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godot/thirdparty/astcenc/astcenc_internal.h
Peter Harris 75ce42d463 Update astcenc to the upstream 5.3.0 release 
This is mostly a maintenance update that brings the compressor inline
with the recently published Khronos Data Format Specification 1.4
release which clarified some ambiguity in the specification. This update
also gives minor codec optimizations, bug fixes, and image quality
improvements.

The biggest improvement for Godot is that builds using MSVC cl.exe will
now correctly default to the SSE2-optimized backend rather than the
reference C backend. This makes compression more than 3 times faster.
Builds using other compilers (GCC, LLVM/Clang) were not impacted by the
underlying issue, and see no performance uplift.
2025-03-21 16:02:50 -07:00

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// SPDX-License-Identifier: Apache-2.0
// ----------------------------------------------------------------------------
// Copyright 2011-2024 Arm Limited
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not
// use this file except in compliance with the License. You may obtain a copy
// of the License at:
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations
// under the License.
// ----------------------------------------------------------------------------
/**
* @brief Functions and data declarations.
*/
#ifndef ASTCENC_INTERNAL_INCLUDED
#define ASTCENC_INTERNAL_INCLUDED
#include <algorithm>
#include <cstddef>
#include <cstdint>
#if defined(ASTCENC_DIAGNOSTICS)
#include <cstdio>
#endif
#include <cstdlib>
#include <limits>
#include "astcenc.h"
#include "astcenc_mathlib.h"
#include "astcenc_vecmathlib.h"
/**
* @brief Make a promise to the compiler's optimizer.
*
* A promise is an expression that the optimizer is can assume is true for to help it generate
* faster code. Common use cases for this are to promise that a for loop will iterate more than
* once, or that the loop iteration count is a multiple of a vector length, which avoids pre-loop
* checks and can avoid loop tails if loops are unrolled by the auto-vectorizer.
*/
#if defined(NDEBUG)
#if !defined(__clang__) && defined(_MSC_VER)
#define promise(cond) __assume(cond)
#elif defined(__clang__)
#if __has_builtin(__builtin_assume)
#define promise(cond) __builtin_assume(cond)
#elif __has_builtin(__builtin_unreachable)
#define promise(cond) if (!(cond)) { __builtin_unreachable(); }
#else
#define promise(cond)
#endif
#else // Assume GCC
#define promise(cond) if (!(cond)) { __builtin_unreachable(); }
#endif
#else
#define promise(cond) assert(cond)
#endif
/* ============================================================================
Constants
============================================================================ */
#if !defined(ASTCENC_BLOCK_MAX_TEXELS)
#define ASTCENC_BLOCK_MAX_TEXELS 216 // A 3D 6x6x6 block
#endif
/** @brief The maximum number of texels a block can support (6x6x6 block). */
static constexpr unsigned int BLOCK_MAX_TEXELS { ASTCENC_BLOCK_MAX_TEXELS };
/** @brief The maximum number of components a block can support. */
static constexpr unsigned int BLOCK_MAX_COMPONENTS { 4 };
/** @brief The maximum number of partitions a block can support. */
static constexpr unsigned int BLOCK_MAX_PARTITIONS { 4 };
/** @brief The number of partitionings, per partition count, suported by the ASTC format. */
static constexpr unsigned int BLOCK_MAX_PARTITIONINGS { 1024 };
/** @brief The maximum number of texels used during partition selection for texel clustering. */
static constexpr uint8_t BLOCK_MAX_KMEANS_TEXELS { 64 };
/** @brief The maximum number of weights a block can support. */
static constexpr unsigned int BLOCK_MAX_WEIGHTS { 64 };
/** @brief The maximum number of weights a block can support per plane in 2 plane mode. */
static constexpr unsigned int BLOCK_MAX_WEIGHTS_2PLANE { BLOCK_MAX_WEIGHTS / 2 };
/** @brief The minimum number of weight bits a candidate encoding must encode. */
static constexpr unsigned int BLOCK_MIN_WEIGHT_BITS { 24 };
/** @brief The maximum number of weight bits a candidate encoding can encode. */
static constexpr unsigned int BLOCK_MAX_WEIGHT_BITS { 96 };
/** @brief The index indicating a bad (unused) block mode in the remap array. */
static constexpr uint16_t BLOCK_BAD_BLOCK_MODE { 0xFFFFu };
/** @brief The index indicating a bad (unused) partitioning in the remap array. */
static constexpr uint16_t BLOCK_BAD_PARTITIONING { 0xFFFFu };
/** @brief The number of partition index bits supported by the ASTC format . */
static constexpr unsigned int PARTITION_INDEX_BITS { 10 };
/** @brief The offset of the plane 2 weights in shared weight arrays. */
static constexpr unsigned int WEIGHTS_PLANE2_OFFSET { BLOCK_MAX_WEIGHTS_2PLANE };
/** @brief The sum of quantized weights for one texel. */
static constexpr float WEIGHTS_TEXEL_SUM { 16.0f };
/** @brief The number of block modes supported by the ASTC format. */
static constexpr unsigned int WEIGHTS_MAX_BLOCK_MODES { 2048 };
/** @brief The number of weight grid decimation modes supported by the ASTC format. */
static constexpr unsigned int WEIGHTS_MAX_DECIMATION_MODES { 87 };
/** @brief The high default error used to initialize error trackers. */
static constexpr float ERROR_CALC_DEFAULT { 1e30f };
/**
* @brief The minimum tuning setting threshold for the one partition fast path.
