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817 lines
22 KiB
V
817 lines
22 KiB
V
// Copyright (c) 2019-2021 Alexander Medvednikov. All rights reserved.
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// Use of this source code is governed by an MIT license
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// that can be found in the LICENSE file.
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module builtin
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// import hash.wyhash as hash
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import hash
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/*
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This is a highly optimized hashmap implementation. It has several traits that
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in combination makes it very fast and memory efficient. Here is a short expl-
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anation of each trait. After reading this you should have a basic understand-
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ing of how it functions:
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1. Hash-function: Wyhash. Wyhash is the fastest hash-function for short keys
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passing SMHasher, so it was an obvious choice.
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2. Open addressing: Robin Hood Hashing. With this method, a hash-collision is
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resolved by probing. As opposed to linear probing, Robin Hood hashing has a
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simple but clever twist: As new keys are inserted, old keys are shifted arou-
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nd in a way such that all keys stay reasonably close to the slot they origin-
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ally hash to. A new key may displace a key already inserted if its probe cou-
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nt is larger than that of the key at the current position.
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3. Memory layout: key-value pairs are stored in a `DenseArray`. This is a dy-
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namic array with a very low volume of unused memory, at the cost of more rea-
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llocations when inserting elements. It also preserves the order of the key-v-
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alues. This array is named `key_values`. Instead of probing a new key-value,
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this map probes two 32-bit numbers collectively. The first number has its 8
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most significant bits reserved for the probe-count and the remaining 24 bits
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are cached bits from the hash which are utilized for faster re-hashing. This
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number is often referred to as `meta`. The other 32-bit number is the index
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at which the key-value was pushed to in `key_values`. Both of these numbers
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are stored in a sparse array `metas`. The `meta`s and `kv_index`s are stored
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at even and odd indices, respectively:
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metas = [meta, kv_index, 0, 0, meta, kv_index, 0, 0, meta, kv_index, ...]
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key_values = [kv, kv, kv, ...]
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4. The size of metas is a power of two. This enables the use of bitwise AND
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to convert the 64-bit hash to a bucket/index that doesn't overflow metas. If
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the size is power of two you can use "hash & (SIZE - 1)" instead of "hash %
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SIZE". Modulo is extremely expensive so using '&' is a big performance impro-
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vement. The general concern with this approach is that you only make use of
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the lower bits of the hash which can cause more collisions. This is solved by
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using a well-dispersed hash-function.
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5. The hashmap keeps track of the highest probe_count. The trick is to alloc-
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ate `extra_metas` > max(probe_count), so you never have to do any bounds-che-
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cking since the extra meta memory ensures that a meta will never go beyond
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the last index.
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6. Cached rehashing. When the `load_factor` of the map exceeds the `max_load_
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factor` the size of metas is doubled and all the key-values are "rehashed" to
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find the index for their meta's in the new array. Instead of rehashing compl-
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etely, it simply uses the cached-hashbits stored in the meta, resulting in
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much faster rehashing.
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*/
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const (
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// Number of bits from the hash stored for each entry
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hashbits = 24
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// Number of bits from the hash stored for rehashing
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max_cached_hashbits = 16
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// Initial log-number of buckets in the hashtable
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init_log_capicity = 5
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// Initial number of buckets in the hashtable
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init_capicity = 1 << init_log_capicity
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// Maximum load-factor (len / capacity)
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max_load_factor = 0.8
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// Initial highest even index in metas
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init_even_index = init_capicity - 2
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// Used for incrementing `extra_metas` when max
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// probe count is too high, to avoid overflow
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extra_metas_inc = 4
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// Bitmask to select all the hashbits
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hash_mask = u32(0x00FFFFFF)
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// Used for incrementing the probe-count
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probe_inc = u32(0x01000000)
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)
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// fast_string_eq is intended to be fast when
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// the strings are very likely to be equal
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// TODO: add branch prediction hints
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[inline]
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fn fast_string_eq(a string, b string) bool {
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if a.len != b.len {
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return false
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}
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unsafe {
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return C.memcmp(a.str, b.str, b.len) == 0
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}
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}
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// DenseArray represents a dynamic array with very low growth factor
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struct DenseArray {
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key_bytes int
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value_bytes int
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mut:
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cap int
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len int
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deletes u32 // count
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// array allocated (with `cap` bytes) on first deletion
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// has non-zero element when key deleted
