;
case SG_VERTEXFORMAT_BYTE4: return MTLVertexFormatChar4;
case SG_VERTEXFORMAT_BYTE4N: return MTLVertexFormatChar4Normalized;
case SG_VERTEXFORMAT_UBYTE4: return MTLVertexFormatUChar4;
case SG_VERTEXFORMAT_UBYTE4N: return MTLVertexFormatUChar4Normalized;
case SG_VERTEXFORMAT_SHORT2: return MTLVertexFormatShort2;
case SG_VERTEXFORMAT_SHORT2N: return MTLVertexFormatShort2Normalized;
case SG_VERTEXFORMAT_USHORT2N: return MTLVertexFormatUShort2Normalized;
case SG_VERTEXFORMAT_SHORT4: return MTLVertexFormatShort4;
case SG_VERTEXFORMAT_SHORT4N: return MTLVertexFormatShort4Normalized;
case SG_VERTEXFORMAT_USHORT4N: return MTLVertexFormatUShort4Normalized;
case SG_VERTEXFORMAT_UINT10_N2: return MTLVertexFormatUInt1010102Normalized;
default: SOKOL_UNREACHABLE; return (MTLVertexFormat)0;
}
}
_SOKOL_PRIVATE MTLPrimitiveType _sg_mtl_primitive_type(sg_primitive_type t) {
switch (t) {
case SG_PRIMITIVETYPE_POINTS: return MTLPrimitiveTypePoint;
case SG_PRIMITIVETYPE_LINES: return MTLPrimitiveTypeLine;
case SG_PRIMITIVETYPE_LINE_STRIP: return MTLPrimitiveTypeLineStrip;
case SG_PRIMITIVETYPE_TRIANGLES: return MTLPrimitiveTypeTriangle;
case SG_PRIMITIVETYPE_TRIANGLE_STRIP: return MTLPrimitiveTypeTriangleStrip;
default: SOKOL_UNREACHABLE; return (MTLPrimitiveType)0;
}
}
_SOKOL_PRIVATE MTLPixelFormat _sg_mtl_pixel_format(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_R8: return MTLPixelFormatR8Unorm;
case SG_PIXELFORMAT_R8SN: return MTLPixelFormatR8Snorm;
case SG_PIXELFORMAT_R8UI: return MTLPixelFormatR8Uint;
case SG_PIXELFORMAT_R8SI: return MTLPixelFormatR8Sint;
case SG_PIXELFORMAT_R16: return MTLPixelFormatR16Unorm;
case SG_PIXELFORMAT_R16SN: return MTLPixelFormatR16Snorm;
case SG_PIXELFORMAT_R16UI: return MTLPixelFormatR16Uint;
case SG_PIXELFORMAT_R16SI: return MTLPixelFormatR16Sint;
case SG_PIXELFORMAT_R16F: return MTLPixelFormatR16Float;
case SG_PIXELFORMAT_RG8: return MTLPixelFormatRG8Unorm;
case SG_PIXELFORMAT_RG8SN: return MTLPixelFormatRG8Snorm;
case SG_PIXELFORMAT_RG8UI: return MTLPixelFormatRG8Uint;
case SG_PIXELFORMAT_RG8SI: return MTLPixelFormatRG8Sint;
case SG_PIXELFORMAT_R32UI: return MTLPixelFormatR32Uint;
case SG_PIXELFORMAT_R32SI: return MTLPixelFormatR32Sint;
case SG_PIXELFORMAT_R32F: return MTLPixelFormatR32Float;
case SG_PIXELFORMAT_RG16: return MTLPixelFormatRG16Unorm;
case SG_PIXELFORMAT_RG16SN: return MTLPixelFormatRG16Snorm;
case SG_PIXELFORMAT_RG16UI: return MTLPixelFormatRG16Uint;
case SG_PIXELFORMAT_RG16SI: return MTLPixelFormatRG16Sint;
case SG_PIXELFORMAT_RG16F: return MTLPixelFormatRG16Float;
case SG_PIXELFORMAT_RGBA8: return MTLPixelFormatRGBA8Unorm;
case SG_PIXELFORMAT_RGBA8SN: return MTLPixelFormatRGBA8Snorm;
case SG_PIXELFORMAT_RGBA8UI: return MTLPixelFormatRGBA8Uint;
case SG_PIXELFORMAT_RGBA8SI: return MTLPixelFormatRGBA8Sint;
case SG_PIXELFORMAT_BGRA8: return MTLPixelFormatBGRA8Unorm;
case SG_PIXELFORMAT_RGB10A2: return MTLPixelFormatRGB10A2Unorm;
case SG_PIXELFORMAT_RG11B10F: return MTLPixelFormatRG11B10Float;
case SG_PIXELFORMAT_RG32UI: return MTLPixelFormatRG32Uint;
case SG_PIXELFORMAT_RG32SI: return MTLPixelFormatRG32Sint;
case SG_PIXELFORMAT_RG32F: return MTLPixelFormatRG32Float;
case SG_PIXELFORMAT_RGBA16: return MTLPixelFormatRGBA16Unorm;
case SG_PIXELFORMAT_RGBA16SN: return MTLPixelFormatRGBA16Snorm;
case SG_PIXELFORMAT_RGBA16UI: return MTLPixelFormatRGBA16Uint;
case SG_PIXELFORMAT_RGBA16SI: return MTLPixelFormatRGBA16Sint;
case SG_PIXELFORMAT_RGBA16F: return MTLPixelFormatRGBA16Float;
case SG_PIXELFORMAT_RGBA32UI: return MTLPixelFormatRGBA32Uint;
case SG_PIXELFORMAT_RGBA32SI: return MTLPixelFormatRGBA32Sint;
case SG_PIXELFORMAT_RGBA32F: return MTLPixelFormatRGBA32Float;
case SG_PIXELFORMAT_DEPTH: return MTLPixelFormatDepth32Float;
case SG_PIXELFORMAT_DEPTH_STENCIL: return MTLPixelFormatDepth32Float_Stencil8;
#if defined(_SG_TARGET_MACOS)
case SG_PIXELFORMAT_BC1_RGBA: return MTLPixelFormatBC1_RGBA;
case SG_PIXELFORMAT_BC2_RGBA: return MTLPixelFormatBC2_RGBA;
case SG_PIXELFORMAT_BC3_RGBA: return MTLPixelFormatBC3_RGBA;
case SG_PIXELFORMAT_BC4_R: return MTLPixelFormatBC4_RUnorm;
case SG_PIXELFORMAT_BC4_RSN: return MTLPixelFormatBC4_RSnorm;
case SG_PIXELFORMAT_BC5_RG: return MTLPixelFormatBC5_RGUnorm;
case SG_PIXELFORMAT_BC5_RGSN: return MTLPixelFormatBC5_RGSnorm;
case SG_PIXELFORMAT_BC6H_RGBF: return MTLPixelFormatBC6H_RGBFloat;
case SG_PIXELFORMAT_BC6H_RGBUF: return MTLPixelFormatBC6H_RGBUfloat;
case SG_PIXELFORMAT_BC7_RGBA: return MTLPixelFormatBC7_RGBAUnorm;
#else
case SG_PIXELFORMAT_PVRTC_RGB_2BPP: return MTLPixelFormatPVRTC_RGB_2BPP;
case SG_PIXELFORMAT_PVRTC_RGB_4BPP: return MTLPixelFormatPVRTC_RGB_4BPP;
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP: return MTLPixelFormatPVRTC_RGBA_2BPP;
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP: return MTLPixelFormatPVRTC_RGBA_4BPP;
case SG_PIXELFORMAT_ETC2_RGB8: return MTLPixelFormatETC2_RGB8;
case SG_PIXELFORMAT_ETC2_RGB8A1: return MTLPixelFormatETC2_RGB8A1;
case SG_PIXELFORMAT_ETC2_RGBA8: return MTLPixelFormatEAC_RGBA8;
case SG_PIXELFORMAT_ETC2_RG11: return MTLPixelFormatEAC_RG11Unorm;
case SG_PIXELFORMAT_ETC2_RG11SN: return MTLPixelFormatEAC_RG11Snorm;
#endif
default: return MTLPixelFormatInvalid;
}
}
_SOKOL_PRIVATE MTLColorWriteMask _sg_mtl_color_write_mask(sg_color_mask m) {
MTLColorWriteMask mtl_mask = MTLColorWriteMaskNone;
if (m & SG_COLORMASK_R) {
mtl_mask |= MTLColorWriteMaskRed;
}
if (m & SG_COLORMASK_G) {
mtl_mask |= MTLColorWriteMaskGreen;
}
if (m & SG_COLORMASK_B) {
mtl_mask |= MTLColorWriteMaskBlue;
}
if (m & SG_COLORMASK_A) {
mtl_mask |= MTLColorWriteMaskAlpha;
}
return mtl_mask;
}
_SOKOL_PRIVATE MTLBlendOperation _sg_mtl_blend_op(sg_blend_op op) {
switch (op) {
case SG_BLENDOP_ADD: return MTLBlendOperationAdd;
case SG_BLENDOP_SUBTRACT: return MTLBlendOperationSubtract;
case SG_BLENDOP_REVERSE_SUBTRACT: return MTLBlendOperationReverseSubtract;
default: SOKOL_UNREACHABLE; return (MTLBlendOperation)0;
}
}
_SOKOL_PRIVATE MTLBlendFactor _sg_mtl_blend_factor(sg_blend_factor f) {
switch (f) {
case SG_BLENDFACTOR_ZERO: return MTLBlendFactorZero;
case SG_BLENDFACTOR_ONE: return MTLBlendFactorOne;
case SG_BLENDFACTOR_SRC_COLOR: return MTLBlendFactorSourceColor;
case SG_BLENDFACTOR_ONE_MINUS_SRC_COLOR: return MTLBlendFactorOneMinusSourceColor;
case SG_BLENDFACTOR_SRC_ALPHA: return MTLBlendFactorSourceAlpha;
case SG_BLENDFACTOR_ONE_MINUS_SRC_ALPHA: return MTLBlendFactorOneMinusSourceAlpha;
case SG_BLENDFACTOR_DST_COLOR: return MTLBlendFactorDestinationColor;
case SG_BLENDFACTOR_ONE_MINUS_DST_COLOR: return MTLBlendFactorOneMinusDestinationColor;
case SG_BLENDFACTOR_DST_ALPHA: return MTLBlendFactorDestinationAlpha;
case SG_BLENDFACTOR_ONE_MINUS_DST_ALPHA: return MTLBlendFactorOneMinusDestinationAlpha;
case SG_BLENDFACTOR_SRC_ALPHA_SATURATED: return MTLBlendFactorSourceAlphaSaturated;
case SG_BLENDFACTOR_BLEND_COLOR: return MTLBlendFactorBlendColor;
case SG_BLENDFACTOR_ONE_MINUS_BLEND_COLOR: return MTLBlendFactorOneMinusBlendColor;
case SG_BLENDFACTOR_BLEND_ALPHA: return MTLBlendFactorBlendAlpha;
case SG_BLENDFACTOR_ONE_MINUS_BLEND_ALPHA: return MTLBlendFactorOneMinusBlendAlpha;
default: SOKOL_UNREACHABLE; return (MTLBlendFactor)0;
}
}
_SOKOL_PRIVATE MTLCompareFunction _sg_mtl_compare_func(sg_compare_func f) {
switch (f) {
case SG_COMPAREFUNC_NEVER: return MTLCompareFunctionNever;
case SG_COMPAREFUNC_LESS: return MTLCompareFunctionLess;
case SG_COMPAREFUNC_EQUAL: return MTLCompareFunctionEqual;
case SG_COMPAREFUNC_LESS_EQUAL: return MTLCompareFunctionLessEqual;
case SG_COMPAREFUNC_GREATER: return MTLCompareFunctionGreater;
case SG_COMPAREFUNC_NOT_EQUAL: return MTLCompareFunctionNotEqual;
case SG_COMPAREFUNC_GREATER_EQUAL: return MTLCompareFunctionGreaterEqual;
case SG_COMPAREFUNC_ALWAYS: return MTLCompareFunctionAlways;
default: SOKOL_UNREACHABLE; return (MTLCompareFunction)0;
}
}
_SOKOL_PRIVATE MTLStencilOperation _sg_mtl_stencil_op(sg_stencil_op op) {
switch (op) {
case SG_STENCILOP_KEEP: return MTLStencilOperationKeep;
case SG_STENCILOP_ZERO: return MTLStencilOperationZero;
case SG_STENCILOP_REPLACE: return MTLStencilOperationReplace;
case SG_STENCILOP_INCR_CLAMP: return MTLStencilOperationIncrementClamp;
case SG_STENCILOP_DECR_CLAMP: return MTLStencilOperationDecrementClamp;
case SG_STENCILOP_INVERT: return MTLStencilOperationInvert;
case SG_STENCILOP_INCR_WRAP: return MTLStencilOperationIncrementWrap;
case SG_STENCILOP_DECR_WRAP: return MTLStencilOperationDecrementWrap;
default: SOKOL_UNREACHABLE; return (MTLStencilOperation)0;
}
}
_SOKOL_PRIVATE MTLCullMode _sg_mtl_cull_mode(sg_cull_mode m) {
switch (m) {
case SG_CULLMODE_NONE: return MTLCullModeNone;
case SG_CULLMODE_FRONT: return MTLCullModeFront;
case SG_CULLMODE_BACK: return MTLCullModeBack;
default: SOKOL_UNREACHABLE; return (MTLCullMode)0;
}
}
_SOKOL_PRIVATE MTLWinding _sg_mtl_winding(sg_face_winding w) {
switch (w) {
case SG_FACEWINDING_CW: return MTLWindingClockwise;
case SG_FACEWINDING_CCW: return MTLWindingCounterClockwise;
default: SOKOL_UNREACHABLE; return (MTLWinding)0;
}
}
_SOKOL_PRIVATE MTLIndexType _sg_mtl_index_type(sg_index_type t) {
switch (t) {
case SG_INDEXTYPE_UINT16: return MTLIndexTypeUInt16;
case SG_INDEXTYPE_UINT32: return MTLIndexTypeUInt32;
default: SOKOL_UNREACHABLE; return (MTLIndexType)0;
}
}
_SOKOL_PRIVATE NSUInteger _sg_mtl_index_size(sg_index_type t) {
switch (t) {
case SG_INDEXTYPE_NONE: return 0;
case SG_INDEXTYPE_UINT16: return 2;
case SG_INDEXTYPE_UINT32: return 4;
default: SOKOL_UNREACHABLE; return 0;
}
}
_SOKOL_PRIVATE MTLTextureType _sg_mtl_texture_type(sg_image_type t) {
switch (t) {
case SG_IMAGETYPE_2D: return MTLTextureType2D;
case SG_IMAGETYPE_CUBE: return MTLTextureTypeCube;
case SG_IMAGETYPE_3D: return MTLTextureType3D;
case SG_IMAGETYPE_ARRAY: return MTLTextureType2DArray;
default: SOKOL_UNREACHABLE; return (MTLTextureType)0;
}
}
_SOKOL_PRIVATE bool _sg_mtl_is_pvrtc(sg_pixel_format fmt) {
switch (fmt) {
case SG_PIXELFORMAT_PVRTC_RGB_2BPP:
case SG_PIXELFORMAT_PVRTC_RGB_4BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_2BPP:
case SG_PIXELFORMAT_PVRTC_RGBA_4BPP:
return true;
default:
return false;
}
}
_SOKOL_PRIVATE MTLSamplerAddressMode _sg_mtl_address_mode(sg_wrap w) {
switch (w) {
case SG_WRAP_REPEAT: return MTLSamplerAddressModeRepeat;
case SG_WRAP_CLAMP_TO_EDGE: return MTLSamplerAddressModeClampToEdge;
#if defined(_SG_TARGET_MACOS)
case SG_WRAP_CLAMP_TO_BORDER: return MTLSamplerAddressModeClampToBorderColor;
#else
/* clamp-to-border not supported on iOS, fall back to clamp-to-edge */
case SG_WRAP_CLAMP_TO_BORDER: return MTLSamplerAddressModeClampToEdge;
#endif
case SG_WRAP_MIRRORED_REPEAT: return MTLSamplerAddressModeMirrorRepeat;
default: SOKOL_UNREACHABLE; return (MTLSamplerAddressMode)0;
}
}
#if defined(_SG_TARGET_MACOS)
_SOKOL_PRIVATE MTLSamplerBorderColor _sg_mtl_border_color(sg_border_color c) {
switch (c) {
case SG_BORDERCOLOR_TRANSPARENT_BLACK: return MTLSamplerBorderColorTransparentBlack;
case SG_BORDERCOLOR_OPAQUE_BLACK: return MTLSamplerBorderColorOpaqueBlack;
case SG_BORDERCOLOR_OPAQUE_WHITE: return MTLSamplerBorderColorOpaqueWhite;
default: SOKOL_UNREACHABLE; return (MTLSamplerBorderColor)0;
}
}
#endif
_SOKOL_PRIVATE MTLSamplerMinMagFilter _sg_mtl_minmag_filter(sg_filter f) {
switch (f) {
case SG_FILTER_NEAREST:
case SG_FILTER_NEAREST_MIPMAP_NEAREST:
case SG_FILTER_NEAREST_MIPMAP_LINEAR:
return MTLSamplerMinMagFilterNearest;
case SG_FILTER_LINEAR:
case SG_FILTER_LINEAR_MIPMAP_NEAREST:
case SG_FILTER_LINEAR_MIPMAP_LINEAR:
return MTLSamplerMinMagFilterLinear;
default:
SOKOL_UNREACHABLE; return (MTLSamplerMinMagFilter)0;
}
}
_SOKOL_PRIVATE MTLSamplerMipFilter _sg_mtl_mip_filter(sg_filter f) {
switch (f) {
case SG_FILTER_NEAREST:
case SG_FILTER_LINEAR:
return MTLSamplerMipFilterNotMipmapped;
case SG_FILTER_NEAREST_MIPMAP_NEAREST:
case SG_FILTER_LINEAR_MIPMAP_NEAREST:
return MTLSamplerMipFilterNearest;
case SG_FILTER_NEAREST_MIPMAP_LINEAR:
case SG_FILTER_LINEAR_MIPMAP_LINEAR:
return MTLSamplerMipFilterLinear;
default:
SOKOL_UNREACHABLE; return (MTLSamplerMipFilter)0;
}
}
/*-- a pool for all Metal resource objects, with deferred release queue -------*/
_SOKOL_PRIVATE void _sg_mtl_init_pool(const sg_desc* desc) {
_sg.mtl.idpool.num_slots = 2 *
(
2 * desc->buffer_pool_size +
5 * desc->image_pool_size +
4 * desc->shader_pool_size +
2 * desc->pipeline_pool_size +
desc->pass_pool_size
);
_sg_mtl_idpool = [NSMutableArray arrayWithCapacity:_sg.mtl.idpool.num_slots];
NSNull* null = [NSNull null];
for (uint32_t i = 0; i < _sg.mtl.idpool.num_slots; i++) {
[_sg_mtl_idpool addObject:null];
}
SOKOL_ASSERT([_sg_mtl_idpool count] == _sg.mtl.idpool.num_slots);
/* a queue of currently free slot indices */
_sg.mtl.idpool.free_queue_top = 0;
_sg.mtl.idpool.free_queue = (uint32_t*)SOKOL_MALLOC(_sg.mtl.idpool.num_slots * sizeof(uint32_t));
/* pool slot 0 is reserved! */
for (int i = _sg.mtl.idpool.num_slots-1; i >= 1; i--) {
_sg.mtl.idpool.free_queue[_sg.mtl.idpool.free_queue_top++] = (uint32_t)i;
}
/* a circular queue which holds release items (frame index
when a resource is to be released, and the resource's
pool index
*/
_sg.mtl.idpool.release_queue_front = 0;
_sg.mtl.idpool.release_queue_back = 0;
_sg.mtl.idpool.release_queue = (_sg_mtl_release_item_t*)SOKOL_MALLOC(_sg.mtl.idpool.num_slots * sizeof(_sg_mtl_release_item_t));
for (uint32_t i = 0; i < _sg.mtl.idpool.num_slots; i++) {
_sg.mtl.idpool.release_queue[i].frame_index = 0;
_sg.mtl.idpool.release_queue[i].slot_index = _SG_MTL_INVALID_SLOT_INDEX;
}
}
_SOKOL_PRIVATE void _sg_mtl_destroy_pool(void) {
SOKOL_FREE(_sg.mtl.idpool.release_queue); _sg.mtl.idpool.release_queue = 0;
SOKOL_FREE(_sg.mtl.idpool.free_queue); _sg.mtl.idpool.free_queue = 0;
_sg_mtl_idpool = nil;
}
/* get a new free resource pool slot */
_SOKOL_PRIVATE uint32_t _sg_mtl_alloc_pool_slot(void) {
SOKOL_ASSERT(_sg.mtl.idpool.free_queue_top > 0);
const uint32_t slot_index = _sg.mtl.idpool.free_queue[--_sg.mtl.idpool.free_queue_top];
SOKOL_ASSERT((slot_index > 0) && (slot_index < _sg.mtl.idpool.num_slots));
return slot_index;
}
/* put a free resource pool slot back into the free-queue */
_SOKOL_PRIVATE void _sg_mtl_free_pool_slot(uint32_t slot_index) {
SOKOL_ASSERT(_sg.mtl.idpool.free_queue_top < _sg.mtl.idpool.num_slots);
SOKOL_ASSERT((slot_index > 0) && (slot_index < _sg.mtl.idpool.num_slots));
_sg.mtl.idpool.free_queue[_sg.mtl.idpool.free_queue_top++] = slot_index;
}
/* add an MTLResource to the pool, return pool index or 0 if input was 'nil' */
_SOKOL_PRIVATE uint32_t _sg_mtl_add_resource(id res) {
if (nil == res) {
return _SG_MTL_INVALID_SLOT_INDEX;
}
const uint32_t slot_index = _sg_mtl_alloc_pool_slot();
SOKOL_ASSERT([NSNull null] == _sg_mtl_idpool[slot_index]);
_sg_mtl_idpool[slot_index] = res;
return slot_index;
}
/* mark an MTLResource for release, this will put the resource into the
deferred-release queue, and the resource will then be released N frames later,
the special pool index 0 will be ignored (this means that a nil
value was provided to _sg_mtl_add_resource()
*/
_SOKOL_PRIVATE void _sg_mtl_release_resource(uint32_t frame_index, uint32_t slot_index) {
if (slot_index == _SG_MTL_INVALID_SLOT_INDEX) {
return;
}
SOKOL_ASSERT((slot_index > 0) && (slot_index < _sg.mtl.idpool.num_slots));
SOKOL_ASSERT([NSNull null] != _sg_mtl_idpool[slot_index]);
int release_index = _sg.mtl.idpool.release_queue_front++;
if (_sg.mtl.idpool.release_queue_front >= _sg.mtl.idpool.num_slots) {
/* wrap-around */
_sg.mtl.idpool.release_queue_front = 0;
}
/* release queue full? */
SOKOL_ASSERT(_sg.mtl.idpool.release_queue_front != _sg.mtl.idpool.release_queue_back);
SOKOL_ASSERT(0 == _sg.mtl.idpool.release_queue[release_index].frame_index);
const uint32_t safe_to_release_frame_index = frame_index + SG_NUM_INFLIGHT_FRAMES + 1;
_sg.mtl.idpool.release_queue[release_index].frame_index = safe_to_release_frame_index;
_sg.mtl.idpool.release_queue[release_index].slot_index = slot_index;
}
/* run garbage-collection pass on all resources in the release-queue */
_SOKOL_PRIVATE void _sg_mtl_garbage_collect(uint32_t frame_index) {
while (_sg.mtl.idpool.release_queue_back != _sg.mtl.idpool.release_queue_front) {
if (frame_index < _sg.mtl.idpool.release_queue[_sg.mtl.idpool.release_queue_back].frame_index) {
/* don't need to check further, release-items past this are too young */
break;
}
/* safe to release this resource */
const uint32_t slot_index = _sg.mtl.idpool.release_queue[_sg.mtl.idpool.release_queue_back].slot_index;
SOKOL_ASSERT((slot_index > 0) && (slot_index < _sg.mtl.idpool.num_slots));
SOKOL_ASSERT(_sg_mtl_idpool[slot_index] != [NSNull null]);
_sg_mtl_idpool[slot_index] = [NSNull null];
/* put the now free pool index back on the free queue */
_sg_mtl_free_pool_slot(slot_index);
/* reset the release queue slot and advance the back index */
_sg.mtl.idpool.release_queue[_sg.mtl.idpool.release_queue_back].frame_index = 0;
_sg.mtl.idpool.release_queue[_sg.mtl.idpool.release_queue_back].slot_index = _SG_MTL_INVALID_SLOT_INDEX;
_sg.mtl.idpool.release_queue_back++;
if (_sg.mtl.idpool.release_queue_back >= _sg.mtl.idpool.num_slots) {
/* wrap-around */
_sg.mtl.idpool.release_queue_back = 0;
}
}
}
/*-- a very simple sampler cache -----------------------------------------------
since there's only a small number of different samplers, sampler objects
will never be deleted (except on shutdown), and searching an identical
sampler is a simple linear search
*/
/* initialize the sampler cache */
_SOKOL_PRIVATE void _sg_mtl_init_sampler_cache(const sg_desc* desc) {
SOKOL_ASSERT(desc->mtl_sampler_cache_size > 0);
_sg.mtl.sampler_cache.capacity = desc->mtl_sampler_cache_size;
_sg.mtl.sampler_cache.num_items = 0;
const int size = _sg.mtl.sampler_cache.capacity * sizeof(_sg_mtl_sampler_cache_item_t);
_sg.mtl.sampler_cache.items = (_sg_mtl_sampler_cache_item_t*)SOKOL_MALLOC(size);
memset(_sg.mtl.sampler_cache.items, 0, size);
}
/* destroy the sampler cache, and release all sampler objects */
_SOKOL_PRIVATE void _sg_mtl_destroy_sampler_cache(uint32_t frame_index) {
SOKOL_ASSERT(_sg.mtl.sampler_cache.items);
SOKOL_ASSERT(_sg.mtl.sampler_cache.num_items <= _sg.mtl.sampler_cache.capacity);
for (int i = 0; i < _sg.mtl.sampler_cache.num_items; i++) {
_sg_mtl_release_resource(frame_index, _sg.mtl.sampler_cache.items[i].mtl_sampler_state);
}
SOKOL_FREE(_sg.mtl.sampler_cache.items); _sg.mtl.sampler_cache.items = 0;
_sg.mtl.sampler_cache.num_items = 0;
_sg.mtl.sampler_cache.capacity = 0;
}
/*
create and add an MTLSamplerStateObject and return its resource pool index,
reuse identical sampler state if one exists
*/
_SOKOL_PRIVATE uint32_t _sg_mtl_create_sampler(id<MTLDevice> mtl_device, const sg_image_desc* img_desc) {
SOKOL_ASSERT(img_desc);
SOKOL_ASSERT(_sg.mtl.sampler_cache.items);
/* sampler state cache is full */
const sg_filter min_filter = img_desc->min_filter;
const sg_filter mag_filter = img_desc->mag_filter;
const sg_wrap wrap_u = img_desc->wrap_u;