*/
static constexpr float TUNE_MIN_SEARCH_MODE0 { 0.85f };
/**
* @brief The maximum number of candidate encodings tested for each encoding mode.
*
* This can be dynamically reduced by the compression quality preset.
*/
static constexpr unsigned int TUNE_MAX_TRIAL_CANDIDATES { 8 };
/**
* @brief The maximum number of candidate partitionings tested for each encoding mode.
*
* This can be dynamically reduced by the compression quality preset.
*/
static constexpr unsigned int TUNE_MAX_PARTITIONING_CANDIDATES { 8 };
/**
* @brief The maximum quant level using full angular endpoint search method.
*
* The angular endpoint search is used to find the min/max weight that should
* be used for a given quantization level. It is effective but expensive, so
* we only use it where it has the most value - low quant levels with wide
* spacing. It is used below TUNE_MAX_ANGULAR_QUANT (inclusive). Above this we
* assume the min weight is 0.0f, and the max weight is 1.0f.
*
* Note the angular algorithm is vectorized, and using QUANT_12 exactly fills
* one 8-wide vector. Decreasing by one doesn't buy much performance, and
* increasing by one is disproportionately expensive.
*/
static constexpr unsigned int TUNE_MAX_ANGULAR_QUANT { 7 }; /* QUANT_12 */
static_assert((BLOCK_MAX_TEXELS % ASTCENC_SIMD_WIDTH) == 0,
"BLOCK_MAX_TEXELS must be multiple of ASTCENC_SIMD_WIDTH");
static_assert(BLOCK_MAX_TEXELS <= 216,
"BLOCK_MAX_TEXELS must not be greater than 216");
static_assert((BLOCK_MAX_WEIGHTS % ASTCENC_SIMD_WIDTH) == 0,
"BLOCK_MAX_WEIGHTS must be multiple of ASTCENC_SIMD_WIDTH");
static_assert((WEIGHTS_MAX_BLOCK_MODES % ASTCENC_SIMD_WIDTH) == 0,
"WEIGHTS_MAX_BLOCK_MODES must be multiple of ASTCENC_SIMD_WIDTH");
/* ============================================================================
Commonly used data structures
============================================================================ */
/**
* @brief The ASTC endpoint formats.
*
* Note, the values here are used directly in the encoding in the format so do not rearrange.
*/
enum endpoint_formats
{
FMT_LUMINANCE = 0,
FMT_LUMINANCE_DELTA = 1,
FMT_HDR_LUMINANCE_LARGE_RANGE = 2,
FMT_HDR_LUMINANCE_SMALL_RANGE = 3,
FMT_LUMINANCE_ALPHA = 4,
FMT_LUMINANCE_ALPHA_DELTA = 5,
FMT_RGB_SCALE = 6,
FMT_HDR_RGB_SCALE = 7,
FMT_RGB = 8,
FMT_RGB_DELTA = 9,
FMT_RGB_SCALE_ALPHA = 10,
FMT_HDR_RGB = 11,
FMT_RGBA = 12,
FMT_RGBA_DELTA = 13,
FMT_HDR_RGB_LDR_ALPHA = 14,
FMT_HDR_RGBA = 15
};
/**
* @brief The ASTC quantization methods.
*
* Note, the values here are used directly in the encoding in the format so do not rearrange.
*/
enum quant_method
{
QUANT_2 = 0,
QUANT_3 = 1,
QUANT_4 = 2,
QUANT_5 = 3,
QUANT_6 = 4,
QUANT_8 = 5,
QUANT_10 = 6,
QUANT_12 = 7,
QUANT_16 = 8,
QUANT_20 = 9,
QUANT_24 = 10,
QUANT_32 = 11,
QUANT_40 = 12,
QUANT_48 = 13,
QUANT_64 = 14,
QUANT_80 = 15,
QUANT_96 = 16,
QUANT_128 = 17,
QUANT_160 = 18,
QUANT_192 = 19,
QUANT_256 = 20
};
/**
* @brief The number of levels use by an ASTC quantization method.