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all_deleted &byte
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values &byte
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keys &byte
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}
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[inline]
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fn new_dense_array(key_bytes int, value_bytes int) DenseArray {
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cap := 8
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return DenseArray{
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key_bytes: key_bytes
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value_bytes: value_bytes
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cap: cap
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len: 0
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deletes: 0
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all_deleted: 0
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keys: unsafe { malloc(cap * key_bytes) }
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values: unsafe { malloc(cap * value_bytes) }
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}
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}
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[inline]
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fn (d &DenseArray) key(i int) voidptr {
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return unsafe { d.keys + i * d.key_bytes }
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}
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// for cgen
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[inline]
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fn (d &DenseArray) value(i int) voidptr {
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return unsafe { d.values + i * d.value_bytes }
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}
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[inline]
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fn (d &DenseArray) has_index(i int) bool {
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return d.deletes == 0 || unsafe { d.all_deleted[i] } == 0
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}
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// Make space to append an element and return index
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// The growth-factor is roughly 1.125 `(x + (x >> 3))`
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[inline]
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fn (mut d DenseArray) expand() int {
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old_cap := d.cap
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old_value_size := d.value_bytes * old_cap
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old_key_size := d.key_bytes * old_cap
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if d.cap == d.len {
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d.cap += d.cap >> 3
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unsafe {
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d.keys = realloc_data(d.keys, old_key_size, d.key_bytes * d.cap)
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d.values = realloc_data(d.values, old_value_size, d.value_bytes * d.cap)
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if d.deletes != 0 {
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d.all_deleted = realloc_data(d.all_deleted, old_cap, d.cap)
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C.memset(d.all_deleted + d.len, 0, d.cap - d.len)
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}
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}
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}
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push_index := d.len
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unsafe {
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if d.deletes != 0 {
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d.all_deleted[push_index] = 0
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}
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}
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d.len++
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return push_index
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}
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// Move all zeros to the end of the array and resize array
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fn (mut d DenseArray) zeros_to_end() {
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// TODO alloca?
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mut tmp_value := unsafe { malloc(d.value_bytes) }
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mut tmp_key := unsafe { malloc(d.key_bytes) }
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mut count := 0
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for i in 0 .. d.len {
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if d.has_index(i) {
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// swap (TODO: optimize)
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unsafe {
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// Swap keys
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C.memcpy(tmp_key, d.key(count), d.key_bytes)
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C.memcpy(d.key(count), d.key(i), d.key_bytes)
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C.memcpy(d.key(i), tmp_key, d.key_bytes)
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// Swap values
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C.memcpy(tmp_value, d.value(count), d.value_bytes)
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C.memcpy(d.value(count), d.value(i), d.value_bytes)
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C.memcpy(d.value(i), tmp_value, d.value_bytes)
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}
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count++
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}
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}
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unsafe {
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free(tmp_value)
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free(tmp_key)
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d.deletes = 0
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// TODO: reallocate instead as more deletes are likely
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free(d.all_deleted)
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}
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d.len = count
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old_cap := d.cap
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d.cap = if count < 8 { 8 } else { count }
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unsafe {
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d.values = realloc_data(d.values, d.value_bytes * old_cap, d.value_bytes * d.cap)
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d.keys = realloc_data(d.keys, d.key_bytes * old_cap, d.key_bytes * d.cap)
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}
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}
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type MapHashFn = fn (voidptr) u64
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type MapEqFn = fn (voidptr, voidptr) bool
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type MapCloneFn = fn (voidptr, voidptr)
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type MapFreeFn = fn (voidptr)
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// map is the internal representation of a V `map` type.
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pub struct map {
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// Number of bytes of a key
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key_bytes int
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// Number of bytes of a value
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value_bytes int
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mut:
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// Highest even index in the hashtable
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even_index u32
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// Number of cached hashbits left for rehashing
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cached_hashbits byte
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// Used for right-shifting out used hashbits
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shift byte
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// Array storing key-values (ordered)
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key_values DenseArray
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// Pointer to meta-data:
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// - Odd indices store kv_index.
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// - Even indices store probe_count and hashbits.