const sg_wrap wrap_v = img_desc->wrap_v;
const sg_wrap wrap_w = img_desc->wrap_w;
const sg_border_color border_color = img_desc->border_color;
const uint32_t max_anisotropy = img_desc->max_anisotropy;
/* convert floats to valid int for proper comparison */
const int min_lod = (int)(img_desc->min_lod * 1000.0f);
const int max_lod = (int)(_sg_clamp(img_desc->max_lod, 0.0f, 1000.0f) * 1000.0f);
/* first try to find identical sampler, number of samplers will be small, so linear search is ok */
for (int i = 0; i < _sg.mtl.sampler_cache.num_items; i++) {
_sg_mtl_sampler_cache_item_t* item = &_sg.mtl.sampler_cache.items[i];
if ((min_filter == item->min_filter) &&
(mag_filter == item->mag_filter) &&
(wrap_u == item->wrap_u) &&
(wrap_v == item->wrap_v) &&
(wrap_w == item->wrap_w) &&
(max_anisotropy == item->max_anisotropy) &&
(border_color == item->border_color) &&
(min_lod == item->min_lod) &&
(max_lod == item->max_lod))
{
return item->mtl_sampler_state;
}
}
/* fallthrough: need to create a new MTLSamplerState object */
SOKOL_ASSERT(_sg.mtl.sampler_cache.num_items < _sg.mtl.sampler_cache.capacity);
_sg_mtl_sampler_cache_item_t* new_item = &_sg.mtl.sampler_cache.items[_sg.mtl.sampler_cache.num_items++];
new_item->min_filter = min_filter;
new_item->mag_filter = mag_filter;
new_item->wrap_u = wrap_u;
new_item->wrap_v = wrap_v;
new_item->wrap_w = wrap_w;
new_item->min_lod = min_lod;
new_item->max_lod = max_lod;
new_item->max_anisotropy = max_anisotropy;
new_item->border_color = border_color;
MTLSamplerDescriptor* mtl_desc = [[MTLSamplerDescriptor alloc] init];
mtl_desc.sAddressMode = _sg_mtl_address_mode(wrap_u);
mtl_desc.tAddressMode = _sg_mtl_address_mode(wrap_v);
if (SG_IMAGETYPE_3D == img_desc->type) {
mtl_desc.rAddressMode = _sg_mtl_address_mode(wrap_w);
}
#if defined(_SG_TARGET_MACOS)
mtl_desc.borderColor = _sg_mtl_border_color(border_color);
#endif
mtl_desc.minFilter = _sg_mtl_minmag_filter(min_filter);
mtl_desc.magFilter = _sg_mtl_minmag_filter(mag_filter);
mtl_desc.mipFilter = _sg_mtl_mip_filter(min_filter);
mtl_desc.lodMinClamp = img_desc->min_lod;
mtl_desc.lodMaxClamp = img_desc->max_lod;
mtl_desc.maxAnisotropy = max_anisotropy;
mtl_desc.normalizedCoordinates = YES;
id<MTLSamplerState> mtl_sampler = [mtl_device newSamplerStateWithDescriptor:mtl_desc];
new_item->mtl_sampler_state = _sg_mtl_add_resource(mtl_sampler);
return new_item->mtl_sampler_state;
}
_SOKOL_PRIVATE void _sg_mtl_clear_state_cache(void) {
memset(&_sg.mtl.state_cache, 0, sizeof(_sg.mtl.state_cache));
}
/* https://developer.apple.com/metal/Metal-Feature-Set-Tables.pdf */
_SOKOL_PRIVATE void _sg_mtl_init_caps(void) {
#if defined(_SG_TARGET_MACOS)
_sg.backend = SG_BACKEND_METAL_MACOS;
#elif defined(_SG_TARGET_IOS)
#if defined(_SG_TARGET_IOS_SIMULATOR)
_sg.backend = SG_BACKEND_METAL_SIMULATOR;
#else
_sg.backend = SG_BACKEND_METAL_IOS;
#endif
#endif
_sg.features.instancing = true;
_sg.features.origin_top_left = true;
_sg.features.multiple_render_targets = true;
_sg.features.msaa_render_targets = true;
_sg.features.imagetype_3d = true;
_sg.features.imagetype_array = true;
#if defined(_SG_TARGET_MACOS)
_sg.features.image_clamp_to_border = true;
#else
_sg.features.image_clamp_to_border = false;
#endif
#if defined(_SG_TARGET_MACOS)
_sg.limits.max_image_size_2d = 16 * 1024;
_sg.limits.max_image_size_cube = 16 * 1024;
_sg.limits.max_image_size_3d = 2 * 1024;
_sg.limits.max_image_size_array = 16 * 1024;
_sg.limits.max_image_array_layers = 2 * 1024;
#else
/* newer iOS devices support 16k textures */
_sg.limits.max_image_size_2d = 8 * 1024;
_sg.limits.max_image_size_cube = 8 * 1024;
_sg.limits.max_image_size_3d = 2 * 1024;
_sg.limits.max_image_size_array = 8 * 1024;
_sg.limits.max_image_array_layers = 2 * 1024;
#endif
_sg.limits.max_vertex_attrs = SG_MAX_VERTEX_ATTRIBUTES;
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R8]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R8SN]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R8UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R8SI]);
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R16]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R16SN]);
#else
_sg_pixelformat_sfbr(&_sg.formats[SG_PIXELFORMAT_R16]);
_sg_pixelformat_sfbr(&_sg.formats[SG_PIXELFORMAT_R16SN]);
#endif
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R16UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_R16SI]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R16F]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG8]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG8SN]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG8UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG8SI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_R32UI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_R32SI]);
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_R32F]);
#else
_sg_pixelformat_sbr(&_sg.formats[SG_PIXELFORMAT_R32F]);
#endif
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG16]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG16SN]);
#else
_sg_pixelformat_sfbr(&_sg.formats[SG_PIXELFORMAT_RG16]);
_sg_pixelformat_sfbr(&_sg.formats[SG_PIXELFORMAT_RG16SN]);
#endif
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG16UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG16SI]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG16F]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA8]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA8SN]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA8UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA8SI]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_BGRA8]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGB10A2]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG11B10F]);
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG32UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RG32SI]);
#else
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_RG32UI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_RG32SI]);
#endif
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RG32F]);
#else
_sg_pixelformat_sbr(&_sg.formats[SG_PIXELFORMAT_RG32F]);
#endif
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16SN]);
#else
_sg_pixelformat_sfbr(&_sg.formats[SG_PIXELFORMAT_RGBA16]);
_sg_pixelformat_sfbr(&_sg.formats[SG_PIXELFORMAT_RGBA16SN]);
#endif
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA16UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA16SI]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA16F]);
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA32UI]);
_sg_pixelformat_srm(&_sg.formats[SG_PIXELFORMAT_RGBA32SI]);
_sg_pixelformat_all(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
#else
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_RGBA32UI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_RGBA32SI]);
_sg_pixelformat_sr(&_sg.formats[SG_PIXELFORMAT_RGBA32F]);
#endif
_sg_pixelformat_srmd(&_sg.formats[SG_PIXELFORMAT_DEPTH]);
_sg_pixelformat_srmd(&_sg.formats[SG_PIXELFORMAT_DEPTH_STENCIL]);
#if defined(_SG_TARGET_MACOS)
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC1_RGBA]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC2_RGBA]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC3_RGBA]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC4_R]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC4_RSN]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC5_RG]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC5_RGSN]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC6H_RGBF]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC6H_RGBUF]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_BC7_RGBA]);
#else
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGB_2BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGB_4BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGBA_2BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_PVRTC_RGBA_4BPP]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RGB8]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RGB8A1]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RGBA8]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RG11]);
_sg_pixelformat_sf(&_sg.formats[SG_PIXELFORMAT_ETC2_RG11SN]);
#endif
}
/*-- main Metal backend state and functions ----------------------------------*/
_SOKOL_PRIVATE void _sg_setup_backend(const sg_desc* desc) {
puts("Sokol backend: Metal");
/* assume already zero-initialized */
SOKOL_ASSERT(desc);
SOKOL_ASSERT(desc->mtl_device);
SOKOL_ASSERT(desc->mtl_renderpass_descriptor_cb);
SOKOL_ASSERT(desc->mtl_drawable_cb);
SOKOL_ASSERT(desc->mtl_global_uniform_buffer_size > 0);
_sg_mtl_init_pool(desc);
_sg_mtl_init_sampler_cache(desc);
_sg_mtl_clear_state_cache();
_sg.mtl.valid = true;
_sg.mtl.renderpass_descriptor_cb = desc->mtl_renderpass_descriptor_cb;
_sg.mtl.drawable_cb = desc->mtl_drawable_cb;
_sg.mtl.frame_index = 1;
_sg.mtl.ub_size = desc->mtl_global_uniform_buffer_size;
_sg_mtl_sem = dispatch_semaphore_create(SG_NUM_INFLIGHT_FRAMES);
_sg_mtl_device = (__bridge id<MTLDevice>) desc->mtl_device;
_sg_mtl_cmd_queue = [_sg_mtl_device newCommandQueue];
MTLResourceOptions res_opts = MTLResourceCPUCacheModeWriteCombined;
#if defined(_SG_TARGET_MACOS)
res_opts |= MTLResourceStorageModeManaged;
#endif
for (int i = 0; i < SG_NUM_INFLIGHT_FRAMES; i++) {
_sg_mtl_uniform_buffers[i] = [_sg_mtl_device
newBufferWithLength:_sg.mtl.ub_size
options:res_opts
];
}
_sg_mtl_init_caps();
}
_SOKOL_PRIVATE void _sg_discard_backend(void) {
SOKOL_ASSERT(_sg.mtl.valid);
/* wait for the last frame to finish */
for (int i = 0; i < SG_NUM_INFLIGHT_FRAMES; i++) {
dispatch_semaphore_wait(_sg_mtl_sem, DISPATCH_TIME_FOREVER);
}
_sg_mtl_destroy_sampler_cache(_sg.mtl.frame_index);
_sg_mtl_garbage_collect(_sg.mtl.frame_index + SG_NUM_INFLIGHT_FRAMES + 2);
_sg_mtl_destroy_pool();
_sg.mtl.valid = false;
_sg_mtl_cmd_encoder = nil;
_sg_mtl_cmd_buffer = nil;
_sg_mtl_cmd_queue = nil;
for (int i = 0; i < SG_NUM_INFLIGHT_FRAMES; i++) {
_sg_mtl_uniform_buffers[i] = nil;
}
_sg_mtl_device = nil;
}
_SOKOL_PRIVATE void _sg_reset_state_cache(void) {
_sg_mtl_clear_state_cache();
}
_SOKOL_PRIVATE sg_resource_state _sg_create_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
_SOKOL_UNUSED(ctx);
/* empty */
}
_SOKOL_PRIVATE void _sg_activate_context(_sg_context_t* ctx) {
_sg_reset_state_cache();
}
_SOKOL_PRIVATE sg_resource_state _sg_create_buffer(_sg_buffer_t* buf, const sg_buffer_desc* desc) {
SOKOL_ASSERT(buf && desc);
buf->size = desc->size;
buf->append_pos = 0;
buf->append_overflow = false;
buf->type = desc->type;
buf->usage = desc->usage;
buf->update_frame_index = 0;
buf->append_frame_index = 0;
buf->num_slots = (buf->usage == SG_USAGE_IMMUTABLE) ? 1 : SG_NUM_INFLIGHT_FRAMES;
buf->active_slot = 0;
const bool injected = (0 != desc->mtl_buffers[0]);
MTLResourceOptions mtl_options = _sg_mtl_buffer_resource_options(buf->usage);
for (int slot = 0; slot < buf->num_slots; slot++) {
id<MTLBuffer> mtl_buf;
if (injected) {
SOKOL_ASSERT(desc->mtl_buffers[slot]);
mtl_buf = (__bridge id<MTLBuffer>) desc->mtl_buffers[slot];
}
else {
if (buf->usage == SG_USAGE_IMMUTABLE) {
SOKOL_ASSERT(desc->content);
mtl_buf = [_sg_mtl_device newBufferWithBytes:desc->content length:buf->size options:mtl_options];
}
else {
mtl_buf = [_sg_mtl_device newBufferWithLength:buf->size options:mtl_options];
}
}
buf->mtl_buf[slot] = _sg_mtl_add_resource(mtl_buf);
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_buffer(_sg_buffer_t* buf) {
SOKOL_ASSERT(buf);
for (int slot = 0; slot < buf->num_slots; slot++) {
/* it's valid to call release resource with '0' */
_sg_mtl_release_resource(_sg.mtl.frame_index, buf->mtl_buf[slot]);
}
}
_SOKOL_PRIVATE void _sg_mtl_copy_image_content(const _sg_image_t* img, __unsafe_unretained id<MTLTexture> mtl_tex, const sg_image_content* content) {
const int num_faces = (img->type == SG_IMAGETYPE_CUBE) ? 6:1;
const int num_slices = (img->type == SG_IMAGETYPE_ARRAY) ? img->depth : 1;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int mip_index = 0; mip_index < img->num_mipmaps; mip_index++) {
SOKOL_ASSERT(content->subimage[face_index][mip_index].ptr);
SOKOL_ASSERT(content->subimage[face_index][mip_index].size > 0);
const uint8_t* data_ptr = (const uint8_t*)content->subimage[face_index][mip_index].ptr;
const int mip_width = _sg_max(img->width >> mip_index, 1);
const int mip_height = _sg_max(img->height >> mip_index, 1);
/* special case PVRTC formats: bytePerRow must be 0 */
int bytes_per_row = 0;
int bytes_per_slice = _sg_surface_pitch(img->pixel_format, mip_width, mip_height);
if (!_sg_mtl_is_pvrtc(img->pixel_format)) {
bytes_per_row = _sg_row_pitch(img->pixel_format, mip_width);
}
MTLRegion region;
if (img->type == SG_IMAGETYPE_3D) {
const int mip_depth = _sg_max(img->depth >> mip_index, 1);
region = MTLRegionMake3D(0, 0, 0, mip_width, mip_height, mip_depth);
/* FIXME: apparently the minimal bytes_per_image size for 3D texture
is 4 KByte... somehow need to handle this */
}
else {
region = MTLRegionMake2D(0, 0, mip_width, mip_height);
}
for (int slice_index = 0; slice_index < num_slices; slice_index++) {
const int mtl_slice_index = (img->type == SG_IMAGETYPE_CUBE) ? face_index : slice_index;
const int slice_offset = slice_index * bytes_per_slice;
SOKOL_ASSERT((slice_offset + bytes_per_slice) <= (int)content->subimage[face_index][mip_index].size);
[mtl_tex replaceRegion:region
mipmapLevel:mip_index
slice:mtl_slice_index
withBytes:data_ptr + slice_offset
bytesPerRow:bytes_per_row
bytesPerImage:bytes_per_slice];
}
}
}
}
/*
FIXME: METAL RESOURCE STORAGE MODE FOR macOS AND iOS
For immutable textures on macOS, the recommended procedure is to create
a MTLStorageModeManaged texture with the immutable content first,
and then use the GPU to blit the content into a MTLStorageModePrivate
texture before the first use.
On iOS use the same one-time-blit procedure, but from a
MTLStorageModeShared to a MTLStorageModePrivate texture.
It probably makes sense to handle this in a separate 'resource manager'
with a recycable pool of blit-source-textures?
*/
/* initialize MTLTextureDescritor with common attributes */
_SOKOL_PRIVATE bool _sg_mtl_init_texdesc_common(MTLTextureDescriptor* mtl_desc, _sg_image_t* img) {
mtl_desc.textureType = _sg_mtl_texture_type(img->type);
mtl_desc.pixelFormat = _sg_mtl_pixel_format(img->pixel_format);
if (MTLPixelFormatInvalid == mtl_desc.pixelFormat) {
SOKOL_LOG("Unsupported texture pixel format!\n");
return false;
}
mtl_desc.width = img->width;
mtl_desc.height = img->height;
if (SG_IMAGETYPE_3D == img->type) {
mtl_desc.depth = img->depth;
}
else {
mtl_desc.depth = 1;
}
mtl_desc.mipmapLevelCount = img->num_mipmaps;
if (SG_IMAGETYPE_ARRAY == img->type) {
mtl_desc.arrayLength = img->depth;
}
else {
mtl_desc.arrayLength = 1;
}
mtl_desc.usage = MTLTextureUsageShaderRead;
if (img->usage != SG_USAGE_IMMUTABLE) {
mtl_desc.cpuCacheMode = MTLCPUCacheModeWriteCombined;
}
#if defined(_SG_TARGET_MACOS)
/* macOS: use managed textures */
mtl_desc.resourceOptions = MTLResourceStorageModeManaged;
mtl_desc.storageMode = MTLStorageModeManaged;
#else
/* iOS: use CPU/GPU shared memory */
mtl_desc.resourceOptions = MTLResourceStorageModeShared;
mtl_desc.storageMode = MTLStorageModeShared;
#endif
return true;
}
/* initialize MTLTextureDescritor with rendertarget attributes */
_SOKOL_PRIVATE void _sg_mtl_init_texdesc_rt(MTLTextureDescriptor* mtl_desc, _sg_image_t* img) {
SOKOL_ASSERT(img->render_target);
/* reset the cpuCacheMode to 'default' */
mtl_desc.cpuCacheMode = MTLCPUCacheModeDefaultCache;
/* render targets are only visible to the GPU */
mtl_desc.resourceOptions = MTLResourceStorageModePrivate;
mtl_desc.storageMode = MTLStorageModePrivate;
/* non-MSAA render targets are shader-readable */
mtl_desc.usage = MTLTextureUsageShaderRead | MTLTextureUsageRenderTarget;
}
/* initialize MTLTextureDescritor with MSAA attributes */
_SOKOL_PRIVATE void _sg_mtl_init_texdesc_rt_msaa(MTLTextureDescriptor* mtl_desc, _sg_image_t* img) {
SOKOL_ASSERT(img->sample_count > 1);
/* reset the cpuCacheMode to 'default' */
mtl_desc.cpuCacheMode = MTLCPUCacheModeDefaultCache;
/* render targets are only visible to the GPU */
mtl_desc.resourceOptions = MTLResourceStorageModePrivate;
mtl_desc.storageMode = MTLStorageModePrivate;
/* MSAA render targets are not shader-readable (instead they are resolved) */
mtl_desc.usage = MTLTextureUsageRenderTarget;
mtl_desc.textureType = MTLTextureType2DMultisample;
mtl_desc.depth = 1;
mtl_desc.arrayLength = 1;
mtl_desc.mipmapLevelCount = 1;
mtl_desc.sampleCount = img->sample_count;
}
_SOKOL_PRIVATE sg_resource_state _sg_create_image(_sg_image_t* img, const sg_image_desc* desc) {
SOKOL_ASSERT(img && desc);
img->type = desc->type;
img->render_target = desc->render_target;
img->width = desc->width;
img->height = desc->height;
img->depth = desc->depth;
img->num_mipmaps = desc->num_mipmaps;
img->usage = desc->usage;
img->pixel_format = desc->pixel_format;
img->sample_count = desc->sample_count;
img->min_filter = desc->min_filter;
img->mag_filter = desc->mag_filter;
img->wrap_u = desc->wrap_u;
img->wrap_v = desc->wrap_v;
img->wrap_w = desc->wrap_w;
img->max_anisotropy = desc->max_anisotropy;
img->upd_frame_index = 0;
img->num_slots = (img->usage == SG_USAGE_IMMUTABLE) ? 1 :SG_NUM_INFLIGHT_FRAMES;
img->active_slot = 0;
const bool injected = (0 != desc->mtl_textures[0]);
const bool msaa = (img->sample_count > 1);
/* first initialize all Metal resource pool slots to 'empty' */
for (int i = 0; i < SG_NUM_INFLIGHT_FRAMES; i++) {
img->mtl_tex[i] = _sg_mtl_add_resource(nil);
}
img->mtl_sampler_state = _sg_mtl_add_resource(nil);
img->mtl_depth_tex = _sg_mtl_add_resource(nil);
img->mtl_msaa_tex = _sg_mtl_add_resource(nil);
/* initialize a Metal texture descriptor with common attributes */
MTLTextureDescriptor* mtl_desc = [[MTLTextureDescriptor alloc] init];
if (!_sg_mtl_init_texdesc_common(mtl_desc, img)) {
return SG_RESOURCESTATE_FAILED;
}
/* special case depth-stencil-buffer? */
if (_sg_is_valid_rendertarget_depth_format(img->pixel_format)) {
/* depth-stencil buffer texture must always be a render target */
SOKOL_ASSERT(img->render_target);
SOKOL_ASSERT(img->type == SG_IMAGETYPE_2D);
SOKOL_ASSERT(img->num_mipmaps == 1);
SOKOL_ASSERT(!injected);
if (msaa) {
_sg_mtl_init_texdesc_rt_msaa(mtl_desc, img);
}
else {
_sg_mtl_init_texdesc_rt(mtl_desc, img);
}
id<MTLTexture> tex = [_sg_mtl_device newTextureWithDescriptor:mtl_desc];
SOKOL_ASSERT(nil != tex);
img->mtl_depth_tex = _sg_mtl_add_resource(tex);
}
else {
/* create the color texture
In case this is a render target without MSAA, add the relevant
render-target descriptor attributes.
In case this is a render target *with* MSAA, the color texture
will serve as MSAA-resolve target (not as render target), and rendering
will go into a separate render target texture of type
MTLTextureType2DMultisample.