*
* @param method The quantization method
*
* @return The number of levels used by @c method.
*/
static inline unsigned int get_quant_level(quant_method method)
{
switch (method)
{
case QUANT_2: return 2;
case QUANT_3: return 3;
case QUANT_4: return 4;
case QUANT_5: return 5;
case QUANT_6: return 6;
case QUANT_8: return 8;
case QUANT_10: return 10;
case QUANT_12: return 12;
case QUANT_16: return 16;
case QUANT_20: return 20;
case QUANT_24: return 24;
case QUANT_32: return 32;
case QUANT_40: return 40;
case QUANT_48: return 48;
case QUANT_64: return 64;
case QUANT_80: return 80;
case QUANT_96: return 96;
case QUANT_128: return 128;
case QUANT_160: return 160;
case QUANT_192: return 192;
case QUANT_256: return 256;
}
// Unreachable - the enum is fully described
return 0;
}
/**
* @brief Computed metrics about a partition in a block.
*/
struct partition_metrics
{
/** @brief The error-weighted average color in the partition. */
vfloat4 avg;
/** @brief The dominant error-weighted direction in the partition. */
vfloat4 dir;
};
/**
* @brief Computed lines for a a three component analysis.
*/
struct partition_lines3
{
/** @brief Line for uncorrelated chroma. */
line3 uncor_line;
/** @brief Line for correlated chroma, passing though the origin. */
line3 samec_line;
/** @brief Post-processed line for uncorrelated chroma. */
processed_line3 uncor_pline;
/** @brief Post-processed line for correlated chroma, passing though the origin. */
processed_line3 samec_pline;
/**
* @brief The length of the line for uncorrelated chroma.
*
* This is used for both the uncorrelated and same chroma lines - they are normally very similar
* and only used for the relative ranking of partitionings against one another.
*/
float line_length;
};
/**
* @brief The partition information for a single partition.
*
* ASTC has a total of 1024 candidate partitions for each of 2/3/4 partition counts, although this
* 1024 includes seeds that generate duplicates of other seeds and seeds that generate completely
* empty partitions. These are both valid encodings, but astcenc will skip both during compression
* as they are not useful.
*/
struct partition_info
{
/** @brief The number of partitions in this partitioning. */
uint16_t partition_count;
/** @brief The index (seed) of this partitioning. */
uint16_t partition_index;
/**
* @brief The number of texels in each partition.
*
* Note that some seeds result in zero texels assigned to a partition. These are valid, but are
* skipped by this compressor as there is no point spending bits encoding an unused endpoints.
*/
uint8_t partition_texel_count[BLOCK_MAX_PARTITIONS];
/** @brief The partition of each texel in the block. */
ASTCENC_ALIGNAS uint8_t partition_of_texel[BLOCK_MAX_TEXELS];
/** @brief The list of texels in each partition. */
ASTCENC_ALIGNAS uint8_t texels_of_partition[BLOCK_MAX_PARTITIONS][BLOCK_MAX_TEXELS];
};
/**
* @brief The weight grid information for a single decimation pattern.
*
* ASTC can store one weight per texel, but is also capable of storing lower resolution weight grids
* that are interpolated during decompression to assign a with to a texel. Storing fewer weights
* can free up a substantial amount of bits that we can then spend on more useful things, such as
* more accurate endpoints and weights, or additional partitions.
*
* This data structure is used to store information about a single weight grid decimation pattern,
* for a single block size.
*/
struct decimation_info
{
/** @brief The total number of texels in the block. */
uint8_t texel_count;
/** @brief The maximum number of stored weights that contribute to each texel, between 1 and 4. */
uint8_t max_texel_weight_count;
/** @brief The total number of weights stored. */
uint8_t weight_count;
/** @brief The number of stored weights in the X dimension. */
uint8_t weight_x;
/** @brief The number of stored weights in the Y dimension. */
uint8_t weight_y;
/** @brief The number of stored weights in the Z dimension. */
uint8_t weight_z;
/**
* @brief The number of weights that contribute to each texel.
* Value is between 1 and 4.
*/
ASTCENC_ALIGNAS uint8_t texel_weight_count[BLOCK_MAX_TEXELS];
/**
* @brief The weight index of the N weights that are interpolated for each texel.
* Stored transposed to improve vectorization.
*/
ASTCENC_ALIGNAS uint8_t texel_weights_tr[4][BLOCK_MAX_TEXELS];
/**
* @brief The bilinear contribution of the N weights that are interpolated for each texel.
* Value is between 0 and 16, stored transposed to improve vectorization.