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metas &u32
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// Extra metas that allows for no ranging when incrementing
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// index in the hashmap
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extra_metas u32
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has_string_keys bool
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hash_fn MapHashFn
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key_eq_fn MapEqFn
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clone_fn MapCloneFn
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free_fn MapFreeFn
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pub mut:
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// Number of key-values currently in the hashmap
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len int
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}
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fn map_hash_string(pkey voidptr) u64 {
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key := *unsafe { &string(pkey) }
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return hash.wyhash_c(key.str, u64(key.len), 0)
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}
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fn map_hash_int_1(pkey voidptr) u64 {
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return hash.wyhash64_c(*unsafe { &byte(pkey) }, 0)
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}
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fn map_hash_int_2(pkey voidptr) u64 {
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return hash.wyhash64_c(*unsafe { &u16(pkey) }, 0)
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}
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fn map_hash_int_4(pkey voidptr) u64 {
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return hash.wyhash64_c(*unsafe { &u32(pkey) }, 0)
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}
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fn map_hash_int_8(pkey voidptr) u64 {
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return hash.wyhash64_c(*unsafe { &u64(pkey) }, 0)
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}
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fn map_eq_string(a voidptr, b voidptr) bool {
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return fast_string_eq(*unsafe { &string(a) }, *unsafe { &string(b) })
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}
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fn map_eq_int_1(a voidptr, b voidptr) bool {
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return unsafe { *&byte(a) == *&byte(b) }
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}
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fn map_eq_int_2(a voidptr, b voidptr) bool {
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return unsafe { *&u16(a) == *&u16(b) }
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}
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fn map_eq_int_4(a voidptr, b voidptr) bool {
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return unsafe { *&u32(a) == *&u32(b) }
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}
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fn map_eq_int_8(a voidptr, b voidptr) bool {
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return unsafe { *&u64(a) == *&u64(b) }
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}
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fn map_clone_string(dest voidptr, pkey voidptr) {
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unsafe {
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s := *&string(pkey)
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(*&string(dest)) = s.clone()
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}
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}
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fn map_clone_int_1(dest voidptr, pkey voidptr) {
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unsafe {
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*&byte(dest) = *&byte(pkey)
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}
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}
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fn map_clone_int_2(dest voidptr, pkey voidptr) {
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unsafe {
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*&u16(dest) = *&u16(pkey)
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}
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}
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fn map_clone_int_4(dest voidptr, pkey voidptr) {
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unsafe {
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*&u32(dest) = *&u32(pkey)
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}
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}
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fn map_clone_int_8(dest voidptr, pkey voidptr) {
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unsafe {
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*&u64(dest) = *&u64(pkey)
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}
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}
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fn map_free_string(pkey voidptr) {
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unsafe {
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(*&string(pkey)).free()
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}
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}
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fn map_free_nop(_ voidptr) {
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}
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fn new_map_2(key_bytes int, value_bytes int, hash_fn MapHashFn, key_eq_fn MapEqFn, clone_fn MapCloneFn, free_fn MapFreeFn) map {
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metasize := int(sizeof(u32) * (init_capicity + extra_metas_inc))
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// for now assume anything bigger than a pointer is a string
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has_string_keys := key_bytes > sizeof(voidptr)
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return map{
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key_bytes: key_bytes
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value_bytes: value_bytes
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even_index: init_even_index
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cached_hashbits: max_cached_hashbits
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shift: init_log_capicity
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key_values: new_dense_array(key_bytes, value_bytes)
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metas: unsafe { &u32(vcalloc(metasize)) }
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extra_metas: extra_metas_inc
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len: 0
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has_string_keys: has_string_keys
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hash_fn: hash_fn
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key_eq_fn: key_eq_fn
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clone_fn: clone_fn
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free_fn: free_fn
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}
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}
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fn new_map_init_2(hash_fn MapHashFn, key_eq_fn MapEqFn, clone_fn MapCloneFn, free_fn MapFreeFn, n int, key_bytes int, value_bytes int, keys voidptr, values voidptr) map {
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mut out := new_map_2(key_bytes, value_bytes, hash_fn, key_eq_fn, clone_fn, free_fn)
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// TODO pre-allocate n slots
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mut pkey := &byte(keys)
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mut pval := &byte(values)
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for _ in 0 .. n {
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unsafe {
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out.set_1(pkey, pval)
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pkey = pkey + key_bytes
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pval = pval + value_bytes
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}
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}
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return out
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}
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pub fn (mut m map) move() map {
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r := *m
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unsafe {