*/
if (img->render_target && !msaa) {
_sg_mtl_init_texdesc_rt(mtl_desc, img);
}
for (int slot = 0; slot < img->num_slots; slot++) {
id<MTLTexture> tex;
if (injected) {
SOKOL_ASSERT(desc->mtl_textures[slot]);
tex = (__bridge id<MTLTexture>) desc->mtl_textures[slot];
}
else {
tex = [_sg_mtl_device newTextureWithDescriptor:mtl_desc];
if ((img->usage == SG_USAGE_IMMUTABLE) && !img->render_target) {
_sg_mtl_copy_image_content(img, tex, &desc->content);
}
}
img->mtl_tex[slot] = _sg_mtl_add_resource(tex);
}
/* if MSAA color render target, create an additional MSAA render-surface texture */
if (img->render_target && msaa) {
_sg_mtl_init_texdesc_rt_msaa(mtl_desc, img);
id<MTLTexture> tex = [_sg_mtl_device newTextureWithDescriptor:mtl_desc];
img->mtl_msaa_tex = _sg_mtl_add_resource(tex);
}
/* create (possibly shared) sampler state */
img->mtl_sampler_state = _sg_mtl_create_sampler(_sg_mtl_device, desc);
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_image(_sg_image_t* img) {
SOKOL_ASSERT(img);
/* it's valid to call release resource with a 'null resource' */
for (int slot = 0; slot < img->num_slots; slot++) {
_sg_mtl_release_resource(_sg.mtl.frame_index, img->mtl_tex[slot]);
}
_sg_mtl_release_resource(_sg.mtl.frame_index, img->mtl_depth_tex);
_sg_mtl_release_resource(_sg.mtl.frame_index, img->mtl_msaa_tex);
/* NOTE: sampler state objects are shared and not released until shutdown */
}
_SOKOL_PRIVATE id<MTLLibrary> _sg_mtl_compile_library(const char* src) {
NSError* err = NULL;
id<MTLLibrary> lib = [_sg_mtl_device
newLibraryWithSource:[NSString stringWithUTF8String:src]
options:nil
error:&err
];
if (err) {
SOKOL_LOG([err.localizedDescription UTF8String]);
}
return lib;
}
_SOKOL_PRIVATE id<MTLLibrary> _sg_mtl_library_from_bytecode(const uint8_t* ptr, int num_bytes) {
NSError* err = NULL;
dispatch_data_t lib_data = dispatch_data_create(ptr, num_bytes, NULL, DISPATCH_DATA_DESTRUCTOR_DEFAULT);
id<MTLLibrary> lib = [_sg_mtl_device newLibraryWithData:lib_data error:&err];
if (err) {
SOKOL_LOG([err.localizedDescription UTF8String]);
}
return lib;
}
_SOKOL_PRIVATE sg_resource_state _sg_create_shader(_sg_shader_t* shd, const sg_shader_desc* desc) {
puts("sokol: create Metal shader");
SOKOL_ASSERT(shd && desc);
/* uniform block sizes and image types */
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const sg_shader_stage_desc* stage_desc = (stage_index == SG_SHADERSTAGE_VS) ? &desc->vs : &desc->fs;
_sg_shader_stage_t* stage = &shd->stage[stage_index];
SOKOL_ASSERT(stage->num_uniform_blocks == 0);
for (int ub_index = 0; ub_index < SG_MAX_SHADERSTAGE_UBS; ub_index++) {
const sg_shader_uniform_block_desc* ub_desc = &stage_desc->uniform_blocks[ub_index];
if (0 == ub_desc->size) {
break;
}
_sg_uniform_block_t* ub = &stage->uniform_blocks[ub_index];
ub->size = ub_desc->size;
stage->num_uniform_blocks++;
}
SOKOL_ASSERT(stage->num_images == 0);
for (int img_index = 0; img_index < SG_MAX_SHADERSTAGE_IMAGES; img_index++) {
const sg_shader_image_desc* img_desc = &stage_desc->images[img_index];
if (img_desc->type == _SG_IMAGETYPE_DEFAULT) {
break;
}
stage->images[img_index].type = img_desc->type;
stage->num_images++;
}
}
/* create metal libray objects and lookup entry functions */
id<MTLLibrary> vs_lib;
id<MTLLibrary> fs_lib;
id<MTLFunction> vs_func;
id<MTLFunction> fs_func;
const char* vs_entry = desc->vs.entry;
const char* fs_entry = desc->fs.entry;
if (desc->vs.byte_code && desc->fs.byte_code) {
/* separate byte code provided */
vs_lib = _sg_mtl_library_from_bytecode(desc->vs.byte_code, desc->vs.byte_code_size);
fs_lib = _sg_mtl_library_from_bytecode(desc->fs.byte_code, desc->fs.byte_code_size);
if (nil == vs_lib || nil == fs_lib) {
return SG_RESOURCESTATE_FAILED;
}
vs_func = [vs_lib newFunctionWithName:[NSString stringWithUTF8String:vs_entry]];
fs_func = [fs_lib newFunctionWithName:[NSString stringWithUTF8String:fs_entry]];
}
else if (desc->vs.source && desc->fs.source) {
/* separate sources provided */
vs_lib = _sg_mtl_compile_library(desc->vs.source);
fs_lib = _sg_mtl_compile_library(desc->fs.source);
if (nil == vs_lib || nil == fs_lib) {
return SG_RESOURCESTATE_FAILED;
}
vs_func = [vs_lib newFunctionWithName:[NSString stringWithUTF8String:vs_entry]];
fs_func = [fs_lib newFunctionWithName:[NSString stringWithUTF8String:fs_entry]];
}
else {
return SG_RESOURCESTATE_FAILED;
}
if (nil == vs_func) {
SOKOL_LOG("vertex shader entry function not found\n");
return SG_RESOURCESTATE_FAILED;
}
if (nil == fs_func) {
SOKOL_LOG("fragment shader entry function not found\n");
return SG_RESOURCESTATE_FAILED;
}
/* it is legal to call _sg_mtl_add_resource with a nil value, this will return a special 0xFFFFFFFF index */
shd->stage[SG_SHADERSTAGE_VS].mtl_lib = _sg_mtl_add_resource(vs_lib);
shd->stage[SG_SHADERSTAGE_FS].mtl_lib = _sg_mtl_add_resource(fs_lib);
shd->stage[SG_SHADERSTAGE_VS].mtl_func = _sg_mtl_add_resource(vs_func);
shd->stage[SG_SHADERSTAGE_FS].mtl_func = _sg_mtl_add_resource(fs_func);
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_shader(_sg_shader_t* shd) {
SOKOL_ASSERT(shd);
/* it is valid to call _sg_mtl_release_resource with a 'null resource' */
_sg_mtl_release_resource(_sg.mtl.frame_index, shd->stage[SG_SHADERSTAGE_VS].mtl_func);
_sg_mtl_release_resource(_sg.mtl.frame_index, shd->stage[SG_SHADERSTAGE_VS].mtl_lib);
_sg_mtl_release_resource(_sg.mtl.frame_index, shd->stage[SG_SHADERSTAGE_FS].mtl_func);
_sg_mtl_release_resource(_sg.mtl.frame_index, shd->stage[SG_SHADERSTAGE_FS].mtl_lib);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pipeline(_sg_pipeline_t* pip, _sg_shader_t* shd, const sg_pipeline_desc* desc) {
SOKOL_ASSERT(pip && shd && desc);
SOKOL_ASSERT(desc->shader.id == shd->slot.id);
pip->shader = shd;
pip->shader_id = desc->shader;
pip->color_attachment_count = desc->blend.color_attachment_count;
pip->color_format = desc->blend.color_format;
pip->depth_format = desc->blend.depth_format;
pip->sample_count = desc->rasterizer.sample_count;
pip->depth_bias = desc->rasterizer.depth_bias;
pip->depth_bias_slope_scale = desc->rasterizer.depth_bias_slope_scale;
pip->depth_bias_clamp = desc->rasterizer.depth_bias_clamp;
sg_primitive_type prim_type = desc->primitive_type;
pip->mtl_prim_type = _sg_mtl_primitive_type(prim_type);
pip->index_type = desc->index_type;
pip->mtl_index_size = _sg_mtl_index_size(pip->index_type);
if (SG_INDEXTYPE_NONE != pip->index_type) {
pip->mtl_index_type = _sg_mtl_index_type(pip->index_type);
}
pip->mtl_cull_mode = _sg_mtl_cull_mode(desc->rasterizer.cull_mode);
pip->mtl_winding = _sg_mtl_winding(desc->rasterizer.face_winding);
pip->mtl_stencil_ref = desc->depth_stencil.stencil_ref;
for (int i = 0; i < 4; i++) {
pip->blend_color[i] = desc->blend.blend_color[i];
}
/* create vertex-descriptor */
MTLVertexDescriptor* vtx_desc = [MTLVertexDescriptor vertexDescriptor];
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
const sg_vertex_attr_desc* a_desc = &desc->layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
break;
}
SOKOL_ASSERT((a_desc->buffer_index >= 0) && (a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS));
vtx_desc.attributes[attr_index].format = _sg_mtl_vertex_format(a_desc->format);
vtx_desc.attributes[attr_index].offset = a_desc->offset;
vtx_desc.attributes[attr_index].bufferIndex = a_desc->buffer_index + SG_MAX_SHADERSTAGE_UBS;
pip->vertex_layout_valid[a_desc->buffer_index] = true;
}
for (int layout_index = 0; layout_index < SG_MAX_SHADERSTAGE_BUFFERS; layout_index++) {
if (pip->vertex_layout_valid[layout_index]) {
const sg_buffer_layout_desc* l_desc = &desc->layout.buffers[layout_index];
const int mtl_vb_slot = layout_index + SG_MAX_SHADERSTAGE_UBS;
SOKOL_ASSERT(l_desc->stride > 0);
vtx_desc.layouts[mtl_vb_slot].stride = l_desc->stride;
vtx_desc.layouts[mtl_vb_slot].stepFunction = _sg_mtl_step_function(l_desc->step_func);
vtx_desc.layouts[mtl_vb_slot].stepRate = l_desc->step_rate;
}
}
/* render-pipeline descriptor */
MTLRenderPipelineDescriptor* rp_desc = [[MTLRenderPipelineDescriptor alloc] init];
rp_desc.vertexDescriptor = vtx_desc;
SOKOL_ASSERT(shd->stage[SG_SHADERSTAGE_VS].mtl_func != _SG_MTL_INVALID_SLOT_INDEX);
rp_desc.vertexFunction = _sg_mtl_idpool[shd->stage[SG_SHADERSTAGE_VS].mtl_func];
SOKOL_ASSERT(shd->stage[SG_SHADERSTAGE_FS].mtl_func != _SG_MTL_INVALID_SLOT_INDEX);
rp_desc.fragmentFunction = _sg_mtl_idpool[shd->stage[SG_SHADERSTAGE_FS].mtl_func];
rp_desc.sampleCount = desc->rasterizer.sample_count;
rp_desc.alphaToCoverageEnabled = desc->rasterizer.alpha_to_coverage_enabled;
rp_desc.alphaToOneEnabled = NO;
rp_desc.rasterizationEnabled = YES;
rp_desc.depthAttachmentPixelFormat = _sg_mtl_pixel_format(desc->blend.depth_format);
if (desc->blend.depth_format == SG_PIXELFORMAT_DEPTH_STENCIL) {
rp_desc.stencilAttachmentPixelFormat = _sg_mtl_pixel_format(desc->blend.depth_format);
}
/* FIXME: this only works on macOS 10.13!
for (int i = 0; i < (SG_MAX_SHADERSTAGE_UBS+SG_MAX_SHADERSTAGE_BUFFERS); i++) {
rp_desc.vertexBuffers[i].mutability = MTLMutabilityImmutable;
}
for (int i = 0; i < SG_MAX_SHADERSTAGE_UBS; i++) {
rp_desc.fragmentBuffers[i].mutability = MTLMutabilityImmutable;
}
*/
const int att_count = desc->blend.color_attachment_count;
for (int i = 0; i < att_count; i++) {
rp_desc.colorAttachments[i].pixelFormat = _sg_mtl_pixel_format(desc->blend.color_format);
rp_desc.colorAttachments[i].writeMask = _sg_mtl_color_write_mask((sg_color_mask)desc->blend.color_write_mask);
rp_desc.colorAttachments[i].blendingEnabled = desc->blend.enabled;
rp_desc.colorAttachments[i].alphaBlendOperation = _sg_mtl_blend_op(desc->blend.op_alpha);
rp_desc.colorAttachments[i].rgbBlendOperation = _sg_mtl_blend_op(desc->blend.op_rgb);
rp_desc.colorAttachments[i].destinationAlphaBlendFactor = _sg_mtl_blend_factor(desc->blend.dst_factor_alpha);
rp_desc.colorAttachments[i].destinationRGBBlendFactor = _sg_mtl_blend_factor(desc->blend.dst_factor_rgb);
rp_desc.colorAttachments[i].sourceAlphaBlendFactor = _sg_mtl_blend_factor(desc->blend.src_factor_alpha);
rp_desc.colorAttachments[i].sourceRGBBlendFactor = _sg_mtl_blend_factor(desc->blend.src_factor_rgb);
}
NSError* err = NULL;
id<MTLRenderPipelineState> mtl_rps = [_sg_mtl_device newRenderPipelineStateWithDescriptor:rp_desc error:&err];
if (nil == mtl_rps) {
SOKOL_ASSERT(err);
SOKOL_LOG([err.localizedDescription UTF8String]);
return SG_RESOURCESTATE_FAILED;
}
/* depth-stencil-state */
MTLDepthStencilDescriptor* ds_desc = [[MTLDepthStencilDescriptor alloc] init];
ds_desc.depthCompareFunction = _sg_mtl_compare_func(desc->depth_stencil.depth_compare_func);
ds_desc.depthWriteEnabled = desc->depth_stencil.depth_write_enabled;
if (desc->depth_stencil.stencil_enabled) {
const sg_stencil_state* sb = &desc->depth_stencil.stencil_back;
ds_desc.backFaceStencil = [[MTLStencilDescriptor alloc] init];
ds_desc.backFaceStencil.stencilFailureOperation = _sg_mtl_stencil_op(sb->fail_op);
ds_desc.backFaceStencil.depthFailureOperation = _sg_mtl_stencil_op(sb->depth_fail_op);
ds_desc.backFaceStencil.depthStencilPassOperation = _sg_mtl_stencil_op(sb->pass_op);
ds_desc.backFaceStencil.stencilCompareFunction = _sg_mtl_compare_func(sb->compare_func);
ds_desc.backFaceStencil.readMask = desc->depth_stencil.stencil_read_mask;
ds_desc.backFaceStencil.writeMask = desc->depth_stencil.stencil_write_mask;
const sg_stencil_state* sf = &desc->depth_stencil.stencil_front;
ds_desc.frontFaceStencil = [[MTLStencilDescriptor alloc] init];
ds_desc.frontFaceStencil.stencilFailureOperation = _sg_mtl_stencil_op(sf->fail_op);
ds_desc.frontFaceStencil.depthFailureOperation = _sg_mtl_stencil_op(sf->depth_fail_op);
ds_desc.frontFaceStencil.depthStencilPassOperation = _sg_mtl_stencil_op(sf->pass_op);
ds_desc.frontFaceStencil.stencilCompareFunction = _sg_mtl_compare_func(sf->compare_func);
ds_desc.frontFaceStencil.readMask = desc->depth_stencil.stencil_read_mask;
ds_desc.frontFaceStencil.writeMask = desc->depth_stencil.stencil_write_mask;
}
id<MTLDepthStencilState> mtl_dss = [_sg_mtl_device newDepthStencilStateWithDescriptor:ds_desc];
pip->mtl_rps = _sg_mtl_add_resource(mtl_rps);
pip->mtl_dss = _sg_mtl_add_resource(mtl_dss);
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
/* it's valid to call release resource with a 'null resource' */
_sg_mtl_release_resource(_sg.mtl.frame_index, pip->mtl_rps);
_sg_mtl_release_resource(_sg.mtl.frame_index, pip->mtl_dss);
}
_SOKOL_PRIVATE sg_resource_state _sg_create_pass(_sg_pass_t* pass, _sg_image_t** att_images, const sg_pass_desc* desc) {
SOKOL_ASSERT(pass && desc);
SOKOL_ASSERT(att_images && att_images[0]);
/* copy image pointers and desc attributes */
const sg_attachment_desc* att_desc;
_sg_attachment_t* att;
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
SOKOL_ASSERT(0 == pass->color_atts[i].image);
att_desc = &desc->color_attachments[i];
if (att_desc->image.id != SG_INVALID_ID) {
pass->num_color_atts++;
SOKOL_ASSERT(att_images[i] && (att_images[i]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_color_format(att_images[i]->pixel_format));
att = &pass->color_atts[i];
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[i];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
}
}
SOKOL_ASSERT(0 == pass->ds_att.image);
att_desc = &desc->depth_stencil_attachment;
const int ds_img_index = SG_MAX_COLOR_ATTACHMENTS;
if (att_desc->image.id != SG_INVALID_ID) {
SOKOL_ASSERT(att_images[ds_img_index] && (att_images[ds_img_index]->slot.id == att_desc->image.id));
SOKOL_ASSERT(_sg_is_valid_rendertarget_depth_format(att_images[ds_img_index]->pixel_format));
att = &pass->ds_att;
SOKOL_ASSERT((att->image == 0) && (att->image_id.id == SG_INVALID_ID));
att->image = att_images[ds_img_index];
att->image_id = att_desc->image;
att->mip_level = att_desc->mip_level;
att->slice = att_desc->slice;
}
return SG_RESOURCESTATE_VALID;
}
_SOKOL_PRIVATE void _sg_destroy_pass(_sg_pass_t* pass) {
SOKOL_ASSERT(pass);
_SOKOL_UNUSED(pass);
}
_SOKOL_PRIVATE void _sg_begin_pass(_sg_pass_t* pass, const sg_pass_action* action, int w, int h) {
SOKOL_ASSERT(action);
SOKOL_ASSERT(!_sg.mtl.in_pass);
SOKOL_ASSERT(_sg_mtl_cmd_queue);
SOKOL_ASSERT(!_sg_mtl_cmd_encoder);
SOKOL_ASSERT(_sg.mtl.renderpass_descriptor_cb);
_sg.mtl.in_pass = true;
_sg.mtl.cur_width = w;
_sg.mtl.cur_height = h;
_sg_mtl_clear_state_cache();
/* if this is the first pass in the frame, create a command buffer */
if (nil == _sg_mtl_cmd_buffer) {
/* block until the oldest frame in flight has finished */
dispatch_semaphore_wait(_sg_mtl_sem, DISPATCH_TIME_FOREVER);
_sg_mtl_cmd_buffer = [_sg_mtl_cmd_queue commandBufferWithUnretainedReferences];
}
/* if this is first pass in frame, get uniform buffer base pointer */
if (0 == _sg.mtl.cur_ub_base_ptr) {
_sg.mtl.cur_ub_base_ptr = (uint8_t*)[_sg_mtl_uniform_buffers[_sg.mtl.cur_frame_rotate_index] contents];
}
/* initialize a render pass descriptor */
MTLRenderPassDescriptor* pass_desc = nil;
if (pass) {
/* offscreen render pass */
pass_desc = [MTLRenderPassDescriptor renderPassDescriptor];
}
else {
/* default render pass, call user-provided callback to provide render pass descriptor */
pass_desc = (__bridge MTLRenderPassDescriptor*) _sg.mtl.renderpass_descriptor_cb();
}
if (pass_desc) {
_sg.mtl.pass_valid = true;
}
else {
/* default pass descriptor will not be valid if window is minimized,
don't do any rendering in this case */
_sg.mtl.pass_valid = false;
return;
}
if (pass) {
/* setup pass descriptor for offscreen rendering */
SOKOL_ASSERT(pass->slot.state == SG_RESOURCESTATE_VALID);
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
const _sg_attachment_t* att = &pass->color_atts[i];
if (0 == att->image) {
break;
}
SOKOL_ASSERT(att->image->slot.state == SG_RESOURCESTATE_VALID);
SOKOL_ASSERT(att->image->slot.id == att->image_id.id);
const bool is_msaa = (att->image->sample_count > 1);
pass_desc.colorAttachments[i].loadAction = _sg_mtl_load_action(action->colors[i].action);
pass_desc.colorAttachments[i].storeAction = is_msaa ? MTLStoreActionMultisampleResolve : MTLStoreActionStore;
const float* c = &(action->colors[i].val[0]);
pass_desc.colorAttachments[i].clearColor = MTLClearColorMake(c[0], c[1], c[2], c[3]);
if (is_msaa) {
SOKOL_ASSERT(att->image->mtl_msaa_tex != _SG_MTL_INVALID_SLOT_INDEX);
SOKOL_ASSERT(att->image->mtl_tex[att->image->active_slot] != _SG_MTL_INVALID_SLOT_INDEX);
pass_desc.colorAttachments[i].texture = _sg_mtl_idpool[att->image->mtl_msaa_tex];
pass_desc.colorAttachments[i].resolveTexture = _sg_mtl_idpool[att->image->mtl_tex[att->image->active_slot]];
pass_desc.colorAttachments[i].resolveLevel = att->mip_level;
switch (att->image->type) {
case SG_IMAGETYPE_CUBE:
case SG_IMAGETYPE_ARRAY:
pass_desc.colorAttachments[i].resolveSlice = att->slice;
break;
case SG_IMAGETYPE_3D:
pass_desc.colorAttachments[i].resolveDepthPlane = att->slice;
break;
default: break;
}
}
else {
SOKOL_ASSERT(att->image->mtl_tex[att->image->active_slot] != _SG_MTL_INVALID_SLOT_INDEX);
pass_desc.colorAttachments[i].texture = _sg_mtl_idpool[att->image->mtl_tex[att->image->active_slot]];
pass_desc.colorAttachments[i].level = att->mip_level;
switch (att->image->type) {
case SG_IMAGETYPE_CUBE:
case SG_IMAGETYPE_ARRAY:
pass_desc.colorAttachments[i].slice = att->slice;
break;
case SG_IMAGETYPE_3D:
pass_desc.colorAttachments[i].depthPlane = att->slice;
break;
default: break;
}
}
}
if (0 != pass->ds_att.image) {
const _sg_attachment_t* att = &pass->ds_att;
SOKOL_ASSERT(att->image->slot.state == SG_RESOURCESTATE_VALID);
SOKOL_ASSERT(att->image->slot.id == att->image_id.id);
SOKOL_ASSERT(att->image->mtl_depth_tex != _SG_MTL_INVALID_SLOT_INDEX);
pass_desc.depthAttachment.texture = _sg_mtl_idpool[att->image->mtl_depth_tex];
pass_desc.depthAttachment.loadAction = _sg_mtl_load_action(action->depth.action);
pass_desc.depthAttachment.clearDepth = action->depth.val;
if (_sg_is_depth_stencil_format(att->image->pixel_format)) {
pass_desc.stencilAttachment.texture = _sg_mtl_idpool[att->image->mtl_depth_tex];
pass_desc.stencilAttachment.loadAction = _sg_mtl_load_action(action->stencil.action);
pass_desc.stencilAttachment.clearStencil = action->stencil.val;
}
}
}
else {
/* setup pass descriptor for default rendering */
pass_desc.colorAttachments[0].loadAction = _sg_mtl_load_action(action->colors[0].action);
const float* c = &(action->colors[0].val[0]);
pass_desc.colorAttachments[0].clearColor = MTLClearColorMake(c[0], c[1], c[2], c[3]);
pass_desc.depthAttachment.loadAction = _sg_mtl_load_action(action->depth.action);
pass_desc.depthAttachment.clearDepth = action->depth.val;
pass_desc.stencilAttachment.loadAction = _sg_mtl_load_action(action->stencil.action);
pass_desc.stencilAttachment.clearStencil = action->stencil.val;
}
/* create a render command encoder, this might return nil if window is minimized */
_sg_mtl_cmd_encoder = [_sg_mtl_cmd_buffer renderCommandEncoderWithDescriptor:pass_desc];
if (_sg_mtl_cmd_encoder == nil) {
_sg.mtl.pass_valid = false;
return;
}
/* bind the global uniform buffer, this only happens once per pass */
for (int slot = 0; slot < SG_MAX_SHADERSTAGE_UBS; slot++) {
[_sg_mtl_cmd_encoder
setVertexBuffer:_sg_mtl_uniform_buffers[_sg.mtl.cur_frame_rotate_index]
offset:0
atIndex:slot];
[_sg_mtl_cmd_encoder
setFragmentBuffer:_sg_mtl_uniform_buffers[_sg.mtl.cur_frame_rotate_index]
offset:0
atIndex:slot];
}
}
_SOKOL_PRIVATE void _sg_end_pass(void) {
SOKOL_ASSERT(_sg.mtl.in_pass);
_sg.mtl.in_pass = false;
_sg.mtl.pass_valid = false;
if (nil != _sg_mtl_cmd_encoder) {
[_sg_mtl_cmd_encoder endEncoding];
_sg_mtl_cmd_encoder = nil;
}
}
_SOKOL_PRIVATE void _sg_commit(void) {
SOKOL_ASSERT(!_sg.mtl.in_pass);
SOKOL_ASSERT(!_sg.mtl.pass_valid);
SOKOL_ASSERT(_sg.mtl.drawable_cb);
SOKOL_ASSERT(nil == _sg_mtl_cmd_encoder);
SOKOL_ASSERT(nil != _sg_mtl_cmd_buffer);
#if defined(_SG_TARGET_MACOS)
[_sg_mtl_uniform_buffers[_sg.mtl.cur_frame_rotate_index] didModifyRange:NSMakeRange(0, _sg.mtl.cur_ub_offset)];
#endif
/* present, commit and signal semaphore when done */
id<MTLDrawable> cur_drawable = (__bridge id<MTLDrawable>) _sg.mtl.drawable_cb();
[_sg_mtl_cmd_buffer presentDrawable:cur_drawable];
[_sg_mtl_cmd_buffer addCompletedHandler:^(id<MTLCommandBuffer> cmd_buffer) {
