// Copyright (c) 2019-2022 Alexander Medvednikov. All rights reserved. // Use of this source code is governed by an MIT license // that can be found in the LICENSE file. module json2 import io import strings import time // Encoder encodes the an `Any` type into JSON representation. // It provides parameters in order to change the end result. pub struct Encoder { newline u8 newline_spaces_count int escape_unicode bool = true } pub const default_encoder = Encoder{} // byte array versions of the most common tokens/chars to avoid reallocations const null_in_bytes = 'null'.bytes() const true_in_bytes = 'true'.bytes() const false_in_bytes = 'false'.bytes() const zero_in_bytes = [u8(`0`)] const comma_bytes = [u8(`,`)] const colon_bytes = [u8(`:`)] const space_bytes = [u8(` `)] const unicode_escape_chars = [u8(`\\`), `u`] const quote_bytes = [u8(`"`)] const escaped_chars = [(r'\b').bytes(), (r'\f').bytes(), (r'\n').bytes(), (r'\r').bytes(), (r'\t').bytes()] // encode_value encodes a value to the specific writer. pub fn (e &Encoder) encode_value[T](val T, mut wr io.Writer) ! { e.encode_value_with_level[T](val, 1, mut wr)! } fn (e &Encoder) encode_newline(level int, mut wr io.Writer) ! { if e.newline != 0 { wr.write([e.newline])! for j := 0; j < level * e.newline_spaces_count; j++ { wr.write(json2.space_bytes)! } } } fn (e &Encoder) encode_any(val Any, level int, mut wr io.Writer) ! { match val { string { e.encode_string(val, mut wr)! } bool { if val == true { wr.write(json2.true_in_bytes)! } else { wr.write(json2.false_in_bytes)! } } i8, i16, int, i64 { wr.write(val.str().bytes())! } u8, u16, u32, u64 { wr.write(val.str().bytes())! } f32, f64 { $if !nofloat ? { str_float := val.str().bytes() wr.write(str_float)! if str_float[str_float.len - 1] == `.` { wr.write(json2.zero_in_bytes)! } return } wr.write(json2.zero_in_bytes)! } map[string]Any { wr.write([u8(`{`)])! mut i := 0 for k, v in val { e.encode_newline(level, mut wr)! e.encode_string(k, mut wr)! wr.write(json2.colon_bytes)! if e.newline != 0 { wr.write(json2.space_bytes)! } e.encode_value_with_level(v, level + 1, mut wr)! if i < val.len - 1 { wr.write(json2.comma_bytes)! } i++ } e.encode_newline(level - 1, mut wr)! wr.write([u8(`}`)])! } []Any { wr.write([u8(`[`)])! for i in 0 .. val.len { e.encode_newline(level, mut wr)! e.encode_value_with_level(val[i], level + 1, mut wr)! if i < val.len - 1 { wr.write(json2.comma_bytes)! } } e.encode_newline(level - 1, mut wr)! wr.write([u8(`]`)])! } time.Time {} Null { wr.write(json2.null_in_bytes)! } } } fn (e &Encoder) encode_value_with_level[T](val T, level int, mut wr io.Writer) ! { $if T is string { e.encode_string(val, mut wr)! } $else $if T is Any { e.encode_any(val, level, mut wr)! } $else $if T is map[string]Any { // weird quirk but val is destructured immediately to Any e.encode_any(val, level, mut wr)! } $else $if T is []Any { e.encode_any(val, level, mut wr)! } $else $if T in [Null, bool, $Float, $Int] { e.encode_any(val, level, mut wr)! } $else $if T is Encodable { wr.write(val.json_str().bytes())! } $else $if T is $Struct { e.encode_struct(val, level, mut wr)! } $else $if T is $Enum { e.encode_any(Any(int(val)), level, mut wr)! } $else { // dump(val.str()) return error('cannot encode value with ${typeof(val).name} type') } } fn (e &Encoder) encode_struct[U](val U, level int, mut wr io.Writer) ! { wr.write([u8(`{`)])! mut i := 0 mut fields_len := 0 $for field in U.fields { value := val.$(field.name) if value.str() != 'Option(error: none)' { fields_len++ } } $for field in U.fields { value := val.$(field.name) mut json_name := '' for attr in field.attrs { if attr.contains('json: ') { json_name = attr.replace('json: ', '') break } } $if field.is_option { is_none := value.str() == 'Option(error: none)' if !is_none { e.encode_newline(level, mut wr)! if json_name != '' { e.encode_string(json_name, mut wr)! } else { e.encode_string(field.name, mut wr)! } wr.write(json2.colon_bytes)! if e.newline != 0 { wr.write(json2.space_bytes)! } $if field.typ is ?string { option_value := val.