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C.memset(m, 0, sizeof(map))
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}
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return r
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}
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[inline]
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fn (m &map) key_to_index(pkey voidptr) (u32, u32) {
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hash := m.hash_fn(pkey)
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index := hash & m.even_index
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meta := ((hash >> m.shift) & hash_mask) | probe_inc
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return u32(index), u32(meta)
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}
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[inline]
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fn (m &map) meta_less(_index u32, _metas u32) (u32, u32) {
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mut index := _index
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mut meta := _metas
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for meta < unsafe { m.metas[index] } {
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index += 2
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meta += probe_inc
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}
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return index, meta
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}
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[inline]
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fn (mut m map) meta_greater(_index u32, _metas u32, kvi u32) {
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mut meta := _metas
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mut index := _index
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mut kv_index := kvi
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for unsafe { m.metas[index] } != 0 {
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if meta > unsafe { m.metas[index] } {
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unsafe {
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tmp_meta := m.metas[index]
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m.metas[index] = meta
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meta = tmp_meta
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tmp_index := m.metas[index + 1]
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m.metas[index + 1] = kv_index
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kv_index = tmp_index
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}
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}
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index += 2
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meta += probe_inc
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}
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unsafe {
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m.metas[index] = meta
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m.metas[index + 1] = kv_index
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}
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probe_count := (meta >> hashbits) - 1
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m.ensure_extra_metas(probe_count)
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}
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[inline]
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fn (mut m map) ensure_extra_metas(probe_count u32) {
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if (probe_count << 1) == m.extra_metas {
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size_of_u32 := sizeof(u32)
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old_mem_size := (m.even_index + 2 + m.extra_metas)
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m.extra_metas += extra_metas_inc
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mem_size := (m.even_index + 2 + m.extra_metas)
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unsafe {
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x := realloc_data(&byte(m.metas), int(size_of_u32 * old_mem_size), int(size_of_u32 * mem_size))
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m.metas = &u32(x)
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C.memset(m.metas + mem_size - extra_metas_inc, 0, int(sizeof(u32) * extra_metas_inc))
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}
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// Should almost never happen
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if probe_count == 252 {
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panic('Probe overflow')
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}
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}
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}
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// Insert new element to the map. The element is inserted if its key is
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// not equivalent to the key of any other element already in the container.
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// If the key already exists, its value is changed to the value of the new element.
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fn (mut m map) set_1(key voidptr, value voidptr) {
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load_factor := f32(m.len << 1) / f32(m.even_index)
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if load_factor > max_load_factor {
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m.expand()
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}
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mut index, mut meta := m.key_to_index(key)
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index, meta = m.meta_less(index, meta)
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// While we might have a match
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for meta == unsafe { m.metas[index] } {
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kv_index := int(unsafe { m.metas[index + 1] })
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pkey := unsafe { m.key_values.key(kv_index) }
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if m.key_eq_fn(key, pkey) {
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unsafe {
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pval := m.key_values.value(kv_index)
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C.memcpy(pval, value, m.value_bytes)
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}
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return
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}
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index += 2
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meta += probe_inc
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}
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kv_index := m.key_values.expand()
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unsafe {
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pkey := m.key_values.key(kv_index)
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pvalue := m.key_values.value(kv_index)
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m.clone_fn(pkey, key)
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C.memcpy(&byte(pvalue), value, m.value_bytes)
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}
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m.meta_greater(index, meta, u32(kv_index))
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m.len++
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}
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// Doubles the size of the hashmap
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fn (mut m map) expand() {
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old_cap := m.even_index
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m.even_index = ((m.even_index + 2) << 1) - 2
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// Check if any hashbits are left
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if m.cached_hashbits == 0 {
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m.shift += max_cached_hashbits
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m.cached_hashbits = max_cached_hashbits
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m.rehash()
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} else {
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m.cached_rehash(old_cap)
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m.cached_hashbits--
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}
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}
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// A rehash is the reconstruction of the hash table:
|
|
// All the elements in the container are rearranged according
|
|
// to their hash value into the newly sized key-value container.