dispatch_semaphore_signal(_sg_mtl_sem);
}];
[_sg_mtl_cmd_buffer commit];
/* garbage-collect resources pending for release */
_sg_mtl_garbage_collect(_sg.mtl.frame_index);
/* rotate uniform buffer slot */
if (++_sg.mtl.cur_frame_rotate_index >= SG_NUM_INFLIGHT_FRAMES) {
_sg.mtl.cur_frame_rotate_index = 0;
}
_sg.mtl.frame_index++;
_sg.mtl.cur_ub_offset = 0;
_sg.mtl.cur_ub_base_ptr = 0;
_sg_mtl_cmd_buffer = nil;
}
_SOKOL_PRIVATE void _sg_apply_viewport(int x, int y, int w, int h, bool origin_top_left) {
SOKOL_ASSERT(_sg.mtl.in_pass);
if (!_sg.mtl.pass_valid) {
return;
}
SOKOL_ASSERT(_sg_mtl_cmd_encoder);
MTLViewport vp;
vp.originX = (double) x;
vp.originY = (double) (origin_top_left ? y : (_sg.mtl.cur_height - (y + h)));
vp.width = (double) w;
vp.height = (double) h;
vp.znear = 0.0;
vp.zfar = 1.0;
[_sg_mtl_cmd_encoder setViewport:vp];
}
_SOKOL_PRIVATE void _sg_apply_scissor_rect(int x, int y, int w, int h, bool origin_top_left) {
SOKOL_ASSERT(_sg.mtl.in_pass);
if (!_sg.mtl.pass_valid) {
return;
}
SOKOL_ASSERT(_sg_mtl_cmd_encoder);
/* clip against framebuffer rect */
x = _sg_min(_sg_max(0, x), _sg.mtl.cur_width-1);
y = _sg_min(_sg_max(0, y), _sg.mtl.cur_height-1);
if ((x + w) > _sg.mtl.cur_width) {
w = _sg.mtl.cur_width - x;
}
if ((y + h) > _sg.mtl.cur_height) {
h = _sg.mtl.cur_height - y;
}
w = _sg_max(w, 1);
h = _sg_max(h, 1);
MTLScissorRect r;
r.x = x;
r.y = origin_top_left ? y : (_sg.mtl.cur_height - (y + h));
r.width = w;
r.height = h;
[_sg_mtl_cmd_encoder setScissorRect:r];
}
_SOKOL_PRIVATE void _sg_apply_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
SOKOL_ASSERT(pip->shader);
SOKOL_ASSERT(_sg.mtl.in_pass);
if (!_sg.mtl.pass_valid) {
return;
}
SOKOL_ASSERT(_sg_mtl_cmd_encoder);
if ((_sg.mtl.state_cache.cur_pipeline != pip) || (_sg.mtl.state_cache.cur_pipeline_id.id != pip->slot.id)) {
_sg.mtl.state_cache.cur_pipeline = pip;
_sg.mtl.state_cache.cur_pipeline_id.id = pip->slot.id;
const float* c = pip->blend_color;
[_sg_mtl_cmd_encoder setBlendColorRed:c[0] green:c[1] blue:c[2] alpha:c[3]];
[_sg_mtl_cmd_encoder setCullMode:pip->mtl_cull_mode];
[_sg_mtl_cmd_encoder setFrontFacingWinding:pip->mtl_winding];
[_sg_mtl_cmd_encoder setStencilReferenceValue:pip->mtl_stencil_ref];
[_sg_mtl_cmd_encoder setDepthBias:pip->depth_bias slopeScale:pip->depth_bias_slope_scale clamp:pip->depth_bias_clamp];
SOKOL_ASSERT(pip->mtl_rps != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setRenderPipelineState:_sg_mtl_idpool[pip->mtl_rps]];
SOKOL_ASSERT(pip->mtl_dss != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setDepthStencilState:_sg_mtl_idpool[pip->mtl_dss]];
}
}
_SOKOL_PRIVATE void _sg_apply_bindings(
_sg_pipeline_t* pip,
_sg_buffer_t** vbs, const int* vb_offsets, int num_vbs,
_sg_buffer_t* ib, int ib_offset,
_sg_image_t** vs_imgs, int num_vs_imgs,
_sg_image_t** fs_imgs, int num_fs_imgs)
{
SOKOL_ASSERT(_sg.mtl.in_pass);
if (!_sg.mtl.pass_valid) {
return;
}
SOKOL_ASSERT(_sg_mtl_cmd_encoder);
/* store index buffer binding, this will be needed later in sg_draw() */
_sg.mtl.state_cache.cur_indexbuffer = ib;
_sg.mtl.state_cache.cur_indexbuffer_offset = ib_offset;
if (ib) {
SOKOL_ASSERT(pip->index_type != SG_INDEXTYPE_NONE);
_sg.mtl.state_cache.cur_indexbuffer_id.id = ib->slot.id;
}
else {
SOKOL_ASSERT(pip->index_type == SG_INDEXTYPE_NONE);
_sg.mtl.state_cache.cur_indexbuffer_id.id = SG_INVALID_ID;
}
/* apply vertex buffers */
int slot;
for (slot = 0; slot < num_vbs; slot++) {
const _sg_buffer_t* vb = vbs[slot];
if ((_sg.mtl.state_cache.cur_vertexbuffers[slot] != vb) ||
(_sg.mtl.state_cache.cur_vertexbuffer_offsets[slot] != vb_offsets[slot]) ||
(_sg.mtl.state_cache.cur_vertexbuffer_ids[slot].id != vb->slot.id))
{
_sg.mtl.state_cache.cur_vertexbuffers[slot] = vb;
_sg.mtl.state_cache.cur_vertexbuffer_offsets[slot] = vb_offsets[slot];
_sg.mtl.state_cache.cur_vertexbuffer_ids[slot].id = vb->slot.id;
const NSUInteger mtl_slot = SG_MAX_SHADERSTAGE_UBS + slot;
SOKOL_ASSERT(vb->mtl_buf[vb->active_slot] != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setVertexBuffer:_sg_mtl_idpool[vb->mtl_buf[vb->active_slot]]
offset:vb_offsets[slot]
atIndex:mtl_slot];
}
}
/* apply vertex shader images */
for (slot = 0; slot < num_vs_imgs; slot++) {
const _sg_image_t* img = vs_imgs[slot];
if ((_sg.mtl.state_cache.cur_vs_images[slot] != img) || (_sg.mtl.state_cache.cur_vs_image_ids[slot].id != img->slot.id)) {
_sg.mtl.state_cache.cur_vs_images[slot] = img;
_sg.mtl.state_cache.cur_vs_image_ids[slot].id = img->slot.id;
SOKOL_ASSERT(img->mtl_tex[img->active_slot] != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setVertexTexture:_sg_mtl_idpool[img->mtl_tex[img->active_slot]] atIndex:slot];
SOKOL_ASSERT(img->mtl_sampler_state != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setVertexSamplerState:_sg_mtl_idpool[img->mtl_sampler_state] atIndex:slot];
}
}
/* apply fragment shader images */
for (slot = 0; slot < num_fs_imgs; slot++) {
const _sg_image_t* img = fs_imgs[slot];
if ((_sg.mtl.state_cache.cur_fs_images[slot] != img) || (_sg.mtl.state_cache.cur_fs_image_ids[slot].id != img->slot.id)) {
_sg.mtl.state_cache.cur_fs_images[slot] = img;
_sg.mtl.state_cache.cur_fs_image_ids[slot].id = img->slot.id;
SOKOL_ASSERT(img->mtl_tex[img->active_slot] != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setFragmentTexture:_sg_mtl_idpool[img->mtl_tex[img->active_slot]] atIndex:slot];
SOKOL_ASSERT(img->mtl_sampler_state != _SG_MTL_INVALID_SLOT_INDEX);
[_sg_mtl_cmd_encoder setFragmentSamplerState:_sg_mtl_idpool[img->mtl_sampler_state] atIndex:slot];
}
}
}
#define _sg_mtl_roundup(val, round_to) (((val)+((round_to)-1))&~((round_to)-1))
_SOKOL_PRIVATE void _sg_apply_uniforms(sg_shader_stage stage_index, int ub_index, const void* data, int num_bytes) {
SOKOL_ASSERT(_sg.mtl.in_pass);
if (!_sg.mtl.pass_valid) {
return;
}
SOKOL_ASSERT(_sg_mtl_cmd_encoder);
SOKOL_ASSERT(data && (num_bytes > 0));
SOKOL_ASSERT((stage_index >= 0) && ((int)stage_index < SG_NUM_SHADER_STAGES));
SOKOL_ASSERT((ub_index >= 0) && (ub_index < SG_MAX_SHADERSTAGE_UBS));
SOKOL_ASSERT((_sg.mtl.cur_ub_offset + num_bytes) <= _sg.mtl.ub_size);
SOKOL_ASSERT((_sg.mtl.cur_ub_offset & (_SG_MTL_UB_ALIGN-1)) == 0);
SOKOL_ASSERT(_sg.mtl.state_cache.cur_pipeline && _sg.mtl.state_cache.cur_pipeline->shader);
SOKOL_ASSERT(_sg.mtl.state_cache.cur_pipeline->slot.id == _sg.mtl.state_cache.cur_pipeline_id.id);
SOKOL_ASSERT(_sg.mtl.state_cache.cur_pipeline->shader->slot.id == _sg.mtl.state_cache.cur_pipeline->shader_id.id);
SOKOL_ASSERT(ub_index < _sg.mtl.state_cache.cur_pipeline->shader->stage[stage_index].num_uniform_blocks);
SOKOL_ASSERT(num_bytes <= _sg.mtl.state_cache.cur_pipeline->shader->stage[stage_index].uniform_blocks[ub_index].size);
/* copy to global uniform buffer, record offset into cmd encoder, and advance offset */
uint8_t* dst = &_sg.mtl.cur_ub_base_ptr[_sg.mtl.cur_ub_offset];
memcpy(dst, data, num_bytes);
if (stage_index == SG_SHADERSTAGE_VS) {
[_sg_mtl_cmd_encoder setVertexBufferOffset:_sg.mtl.cur_ub_offset atIndex:ub_index];
}
else {
[_sg_mtl_cmd_encoder setFragmentBufferOffset:_sg.mtl.cur_ub_offset atIndex:ub_index];
}
_sg.mtl.cur_ub_offset = _sg_mtl_roundup(_sg.mtl.cur_ub_offset + num_bytes, _SG_MTL_UB_ALIGN);
}
_SOKOL_PRIVATE void _sg_draw(int base_element, int num_elements, int num_instances) {
SOKOL_ASSERT(_sg.mtl.in_pass);
if (!_sg.mtl.pass_valid) {
return;
}
SOKOL_ASSERT(_sg_mtl_cmd_encoder);
SOKOL_ASSERT(_sg.mtl.state_cache.cur_pipeline && (_sg.mtl.state_cache.cur_pipeline->slot.id == _sg.mtl.state_cache.cur_pipeline_id.id));
if (SG_INDEXTYPE_NONE != _sg.mtl.state_cache.cur_pipeline->index_type) {
/* indexed rendering */
SOKOL_ASSERT(_sg.mtl.state_cache.cur_indexbuffer && (_sg.mtl.state_cache.cur_indexbuffer->slot.id == _sg.mtl.state_cache.cur_indexbuffer_id.id));
const _sg_buffer_t* ib = _sg.mtl.state_cache.cur_indexbuffer;
SOKOL_ASSERT(ib->mtl_buf[ib->active_slot] != _SG_MTL_INVALID_SLOT_INDEX);
const NSUInteger index_buffer_offset = _sg.mtl.state_cache.cur_indexbuffer_offset +
base_element * _sg.mtl.state_cache.cur_pipeline->mtl_index_size;
[_sg_mtl_cmd_encoder drawIndexedPrimitives:_sg.mtl.state_cache.cur_pipeline->mtl_prim_type
indexCount:num_elements
indexType:_sg.mtl.state_cache.cur_pipeline->mtl_index_type
indexBuffer:_sg_mtl_idpool[ib->mtl_buf[ib->active_slot]]
indexBufferOffset:index_buffer_offset
instanceCount:num_instances];
}
else {
/* non-indexed rendering */
[_sg_mtl_cmd_encoder drawPrimitives:_sg.mtl.state_cache.cur_pipeline->mtl_prim_type
vertexStart:base_element
vertexCount:num_elements
instanceCount:num_instances];
}
}
_SOKOL_PRIVATE void _sg_update_buffer(_sg_buffer_t* buf, const void* data, int data_size) {
SOKOL_ASSERT(buf && data && (data_size > 0));
if (++buf->active_slot >= buf->num_slots) {
buf->active_slot = 0;
}
__unsafe_unretained id<MTLBuffer> mtl_buf = _sg_mtl_idpool[buf->mtl_buf[buf->active_slot]];
void* dst_ptr = [mtl_buf contents];
memcpy(dst_ptr, data, data_size);
#if defined(_SG_TARGET_MACOS)
[mtl_buf didModifyRange:NSMakeRange(0, data_size)];
#endif
}
_SOKOL_PRIVATE void _sg_append_buffer(_sg_buffer_t* buf, const void* data, int data_size, bool new_frame) {
SOKOL_ASSERT(buf && data && (data_size > 0));
if (new_frame) {
if (++buf->active_slot >= buf->num_slots) {
buf->active_slot = 0;
}
}
__unsafe_unretained id<MTLBuffer> mtl_buf = _sg_mtl_idpool[buf->mtl_buf[buf->active_slot]];
uint8_t* dst_ptr = (uint8_t*) [mtl_buf contents];
dst_ptr += buf->append_pos;
memcpy(dst_ptr, data, data_size);
#if defined(_SG_TARGET_MACOS)
[mtl_buf didModifyRange:NSMakeRange(buf->append_pos, data_size)];
#endif
}
_SOKOL_PRIVATE void _sg_update_image(_sg_image_t* img, const sg_image_content* data) {
SOKOL_ASSERT(img && data);
if (++img->active_slot >= img->num_slots) {
img->active_slot = 0;
}
__unsafe_unretained id<MTLTexture> mtl_tex = _sg_mtl_idpool[img->mtl_tex[img->active_slot]];
_sg_mtl_copy_image_content(img, mtl_tex, data);
}
#endif
/*== RESOURCE POOLS ==========================================================*/
_SOKOL_PRIVATE void _sg_init_pool(_sg_pool_t* pool, int num) {
SOKOL_ASSERT(pool && (num >= 1));
/* slot 0 is reserved for the 'invalid id', so bump the pool size by 1 */
pool->size = num + 1;
pool->queue_top = 0;
/* generation counters indexable by pool slot index, slot 0 is reserved */
size_t gen_ctrs_size = sizeof(uint32_t) * pool->size;
pool->gen_ctrs = (uint32_t*) SOKOL_MALLOC(gen_ctrs_size);
SOKOL_ASSERT(pool->gen_ctrs);
memset(pool->gen_ctrs, 0, gen_ctrs_size);
/* it's not a bug to only reserve 'num' here */
pool->free_queue = (int*) SOKOL_MALLOC(sizeof(int)*num);
SOKOL_ASSERT(pool->free_queue);
/* never allocate the zero-th pool item since the invalid id is 0 */
for (int i = pool->size-1; i >= 1; i--) {
pool->free_queue[pool->queue_top++] = i;
}
}
_SOKOL_PRIVATE void _sg_discard_pool(_sg_pool_t* pool) {
SOKOL_ASSERT(pool);
SOKOL_ASSERT(pool->free_queue);
SOKOL_FREE(pool->free_queue);
pool->free_queue = 0;
SOKOL_ASSERT(pool->gen_ctrs);
SOKOL_FREE(pool->gen_ctrs);
pool->gen_ctrs = 0;
pool->size = 0;
pool->queue_top = 0;
}
_SOKOL_PRIVATE int _sg_pool_alloc_index(_sg_pool_t* pool) {
SOKOL_ASSERT(pool);
SOKOL_ASSERT(pool->free_queue);
if (pool->queue_top > 0) {
int slot_index = pool->free_queue[--pool->queue_top];
SOKOL_ASSERT((slot_index > 0) && (slot_index < pool->size));
return slot_index;
}
else {
/* pool exhausted */
return _SG_INVALID_SLOT_INDEX;
}
}
_SOKOL_PRIVATE void _sg_pool_free_index(_sg_pool_t* pool, int slot_index) {
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < pool->size));
SOKOL_ASSERT(pool);
SOKOL_ASSERT(pool->free_queue);
SOKOL_ASSERT(pool->queue_top < pool->size);
#ifdef SOKOL_DEBUG
/* debug check against double-free */
for (int i = 0; i < pool->queue_top; i++) {
SOKOL_ASSERT(pool->free_queue[i] != slot_index);
}
#endif
pool->free_queue[pool->queue_top++] = slot_index;
SOKOL_ASSERT(pool->queue_top <= (pool->size-1));
}
_SOKOL_PRIVATE void _sg_reset_buffer(_sg_buffer_t* buf) {
SOKOL_ASSERT(buf);
memset(buf, 0, sizeof(_sg_buffer_t));
}
_SOKOL_PRIVATE void _sg_reset_image(_sg_image_t* img) {
SOKOL_ASSERT(img);
memset(img, 0, sizeof(_sg_image_t));
}
_SOKOL_PRIVATE void _sg_reset_shader(_sg_shader_t* shd) {
SOKOL_ASSERT(shd);
memset(shd, 0, sizeof(_sg_shader_t));
}
_SOKOL_PRIVATE void _sg_reset_pipeline(_sg_pipeline_t* pip) {
SOKOL_ASSERT(pip);
memset(pip, 0, sizeof(_sg_pipeline_t));
}
_SOKOL_PRIVATE void _sg_reset_pass(_sg_pass_t* pass) {
SOKOL_ASSERT(pass);
memset(pass, 0, sizeof(_sg_pass_t));
}
_SOKOL_PRIVATE void _sg_reset_context(_sg_context_t* ctx) {
SOKOL_ASSERT(ctx);
memset(ctx, 0, sizeof(_sg_context_t));
}
_SOKOL_PRIVATE void _sg_setup_pools(_sg_pools_t* p, const sg_desc* desc) {
SOKOL_ASSERT(p);
SOKOL_ASSERT(desc);
/* note: the pools here will have an additional item, since slot 0 is reserved */
SOKOL_ASSERT((desc->buffer_pool_size > 0) && (desc->buffer_pool_size < _SG_MAX_POOL_SIZE));
_sg_init_pool(&p->buffer_pool, desc->buffer_pool_size);
size_t buffer_pool_byte_size = sizeof(_sg_buffer_t) * p->buffer_pool.size;
p->buffers = (_sg_buffer_t*) SOKOL_MALLOC(buffer_pool_byte_size);
SOKOL_ASSERT(p->buffers);
memset(p->buffers, 0, buffer_pool_byte_size);
SOKOL_ASSERT((desc->image_pool_size > 0) && (desc->image_pool_size < _SG_MAX_POOL_SIZE));
_sg_init_pool(&p->image_pool, desc->image_pool_size);
size_t image_pool_byte_size = sizeof(_sg_image_t) * p->image_pool.size;
p->images = (_sg_image_t*) SOKOL_MALLOC(image_pool_byte_size);
SOKOL_ASSERT(p->images);
memset(p->images, 0, image_pool_byte_size);
SOKOL_ASSERT((desc->shader_pool_size > 0) && (desc->shader_pool_size < _SG_MAX_POOL_SIZE));
_sg_init_pool(&p->shader_pool, desc->shader_pool_size);
size_t shader_pool_byte_size = sizeof(_sg_shader_t) * p->shader_pool.size;
p->shaders = (_sg_shader_t*) SOKOL_MALLOC(shader_pool_byte_size);
SOKOL_ASSERT(p->shaders);
memset(p->shaders, 0, shader_pool_byte_size);
SOKOL_ASSERT((desc->pipeline_pool_size > 0) && (desc->pipeline_pool_size < _SG_MAX_POOL_SIZE));
_sg_init_pool(&p->pipeline_pool, desc->pipeline_pool_size);
size_t pipeline_pool_byte_size = sizeof(_sg_pipeline_t) * p->pipeline_pool.size;
p->pipelines = (_sg_pipeline_t*) SOKOL_MALLOC(pipeline_pool_byte_size);
SOKOL_ASSERT(p->pipelines);
memset(p->pipelines, 0, pipeline_pool_byte_size);
SOKOL_ASSERT((desc->pass_pool_size > 0) && (desc->pass_pool_size < _SG_MAX_POOL_SIZE));
_sg_init_pool(&p->pass_pool, desc->pass_pool_size);
size_t pass_pool_byte_size = sizeof(_sg_pass_t) * p->pass_pool.size;
p->passes = (_sg_pass_t*) SOKOL_MALLOC(pass_pool_byte_size);
SOKOL_ASSERT(p->passes);
memset(p->passes, 0, pass_pool_byte_size);
SOKOL_ASSERT((desc->context_pool_size > 0) && (desc->context_pool_size < _SG_MAX_POOL_SIZE));
_sg_init_pool(&p->context_pool, desc->context_pool_size);
size_t context_pool_byte_size = sizeof(_sg_context_t) * p->context_pool.size;
p->contexts = (_sg_context_t*) SOKOL_MALLOC(context_pool_byte_size);
SOKOL_ASSERT(p->contexts);
memset(p->contexts, 0, context_pool_byte_size);
}
_SOKOL_PRIVATE void _sg_discard_pools(_sg_pools_t* p) {
SOKOL_ASSERT(p);
SOKOL_FREE(p->contexts); p->contexts = 0;
SOKOL_FREE(p->passes); p->passes = 0;
SOKOL_FREE(p->pipelines); p->pipelines = 0;
SOKOL_FREE(p->shaders); p->shaders = 0;
SOKOL_FREE(p->images); p->images = 0;
SOKOL_FREE(p->buffers); p->buffers = 0;
_sg_discard_pool(&p->context_pool);
_sg_discard_pool(&p->pass_pool);
_sg_discard_pool(&p->pipeline_pool);
_sg_discard_pool(&p->shader_pool);
_sg_discard_pool(&p->image_pool);
_sg_discard_pool(&p->buffer_pool);
}
/* allocate the slot at slot_index:
- bump the slot's generation counter
- create a resource id from the generation counter and slot index
- set the slot's id to this id
- set the slot's state to ALLOC
- return the resource id
*/
_SOKOL_PRIVATE uint32_t _sg_slot_alloc(_sg_pool_t* pool, _sg_slot_t* slot, int slot_index) {
/* FIXME: add handling for an overflowing generation counter,
for now, just overflow (another option is to disable
the slot)
*/
SOKOL_ASSERT(pool && pool->gen_ctrs);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < pool->size));
SOKOL_ASSERT((slot->state == SG_RESOURCESTATE_INITIAL) && (slot->id == SG_INVALID_ID));
uint32_t ctr = ++pool->gen_ctrs[slot_index];
slot->id = (ctr<<_SG_SLOT_SHIFT)|(slot_index & _SG_SLOT_MASK);
slot->state = SG_RESOURCESTATE_ALLOC;
return slot->id;
}
/* extract slot index from id */
_SOKOL_PRIVATE int _sg_slot_index(uint32_t id) {
int slot_index = (int) (id & _SG_SLOT_MASK);
SOKOL_ASSERT(_SG_INVALID_SLOT_INDEX != slot_index);
return slot_index;
}
/* returns pointer to resource by id without matching id check */
_SOKOL_PRIVATE _sg_buffer_t* _sg_buffer_at(const _sg_pools_t* p, uint32_t buf_id) {
SOKOL_ASSERT(p && (SG_INVALID_ID != buf_id));
int slot_index = _sg_slot_index(buf_id);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < p->buffer_pool.size));
return &p->buffers[slot_index];
}
_SOKOL_PRIVATE _sg_image_t* _sg_image_at(const _sg_pools_t* p, uint32_t img_id) {
SOKOL_ASSERT(p && (SG_INVALID_ID != img_id));
int slot_index = _sg_slot_index(img_id);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < p->image_pool.size));
return &p->images[slot_index];
}
_SOKOL_PRIVATE _sg_shader_t* _sg_shader_at(const _sg_pools_t* p, uint32_t shd_id) {
SOKOL_ASSERT(p && (SG_INVALID_ID != shd_id));
int slot_index = _sg_slot_index(shd_id);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < p->shader_pool.size));
return &p->shaders[slot_index];
}
_SOKOL_PRIVATE _sg_pipeline_t* _sg_pipeline_at(const _sg_pools_t* p, uint32_t pip_id) {
SOKOL_ASSERT(p && (SG_INVALID_ID != pip_id));
int slot_index = _sg_slot_index(pip_id);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < p->pipeline_pool.size));
return &p->pipelines[slot_index];
}
_SOKOL_PRIVATE _sg_pass_t* _sg_pass_at(const _sg_pools_t* p, uint32_t pass_id) {
SOKOL_ASSERT(p && (SG_INVALID_ID != pass_id));
int slot_index = _sg_slot_index(pass_id);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < p->pass_pool.size));
return &p->passes[slot_index];
}
_SOKOL_PRIVATE _sg_context_t* _sg_context_at(const _sg_pools_t* p, uint32_t context_id) {
SOKOL_ASSERT(p && (SG_INVALID_ID != context_id));
int slot_index = _sg_slot_index(context_id);
SOKOL_ASSERT((slot_index > _SG_INVALID_SLOT_INDEX) && (slot_index < p->context_pool.size));
return &p->contexts[slot_index];
}
/* returns pointer to resource with matching id check, may return 0 */
_SOKOL_PRIVATE _sg_buffer_t* _sg_lookup_buffer(const _sg_pools_t* p, uint32_t buf_id) {
if (SG_INVALID_ID != buf_id) {
_sg_buffer_t* buf = _sg_buffer_at(p, buf_id);
if (buf->slot.id == buf_id) {
return buf;
}
}
return 0;
}
_SOKOL_PRIVATE _sg_image_t* _sg_lookup_image(const _sg_pools_t* p, uint32_t img_id) {
if (SG_INVALID_ID != img_id) {
_sg_image_t* img = _sg_image_at(p, img_id);
if (img->slot.id == img_id) {
return img;
}
}
return 0;
}
_SOKOL_PRIVATE _sg_shader_t* _sg_lookup_shader(const _sg_pools_t* p, uint32_t shd_id) {
SOKOL_ASSERT(p);
if (SG_INVALID_ID != shd_id) {
_sg_shader_t* shd = _sg_shader_at(p, shd_id);
if (shd->slot.id == shd_id) {
return shd;
}
}
return 0;
}
_SOKOL_PRIVATE _sg_pipeline_t* _sg_lookup_pipeline(const _sg_pools_t* p, uint32_t pip_id) {
SOKOL_ASSERT(p);
if (SG_INVALID_ID != pip_id) {
_sg_pipeline_t* pip = _sg_pipeline_at(p, pip_id);
if (pip->slot.id == pip_id) {
return pip;
}
}
return 0;
}
_SOKOL_PRIVATE _sg_pass_t* _sg_lookup_pass(const _sg_pools_t* p, uint32_t pass_id) {
SOKOL_ASSERT(p);
if (SG_INVALID_ID != pass_id) {
_sg_pass_t* pass = _sg_pass_at(p, pass_id);
if (pass->slot.id == pass_id) {
return pass;
}
}
return 0;
}
_SOKOL_PRIVATE _sg_context_t* _sg_lookup_context(const _sg_pools_t* p, uint32_t ctx_id) {
SOKOL_ASSERT(p);
if (SG_INVALID_ID != ctx_id) {
_sg_context_t* ctx = _sg_context_at(p, ctx_id);
if (ctx->slot.id == ctx_id) {
return ctx;
}
}
return 0;
}
_SOKOL_PRIVATE void _sg_destroy_all_resources(_sg_pools_t* p, uint32_t ctx_id) {
/* this is a bit dumb since it loops over all pool slots to
find the occupied slots, on the other hand it is only ever
executed at shutdown
NOTE: ONLY EXECUTE THIS AT SHUTDOWN
...because the free queues will not be reset
and the resource slots not be cleared!