$(field.name) as ?string e.encode_string(option_value, mut wr)! } $else $if field.typ is ?bool { option_value := val.$(field.name) as ?bool wr.write(Any(option_value).str().bytes())! } $else $if field.typ is ?f32 { option_value := val.$(field.name) as ?f32 wr.write(Any(option_value).str().bytes())! } $else $if field.typ is ?f64 { option_value := val.$(field.name) as ?f64 wr.write(Any(option_value).str().bytes())! } $else $if field.typ is ?i8 { option_value := val.$(field.name) as ?i8 wr.write(Any(option_value).str().bytes())! } $else $if field.typ is ?i16 { option_value := val.$(field.name) as ?i16 wr.write(Any(option_value).str().bytes())! } $else $if field.typ is ?int { option_value := val.$(field.name) as ?int wr.write(Any(option_value).int().str().bytes())! } $else $if field.typ is ?time.Time { option_value := val.$(field.name) as ?time.Time parsed_time := option_value as time.Time e.encode_string(parsed_time.format_rfc3339(), mut wr)! } $else $if field.is_array { e.encode_array(value, level + 1, mut wr)! } $else $if field.is_enum { option_value := val.$(field.name) as ?int wr.write(Any(option_value).int().str().bytes())! } $else $if field.is_alias { match field.unaliased_typ { typeof[string]().idx { e.encode_string(value.str(), mut wr)! } typeof[bool]().idx, typeof[f32]().idx, typeof[f64]().idx, typeof[i8]().idx, typeof[i16]().idx, typeof[int]().idx, typeof[i64]().idx, typeof[u8]().idx, typeof[u16]().idx, typeof[u32]().idx, typeof[u64]().idx { wr.write(value.str().bytes())! } typeof[[]byte]().idx, typeof[[]int]().idx { // FIXME - error: could not infer generic type `U` in call to `encode_array` // e.encode_array(value, level, mut wr)! } else { // e.encode_value_with_level(value, level + 1, mut wr)! } } } $else { return error('type ${typeof(val).name} cannot be array encoded') } } } $else { e.encode_newline(level, mut wr)! if json_name != '' { e.encode_string(json_name, mut wr)! } else { e.encode_string(field.name, mut wr)! } wr.write(json2.colon_bytes)! if e.newline != 0 { wr.write(json2.space_bytes)! } $if field.typ is string { e.encode_string(value.str(), mut wr)! } $else $if field.typ is time.Time { parsed_time := val.$(field.name) as time.Time e.encode_string(parsed_time.format_rfc3339(), mut wr)! } $else $if field.typ in [bool, $Float, $Int] { wr.write(value.str().bytes())! } $else $if field.is_array { e.encode_array(value, level + 1, mut wr)! } $else $if field.is_struct { e.encode_struct(value, level + 1, mut wr)! } $else $if field.is_enum { wr.write(int(val.$(field.name)).str().bytes())! } $else $if field.is_alias { match field.unaliased_typ { typeof[string]().idx { e.encode_string(value.str(), mut wr)! } typeof[bool]().idx, typeof[f32]().idx, typeof[f64]().idx, typeof[i8]().idx, typeof[i16]().idx, typeof[int]().idx, typeof[i64]().idx, typeof[u8]().idx, typeof[u16]().idx, typeof[u32]().idx, typeof[u64]().idx { wr.write(value.str().bytes())! } typeof[[]byte]().idx, typeof[[]int]().idx { // FIXME - error: could not infer generic type `U` in call to `encode_array` // e.encode_array(value, level, mut wr)! } else { e.encode_struct(value, level + 1, mut wr)! // e.encode_value_with_level(value, level + 1, mut wr)! } } } $else { return error('type ${typeof(val).name} cannot be array encoded') } } if i < fields_len - 1 { wr.write(json2.comma_bytes)! } i++ } e.encode_newline(level - 1, mut wr)! wr.write([u8(`}`)])! } fn (e &Encoder) encode_array[U](val []U, level int, mut wr io.Writer) ! { wr.write([u8(`[`)])! for i in 0 .. val.len { e.encode_newline(level, mut wr)! $if U is string { e.encode_any(val[i], level + 1, mut wr)! } $else $if U is bool { e.encode_any(bool(val[i]), level + 1, mut wr)! } $else $if U is f32 { e.encode_any(f32(val[i]), level + 1, mut