|
|
// Rehashes are performed when the load_factor is going to surpass
|
|
// the max_load_factor in an operation.
|
|
fn (mut m map) rehash() {
|
|
meta_bytes := sizeof(u32) * (m.even_index + 2 + m.extra_metas)
|
|
unsafe {
|
|
// TODO: use realloc_data here too
|
|
x := v_realloc(&byte(m.metas), int(meta_bytes))
|
|
m.metas = &u32(x)
|
|
C.memset(m.metas, 0, meta_bytes)
|
|
}
|
|
for i := 0; i < m.key_values.len; i++ {
|
|
if !m.key_values.has_index(i) {
|
|
continue
|
|
}
|
|
pkey := unsafe { m.key_values.key(i) }
|
|
mut index, mut meta := m.key_to_index(pkey)
|
|
index, meta = m.meta_less(index, meta)
|
|
m.meta_greater(index, meta, u32(i))
|
|
}
|
|
}
|
|
|
|
// This method works like rehash. However, instead of rehashing the
|
|
// key completely, it uses the bits cached in `metas`.
|
|
fn (mut m map) cached_rehash(old_cap u32) {
|
|
old_metas := m.metas
|
|
metasize := int(sizeof(u32) * (m.even_index + 2 + m.extra_metas))
|
|
m.metas = unsafe { &u32(vcalloc(metasize)) }
|
|
old_extra_metas := m.extra_metas
|
|
for i := u32(0); i <= old_cap + old_extra_metas; i += 2 {
|
|
if unsafe { old_metas[i] } == 0 {
|
|
continue
|
|
}
|
|
old_meta := unsafe { old_metas[i] }
|
|
old_probe_count := ((old_meta >> hashbits) - 1) << 1
|
|
old_index := (i - old_probe_count) & (m.even_index >> 1)
|
|
mut index := (old_index | (old_meta << m.shift)) & m.even_index
|
|
mut meta := (old_meta & hash_mask) | probe_inc
|
|
index, meta = m.meta_less(index, meta)
|
|
kv_index := unsafe { old_metas[i + 1] }
|
|
m.meta_greater(index, meta, kv_index)
|
|
}
|
|
unsafe { free(old_metas) }
|
|
}
|
|
|
|
// This method is used for assignment operators. If the argument-key
|
|
// does not exist in the map, it's added to the map along with the zero/default value.
|
|
// If the key exists, its respective value is returned.
|
|
fn (mut m map) get_and_set_1(key voidptr, zero voidptr) voidptr {
|
|
for {
|
|
mut index, mut meta := m.key_to_index(key)
|
|
for {
|
|
if meta == unsafe { m.metas[index] } {
|
|
kv_index := int(unsafe { m.metas[index + 1] })
|
|
pkey := unsafe { m.key_values.key(kv_index) }
|
|
if m.key_eq_fn(key, pkey) {
|
|
pval := unsafe { m.key_values.value(kv_index) }
|
|
return unsafe { &byte(pval) }
|
|
}
|
|
}
|
|
index += 2
|
|
meta += probe_inc
|
|
if meta > unsafe { m.metas[index] } {
|
|
break
|
|
}
|
|
}
|
|
// Key not found, insert key with zero-value
|
|
m.set_1(key, zero)
|
|
}
|
|
assert false
|
|
return voidptr(0)
|
|
}
|
|
|
|
// If `key` matches the key of an element in the container,
|
|
// the method returns a reference to its mapped value.
|
|
// If not, a zero/default value is returned.
|
|
fn (m &map) get_1(key voidptr, zero voidptr) voidptr {
|
|
mut index, mut meta := m.key_to_index(key)
|
|
for {
|
|
if meta == unsafe { m.metas[index] } {
|
|
kv_index := int(unsafe { m.metas[index + 1] })
|
|
pkey := unsafe { m.key_values.key(kv_index) }
|
|
if m.key_eq_fn(key, pkey) {
|
|
pval := unsafe { m.key_values.value(kv_index) }
|
|
return unsafe { &byte(pval) }
|
|
}
|
|
}
|
|
index += 2
|
|
meta += probe_inc
|
|
if meta > unsafe { m.metas[index] } {
|
|
break
|
|
}
|
|
}
|
|
return zero
|
|
}
|
|
|
|
// If `key` matches the key of an element in the container,
|
|
// the method returns a reference to its mapped value.