*/
for (int i = 1; i < p->buffer_pool.size; i++) {
if (p->buffers[i].slot.ctx_id == ctx_id) {
sg_resource_state state = p->buffers[i].slot.state;
if ((state == SG_RESOURCESTATE_VALID) || (state == SG_RESOURCESTATE_FAILED)) {
_sg_destroy_buffer(&p->buffers[i]);
}
}
}
for (int i = 1; i < p->image_pool.size; i++) {
if (p->images[i].slot.ctx_id == ctx_id) {
sg_resource_state state = p->images[i].slot.state;
if ((state == SG_RESOURCESTATE_VALID) || (state == SG_RESOURCESTATE_FAILED)) {
_sg_destroy_image(&p->images[i]);
}
}
}
for (int i = 1; i < p->shader_pool.size; i++) {
if (p->shaders[i].slot.ctx_id == ctx_id) {
sg_resource_state state = p->shaders[i].slot.state;
if ((state == SG_RESOURCESTATE_VALID) || (state == SG_RESOURCESTATE_FAILED)) {
_sg_destroy_shader(&p->shaders[i]);
}
}
}
for (int i = 1; i < p->pipeline_pool.size; i++) {
if (p->pipelines[i].slot.ctx_id == ctx_id) {
sg_resource_state state = p->pipelines[i].slot.state;
if ((state == SG_RESOURCESTATE_VALID) || (state == SG_RESOURCESTATE_FAILED)) {
_sg_destroy_pipeline(&p->pipelines[i]);
}
}
}
for (int i = 1; i < p->pass_pool.size; i++) {
if (p->passes[i].slot.ctx_id == ctx_id) {
sg_resource_state state = p->passes[i].slot.state;
if ((state == SG_RESOURCESTATE_VALID) || (state == SG_RESOURCESTATE_FAILED)) {
_sg_destroy_pass(&p->passes[i]);
}
}
}
}
/*== VALIDATION LAYER ========================================================*/
#if defined(SOKOL_DEBUG)
/* return a human readable string for an _sg_validate_error */
_SOKOL_PRIVATE const char* _sg_validate_string(_sg_validate_error_t err) {
switch (err) {
/* buffer creation validation errors */
case _SG_VALIDATE_BUFFERDESC_CANARY: return "sg_buffer_desc not initialized";
case _SG_VALIDATE_BUFFERDESC_SIZE: return "sg_buffer_desc.size cannot be 0";
case _SG_VALIDATE_BUFFERDESC_CONTENT: return "immutable buffers must be initialized with content (sg_buffer_desc.content)";
case _SG_VALIDATE_BUFFERDESC_NO_CONTENT: return "dynamic/stream usage buffers cannot be initialized with content";
/* image creation validation errros */
case _SG_VALIDATE_IMAGEDESC_CANARY: return "sg_image_desc not initialized";
case _SG_VALIDATE_IMAGEDESC_WIDTH: return "sg_image_desc.width must be > 0";
case _SG_VALIDATE_IMAGEDESC_HEIGHT: return "sg_image_desc.height must be > 0";
case _SG_VALIDATE_IMAGEDESC_RT_PIXELFORMAT: return "invalid pixel format for render-target image";
case _SG_VALIDATE_IMAGEDESC_NONRT_PIXELFORMAT: return "invalid pixel format for non-render-target image";
case _SG_VALIDATE_IMAGEDESC_MSAA_BUT_NO_RT: return "non-render-target images cannot be multisampled";
case _SG_VALIDATE_IMAGEDESC_NO_MSAA_RT_SUPPORT: return "MSAA not supported for this pixel format";
case _SG_VALIDATE_IMAGEDESC_RT_IMMUTABLE: return "render target images must be SG_USAGE_IMMUTABLE";
case _SG_VALIDATE_IMAGEDESC_RT_NO_CONTENT: return "render target images cannot be initialized with content";
case _SG_VALIDATE_IMAGEDESC_CONTENT: return "missing or invalid content for immutable image";
case _SG_VALIDATE_IMAGEDESC_NO_CONTENT: return "dynamic/stream usage images cannot be initialized with content";
/* shader creation */
case _SG_VALIDATE_SHADERDESC_CANARY: return "sg_shader_desc not initialized";
case _SG_VALIDATE_SHADERDESC_SOURCE: return "shader source code required";
case _SG_VALIDATE_SHADERDESC_BYTECODE: return "shader byte code required";
case _SG_VALIDATE_SHADERDESC_SOURCE_OR_BYTECODE: return "shader source or byte code required";
case _SG_VALIDATE_SHADERDESC_NO_BYTECODE_SIZE: return "shader byte code length (in bytes) required";
case _SG_VALIDATE_SHADERDESC_NO_CONT_UBS: return "shader uniform blocks must occupy continuous slots";
case _SG_VALIDATE_SHADERDESC_NO_CONT_UB_MEMBERS: return "uniform block members must occupy continuous slots";
case _SG_VALIDATE_SHADERDESC_NO_UB_MEMBERS: return "GL backend requires uniform block member declarations";
case _SG_VALIDATE_SHADERDESC_UB_MEMBER_NAME: return "uniform block member name missing";
case _SG_VALIDATE_SHADERDESC_UB_SIZE_MISMATCH: return "size of uniform block members doesn't match uniform block size";
case _SG_VALIDATE_SHADERDESC_NO_CONT_IMGS: return "shader images must occupy continuous slots";
case _SG_VALIDATE_SHADERDESC_IMG_NAME: return "GL backend requires uniform block member names";
case _SG_VALIDATE_SHADERDESC_ATTR_NAMES: return "GLES2 backend requires vertex attribute names";
case _SG_VALIDATE_SHADERDESC_ATTR_SEMANTICS: return "D3D11 backend requires vertex attribute semantics";
case _SG_VALIDATE_SHADERDESC_ATTR_STRING_TOO_LONG: return "vertex attribute name/semantic string too long (max len 16)";
/* pipeline creation */
case _SG_VALIDATE_PIPELINEDESC_CANARY: return "sg_pipeline_desc not initialized";
case _SG_VALIDATE_PIPELINEDESC_SHADER: return "sg_pipeline_desc.shader missing or invalid";
case _SG_VALIDATE_PIPELINEDESC_NO_ATTRS: return "sg_pipeline_desc.layout.attrs is empty or not continuous";
case _SG_VALIDATE_PIPELINEDESC_LAYOUT_STRIDE4: return "sg_pipeline_desc.layout.buffers[].stride must be multiple of 4";
case _SG_VALIDATE_PIPELINEDESC_ATTR_NAME: return "GLES2/WebGL missing vertex attribute name in shader";
case _SG_VALIDATE_PIPELINEDESC_ATTR_SEMANTICS: return "D3D11 missing vertex attribute semantics in shader";
/* pass creation */
case _SG_VALIDATE_PASSDESC_CANARY: return "sg_pass_desc not initialized";
case _SG_VALIDATE_PASSDESC_NO_COLOR_ATTS: return "sg_pass_desc.color_attachments[0] must be valid";
case _SG_VALIDATE_PASSDESC_NO_CONT_COLOR_ATTS: return "color attachments must occupy continuous slots";
case _SG_VALIDATE_PASSDESC_IMAGE: return "pass attachment image is not valid";
case _SG_VALIDATE_PASSDESC_MIPLEVEL: return "pass attachment mip level is bigger than image has mipmaps";
case _SG_VALIDATE_PASSDESC_FACE: return "pass attachment image is cubemap, but face index is too big";
case _SG_VALIDATE_PASSDESC_LAYER: return "pass attachment image is array texture, but layer index is too big";
case _SG_VALIDATE_PASSDESC_SLICE: return "pass attachment image is 3d texture, but slice value is too big";
case _SG_VALIDATE_PASSDESC_IMAGE_NO_RT: return "pass attachment image must be render targets";
case _SG_VALIDATE_PASSDESC_COLOR_PIXELFORMATS: return "all pass color attachment images must have the same pixel format";
case _SG_VALIDATE_PASSDESC_COLOR_INV_PIXELFORMAT: return "pass color-attachment images must have a renderable pixel format";
case _SG_VALIDATE_PASSDESC_DEPTH_INV_PIXELFORMAT: return "pass depth-attachment image must have depth pixel format";
case _SG_VALIDATE_PASSDESC_IMAGE_SIZES: return "all pass attachments must have the same size";
case _SG_VALIDATE_PASSDESC_IMAGE_SAMPLE_COUNTS: return "all pass attachments must have the same sample count";
/* sg_begin_pass */
case _SG_VALIDATE_BEGINPASS_PASS: return "sg_begin_pass: pass must be valid";
case _SG_VALIDATE_BEGINPASS_IMAGE: return "sg_begin_pass: one or more attachment images are not valid";
/* sg_apply_pipeline */
case _SG_VALIDATE_APIP_PIPELINE_VALID_ID: return "sg_apply_pipeline: invalid pipeline id provided";
case _SG_VALIDATE_APIP_PIPELINE_EXISTS: return "sg_apply_pipeline: pipeline object no longer alive";
case _SG_VALIDATE_APIP_PIPELINE_VALID: return "sg_apply_pipeline: pipeline object not in valid state";
case _SG_VALIDATE_APIP_SHADER_EXISTS: return "sg_apply_pipeline: shader object no longer alive";
case _SG_VALIDATE_APIP_SHADER_VALID: return "sg_apply_pipeline: shader object not in valid state";
case _SG_VALIDATE_APIP_ATT_COUNT: return "sg_apply_pipeline: color_attachment_count in pipeline doesn't match number of pass color attachments";
case _SG_VALIDATE_APIP_COLOR_FORMAT: return "sg_apply_pipeline: color_format in pipeline doesn't match pass color attachment pixel format";
case _SG_VALIDATE_APIP_DEPTH_FORMAT: return "sg_apply_pipeline: depth_format in pipeline doesn't match pass depth attachment pixel format";
case _SG_VALIDATE_APIP_SAMPLE_COUNT: return "sg_apply_pipeline: MSAA sample count in pipeline doesn't match render pass attachment sample count";
/* sg_apply_bindings */
case _SG_VALIDATE_ABND_PIPELINE: return "sg_apply_bindings: must be called after sg_apply_pipeline";
case _SG_VALIDATE_ABND_PIPELINE_EXISTS: return "sg_apply_bindings: currently applied pipeline object no longer alive";
case _SG_VALIDATE_ABND_PIPELINE_VALID: return "sg_apply_bindings: currently applied pipeline object not in valid state";
case _SG_VALIDATE_ABND_VBS: return "sg_apply_bindings: number of vertex buffers doesn't match number of pipeline vertex layouts";
case _SG_VALIDATE_ABND_VB_EXISTS: return "sg_apply_bindings: vertex buffer no longer alive";
case _SG_VALIDATE_ABND_VB_TYPE: return "sg_apply_bindings: buffer in vertex buffer slot is not a SG_BUFFERTYPE_VERTEXBUFFER";
case _SG_VALIDATE_ABND_VB_OVERFLOW: return "sg_apply_bindings: buffer in vertex buffer slot is overflown";
case _SG_VALIDATE_ABND_NO_IB: return "sg_apply_bindings: pipeline object defines indexed rendering, but no index buffer provided";
case _SG_VALIDATE_ABND_IB: return "sg_apply_bindings: pipeline object defines non-indexed rendering, but index buffer provided";
case _SG_VALIDATE_ABND_IB_EXISTS: return "sg_apply_bindings: index buffer no longer alive";
case _SG_VALIDATE_ABND_IB_TYPE: return "sg_apply_bindings: buffer in index buffer slot is not a SG_BUFFERTYPE_INDEXBUFFER";
case _SG_VALIDATE_ABND_IB_OVERFLOW: return "sg_apply_bindings: buffer in index buffer slot is overflown";
case _SG_VALIDATE_ABND_VS_IMGS: return "sg_apply_bindings: vertex shader image count doesn't match sg_shader_desc";
case _SG_VALIDATE_ABND_VS_IMG_EXISTS: return "sg_apply_bindings: vertex shader image no longer alive";
case _SG_VALIDATE_ABND_VS_IMG_TYPES: return "sg_apply_bindings: one or more vertex shader image types don't match sg_shader_desc";
case _SG_VALIDATE_ABND_FS_IMGS: return "sg_apply_bindings: fragment shader image count doesn't match sg_shader_desc";
case _SG_VALIDATE_ABND_FS_IMG_EXISTS: return "sg_apply_bindings: fragment shader image no longer alive";
case _SG_VALIDATE_ABND_FS_IMG_TYPES: return "sg_apply_bindings: one or more fragment shader image types don't match sg_shader_desc";
/* sg_apply_uniforms */
case _SG_VALIDATE_AUB_NO_PIPELINE: return "sg_apply_uniforms: must be called after sg_apply_pipeline()";
case _SG_VALIDATE_AUB_NO_UB_AT_SLOT: return "sg_apply_uniforms: no uniform block declaration at this shader stage UB slot";
case _SG_VALIDATE_AUB_SIZE: return "sg_apply_uniforms: data size exceeds declared uniform block size";
/* sg_update_buffer */
case _SG_VALIDATE_UPDATEBUF_USAGE: return "sg_update_buffer: cannot update immutable buffer";
case _SG_VALIDATE_UPDATEBUF_SIZE: return "sg_update_buffer: update size is bigger than buffer size";
case _SG_VALIDATE_UPDATEBUF_ONCE: return "sg_update_buffer: only one update allowed per buffer and frame";
case _SG_VALIDATE_UPDATEBUF_APPEND: return "sg_update_buffer: cannot call sg_update_buffer and sg_append_buffer in same frame";
/* sg_append_buffer */
case _SG_VALIDATE_APPENDBUF_USAGE: return "sg_append_buffer: cannot append to immutable buffer";
case _SG_VALIDATE_APPENDBUF_SIZE: return "sg_append_buffer: overall appended size is bigger than buffer size";
case _SG_VALIDATE_APPENDBUF_UPDATE: return "sg_append_buffer: cannot call sg_append_buffer and sg_update_buffer in same frame";
/* sg_update_image */
case _SG_VALIDATE_UPDIMG_USAGE: return "sg_update_image: cannot update immutable image";
case _SG_VALIDATE_UPDIMG_NOTENOUGHDATA: return "sg_update_image: not enough subimage data provided";
case _SG_VALIDATE_UPDIMG_SIZE: return "sg_update_image: provided subimage data size too big";
case _SG_VALIDATE_UPDIMG_COMPRESSED: return "sg_update_image: cannot update images with compressed format";
case _SG_VALIDATE_UPDIMG_ONCE: return "sg_update_image: only one update allowed per image and frame";
default: return "unknown validation error";
}
}
#endif /* defined(SOKOL_DEBUG) */
/*-- validation checks -------------------------------------------------------*/
#if defined(SOKOL_DEBUG)
_SOKOL_PRIVATE void _sg_validate_begin(void) {
_sg.validate_error = _SG_VALIDATE_SUCCESS;
}
_SOKOL_PRIVATE void _sg_validate(bool cond, _sg_validate_error_t err) {
if (!cond) {
_sg.validate_error = err;
SOKOL_LOG(_sg_validate_string(err));
}
}
_SOKOL_PRIVATE bool _sg_validate_end(void) {
if (_sg.validate_error != _SG_VALIDATE_SUCCESS) {
#if !defined(SOKOL_VALIDATE_NON_FATAL)
SOKOL_LOG("^^^^ VALIDATION FAILED, TERMINATING ^^^^");
SOKOL_ASSERT(false);
#endif
return false;
}
else {
return true;
}
}
#endif
_SOKOL_PRIVATE bool _sg_validate_buffer_desc(const sg_buffer_desc* desc) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(desc);
return true;
#else
SOKOL_ASSERT(desc);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(desc->_start_canary == 0, _SG_VALIDATE_BUFFERDESC_CANARY);
SOKOL_VALIDATE(desc->_end_canary == 0, _SG_VALIDATE_BUFFERDESC_CANARY);
SOKOL_VALIDATE(desc->size > 0, _SG_VALIDATE_BUFFERDESC_SIZE);
bool ext = (0 != desc->gl_buffers[0]) || (0 != desc->mtl_buffers[0]) || (0 != desc->d3d11_buffer);
if (!ext && (desc->usage == SG_USAGE_IMMUTABLE)) {
SOKOL_VALIDATE(0 != desc->content, _SG_VALIDATE_BUFFERDESC_CONTENT);
}
else {
SOKOL_VALIDATE(0 == desc->content, _SG_VALIDATE_BUFFERDESC_NO_CONTENT);
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_image_desc(const sg_image_desc* desc) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(desc);
return true;
#else
SOKOL_ASSERT(desc);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(desc->_start_canary == 0, _SG_VALIDATE_IMAGEDESC_CANARY);
SOKOL_VALIDATE(desc->_end_canary == 0, _SG_VALIDATE_IMAGEDESC_CANARY);
SOKOL_VALIDATE(desc->width > 0, _SG_VALIDATE_IMAGEDESC_WIDTH);
SOKOL_VALIDATE(desc->height > 0, _SG_VALIDATE_IMAGEDESC_HEIGHT);
const sg_pixel_format fmt = desc->pixel_format;
const sg_usage usage = desc->usage;
const bool ext = (0 != desc->gl_textures[0]) || (0 != desc->mtl_textures[0]) || (0 != desc->d3d11_texture);
if (desc->render_target) {
SOKOL_ASSERT(((int)fmt >= 0) && ((int)fmt < _SG_PIXELFORMAT_NUM));
SOKOL_VALIDATE(_sg.formats[fmt].render, _SG_VALIDATE_IMAGEDESC_RT_PIXELFORMAT);
/* on GLES2, sample count for render targets is completely ignored */
#if defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
if (!_sg.gl.gles2) {
#endif
if (desc->sample_count > 1) {
SOKOL_VALIDATE(_sg.features.msaa_render_targets && _sg.formats[fmt].msaa, _SG_VALIDATE_IMAGEDESC_NO_MSAA_RT_SUPPORT);
}
#if defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
}
#endif
SOKOL_VALIDATE(usage == SG_USAGE_IMMUTABLE, _SG_VALIDATE_IMAGEDESC_RT_IMMUTABLE);
SOKOL_VALIDATE(desc->content.subimage[0][0].ptr==0, _SG_VALIDATE_IMAGEDESC_RT_NO_CONTENT);
}
else {
SOKOL_VALIDATE(desc->sample_count <= 1, _SG_VALIDATE_IMAGEDESC_MSAA_BUT_NO_RT);
const bool valid_nonrt_fmt = !_sg_is_valid_rendertarget_depth_format(fmt);
SOKOL_VALIDATE(valid_nonrt_fmt, _SG_VALIDATE_IMAGEDESC_NONRT_PIXELFORMAT);
/* FIXME: should use the same "expected size" computation as in _sg_validate_update_image() here */
if (!ext && (usage == SG_USAGE_IMMUTABLE)) {
const int num_faces = desc->type == SG_IMAGETYPE_CUBE ? 6:1;
const int num_mips = desc->num_mipmaps;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int mip_index = 0; mip_index < num_mips; mip_index++) {
const bool has_data = desc->content.subimage[face_index][mip_index].ptr != 0;
const bool has_size = desc->content.subimage[face_index][mip_index].size > 0;
SOKOL_VALIDATE(has_data && has_size, _SG_VALIDATE_IMAGEDESC_CONTENT);
}
}
}
else {
for (int face_index = 0; face_index < SG_CUBEFACE_NUM; face_index++) {
for (int mip_index = 0; mip_index < SG_MAX_MIPMAPS; mip_index++) {
const bool no_data = 0 == desc->content.subimage[face_index][mip_index].ptr;
const bool no_size = 0 == desc->content.subimage[face_index][mip_index].size;
SOKOL_VALIDATE(no_data && no_size, _SG_VALIDATE_IMAGEDESC_NO_CONTENT);
}
}
}
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_shader_desc(const sg_shader_desc* desc) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(desc);
return true;
#else
SOKOL_ASSERT(desc);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(desc->_start_canary == 0, _SG_VALIDATE_SHADERDESC_CANARY);
SOKOL_VALIDATE(desc->_end_canary == 0, _SG_VALIDATE_SHADERDESC_CANARY);
#if defined(SOKOL_GLES2)
SOKOL_VALIDATE(0 != desc->attrs[0].name, _SG_VALIDATE_SHADERDESC_ATTR_NAMES);
#elif defined(SOKOL_D3D11)
SOKOL_VALIDATE(0 != desc->attrs[0].sem_name, _SG_VALIDATE_SHADERDESC_ATTR_SEMANTICS);
#endif
#if defined(SOKOL_GLCORE33) || defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
/* on GL, must provide shader source code */
SOKOL_VALIDATE(0 != desc->vs.source, _SG_VALIDATE_SHADERDESC_SOURCE);
SOKOL_VALIDATE(0 != desc->fs.source, _SG_VALIDATE_SHADERDESC_SOURCE);
#elif defined(SOKOL_METAL) || defined(SOKOL_D3D11)
/* on Metal or D3D11, must provide shader source code or byte code */
SOKOL_VALIDATE((0 != desc->vs.source)||(0 != desc->vs.byte_code), _SG_VALIDATE_SHADERDESC_SOURCE_OR_BYTECODE);
SOKOL_VALIDATE((0 != desc->fs.source)||(0 != desc->fs.byte_code), _SG_VALIDATE_SHADERDESC_SOURCE_OR_BYTECODE);
#else
/* Dummy Backend, don't require source or bytecode */
#endif
for (int i = 0; i < SG_MAX_VERTEX_ATTRIBUTES; i++) {
if (desc->attrs[i].name) {
SOKOL_VALIDATE(strlen(desc->attrs[i].name) < _SG_STRING_SIZE, _SG_VALIDATE_SHADERDESC_ATTR_STRING_TOO_LONG);
}
if (desc->attrs[i].sem_name) {
SOKOL_VALIDATE(strlen(desc->attrs[i].sem_name) < _SG_STRING_SIZE, _SG_VALIDATE_SHADERDESC_ATTR_STRING_TOO_LONG);
}
}
/* if shader byte code, the size must also be provided */
if (0 != desc->vs.byte_code) {
SOKOL_VALIDATE(desc->vs.byte_code_size > 0, _SG_VALIDATE_SHADERDESC_NO_BYTECODE_SIZE);
}
if (0 != desc->fs.byte_code) {
SOKOL_VALIDATE(desc->fs.byte_code_size > 0, _SG_VALIDATE_SHADERDESC_NO_BYTECODE_SIZE);
}
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
const sg_shader_stage_desc* stage_desc = (stage_index == 0)? &desc->vs : &desc->fs;
bool uniform_blocks_continuous = true;
for (int ub_index = 0; ub_index < SG_MAX_SHADERSTAGE_UBS; ub_index++) {
const sg_shader_uniform_block_desc* ub_desc = &stage_desc->uniform_blocks[ub_index];
if (ub_desc->size > 0) {
SOKOL_VALIDATE(uniform_blocks_continuous, _SG_VALIDATE_SHADERDESC_NO_CONT_UBS);
bool uniforms_continuous = true;
int uniform_offset = 0;
int num_uniforms = 0;
for (int u_index = 0; u_index < SG_MAX_UB_MEMBERS; u_index++) {
const sg_shader_uniform_desc* u_desc = &ub_desc->uniforms[u_index];