wr)! } $else $if U is f64 { e.encode_any(f64(val[i]), level + 1, mut wr)! } $else $if U is i8 { e.encode_any(i8(val[i]), level + 1, mut wr)! } $else $if U is i16 { e.encode_any(i16(val[i]), level + 1, mut wr)! } $else $if U is int { e.encode_any(int(val[i]), level + 1, mut wr)! } $else $if U is i64 { e.encode_any(i64(val[i]), level + 1, mut wr)! } $else $if U is u8 { e.encode_any(u8(val[i]), level + 1, mut wr)! } $else $if U is byte { e.encode_any(u8(val[i]), level + 1, mut wr)! } $else $if U is u16 { e.encode_any(u16(val[i]), level + 1, mut wr)! } $else $if U is u32 { e.encode_any(u32(val[i]), level + 1, mut wr)! } $else $if U is u64 { e.encode_any(u64(val[i]), level + 1, mut wr)! } $else $if U is $Array { // FIXME - error: could not infer generic type `U` in call to `encode_array` // e.encode_array(val[i], level + 1, mut wr)! } $else $if U is $Struct { e.encode_struct(val[i], level + 1, mut wr)! } $else $if U is $Enum { e.encode_any(i64(val[i]), level + 1, mut wr)! } $else { return error('type ${typeof(val).name} cannot be array encoded') } if i < val.len - 1 { wr.write(json2.comma_bytes)! } } e.encode_newline(level - 1, mut wr)! wr.write([u8(`]`)])! } // str returns the JSON string representation of the `map[string]Any` type. pub fn (f map[string]Any) str() string { return Any(f).json_str() } // str returns the JSON string representation of the `[]Any` type. pub fn (f []Any) str() string { return Any(f).json_str() } // str returns the string representation of the `Any` type. Use the `json_str` method // if you want to use the escaped str() version of the `Any` type. pub fn (f Any) str() string { if f is string { return f } else { return f.json_str() } } // json_str returns the JSON string representation of the `Any` type. [manualfree] pub fn (f Any) json_str() string { return encode(f) } // prettify_json_str returns the pretty-formatted JSON string representation of the `Any` type. [manualfree] pub fn (f Any) prettify_json_str() string { mut sb := strings.new_builder(4096) defer { unsafe { sb.free() } } mut enc := Encoder{ newline: `\n` newline_spaces_count: 2 } enc.encode_value(f, mut sb) or {} return sb.str() } // CharLengthIterator is an iterator that generates a char // length value of every iteration based on the given text. // (e.g.: "t✔" => [t => 1, ✔ => 2]) struct CharLengthIterator { text string mut: idx int } fn (mut iter CharLengthIterator) next() ?int { if iter.idx >= iter.text.len { return none } defer { iter.idx++ } mut len := 1 c := iter.text[iter.idx] if (c & (1 << 7)) != 0 { for t := u8(1 << 6); (c & t) != 0; t >>= 1 { len++ iter.idx++ } } return len } // encode_string returns the JSON spec-compliant version of the string. [manualfree] fn (e &Encoder) encode_string(s string, mut wr io.Writer) ! { mut char_lens := CharLengthIterator{ text: s } mut i := 0 wr.write(json2.quote_bytes)! for char_len in char_lens { if char_len == 1 { chr := s[i] if chr in important_escapable_chars { for j := 0; j < important_escapable_chars.len; j++ { if chr == important_escapable_chars[j] { wr.write(json2.escaped_chars[j])! break } } } else if chr == `"` || chr == `/` || chr == `\\` { wr.write([u8(`\\`), chr])! } else if int(chr) < 0x20 { hex_code := chr.hex().bytes() wr.write(json2.unicode_escape_chars)! // \u wr.write(json2.zero_in_bytes)! // \u0 wr.write(json2.zero_in_bytes)! // \u00 wr.write(hex_code)! // \u00xxxx } else { wr.write([u8(chr)])! } } else { slice := s[i..i + char_len] hex_code := slice.utf32_code().hex().bytes() if !e.escape_unicode || hex_code.len < 4 { // unescaped non-ASCII char wr.write(slice.bytes())! } else if hex_code.len == 4 { // a unicode endpoint wr.write(json2.unicode_escape_chars)! wr.write(hex_code)! } else { // TODO: still figuring out what // to do with more than 4 chars wr.write(json2.space_bytes)! } unsafe { slice.free() hex_code.free() } } i += char_len } wr.write(json2.quote_bytes)! }