|
|
// If not, a zero pointer is returned.
|
|
// This is used in `x := m['key'] or { ... }`
|
|
fn (m &map) get_1_check(key voidptr) voidptr {
|
|
mut index, mut meta := m.key_to_index(key)
|
|
for {
|
|
if meta == unsafe { m.metas[index] } {
|
|
kv_index := int(unsafe { m.metas[index + 1] })
|
|
pkey := unsafe { m.key_values.key(kv_index) }
|
|
if m.key_eq_fn(key, pkey) {
|
|
pval := unsafe { m.key_values.value(kv_index) }
|
|
return unsafe { &byte(pval) }
|
|
}
|
|
}
|
|
index += 2
|
|
meta += probe_inc
|
|
if meta > unsafe { m.metas[index] } {
|
|
break
|
|
}
|
|
}
|
|
return 0
|
|
}
|
|
|
|
// Checks whether a particular key exists in the map.
|
|
fn (m &map) exists_1(key voidptr) bool {
|
|
mut index, mut meta := m.key_to_index(key)
|
|
for {
|
|
if meta == unsafe { m.metas[index] } {
|
|
kv_index := int(unsafe { m.metas[index + 1] })
|
|
pkey := unsafe { m.key_values.key(kv_index) }
|
|
if m.key_eq_fn(key, pkey) {
|
|
return true
|
|
}
|
|
}
|
|
index += 2
|
|
meta += probe_inc
|
|
if meta > unsafe { m.metas[index] } {
|
|
break
|
|
}
|
|
}
|
|
return false
|
|
}
|
|
|
|
[inline]
|
|
fn (mut d DenseArray) delete(i int) {
|
|
if d.deletes == 0 {
|
|
d.all_deleted = vcalloc(d.cap) // sets to 0
|
|
}
|
|
d.deletes++
|
|
unsafe {
|
|
d.all_deleted[i] = 1
|
|
}
|
|
}
|
|
|
|
// delete this
|
|
pub fn (mut m map) delete(key string) {
|
|
unsafe {
|
|
m.delete_1(&key)
|
|
}
|
|
}
|
|
|
|
// Removes the mapping of a particular key from the map.
|
|
[unsafe]
|
|
pub fn (mut m map) delete_1(key voidptr) {
|
|
mut index, mut meta := m.key_to_index(key)
|
|
index, meta = m.meta_less(index, meta)
|
|
// Perform backwards shifting
|
|
for meta == unsafe { m.metas[index] } {
|
|
kv_index := int(unsafe { m.metas[index + 1] })
|
|
pkey := unsafe { m.key_values.key(kv_index) }
|
|
if m.key_eq_fn(key, pkey) {
|
|
for (unsafe { m.metas[index + 2] } >> hashbits) > 1 {
|
|
unsafe {
|
|
m.metas[index] = m.metas[index + 2] - probe_inc
|
|
m.metas[index + 1] = m.metas[index + 3]
|
|
}
|
|
index += 2
|
|
}
|
|
m.len--
|
|
m.key_values.delete(kv_index)
|
|
unsafe {
|
|
m.metas[index] = 0
|
|
m.free_fn(pkey)
|
|
// Mark key as deleted
|
|
C.memset(pkey, 0, m.key_bytes)
|
|
}
|
|
if m.key_values.len <= 32 {
|
|
return
|
|
}
|
|
// Clean up key_values if too many have been deleted
|
|
if m.key_values.deletes >= (m.key_values.len >> 1) {
|
|
m.key_values.zeros_to_end()
|
|
m.rehash()
|
|
}
|
|
return
|
|
}
|
|
index += 2
|
|
meta += probe_inc
|
|
}
|
|
}
|
|
|
|
// bootstrap
|
|
// delete this
|
|
pub fn (m &map) keys() []string {
|
|
mut keys := []string{len: m.len}
|
|
mut item := unsafe { &byte(keys.data) }
|
|
for i := 0; i < m.key_values.len; i++ {
|
|
if !m.key_values.has_index(i) {
|
|
continue
|
|
}
|
|
unsafe {
|
|
pkey := m.key_values.key(i)
|
|
m.clone_fn(item, pkey)
|
|
item = item + m.key_bytes
|
|
}
|
|
}
|
|
return keys
|
|
}
|
|
|
|
// Returns all keys in the map.