if (u_desc->type != SG_UNIFORMTYPE_INVALID) {
SOKOL_VALIDATE(uniforms_continuous, _SG_VALIDATE_SHADERDESC_NO_CONT_UB_MEMBERS);
#if defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
SOKOL_VALIDATE(u_desc->name, _SG_VALIDATE_SHADERDESC_UB_MEMBER_NAME);
#endif
const int array_count = u_desc->array_count;
uniform_offset += _sg_uniform_size(u_desc->type, array_count);
num_uniforms++;
}
else {
uniforms_continuous = false;
}
}
#if defined(SOKOL_GLCORE33) || defined(SOKOL_GLES2) || defined(SOKOL_GLES3)
SOKOL_VALIDATE(uniform_offset == ub_desc->size, _SG_VALIDATE_SHADERDESC_UB_SIZE_MISMATCH);
SOKOL_VALIDATE(num_uniforms > 0, _SG_VALIDATE_SHADERDESC_NO_UB_MEMBERS);
#endif
}
else {
uniform_blocks_continuous = false;
}
}
bool images_continuous = true;
for (int img_index = 0; img_index < SG_MAX_SHADERSTAGE_IMAGES; img_index++) {
const sg_shader_image_desc* img_desc = &stage_desc->images[img_index];
if (img_desc->type != _SG_IMAGETYPE_DEFAULT) {
SOKOL_VALIDATE(images_continuous, _SG_VALIDATE_SHADERDESC_NO_CONT_IMGS);
#if defined(SOKOL_GLES2)
SOKOL_VALIDATE(img_desc->name, _SG_VALIDATE_SHADERDESC_IMG_NAME);
#endif
}
else {
images_continuous = false;
}
}
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_pipeline_desc(const sg_pipeline_desc* desc) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(desc);
return true;
#else
SOKOL_ASSERT(desc);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(desc->_start_canary == 0, _SG_VALIDATE_PIPELINEDESC_CANARY);
SOKOL_VALIDATE(desc->_end_canary == 0, _SG_VALIDATE_PIPELINEDESC_CANARY);
SOKOL_VALIDATE(desc->shader.id != SG_INVALID_ID, _SG_VALIDATE_PIPELINEDESC_SHADER);
const _sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, desc->shader.id);
SOKOL_VALIDATE(shd && shd->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_PIPELINEDESC_SHADER);
for (int buf_index = 0; buf_index < SG_MAX_SHADERSTAGE_BUFFERS; buf_index++) {
const sg_buffer_layout_desc* l_desc = &desc->layout.buffers[buf_index];
if (l_desc->stride == 0) {
continue;
}
SOKOL_VALIDATE((l_desc->stride & 3) == 0, _SG_VALIDATE_PIPELINEDESC_LAYOUT_STRIDE4);
}
SOKOL_VALIDATE(desc->layout.attrs[0].format != SG_VERTEXFORMAT_INVALID, _SG_VALIDATE_PIPELINEDESC_NO_ATTRS);
bool attrs_cont = true;
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
const sg_vertex_attr_desc* a_desc = &desc->layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
attrs_cont = false;
continue;
}
SOKOL_VALIDATE(attrs_cont, _SG_VALIDATE_PIPELINEDESC_NO_ATTRS);
SOKOL_ASSERT(a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS);
#if defined(SOKOL_GLES2)
/* on GLES2, vertex attribute names must be provided */
SOKOL_VALIDATE(!_sg_strempty(&shd->attrs[attr_index].name), _SG_VALIDATE_PIPELINEDESC_ATTR_NAME);
#elif defined(SOKOL_D3D11)
/* on D3D11, semantic names (and semantic indices) must be provided */
SOKOL_VALIDATE(!_sg_strempty(&shd->attrs[attr_index].sem_name), _SG_VALIDATE_PIPELINEDESC_ATTR_SEMANTICS);
#endif
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_pass_desc(const sg_pass_desc* desc) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(desc);
return true;
#else
SOKOL_ASSERT(desc);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(desc->_start_canary == 0, _SG_VALIDATE_PASSDESC_CANARY);
SOKOL_VALIDATE(desc->_end_canary == 0, _SG_VALIDATE_PASSDESC_CANARY);
bool atts_cont = true;
sg_pixel_format color_fmt = SG_PIXELFORMAT_NONE;
int width = -1, height = -1, sample_count = -1;
for (int att_index = 0; att_index < SG_MAX_COLOR_ATTACHMENTS; att_index++) {
const sg_attachment_desc* att = &desc->color_attachments[att_index];
if (att->image.id == SG_INVALID_ID) {
SOKOL_VALIDATE(att_index > 0, _SG_VALIDATE_PASSDESC_NO_COLOR_ATTS);
atts_cont = false;
continue;
}
SOKOL_VALIDATE(atts_cont, _SG_VALIDATE_PASSDESC_NO_CONT_COLOR_ATTS);
const _sg_image_t* img = _sg_lookup_image(&_sg.pools, att->image.id);
SOKOL_VALIDATE(img && img->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_PASSDESC_IMAGE);
SOKOL_VALIDATE(att->mip_level < img->num_mipmaps, _SG_VALIDATE_PASSDESC_MIPLEVEL);
if (img->type == SG_IMAGETYPE_CUBE) {
SOKOL_VALIDATE(att->face < 6, _SG_VALIDATE_PASSDESC_FACE);
}
else if (img->type == SG_IMAGETYPE_ARRAY) {
SOKOL_VALIDATE(att->layer < img->depth, _SG_VALIDATE_PASSDESC_LAYER);
}
else if (img->type == SG_IMAGETYPE_3D) {
SOKOL_VALIDATE(att->slice < img->depth, _SG_VALIDATE_PASSDESC_SLICE);
}
SOKOL_VALIDATE(img->render_target, _SG_VALIDATE_PASSDESC_IMAGE_NO_RT);
if (att_index == 0) {
color_fmt = img->pixel_format;
width = img->width >> att->mip_level;
height = img->height >> att->mip_level;
sample_count = img->sample_count;
}
else {
SOKOL_VALIDATE(img->pixel_format == color_fmt, _SG_VALIDATE_PASSDESC_COLOR_PIXELFORMATS);
SOKOL_VALIDATE(width == img->width >> att->mip_level, _SG_VALIDATE_PASSDESC_IMAGE_SIZES);
SOKOL_VALIDATE(height == img->height >> att->mip_level, _SG_VALIDATE_PASSDESC_IMAGE_SIZES);
SOKOL_VALIDATE(sample_count == img->sample_count, _SG_VALIDATE_PASSDESC_IMAGE_SAMPLE_COUNTS);
}
SOKOL_VALIDATE(_sg_is_valid_rendertarget_color_format(img->pixel_format), _SG_VALIDATE_PASSDESC_COLOR_INV_PIXELFORMAT);
}
if (desc->depth_stencil_attachment.image.id != SG_INVALID_ID) {
const sg_attachment_desc* att = &desc->depth_stencil_attachment;
const _sg_image_t* img = _sg_lookup_image(&_sg.pools, att->image.id);
SOKOL_VALIDATE(img && img->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_PASSDESC_IMAGE);
SOKOL_VALIDATE(att->mip_level < img->num_mipmaps, _SG_VALIDATE_PASSDESC_MIPLEVEL);
if (img->type == SG_IMAGETYPE_CUBE) {
SOKOL_VALIDATE(att->face < 6, _SG_VALIDATE_PASSDESC_FACE);
}
else if (img->type == SG_IMAGETYPE_ARRAY) {
SOKOL_VALIDATE(att->layer < img->depth, _SG_VALIDATE_PASSDESC_LAYER);
}
else if (img->type == SG_IMAGETYPE_3D) {
SOKOL_VALIDATE(att->slice < img->depth, _SG_VALIDATE_PASSDESC_SLICE);
}
SOKOL_VALIDATE(img->render_target, _SG_VALIDATE_PASSDESC_IMAGE_NO_RT);
SOKOL_VALIDATE(width == img->width >> att->mip_level, _SG_VALIDATE_PASSDESC_IMAGE_SIZES);
SOKOL_VALIDATE(height == img->height >> att->mip_level, _SG_VALIDATE_PASSDESC_IMAGE_SIZES);
SOKOL_VALIDATE(sample_count == img->sample_count, _SG_VALIDATE_PASSDESC_IMAGE_SAMPLE_COUNTS);
SOKOL_VALIDATE(_sg_is_valid_rendertarget_depth_format(img->pixel_format), _SG_VALIDATE_PASSDESC_DEPTH_INV_PIXELFORMAT);
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_begin_pass(_sg_pass_t* pass) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(pass);
return true;
#else
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(pass->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_BEGINPASS_PASS);
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
const _sg_attachment_t* att = &pass->color_atts[i];
if (att->image) {
SOKOL_VALIDATE(att->image->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_BEGINPASS_IMAGE);
SOKOL_VALIDATE(att->image->slot.id == att->image_id.id, _SG_VALIDATE_BEGINPASS_IMAGE);
}
}
if (pass->ds_att.image) {
const _sg_attachment_t* att = &pass->ds_att;
SOKOL_VALIDATE(att->image->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_BEGINPASS_IMAGE);
SOKOL_VALIDATE(att->image->slot.id == att->image_id.id, _SG_VALIDATE_BEGINPASS_IMAGE);
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_apply_pipeline(sg_pipeline pip_id) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(pip_id);
return true;
#else
SOKOL_VALIDATE_BEGIN();
/* the pipeline object must be alive and valid */
SOKOL_VALIDATE(pip_id.id != SG_INVALID_ID, _SG_VALIDATE_APIP_PIPELINE_VALID_ID);
const _sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
SOKOL_VALIDATE(pip != 0, _SG_VALIDATE_APIP_PIPELINE_EXISTS);
if (!pip) {
return SOKOL_VALIDATE_END();
}
SOKOL_VALIDATE(pip->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_APIP_PIPELINE_VALID);
/* the pipeline's shader must be alive and valid */
SOKOL_ASSERT(pip->shader);
SOKOL_VALIDATE(pip->shader->slot.id == pip->shader_id.id, _SG_VALIDATE_APIP_SHADER_EXISTS);
SOKOL_VALIDATE(pip->shader->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_APIP_SHADER_VALID);
/* check that pipeline attributes match current pass attributes */
const _sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, _sg.cur_pass.id);
if (pass) {
/* an offscreen pass */
SOKOL_VALIDATE(pip->color_attachment_count == pass->num_color_atts, _SG_VALIDATE_APIP_ATT_COUNT);
SOKOL_VALIDATE(pip->color_format == pass->color_atts[0].image->pixel_format, _SG_VALIDATE_APIP_COLOR_FORMAT);
SOKOL_VALIDATE(pip->sample_count == pass->color_atts[0].image->sample_count, _SG_VALIDATE_APIP_SAMPLE_COUNT);
if (pass->ds_att.image) {
SOKOL_VALIDATE(pip->depth_format == pass->ds_att.image->pixel_format, _SG_VALIDATE_APIP_DEPTH_FORMAT);
}
else {
SOKOL_VALIDATE(pip->depth_format == SG_PIXELFORMAT_NONE, _SG_VALIDATE_APIP_DEPTH_FORMAT);
}
}
else {
/* default pass */
SOKOL_VALIDATE(pip->color_attachment_count == 1, _SG_VALIDATE_APIP_ATT_COUNT);
SOKOL_VALIDATE(pip->color_format == _sg_default_rendertarget_colorformat(), _SG_VALIDATE_APIP_COLOR_FORMAT);
SOKOL_VALIDATE(pip->depth_format == _sg_default_rendertarget_depthformat(), _SG_VALIDATE_APIP_DEPTH_FORMAT);
/* FIXME: hmm, we don't know if the default framebuffer is multisampled here */
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_apply_bindings(const sg_bindings* bindings) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(bindings);
return true;
#else
SOKOL_VALIDATE_BEGIN();
/* a pipeline object must have been applied */
SOKOL_VALIDATE(_sg.cur_pipeline.id != SG_INVALID_ID, _SG_VALIDATE_ABND_PIPELINE);
const _sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, _sg.cur_pipeline.id);
SOKOL_VALIDATE(pip != 0, _SG_VALIDATE_ABND_PIPELINE_EXISTS);
if (!pip) {
return SOKOL_VALIDATE_END();
}
SOKOL_VALIDATE(pip->slot.state == SG_RESOURCESTATE_VALID, _SG_VALIDATE_ABND_PIPELINE_VALID);
SOKOL_ASSERT(pip->shader);
/* has expected vertex buffers, and vertex buffers still exist */
for (int i = 0; i < SG_MAX_SHADERSTAGE_BUFFERS; i++) {
if (bindings->vertex_buffers[i].id != SG_INVALID_ID) {
SOKOL_VALIDATE(pip->vertex_layout_valid[i], _SG_VALIDATE_ABND_VBS);
/* buffers in vertex-buffer-slots must be of type SG_BUFFERTYPE_VERTEXBUFFER */
const _sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, bindings->vertex_buffers[i].id);
SOKOL_VALIDATE(buf != 0, _SG_VALIDATE_ABND_VB_EXISTS);
if (buf && buf->slot.state == SG_RESOURCESTATE_VALID) {
SOKOL_VALIDATE(SG_BUFFERTYPE_VERTEXBUFFER == buf->type, _SG_VALIDATE_ABND_VB_TYPE);
SOKOL_VALIDATE(!buf->append_overflow, _SG_VALIDATE_ABND_VB_OVERFLOW);
}
}
else {
/* vertex buffer provided in a slot which has no vertex layout in pipeline */
SOKOL_VALIDATE(!pip->vertex_layout_valid[i], _SG_VALIDATE_ABND_VBS);
}
}
/* index buffer expected or not, and index buffer still exists */
if (pip->index_type == SG_INDEXTYPE_NONE) {
/* pipeline defines non-indexed rendering, but index buffer provided */
SOKOL_VALIDATE(bindings->index_buffer.id == SG_INVALID_ID, _SG_VALIDATE_ABND_IB);
}
else {
/* pipeline defines indexed rendering, but no index buffer provided */
SOKOL_VALIDATE(bindings->index_buffer.id != SG_INVALID_ID, _SG_VALIDATE_ABND_NO_IB);
}
if (bindings->index_buffer.id != SG_INVALID_ID) {
/* buffer in index-buffer-slot must be of type SG_BUFFERTYPE_INDEXBUFFER */
const _sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, bindings->index_buffer.id);
SOKOL_VALIDATE(buf != 0, _SG_VALIDATE_ABND_IB_EXISTS);
if (buf && buf->slot.state == SG_RESOURCESTATE_VALID) {
SOKOL_VALIDATE(SG_BUFFERTYPE_INDEXBUFFER == buf->type, _SG_VALIDATE_ABND_IB_TYPE);
SOKOL_VALIDATE(!buf->append_overflow, _SG_VALIDATE_ABND_IB_OVERFLOW);
}
}
/* has expected vertex shader images */
for (int i = 0; i < SG_MAX_SHADERSTAGE_IMAGES; i++) {
_sg_shader_stage_t* stage = &pip->shader->stage[SG_SHADERSTAGE_VS];
if (bindings->vs_images[i].id != SG_INVALID_ID) {
SOKOL_VALIDATE(i < stage->num_images, _SG_VALIDATE_ABND_VS_IMGS);
const _sg_image_t* img = _sg_lookup_image(&_sg.pools, bindings->vs_images[i].id);
SOKOL_VALIDATE(img != 0, _SG_VALIDATE_ABND_VS_IMG_EXISTS);
if (img && img->slot.state == SG_RESOURCESTATE_VALID) {
SOKOL_VALIDATE(img->type == stage->images[i].type, _SG_VALIDATE_ABND_VS_IMG_TYPES);
}
}
else {
SOKOL_VALIDATE(i >= stage->num_images, _SG_VALIDATE_ABND_VS_IMGS);
}
}
/* has expected fragment shader images */
for (int i = 0; i < SG_MAX_SHADERSTAGE_IMAGES; i++) {
_sg_shader_stage_t* stage = &pip->shader->stage[SG_SHADERSTAGE_FS];
if (bindings->fs_images[i].id != SG_INVALID_ID) {
SOKOL_VALIDATE(i < stage->num_images, _SG_VALIDATE_ABND_FS_IMGS);
const _sg_image_t* img = _sg_lookup_image(&_sg.pools, bindings->fs_images[i].id);
SOKOL_VALIDATE(img != 0, _SG_VALIDATE_ABND_FS_IMG_EXISTS);
if (img && img->slot.state == SG_RESOURCESTATE_VALID) {
SOKOL_VALIDATE(img->type == stage->images[i].type, _SG_VALIDATE_ABND_FS_IMG_TYPES);
}
}
else {
SOKOL_VALIDATE(i >= stage->num_images, _SG_VALIDATE_ABND_FS_IMGS);
}
}
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_apply_uniforms(sg_shader_stage stage_index, int ub_index, const void* data, int num_bytes) {
_SOKOL_UNUSED(data);
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(stage_index);
_SOKOL_UNUSED(ub_index);
_SOKOL_UNUSED(num_bytes);
return true;
#else
SOKOL_ASSERT((stage_index == SG_SHADERSTAGE_VS) || (stage_index == SG_SHADERSTAGE_FS));
SOKOL_ASSERT((ub_index >= 0) && (ub_index < SG_MAX_SHADERSTAGE_UBS));
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(_sg.cur_pipeline.id != SG_INVALID_ID, _SG_VALIDATE_AUB_NO_PIPELINE);
const _sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, _sg.cur_pipeline.id);
SOKOL_ASSERT(pip && (pip->slot.id == _sg.cur_pipeline.id));
SOKOL_ASSERT(pip->shader && (pip->shader->slot.id == pip->shader_id.id));
/* check that there is a uniform block at 'stage' and 'ub_index' */
const _sg_shader_stage_t* stage = &pip->shader->stage[stage_index];
SOKOL_VALIDATE(ub_index < stage->num_uniform_blocks, _SG_VALIDATE_AUB_NO_UB_AT_SLOT);
/* check that the provided data size doesn't exceed the uniform block size */
SOKOL_VALIDATE(num_bytes <= stage->uniform_blocks[ub_index].size, _SG_VALIDATE_AUB_SIZE);
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_update_buffer(const _sg_buffer_t* buf, const void* data, int size) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(buf);
_SOKOL_UNUSED(data);
_SOKOL_UNUSED(size);
return true;
#else
SOKOL_ASSERT(buf && data);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(buf->usage != SG_USAGE_IMMUTABLE, _SG_VALIDATE_UPDATEBUF_USAGE);
SOKOL_VALIDATE(buf->size >= size, _SG_VALIDATE_UPDATEBUF_SIZE);
SOKOL_VALIDATE(buf->update_frame_index != _sg.frame_index, _SG_VALIDATE_UPDATEBUF_ONCE);
SOKOL_VALIDATE(buf->append_frame_index != _sg.frame_index, _SG_VALIDATE_UPDATEBUF_APPEND);
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_append_buffer(const _sg_buffer_t* buf, const void* data, int size) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(buf);
_SOKOL_UNUSED(data);
_SOKOL_UNUSED(size);
return true;
#else
SOKOL_ASSERT(buf && data);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(buf->usage != SG_USAGE_IMMUTABLE, _SG_VALIDATE_APPENDBUF_USAGE);
SOKOL_VALIDATE(buf->size >= (buf->append_pos+size), _SG_VALIDATE_APPENDBUF_SIZE);
SOKOL_VALIDATE(buf->update_frame_index != _sg.frame_index, _SG_VALIDATE_APPENDBUF_UPDATE);
return SOKOL_VALIDATE_END();
#endif
}
_SOKOL_PRIVATE bool _sg_validate_update_image(const _sg_image_t* img, const sg_image_content* data) {
#if !defined(SOKOL_DEBUG)
_SOKOL_UNUSED(img);
_SOKOL_UNUSED(data);
return true;
#else
SOKOL_ASSERT(img && data);
SOKOL_VALIDATE_BEGIN();
SOKOL_VALIDATE(img->usage != SG_USAGE_IMMUTABLE, _SG_VALIDATE_UPDIMG_USAGE);
SOKOL_VALIDATE(img->upd_frame_index != _sg.frame_index, _SG_VALIDATE_UPDIMG_ONCE);
SOKOL_VALIDATE(!_sg_is_compressed_pixel_format(img->pixel_format), _SG_VALIDATE_UPDIMG_COMPRESSED);
const int num_faces = (img->type == SG_IMAGETYPE_CUBE) ? 6 : 1;
const int num_mips = img->num_mipmaps;
for (int face_index = 0; face_index < num_faces; face_index++) {
for (int mip_index = 0; mip_index < num_mips; mip_index++) {
SOKOL_VALIDATE(0 != data->subimage[face_index][mip_index].ptr, _SG_VALIDATE_UPDIMG_NOTENOUGHDATA);
const int mip_width = _sg_max(img->width >> mip_index, 1);
const int mip_height = _sg_max(img->height >> mip_index, 1);
const int bytes_per_slice = _sg_surface_pitch(img->pixel_format, mip_width, mip_height);
const int expected_size = bytes_per_slice * img->depth;
SOKOL_VALIDATE(data->subimage[face_index][mip_index].size <= expected_size, _SG_VALIDATE_UPDIMG_SIZE);
}
}
return SOKOL_VALIDATE_END();
#endif
}
/*== fill in desc default values =============================================*/
_SOKOL_PRIVATE sg_buffer_desc _sg_buffer_desc_defaults(const sg_buffer_desc* desc) {
sg_buffer_desc def = *desc;
def.type = _sg_def(def.type, SG_BUFFERTYPE_VERTEXBUFFER);
def.usage = _sg_def(def.usage, SG_USAGE_IMMUTABLE);
return def;
}
_SOKOL_PRIVATE sg_image_desc _sg_image_desc_defaults(const sg_image_desc* desc) {
sg_image_desc def = *desc;
def.type = _sg_def(def.type, SG_IMAGETYPE_2D);
def.depth = _sg_def(def.depth, 1);
def.num_mipmaps = _sg_def(def.num_mipmaps, 1);
def.usage = _sg_def(def.usage, SG_USAGE_IMMUTABLE);
if (desc->render_target) {
def.pixel_format = _sg_def(def.pixel_format, _sg_default_rendertarget_colorformat());
}
else {
def.pixel_format = _sg_def(def.pixel_format, SG_PIXELFORMAT_RGBA8);
}
def.sample_count = _sg_def(def.sample_count, 1);
def.min_filter = _sg_def(def.min_filter, SG_FILTER_NEAREST);
def.mag_filter = _sg_def(def.mag_filter, SG_FILTER_NEAREST);
def.wrap_u = _sg_def(def.wrap_u, SG_WRAP_REPEAT);
def.wrap_v = _sg_def(def.wrap_v, SG_WRAP_REPEAT);
def.wrap_w = _sg_def(def.wrap_w, SG_WRAP_REPEAT);
def.border_color = _sg_def(def.border_color, SG_BORDERCOLOR_OPAQUE_BLACK);
def.max_anisotropy = _sg_def(def.max_anisotropy, 1);
def.max_lod = _sg_def_flt(def.max_lod, FLT_MAX);
return def;
}
_SOKOL_PRIVATE sg_shader_desc _sg_shader_desc_defaults(const sg_shader_desc* desc) {
sg_shader_desc def = *desc;
#if defined(SOKOL_METAL)
def.vs.entry = _sg_def(def.vs.entry, "_main");
def.fs.entry = _sg_def(def.fs.entry, "_main");
#else
def.vs.entry = _sg_def(def.vs.entry, "main");
def.fs.entry = _sg_def(def.fs.entry, "main");
#endif
for (int stage_index = 0; stage_index < SG_NUM_SHADER_STAGES; stage_index++) {
sg_shader_stage_desc* stage_desc = (stage_index == SG_SHADERSTAGE_VS)? &def.vs : &def.fs;
for (int ub_index = 0; ub_index < SG_MAX_SHADERSTAGE_UBS; ub_index++) {
sg_shader_uniform_block_desc* ub_desc = &stage_desc->uniform_blocks[ub_index];
if (0 == ub_desc->size) {
break;
}
for (int u_index = 0; u_index < SG_MAX_UB_MEMBERS; u_index++) {
sg_shader_uniform_desc* u_desc = &ub_desc->uniforms[u_index];
if (u_desc->type == SG_UNIFORMTYPE_INVALID) {
break;
}
u_desc->array_count = _sg_def(u_desc->array_count, 1);
}
}
}
return def;
}
_SOKOL_PRIVATE sg_pipeline_desc _sg_pipeline_desc_defaults(const sg_pipeline_desc* desc) {
sg_pipeline_desc def = *desc;
def.primitive_type = _sg_def(def.primitive_type, SG_PRIMITIVETYPE_TRIANGLES);
def.index_type = _sg_def(def.index_type, SG_INDEXTYPE_NONE);
def.depth_stencil.stencil_front.fail_op = _sg_def(def.depth_stencil.stencil_front.fail_op, SG_STENCILOP_KEEP);
def.depth_stencil.stencil_front.depth_fail_op = _sg_def(def.depth_stencil.stencil_front.depth_fail_op, SG_STENCILOP_KEEP);
def.depth_stencil.stencil_front.pass_op = _sg_def(def.depth_stencil.stencil_front.pass_op, SG_STENCILOP_KEEP);
def.depth_stencil.stencil_front.compare_func = _sg_def(def.depth_stencil.stencil_front.compare_func, SG_COMPAREFUNC_ALWAYS);
def.depth_stencil.stencil_back.fail_op = _sg_def(def.depth_stencil.stencil_back.fail_op, SG_STENCILOP_KEEP);
def.depth_stencil.stencil_back.depth_fail_op = _sg_def(def.depth_stencil.stencil_back.depth_fail_op, SG_STENCILOP_KEEP);
def.depth_stencil.stencil_back.pass_op = _sg_def(def.depth_stencil.stencil_back.pass_op, SG_STENCILOP_KEEP);
def.depth_stencil.stencil_back.compare_func = _sg_def(def.depth_stencil.stencil_back.compare_func, SG_COMPAREFUNC_ALWAYS);
def.depth_stencil.depth_compare_func = _sg_def(def.depth_stencil.depth_compare_func, SG_COMPAREFUNC_ALWAYS);
def.blend.src_factor_rgb = _sg_def(def.blend.src_factor_rgb, SG_BLENDFACTOR_ONE);
def.blend.dst_factor_rgb = _sg_def(def.blend.dst_factor_rgb, SG_BLENDFACTOR_ZERO);
def.blend.op_rgb = _sg_def(def.blend.op_rgb, SG_BLENDOP_ADD);
def.blend.src_factor_alpha = _sg_def(def.blend.src_factor_alpha, SG_BLENDFACTOR_ONE);
def.blend.dst_factor_alpha = _sg_def(def.blend.dst_factor_alpha, SG_BLENDFACTOR_ZERO);
def.blend.op_alpha = _sg_def(def.blend.op_alpha, SG_BLENDOP_ADD);
if (def.blend.color_write_mask == SG_COLORMASK_NONE) {
def.blend.color_write_mask = 0;
}
else {
def.blend.color_write_mask = (uint8_t) _sg_def((sg_color_mask)def.blend.color_write_mask, SG_COLORMASK_RGBA);
}
def.blend.color_attachment_count = _sg_def(def.blend.color_attachment_count, 1);
def.blend.color_format = _sg_def(def.blend.color_format, _sg_default_rendertarget_colorformat());
def.blend.depth_format = _sg_def(def.blend.depth_format, _sg_default_rendertarget_depthformat());
def.rasterizer.cull_mode = _sg_def(def.rasterizer.cull_mode, SG_CULLMODE_NONE);
def.rasterizer.face_winding = _sg_def(def.rasterizer.face_winding, SG_FACEWINDING_CW);
def.rasterizer.sample_count = _sg_def(def.rasterizer.sample_count, 1);
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
sg_vertex_attr_desc* a_desc = &def.layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
break;
}
SOKOL_ASSERT((a_desc->buffer_index >= 0) && (a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS));
sg_buffer_layout_desc* b_desc = &def.layout.buffers[a_desc->buffer_index];
b_desc->step_func = _sg_def(b_desc->step_func, SG_VERTEXSTEP_PER_VERTEX);
b_desc->step_rate = _sg_def(b_desc->step_rate, 1);
}
/* resolve vertex layout strides and offsets */
int auto_offset[SG_MAX_SHADERSTAGE_BUFFERS];
memset(auto_offset, 0, sizeof(auto_offset));
bool use_auto_offset = true;
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
/* to use computed offsets, *all* attr offsets must be 0 */
if (def.layout.attrs[attr_index].offset != 0) {
use_auto_offset = false;
}
}
for (int attr_index = 0; attr_index < SG_MAX_VERTEX_ATTRIBUTES; attr_index++) {
sg_vertex_attr_desc* a_desc = &def.layout.attrs[attr_index];
if (a_desc->format == SG_VERTEXFORMAT_INVALID) {
break;
}
SOKOL_ASSERT((a_desc->buffer_index >= 0) && (a_desc->buffer_index < SG_MAX_SHADERSTAGE_BUFFERS));
if (use_auto_offset) {
a_desc->offset = auto_offset[a_desc->buffer_index];
}
auto_offset[a_desc->buffer_index] += _sg_vertexformat_bytesize(a_desc->format);
}
/* compute vertex strides if needed */
for (int buf_index = 0; buf_index < SG_MAX_SHADERSTAGE_BUFFERS; buf_index++) {
sg_buffer_layout_desc* l_desc = &def.layout.buffers[buf_index];
if (l_desc->stride == 0) {
l_desc->stride = auto_offset[buf_index];
}
}
return def;
}
_SOKOL_PRIVATE sg_pass_desc _sg_pass_desc_defaults(const sg_pass_desc* desc) {
/* FIXME: no values to replace in sg_pass_desc? */
sg_pass_desc def = *desc;
return def;
}
/*== allocate/initialize resource private functions ==========================*/
_SOKOL_PRIVATE sg_buffer _sg_alloc_buffer(void) {
sg_buffer res;
int slot_index = _sg_pool_alloc_index(&_sg.pools.buffer_pool);
if (_SG_INVALID_SLOT_INDEX != slot_index) {
res.id = _sg_slot_alloc(&_sg.pools.buffer_pool, &_sg.pools.buffers[slot_index].slot, slot_index);
}
else {
/* pool is exhausted */
res.id = SG_INVALID_ID;
}
return res;
}
_SOKOL_PRIVATE sg_image _sg_alloc_image(void) {
sg_image res;
int slot_index = _sg_pool_alloc_index(&_sg.pools.image_pool);
if (_SG_INVALID_SLOT_INDEX != slot_index) {
res.id = _sg_slot_alloc(&_sg.pools.image_pool, &_sg.pools.images[slot_index].slot, slot_index);
}
else {
/* pool is exhausted */
res.id = SG_INVALID_ID;
}
return res;
}
_SOKOL_PRIVATE sg_shader _sg_alloc_shader(void) {
sg_shader res;
int slot_index = _sg_pool_alloc_index(&_sg.pools.shader_pool);
if (_SG_INVALID_SLOT_INDEX != slot_index) {
res.id = _sg_slot_alloc(&_sg.pools.shader_pool, &_sg.pools.shaders[slot_index].slot, slot_index);
}
else {
/* pool is exhausted */
res.id = SG_INVALID_ID;
}
return res;
}
_SOKOL_PRIVATE sg_pipeline _sg_alloc_pipeline(void) {
sg_pipeline res;
int slot_index = _sg_pool_alloc_index(&_sg.pools.pipeline_pool);
if (_SG_INVALID_SLOT_INDEX != slot_index) {
res.id =_sg_slot_alloc(&_sg.pools.pipeline_pool, &_sg.pools.pipelines[slot_index].slot, slot_index);
}
else {
/* pool is exhausted */
res.id = SG_INVALID_ID;
}
return res;
}
_SOKOL_PRIVATE sg_pass _sg_alloc_pass(void) {
sg_pass res;
int slot_index = _sg_pool_alloc_index(&_sg.pools.pass_pool);
if (_SG_INVALID_SLOT_INDEX != slot_index) {
res.id = _sg_slot_alloc(&_sg.pools.pass_pool, &_sg.pools.passes[slot_index].slot, slot_index);
}
else {
/* pool is exhausted */
res.id = SG_INVALID_ID;
}
return res;
}
_SOKOL_PRIVATE void _sg_init_buffer(sg_buffer buf_id, const sg_buffer_desc* desc) {
SOKOL_ASSERT(buf_id.id != SG_INVALID_ID && desc);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
SOKOL_ASSERT(buf && buf->slot.state == SG_RESOURCESTATE_ALLOC);
buf->slot.ctx_id = _sg.active_context.id;
if (_sg_validate_buffer_desc(desc)) {
buf->slot.state = _sg_create_buffer(buf, desc);
}
else {
buf->slot.state = SG_RESOURCESTATE_FAILED;
}
SOKOL_ASSERT((buf->slot.state == SG_RESOURCESTATE_VALID)||(buf->slot.state == SG_RESOURCESTATE_FAILED));
}
_SOKOL_PRIVATE void _sg_init_image(sg_image img_id, const sg_image_desc* desc) {
SOKOL_ASSERT(img_id.id != SG_INVALID_ID && desc);
_sg_image_t* img = _sg_lookup_image(&_sg.pools, img_id.id);
SOKOL_ASSERT(img && img->slot.state == SG_RESOURCESTATE_ALLOC);
img->slot.ctx_id = _sg.active_context.id;
if (_sg_validate_image_desc(desc)) {
img->slot.state = _sg_create_image(img, desc);
}
else {
img->slot.state = SG_RESOURCESTATE_FAILED;
}
SOKOL_ASSERT((img->slot.state == SG_RESOURCESTATE_VALID)||(img->slot.state == SG_RESOURCESTATE_FAILED));
}
_SOKOL_PRIVATE void _sg_init_shader(sg_shader shd_id, const sg_shader_desc* desc) {
SOKOL_ASSERT(shd_id.id != SG_INVALID_ID && desc);
_sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, shd_id.id);
SOKOL_ASSERT(shd && shd->slot.state == SG_RESOURCESTATE_ALLOC);
shd->slot.ctx_id = _sg.active_context.id;
if (_sg_validate_shader_desc(desc)) {
shd->slot.state = _sg_create_shader(shd, desc);
}
else {
shd->slot.state = SG_RESOURCESTATE_FAILED;
}
SOKOL_ASSERT((shd->slot.state == SG_RESOURCESTATE_VALID)||(shd->slot.state == SG_RESOURCESTATE_FAILED));
}
_SOKOL_PRIVATE void _sg_init_pipeline(sg_pipeline pip_id, const sg_pipeline_desc* desc) {
SOKOL_ASSERT(pip_id.id != SG_INVALID_ID && desc);
_sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
SOKOL_ASSERT(pip && pip->slot.state == SG_RESOURCESTATE_ALLOC);
pip->slot.ctx_id = _sg.active_context.id;
if (_sg_validate_pipeline_desc(desc)) {
_sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, desc->shader.id);
SOKOL_ASSERT(shd && shd->slot.state == SG_RESOURCESTATE_VALID);
pip->slot.state = _sg_create_pipeline(pip, shd, desc);
}
else {
pip->slot.state = SG_RESOURCESTATE_FAILED;
}
SOKOL_ASSERT((pip->slot.state == SG_RESOURCESTATE_VALID)||(pip->slot.state == SG_RESOURCESTATE_FAILED));
}
_SOKOL_PRIVATE void _sg_init_pass(sg_pass pass_id, const sg_pass_desc* desc) {
SOKOL_ASSERT(pass_id.id != SG_INVALID_ID && desc);
_sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, pass_id.id);
SOKOL_ASSERT(pass && pass->slot.state == SG_RESOURCESTATE_ALLOC);
pass->slot.ctx_id = _sg.active_context.id;
if (_sg_validate_pass_desc(desc)) {
/* lookup pass attachment image pointers */
_sg_image_t* att_imgs[SG_MAX_COLOR_ATTACHMENTS + 1];
for (int i = 0; i < SG_MAX_COLOR_ATTACHMENTS; i++) {
if (desc->color_attachments[i].image.id) {
att_imgs[i] = _sg_lookup_image(&_sg.pools, desc->color_attachments[i].image.id);
SOKOL_ASSERT(att_imgs[i] && att_imgs[i]->slot.state == SG_RESOURCESTATE_VALID);
}
else {
att_imgs[i] = 0;
}
}
const int ds_att_index = SG_MAX_COLOR_ATTACHMENTS;
if (desc->depth_stencil_attachment.image.id) {
att_imgs[ds_att_index] = _sg_lookup_image(&_sg.pools, desc->depth_stencil_attachment.image.id);
SOKOL_ASSERT(att_imgs[ds_att_index] && att_imgs[ds_att_index]->slot.state == SG_RESOURCESTATE_VALID);
}
else {
att_imgs[ds_att_index] = 0;
}
pass->slot.state = _sg_create_pass(pass, att_imgs, desc);
}
else {
pass->slot.state = SG_RESOURCESTATE_FAILED;
}
SOKOL_ASSERT((pass->slot.state == SG_RESOURCESTATE_VALID)||(pass->slot.state == SG_RESOURCESTATE_FAILED));
}
/*== PUBLIC API FUNCTIONS ====================================================*/
SOKOL_API_IMPL void sg_setup(const sg_desc* desc) {
SOKOL_ASSERT(desc);
SOKOL_ASSERT((desc->_start_canary == 0) && (desc->_end_canary == 0));
memset(&_sg, 0, sizeof(_sg));
_sg.desc = *desc;
/* replace zero-init items with their default values */
_sg.desc.buffer_pool_size = _sg_def(_sg.desc.buffer_pool_size, _SG_DEFAULT_BUFFER_POOL_SIZE);
_sg.desc.image_pool_size = _sg_def(_sg.desc.image_pool_size, _SG_DEFAULT_IMAGE_POOL_SIZE);
_sg.desc.shader_pool_size = _sg_def(_sg.desc.shader_pool_size, _SG_DEFAULT_SHADER_POOL_SIZE);
_sg.desc.pipeline_pool_size = _sg_def(_sg.desc.pipeline_pool_size, _SG_DEFAULT_PIPELINE_POOL_SIZE);
_sg.desc.pass_pool_size = _sg_def(_sg.desc.pass_pool_size, _SG_DEFAULT_PASS_POOL_SIZE);
_sg.desc.context_pool_size = _sg_def(_sg.desc.context_pool_size, _SG_DEFAULT_CONTEXT_POOL_SIZE);
_sg.desc.mtl_global_uniform_buffer_size = _sg_def(_sg.desc.mtl_global_uniform_buffer_size, _SG_MTL_DEFAULT_UB_SIZE);
_sg.desc.mtl_sampler_cache_size = _sg_def(_sg.desc.mtl_sampler_cache_size, _SG_MTL_DEFAULT_SAMPLER_CACHE_CAPACITY);
_sg_setup_pools(&_sg.pools, &_sg.desc);
_sg.frame_index = 1;
_sg_setup_backend(&_sg.desc);
_sg.valid = true;
sg_setup_context();
}
SOKOL_API_IMPL void sg_shutdown(void) {
/* can only delete resources for the currently set context here, if multiple
contexts are used, the app code must take care of properly releasing them
(since only the app code can switch between 3D-API contexts)
*/
if (_sg.active_context.id != SG_INVALID_ID) {
_sg_context_t* ctx = _sg_lookup_context(&_sg.pools, _sg.active_context.id);
if (ctx) {
_sg_destroy_all_resources(&_sg.pools, _sg.active_context.id);
_sg_destroy_context(ctx);
}
}
_sg_discard_backend();
_sg_discard_pools(&_sg.pools);
_sg.valid = false;
}
SOKOL_API_IMPL bool sg_isvalid(void) {
return _sg.valid;
}
SOKOL_API_IMPL sg_desc sg_query_desc(void) {
SOKOL_ASSERT(_sg.valid);
return _sg.desc;
}
SOKOL_API_IMPL sg_backend sg_query_backend(void) {
SOKOL_ASSERT(_sg.valid);
return _sg.backend;
}
SOKOL_API_IMPL sg_features sg_query_features(void) {
SOKOL_ASSERT(_sg.valid);
return _sg.features;
}
SOKOL_API_IMPL sg_limits sg_query_limits(void) {
SOKOL_ASSERT(_sg.valid);
return _sg.limits;
}
SOKOL_API_IMPL sg_pixelformat_info sg_query_pixelformat(sg_pixel_format fmt) {
SOKOL_ASSERT(_sg.valid);
int fmt_index = (int) fmt;
SOKOL_ASSERT((fmt_index > SG_PIXELFORMAT_NONE) && (fmt_index < _SG_PIXELFORMAT_NUM));
return _sg.formats[fmt_index];
}
SOKOL_API_IMPL sg_context sg_setup_context(void) {
SOKOL_ASSERT(_sg.valid);
sg_context res;
int slot_index = _sg_pool_alloc_index(&_sg.pools.context_pool);
if (_SG_INVALID_SLOT_INDEX != slot_index) {
res.id = _sg_slot_alloc(&_sg.pools.context_pool, &_sg.pools.contexts[slot_index].slot, slot_index);
_sg_context_t* ctx = _sg_context_at(&_sg.pools, res.id);
ctx->slot.state = _sg_create_context(ctx);
SOKOL_ASSERT(ctx->slot.state == SG_RESOURCESTATE_VALID);
_sg_activate_context(ctx);
}
else {
/* pool is exhausted */
res.id = SG_INVALID_ID;
}
_sg.active_context = res;
return res;
}
SOKOL_API_IMPL void sg_discard_context(sg_context ctx_id) {
SOKOL_ASSERT(_sg.valid);
_sg_destroy_all_resources(&_sg.pools, ctx_id.id);
_sg_context_t* ctx = _sg_lookup_context(&_sg.pools, ctx_id.id);
if (ctx) {
_sg_destroy_context(ctx);
_sg_reset_context(ctx);
_sg_pool_free_index(&_sg.pools.context_pool, _sg_slot_index(ctx_id.id));
}
_sg.active_context.id = SG_INVALID_ID;
_sg_activate_context(0);
}
SOKOL_API_IMPL void sg_activate_context(sg_context ctx_id) {
SOKOL_ASSERT(_sg.valid);
_sg.active_context = ctx_id;
_sg_context_t* ctx = _sg_lookup_context(&_sg.pools, ctx_id.id);
/* NOTE: ctx can be 0 here if the context is no longer valid */
_sg_activate_context(ctx);
}
SOKOL_API_IMPL sg_trace_hooks sg_install_trace_hooks(const sg_trace_hooks* trace_hooks) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(trace_hooks);
#if defined(SOKOL_TRACE_HOOKS)
sg_trace_hooks old_hooks = _sg.hooks;
_sg.hooks = *trace_hooks;
#else
static sg_trace_hooks old_hooks;
SOKOL_LOG("sg_install_trace_hooks() called, but SG_TRACE_HOOKS is not defined!");
#endif
return old_hooks;
}
SOKOL_API_IMPL sg_buffer sg_alloc_buffer(void) {
SOKOL_ASSERT(_sg.valid);
sg_buffer res = _sg_alloc_buffer();
_SG_TRACE_ARGS(alloc_buffer, res);
return res;
}
SOKOL_API_IMPL sg_image sg_alloc_image(void) {
SOKOL_ASSERT(_sg.valid);
sg_image res = _sg_alloc_image();
_SG_TRACE_ARGS(alloc_image, res);
return res;
}
SOKOL_API_IMPL sg_shader sg_alloc_shader(void) {
SOKOL_ASSERT(_sg.valid);
sg_shader res = _sg_alloc_shader();
_SG_TRACE_ARGS(alloc_shader, res);
return res;
}
SOKOL_API_IMPL sg_pipeline sg_alloc_pipeline(void) {
SOKOL_ASSERT(_sg.valid);
sg_pipeline res = _sg_alloc_pipeline();
_SG_TRACE_ARGS(alloc_pipeline, res);
return res;
}
SOKOL_API_IMPL sg_pass sg_alloc_pass(void) {
SOKOL_ASSERT(_sg.valid);
sg_pass res = _sg_alloc_pass();
_SG_TRACE_ARGS(alloc_pass, res);
return res;
}
SOKOL_API_IMPL void sg_init_buffer(sg_buffer buf_id, const sg_buffer_desc* desc) {
SOKOL_ASSERT(_sg.valid);
sg_buffer_desc desc_def = _sg_buffer_desc_defaults(desc);
_sg_init_buffer(buf_id, &desc_def);
_SG_TRACE_ARGS(init_buffer, buf_id, &desc_def);
}
SOKOL_API_IMPL void sg_init_image(sg_image img_id, const sg_image_desc* desc) {
SOKOL_ASSERT(_sg.valid);
sg_image_desc desc_def = _sg_image_desc_defaults(desc);
_sg_init_image(img_id, &desc_def);
_SG_TRACE_ARGS(init_image, img_id, &desc_def);
}
SOKOL_API_IMPL void sg_init_shader(sg_shader shd_id, const sg_shader_desc* desc) {
SOKOL_ASSERT(_sg.valid);
sg_shader_desc desc_def = _sg_shader_desc_defaults(desc);
_sg_init_shader(shd_id, &desc_def);
_SG_TRACE_ARGS(init_shader, shd_id, &desc_def);
}
SOKOL_API_IMPL void sg_init_pipeline(sg_pipeline pip_id, const sg_pipeline_desc* desc) {
SOKOL_ASSERT(_sg.valid);
sg_pipeline_desc desc_def = _sg_pipeline_desc_defaults(desc);
_sg_init_pipeline(pip_id, &desc_def);
_SG_TRACE_ARGS(init_pipeline, pip_id, &desc_def);
}
SOKOL_API_IMPL void sg_init_pass(sg_pass pass_id, const sg_pass_desc* desc) {
SOKOL_ASSERT(_sg.valid);
sg_pass_desc desc_def = _sg_pass_desc_defaults(desc);
_sg_init_pass(pass_id, &desc_def);
_SG_TRACE_ARGS(init_pass, pass_id, &desc_def);
}
/*-- set allocated resource to failed state ----------------------------------*/
SOKOL_API_IMPL void sg_fail_buffer(sg_buffer buf_id) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(buf_id.id != SG_INVALID_ID);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
SOKOL_ASSERT(buf && buf->slot.state == SG_RESOURCESTATE_ALLOC);
buf->slot.ctx_id = _sg.active_context.id;
buf->slot.state = SG_RESOURCESTATE_FAILED;
_SG_TRACE_ARGS(fail_buffer, buf_id);
}
SOKOL_API_IMPL void sg_fail_image(sg_image img_id) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(img_id.id != SG_INVALID_ID);
_sg_image_t* img = _sg_lookup_image(&_sg.pools, img_id.id);
SOKOL_ASSERT(img && img->slot.state == SG_RESOURCESTATE_ALLOC);
img->slot.ctx_id = _sg.active_context.id;
img->slot.state = SG_RESOURCESTATE_FAILED;
_SG_TRACE_ARGS(fail_image, img_id);
}
SOKOL_API_IMPL void sg_fail_shader(sg_shader shd_id) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(shd_id.id != SG_INVALID_ID);
_sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, shd_id.id);
SOKOL_ASSERT(shd && shd->slot.state == SG_RESOURCESTATE_ALLOC);
shd->slot.ctx_id = _sg.active_context.id;
shd->slot.state = SG_RESOURCESTATE_FAILED;
_SG_TRACE_ARGS(fail_shader, shd_id);
}
SOKOL_API_IMPL void sg_fail_pipeline(sg_pipeline pip_id) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(pip_id.id != SG_INVALID_ID);
_sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
SOKOL_ASSERT(pip && pip->slot.state == SG_RESOURCESTATE_ALLOC);
pip->slot.ctx_id = _sg.active_context.id;
pip->slot.state = SG_RESOURCESTATE_FAILED;
_SG_TRACE_ARGS(fail_pipeline, pip_id);
}
SOKOL_API_IMPL void sg_fail_pass(sg_pass pass_id) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(pass_id.id != SG_INVALID_ID);
_sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, pass_id.id);
SOKOL_ASSERT(pass && pass->slot.state == SG_RESOURCESTATE_ALLOC);
pass->slot.ctx_id = _sg.active_context.id;
pass->slot.state = SG_RESOURCESTATE_FAILED;
_SG_TRACE_ARGS(fail_pass, pass_id);
}
/*-- get resource state */
SOKOL_API_IMPL sg_resource_state sg_query_buffer_state(sg_buffer buf_id) {
SOKOL_ASSERT(_sg.valid);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