|
|
fn (m &map) keys_1() array {
|
|
mut keys := __new_array(m.len, 0, m.key_bytes)
|
|
mut item := unsafe { &byte(keys.data) }
|
|
if m.key_values.deletes == 0 {
|
|
for i := 0; i < m.key_values.len; i++ {
|
|
unsafe {
|
|
pkey := m.key_values.key(i)
|
|
m.clone_fn(item, pkey)
|
|
item = item + m.key_bytes
|
|
}
|
|
}
|
|
return keys
|
|
}
|
|
for i := 0; i < m.key_values.len; i++ {
|
|
if !m.key_values.has_index(i) {
|
|
continue
|
|
}
|
|
unsafe {
|
|
pkey := m.key_values.key(i)
|
|
m.clone_fn(item, pkey)
|
|
item = item + m.key_bytes
|
|
}
|
|
}
|
|
return keys
|
|
}
|
|
|
|
// warning: only copies keys, does not clone
|
|
[unsafe]
|
|
fn (d &DenseArray) clone() DenseArray {
|
|
res := DenseArray{
|
|
key_bytes: d.key_bytes
|
|
value_bytes: d.value_bytes
|
|
cap: d.cap
|
|
len: d.len
|
|
deletes: d.deletes
|
|
all_deleted: 0
|
|
values: 0
|
|
keys: 0
|
|
}
|
|
unsafe {
|
|
if d.deletes != 0 {
|
|
res.all_deleted = memdup(d.all_deleted, d.cap)
|
|
}
|
|
res.keys = memdup(d.keys, d.cap * d.key_bytes)
|
|
res.values = memdup(d.values, d.cap * d.value_bytes)
|
|
}
|
|
return res
|
|
}
|
|
|
|
// clone returns a clone of the `map`.
|
|
[unsafe]
|
|
pub fn (m &map) clone() map {
|
|
metasize := int(sizeof(u32) * (m.even_index + 2 + m.extra_metas))
|
|
res := map{
|
|
key_bytes: m.key_bytes
|
|
value_bytes: m.value_bytes
|
|
even_index: m.even_index
|
|
cached_hashbits: m.cached_hashbits
|
|
shift: m.shift
|
|
key_values: unsafe { m.key_values.clone() }
|
|
metas: unsafe { &u32(malloc(metasize)) }
|
|
extra_metas: m.extra_metas
|
|
len: m.len
|
|
has_string_keys: m.has_string_keys
|
|
hash_fn: m.hash_fn
|
|
key_eq_fn: m.key_eq_fn
|
|
clone_fn: m.clone_fn
|
|
free_fn: m.free_fn
|
|
}
|
|
unsafe { C.memcpy(res.metas, m.metas, metasize) }
|
|
if !m.has_string_keys {
|
|
return res
|
|
}
|
|
// clone keys
|
|
for i in 0 .. m.key_values.len {
|
|
if !m.key_values.has_index(i) {
|
|
continue
|
|
}
|
|
m.clone_fn(res.key_values.key(i), m.key_values.key(i))
|
|
}
|
|
return res
|
|
}
|
|
|
|
// free releases all memory resources occupied by the `map`.
|
|
[unsafe]
|
|
pub fn (m &map) free() {
|
|
unsafe { free(m.metas) }
|
|
if m.key_values.deletes == 0 {
|
|
for i := 0; i < m.key_values.len; i++ {
|
|
unsafe {
|
|
pkey := m.key_values.key(i)
|
|
m.free_fn(pkey)
|
|
}
|
|
}
|
|
} else {
|
|
for i := 0; i < m.key_values.len; i++ {
|
|
if !m.key_values.has_index(i) {
|
|
continue
|
|
}
|
|
unsafe {
|
|
pkey := m.key_values.key(i)
|
|
m.free_fn(pkey)
|
|
}
|
|
}
|
|
unsafe { free(m.key_values.all_deleted) }
|
|
}
|
|
unsafe {
|
|
free(m.key_values.keys)
|
|
free(m.key_values.values)
|
|
}
|
|
}
|