sg_resource_state res = buf ? buf->slot.state : SG_RESOURCESTATE_INVALID;
return res;
}
SOKOL_API_IMPL sg_resource_state sg_query_image_state(sg_image img_id) {
SOKOL_ASSERT(_sg.valid);
_sg_image_t* img = _sg_lookup_image(&_sg.pools, img_id.id);
sg_resource_state res = img ? img->slot.state : SG_RESOURCESTATE_INVALID;
return res;
}
SOKOL_API_IMPL sg_resource_state sg_query_shader_state(sg_shader shd_id) {
SOKOL_ASSERT(_sg.valid);
_sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, shd_id.id);
sg_resource_state res = shd ? shd->slot.state : SG_RESOURCESTATE_INVALID;
return res;
}
SOKOL_API_IMPL sg_resource_state sg_query_pipeline_state(sg_pipeline pip_id) {
SOKOL_ASSERT(_sg.valid);
_sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
sg_resource_state res = pip ? pip->slot.state : SG_RESOURCESTATE_INVALID;
return res;
}
SOKOL_API_IMPL sg_resource_state sg_query_pass_state(sg_pass pass_id) {
SOKOL_ASSERT(_sg.valid);
_sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, pass_id.id);
sg_resource_state res = pass ? pass->slot.state : SG_RESOURCESTATE_INVALID;
return res;
}
/*-- allocate and initialize resource ----------------------------------------*/
SOKOL_API_IMPL sg_buffer sg_make_buffer(const sg_buffer_desc* desc) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(desc);
sg_buffer_desc desc_def = _sg_buffer_desc_defaults(desc);
sg_buffer buf_id = _sg_alloc_buffer();
if (buf_id.id != SG_INVALID_ID) {
_sg_init_buffer(buf_id, &desc_def);
}
else {
SOKOL_LOG("buffer pool exhausted!");
_SG_TRACE_NOARGS(err_buffer_pool_exhausted);
}
_SG_TRACE_ARGS(make_buffer, &desc_def, buf_id);
return buf_id;
}
SOKOL_API_IMPL sg_image sg_make_image(const sg_image_desc* desc) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(desc);
sg_image_desc desc_def = _sg_image_desc_defaults(desc);
sg_image img_id = _sg_alloc_image();
if (img_id.id != SG_INVALID_ID) {
_sg_init_image(img_id, &desc_def);
}
else {
SOKOL_LOG("image pool exhausted!");
_SG_TRACE_NOARGS(err_image_pool_exhausted);
}
_SG_TRACE_ARGS(make_image, &desc_def, img_id);
return img_id;
}
SOKOL_API_IMPL sg_shader sg_make_shader(const sg_shader_desc* desc) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(desc);
sg_shader_desc desc_def = _sg_shader_desc_defaults(desc);
sg_shader shd_id = _sg_alloc_shader();
if (shd_id.id != SG_INVALID_ID) {
_sg_init_shader(shd_id, &desc_def);
}
else {
SOKOL_LOG("shader pool exhausted!");
_SG_TRACE_NOARGS(err_shader_pool_exhausted);
}
_SG_TRACE_ARGS(make_shader, &desc_def, shd_id);
return shd_id;
}
SOKOL_API_IMPL sg_pipeline sg_make_pipeline(const sg_pipeline_desc* desc) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(desc);
sg_pipeline_desc desc_def = _sg_pipeline_desc_defaults(desc);
sg_pipeline pip_id = _sg_alloc_pipeline();
if (pip_id.id != SG_INVALID_ID) {
_sg_init_pipeline(pip_id, &desc_def);
}
else {
SOKOL_LOG("pipeline pool exhausted!");
_SG_TRACE_NOARGS(err_pipeline_pool_exhausted);
}
_SG_TRACE_ARGS(make_pipeline, &desc_def, pip_id);
return pip_id;
}
SOKOL_API_IMPL sg_pass sg_make_pass(const sg_pass_desc* desc) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(desc);
sg_pass_desc desc_def = _sg_pass_desc_defaults(desc);
sg_pass pass_id = _sg_alloc_pass();
if (pass_id.id != SG_INVALID_ID) {
_sg_init_pass(pass_id, &desc_def);
}
else {
SOKOL_LOG("pass pool exhausted!");
_SG_TRACE_NOARGS(err_pass_pool_exhausted);
}
_SG_TRACE_ARGS(make_pass, &desc_def, pass_id);
return pass_id;
}
/*-- destroy resource --------------------------------------------------------*/
SOKOL_API_IMPL void sg_destroy_buffer(sg_buffer buf_id) {
SOKOL_ASSERT(_sg.valid);
_SG_TRACE_ARGS(destroy_buffer, buf_id);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
if (buf) {
if (buf->slot.ctx_id == _sg.active_context.id) {
_sg_destroy_buffer(buf);
_sg_reset_buffer(buf);
_sg_pool_free_index(&_sg.pools.buffer_pool, _sg_slot_index(buf_id.id));
}
else {
SOKOL_LOG("sg_destroy_buffer: active context mismatch (must be same as for creation)");
_SG_TRACE_NOARGS(err_context_mismatch);
}
}
}
SOKOL_API_IMPL void sg_destroy_image(sg_image img_id) {
SOKOL_ASSERT(_sg.valid);
_SG_TRACE_ARGS(destroy_image, img_id);
_sg_image_t* img = _sg_lookup_image(&_sg.pools, img_id.id);
if (img) {
if (img->slot.ctx_id == _sg.active_context.id) {
_sg_destroy_image(img);
_sg_reset_image(img);
_sg_pool_free_index(&_sg.pools.image_pool, _sg_slot_index(img_id.id));
}
else {
SOKOL_LOG("sg_destroy_image: active context mismatch (must be same as for creation)");
_SG_TRACE_NOARGS(err_context_mismatch);
}
}
}
SOKOL_API_IMPL void sg_destroy_shader(sg_shader shd_id) {
SOKOL_ASSERT(_sg.valid);
_SG_TRACE_ARGS(destroy_shader, shd_id);
_sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, shd_id.id);
if (shd) {
if (shd->slot.ctx_id == _sg.active_context.id) {
_sg_destroy_shader(shd);
_sg_reset_shader(shd);
_sg_pool_free_index(&_sg.pools.shader_pool, _sg_slot_index(shd_id.id));
}
else {
SOKOL_LOG("sg_destroy_shader: active context mismatch (must be same as for creation)");
_SG_TRACE_NOARGS(err_context_mismatch);
}
}
}
SOKOL_API_IMPL void sg_destroy_pipeline(sg_pipeline pip_id) {
SOKOL_ASSERT(_sg.valid);
_SG_TRACE_ARGS(destroy_pipeline, pip_id);
_sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
if (pip) {
if (pip->slot.ctx_id == _sg.active_context.id) {
_sg_destroy_pipeline(pip);
_sg_reset_pipeline(pip);
_sg_pool_free_index(&_sg.pools.pipeline_pool, _sg_slot_index(pip_id.id));
}
else {
SOKOL_LOG("sg_destroy_pipeline: active context mismatch (must be same as for creation)");
_SG_TRACE_NOARGS(err_context_mismatch);
}
}
}
SOKOL_API_IMPL void sg_destroy_pass(sg_pass pass_id) {
SOKOL_ASSERT(_sg.valid);
_SG_TRACE_ARGS(destroy_pass, pass_id);
_sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, pass_id.id);
if (pass) {
if (pass->slot.ctx_id == _sg.active_context.id) {
_sg_destroy_pass(pass);
_sg_reset_pass(pass);
_sg_pool_free_index(&_sg.pools.pass_pool, _sg_slot_index(pass_id.id));
}
else {
SOKOL_LOG("sg_destroy_pass: active context mismatch (must be same as for creation)");
_SG_TRACE_NOARGS(err_context_mismatch);
}
}
}
SOKOL_API_IMPL void sg_begin_default_pass(const sg_pass_action* pass_action, int width, int height) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(pass_action);
SOKOL_ASSERT((pass_action->_start_canary == 0) && (pass_action->_end_canary == 0));
sg_pass_action pa;
_sg_resolve_default_pass_action(pass_action, &pa);
_sg.cur_pass.id = SG_INVALID_ID;
_sg.pass_valid = true;
_sg_begin_pass(0, &pa, width, height);
_SG_TRACE_ARGS(begin_default_pass, pass_action, width, height);
}
SOKOL_API_IMPL void sg_begin_pass(sg_pass pass_id, const sg_pass_action* pass_action) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(pass_action);
SOKOL_ASSERT((pass_action->_start_canary == 0) && (pass_action->_end_canary == 0));
_sg.cur_pass = pass_id;
_sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, pass_id.id);
if (pass && _sg_validate_begin_pass(pass)) {
_sg.pass_valid = true;
sg_pass_action pa;
_sg_resolve_default_pass_action(pass_action, &pa);
const int w = pass->color_atts[0].image->width;
const int h = pass->color_atts[0].image->height;
_sg_begin_pass(pass, &pa, w, h);
_SG_TRACE_ARGS(begin_pass, pass_id, pass_action);
}
else {
_sg.pass_valid = false;
_SG_TRACE_NOARGS(err_pass_invalid);
}
}
SOKOL_API_IMPL void sg_apply_viewport(int x, int y, int width, int height, bool origin_top_left) {
SOKOL_ASSERT(_sg.valid);
if (!_sg.pass_valid) {
_SG_TRACE_NOARGS(err_pass_invalid);
return;
}
_sg_apply_viewport(x, y, width, height, origin_top_left);
_SG_TRACE_ARGS(apply_viewport, x, y, width, height, origin_top_left);
}
SOKOL_API_IMPL void sg_apply_scissor_rect(int x, int y, int width, int height, bool origin_top_left) {
SOKOL_ASSERT(_sg.valid);
if (!_sg.pass_valid) {
_SG_TRACE_NOARGS(err_pass_invalid);
return;
}
_sg_apply_scissor_rect(x, y, width, height, origin_top_left);
_SG_TRACE_ARGS(apply_scissor_rect, x, y, width, height, origin_top_left);
}
SOKOL_API_IMPL void sg_apply_pipeline(sg_pipeline pip_id) {
SOKOL_ASSERT(_sg.valid);
_sg.bindings_valid = false;
if (!_sg_validate_apply_pipeline(pip_id)) {
_sg.next_draw_valid = false;
_SG_TRACE_NOARGS(err_draw_invalid);
return;
}
if (!_sg.pass_valid) {
_SG_TRACE_NOARGS(err_pass_invalid);
return;
}
_sg.cur_pipeline = pip_id;
_sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
SOKOL_ASSERT(pip);
_sg.next_draw_valid = (SG_RESOURCESTATE_VALID == pip->slot.state);
SOKOL_ASSERT(pip->shader && (pip->shader->slot.id == pip->shader_id.id));
_sg_apply_pipeline(pip);
_SG_TRACE_ARGS(apply_pipeline, pip_id);
}
SOKOL_API_IMPL void sg_apply_bindings(const sg_bindings* bindings) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(bindings);
SOKOL_ASSERT((bindings->_start_canary == 0) && (bindings->_end_canary==0));
if (!_sg_validate_apply_bindings(bindings)) {
_sg.next_draw_valid = false;
_SG_TRACE_NOARGS(err_draw_invalid);
return;
}
_sg.bindings_valid = true;
_sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, _sg.cur_pipeline.id);
SOKOL_ASSERT(pip);
_sg_buffer_t* vbs[SG_MAX_SHADERSTAGE_BUFFERS] = { 0 };
int num_vbs = 0;
for (int i = 0; i < SG_MAX_SHADERSTAGE_BUFFERS; i++, num_vbs++) {
if (bindings->vertex_buffers[i].id) {
vbs[i] = _sg_lookup_buffer(&_sg.pools, bindings->vertex_buffers[i].id);
SOKOL_ASSERT(vbs[i]);
_sg.next_draw_valid &= (SG_RESOURCESTATE_VALID == vbs[i]->slot.state);
_sg.next_draw_valid &= !vbs[i]->append_overflow;
}
else {
break;
}
}
_sg_buffer_t* ib = 0;
if (bindings->index_buffer.id) {
ib = _sg_lookup_buffer(&_sg.pools, bindings->index_buffer.id);
SOKOL_ASSERT(ib);
_sg.next_draw_valid &= (SG_RESOURCESTATE_VALID == ib->slot.state);
_sg.next_draw_valid &= !ib->append_overflow;
}
_sg_image_t* vs_imgs[SG_MAX_SHADERSTAGE_IMAGES] = { 0 };
int num_vs_imgs = 0;
for (int i = 0; i < SG_MAX_SHADERSTAGE_IMAGES; i++, num_vs_imgs++) {
if (bindings->vs_images[i].id) {
vs_imgs[i] = _sg_lookup_image(&_sg.pools, bindings->vs_images[i].id);
SOKOL_ASSERT(vs_imgs[i]);
_sg.next_draw_valid &= (SG_RESOURCESTATE_VALID == vs_imgs[i]->slot.state);
}
else {
break;
}
}
_sg_image_t* fs_imgs[SG_MAX_SHADERSTAGE_IMAGES] = { 0 };
int num_fs_imgs = 0;
for (int i = 0; i < SG_MAX_SHADERSTAGE_IMAGES; i++, num_fs_imgs++) {
if (bindings->fs_images[i].id) {
fs_imgs[i] = _sg_lookup_image(&_sg.pools, bindings->fs_images[i].id);
SOKOL_ASSERT(fs_imgs[i]);
_sg.next_draw_valid &= (SG_RESOURCESTATE_VALID == fs_imgs[i]->slot.state);
}
else {
break;
}
}
if (_sg.next_draw_valid) {
const int* vb_offsets = bindings->vertex_buffer_offsets;
int ib_offset = bindings->index_buffer_offset;
_sg_apply_bindings(pip, vbs, vb_offsets, num_vbs, ib, ib_offset, vs_imgs, num_vs_imgs, fs_imgs, num_fs_imgs);
_SG_TRACE_ARGS(apply_bindings, bindings);
}
else {
_SG_TRACE_NOARGS(err_draw_invalid);
}
}
SOKOL_API_IMPL void sg_apply_uniforms(sg_shader_stage stage, int ub_index, const void* data, int num_bytes) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT((stage == SG_SHADERSTAGE_VS) || (stage == SG_SHADERSTAGE_FS));
SOKOL_ASSERT((ub_index >= 0) && (ub_index < SG_MAX_SHADERSTAGE_UBS));
SOKOL_ASSERT(data && (num_bytes > 0));
if (!_sg_validate_apply_uniforms(stage, ub_index, data, num_bytes)) {
_sg.next_draw_valid = false;
_SG_TRACE_NOARGS(err_draw_invalid);
return;
}
if (!_sg.pass_valid) {
_SG_TRACE_NOARGS(err_pass_invalid);
return;
}
if (!_sg.next_draw_valid) {
_SG_TRACE_NOARGS(err_draw_invalid);
}
_sg_apply_uniforms(stage, ub_index, data, num_bytes);
_SG_TRACE_ARGS(apply_uniforms, stage, ub_index, data, num_bytes);
}
SOKOL_API_IMPL void sg_draw(int base_element, int num_elements, int num_instances) {
SOKOL_ASSERT(_sg.valid);
#if defined(SOKOL_DEBUG)
if (!_sg.bindings_valid) {
SOKOL_LOG("attempting to draw without resource bindings");
}
#endif
if (!_sg.pass_valid) {
_SG_TRACE_NOARGS(err_pass_invalid);
return;
}
if (!_sg.next_draw_valid) {
_SG_TRACE_NOARGS(err_draw_invalid);
return;
}
if (!_sg.bindings_valid) {
_SG_TRACE_NOARGS(err_bindings_invalid);
return;
}
_sg_draw(base_element, num_elements, num_instances);
_SG_TRACE_ARGS(draw, base_element, num_elements, num_instances);
}
SOKOL_API_IMPL void sg_end_pass(void) {
SOKOL_ASSERT(_sg.valid);
if (!_sg.pass_valid) {
_SG_TRACE_NOARGS(err_pass_invalid);
return;
}
_sg_end_pass();
_sg.cur_pass.id = SG_INVALID_ID;
_sg.cur_pipeline.id = SG_INVALID_ID;
_sg.pass_valid = false;
_SG_TRACE_NOARGS(end_pass);
}
SOKOL_API_IMPL void sg_commit(void) {
SOKOL_ASSERT(_sg.valid);
_sg_commit();
_SG_TRACE_NOARGS(commit);
_sg.frame_index++;
}
SOKOL_API_IMPL void sg_reset_state_cache(void) {
SOKOL_ASSERT(_sg.valid);
_sg_reset_state_cache();
_SG_TRACE_NOARGS(reset_state_cache);
}
SOKOL_API_IMPL void sg_update_buffer(sg_buffer buf_id, const void* data, int num_bytes) {
SOKOL_ASSERT(_sg.valid);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
if ((num_bytes > 0) && buf && (buf->slot.state == SG_RESOURCESTATE_VALID)) {
if (_sg_validate_update_buffer(buf, data, num_bytes)) {
SOKOL_ASSERT(num_bytes <= buf->size);
/* only one update allowed per buffer and frame */
SOKOL_ASSERT(buf->update_frame_index != _sg.frame_index);
/* update and append on same buffer in same frame not allowed */
SOKOL_ASSERT(buf->append_frame_index != _sg.frame_index);
_sg_update_buffer(buf, data, num_bytes);
buf->update_frame_index = _sg.frame_index;
}
}
_SG_TRACE_ARGS(update_buffer, buf_id, data, num_bytes);
}
SOKOL_API_IMPL int sg_append_buffer(sg_buffer buf_id, const void* data, int num_bytes) {
SOKOL_ASSERT(_sg.valid);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
int result;
if (buf) {
/* rewind append cursor in a new frame */
if (buf->append_frame_index != _sg.frame_index) {
buf->append_pos = 0;
buf->append_overflow = false;
}
if ((buf->append_pos + num_bytes) > buf->size) {
buf->append_overflow = true;
}
const int start_pos = buf->append_pos;
if (buf->slot.state == SG_RESOURCESTATE_VALID) {
if (_sg_validate_append_buffer(buf, data, num_bytes)) {
if (!buf->append_overflow && (num_bytes > 0)) {
/* update and append on same buffer in same frame not allowed */
SOKOL_ASSERT(buf->update_frame_index != _sg.frame_index);
_sg_append_buffer(buf, data, num_bytes, buf->append_frame_index != _sg.frame_index);
buf->append_pos += num_bytes;
buf->append_frame_index = _sg.frame_index;
}
}
}
result = start_pos;
}
else {
/* FIXME: should we return -1 here? */
result = 0;
}
_SG_TRACE_ARGS(append_buffer, buf_id, data, num_bytes, result);
return result;
}
SOKOL_API_IMPL bool sg_query_buffer_overflow(sg_buffer buf_id) {
SOKOL_ASSERT(_sg.valid);
_sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
bool result = buf ? buf->append_overflow : false;
return result;
}
SOKOL_API_IMPL void sg_update_image(sg_image img_id, const sg_image_content* data) {
SOKOL_ASSERT(_sg.valid);
_sg_image_t* img = _sg_lookup_image(&_sg.pools, img_id.id);
if (img && img->slot.state == SG_RESOURCESTATE_VALID) {
if (_sg_validate_update_image(img, data)) {
SOKOL_ASSERT(img->upd_frame_index != _sg.frame_index);
_sg_update_image(img, data);
img->upd_frame_index = _sg.frame_index;
}
}
_SG_TRACE_ARGS(update_image, img_id, data);
}
SOKOL_API_IMPL void sg_push_debug_group(const char* name) {
SOKOL_ASSERT(_sg.valid);
SOKOL_ASSERT(name);
_SG_TRACE_ARGS(push_debug_group, name);
}
SOKOL_API_IMPL void sg_pop_debug_group(void) {
SOKOL_ASSERT(_sg.valid);
_SG_TRACE_NOARGS(pop_debug_group);
}
SOKOL_API_IMPL sg_buffer_info sg_query_buffer_info(sg_buffer buf_id) {
SOKOL_ASSERT(_sg.valid);
sg_buffer_info info;
memset(&info, 0, sizeof(info));
const _sg_buffer_t* buf = _sg_lookup_buffer(&_sg.pools, buf_id.id);
if (buf) {
info.slot.state = buf->slot.state;
info.slot.res_id = buf->slot.id;
info.slot.ctx_id = buf->slot.ctx_id;
info.update_frame_index = buf->update_frame_index;
info.append_frame_index = buf->append_frame_index;
info.append_pos = buf->append_pos;
info.append_overflow = buf->append_overflow;
#if defined(SOKOL_D3D11)
info.num_slots = 1;
info.active_slot = 0;
#else
info.num_slots = buf->num_slots;
info.active_slot = buf->active_slot;
#endif
}
return info;
}
SOKOL_API_IMPL sg_image_info sg_query_image_info(sg_image img_id) {
SOKOL_ASSERT(_sg.valid);
sg_image_info info;
memset(&info, 0, sizeof(info));
const _sg_image_t* img = _sg_lookup_image(&_sg.pools, img_id.id);
if (img) {
info.slot.state = img->slot.state;
info.slot.res_id = img->slot.id;
info.slot.ctx_id = img->slot.ctx_id;
#if defined(SOKOL_D3D11)
info.num_slots = 1;
info.active_slot = 0;
#else
info.num_slots = img->num_slots;
info.active_slot = img->active_slot;
#endif
}
return info;
}
SOKOL_API_IMPL sg_shader_info sg_query_shader_info(sg_shader shd_id) {
SOKOL_ASSERT(_sg.valid);
sg_shader_info info;
memset(&info, 0, sizeof(info));
const _sg_shader_t* shd = _sg_lookup_shader(&_sg.pools, shd_id.id);
if (shd) {
info.slot.state = shd->slot.state;
info.slot.res_id = shd->slot.id;
info.slot.ctx_id = shd->slot.ctx_id;
}
return info;
}
SOKOL_API_IMPL sg_pipeline_info sg_query_pipeline_info(sg_pipeline pip_id) {
SOKOL_ASSERT(_sg.valid);
sg_pipeline_info info;
memset(&info, 0, sizeof(info));
const _sg_pipeline_t* pip = _sg_lookup_pipeline(&_sg.pools, pip_id.id);
if (pip) {
info.slot.state = pip->slot.state;
info.slot.res_id = pip->slot.id;
info.slot.ctx_id = pip->slot.ctx_id;
}
return info;
}
SOKOL_API_IMPL sg_pass_info sg_query_pass_info(sg_pass pass_id) {
SOKOL_ASSERT(_sg.valid);
sg_pass_info info;
memset(&info, 0, sizeof(info));
const _sg_pass_t* pass = _sg_lookup_pass(&_sg.pools, pass_id.id);
if (pass) {
info.slot.state = pass->slot.state;
info.slot.res_id = pass->slot.id;
info.slot.ctx_id = pass->slot.ctx_id;
}
return info;
}
SOKOL_API_IMPL sg_buffer_desc sg_query_buffer_defaults(const sg_buffer_desc* desc) {
SOKOL_ASSERT(_sg.valid && desc);
return _sg_buffer_desc_defaults(desc);
}
SOKOL_API_IMPL sg_image_desc sg_query_image_defaults(const sg_image_desc* desc) {
SOKOL_ASSERT(_sg.valid && desc);
return _sg_image_desc_defaults(desc);
}
SOKOL_API_IMPL sg_shader_desc sg_query_shader_defaults(const sg_shader_desc* desc) {
SOKOL_ASSERT(_sg.valid && desc);
return _sg_shader_desc_defaults(desc);
}
SOKOL_API_IMPL sg_pipeline_desc sg_query_pipeline_defaults(const sg_pipeline_desc* desc) {
SOKOL_ASSERT(_sg.valid && desc);
return _sg_pipeline_desc_defaults(desc);
}
SOKOL_API_IMPL sg_pass_desc sg_query_pass_defaults(const sg_pass_desc* desc) {
SOKOL_ASSERT(_sg.valid && desc);
return _sg_pass_desc_defaults(desc);
}
#ifdef _MSC_VER
#pragma warning(pop)
#endif
#endif /* SOKOL_IMPL */