*/
ASTCENC_ALIGNAS uint8_t texel_weight_contribs_int_tr[4][BLOCK_MAX_TEXELS];
/**
* @brief The bilinear contribution of the N weights that are interpolated for each texel.
* Value is between 0 and 1, stored transposed to improve vectorization.
*/
ASTCENC_ALIGNAS float texel_weight_contribs_float_tr[4][BLOCK_MAX_TEXELS];
/** @brief The number of texels that each stored weight contributes to. */
ASTCENC_ALIGNAS uint8_t weight_texel_count[BLOCK_MAX_WEIGHTS];
/**
* @brief The list of texels that use a specific weight index.
* Stored transposed to improve vectorization.
*/
ASTCENC_ALIGNAS uint8_t weight_texels_tr[BLOCK_MAX_TEXELS][BLOCK_MAX_WEIGHTS];
/**
* @brief The bilinear contribution to the N texels that use each weight.
* Value is between 0 and 1, stored transposed to improve vectorization.
*/
ASTCENC_ALIGNAS float weights_texel_contribs_tr[BLOCK_MAX_TEXELS][BLOCK_MAX_WEIGHTS];
/**
* @brief The bilinear contribution to the Nth texel that uses each weight.
* Value is between 0 and 1, stored transposed to improve vectorization.
*/
float texel_contrib_for_weight[BLOCK_MAX_TEXELS][BLOCK_MAX_WEIGHTS];
};
/**
* @brief Metadata for single block mode for a specific block size.
*/
struct block_mode
{
/** @brief The block mode index in the ASTC encoded form. */
uint16_t mode_index;
/** @brief The decimation mode index in the compressor reindexed list. */
uint8_t decimation_mode;
/** @brief The weight quantization used by this block mode. */
uint8_t quant_mode;
/** @brief The weight quantization used by this block mode. */
uint8_t weight_bits;
/** @brief Is a dual weight plane used by this block mode? */
uint8_t is_dual_plane : 1;
/**
* @brief Get the weight quantization used by this block mode.
*
* @return The quantization level.
*/
inline quant_method get_weight_quant_mode() const
{
return static_cast<quant_method>(this->quant_mode);
}
};
/**
* @brief Metadata for single decimation mode for a specific block size.
*/
struct decimation_mode
{
/** @brief The max weight precision for 1 plane, or -1 if not supported. */
int8_t maxprec_1plane;
/** @brief The max weight precision for 2 planes, or -1 if not supported. */
int8_t maxprec_2planes;
/**
* @brief Bitvector indicating weight quant modes used by active 1 plane block modes.
*
* Bit 0 = QUANT_2, Bit 1 = QUANT_3, etc.
*/
uint16_t refprec_1plane;
/**
* @brief Bitvector indicating weight quant methods used by active 2 plane block modes.
*
* Bit 0 = QUANT_2, Bit 1 = QUANT_3, etc.
*/
uint16_t refprec_2planes;
/**
* @brief Set a 1 plane weight quant as active.
*
* @param weight_quant The quant method to set.
*/
void set_ref_1plane(quant_method weight_quant)
{
refprec_1plane |= (1 << weight_quant);
}
/**
* @brief Test if this mode is active below a given 1 plane weight quant (inclusive).
*
* @param max_weight_quant The max quant method to test.
*/
bool is_ref_1plane(quant_method max_weight_quant) const
{
uint16_t mask = static_cast<uint16_t>((1 << (max_weight_quant + 1)) - 1);
return (refprec_1plane & mask) != 0;
}
/**
* @brief Set a 2 plane weight quant as active.
*
* @param weight_quant The quant method to set.
*/
void set_ref_2plane(quant_method weight_quant)
{
refprec_2planes |= static_cast<uint16_t>(1 << weight_quant);
}
/**
* @brief Test if this mode is active below a given 2 plane weight quant (inclusive).
*
* @param max_weight_quant The max quant method to test.
*/
bool is_ref_2plane(quant_method max_weight_quant) const
{
uint16_t mask = static_cast<uint16_t>((1 << (max_weight_quant + 1)) - 1);
return (refprec_2planes & mask) != 0;
}
};
/**
* @brief Data tables for a single block size.
*
* The decimation tables store the information to apply weight grid dimension reductions. We only
* store the decimation modes that are actually needed by the current context; many of the possible
* modes will be unused (too many weights for the current block size or disabled by heuristics). The
* actual number of weights stored is @c decimation_mode_count, and the @c decimation_modes and
* @c decimation_tables arrays store the active modes contiguously at the start of the array. These
* entries are not stored in any particular order.
*
* The block mode tables store the unpacked block mode settings. Block modes are stored in the
* compressed block as an 11 bit field, but for any given block size and set of compressor
* heuristics, only a subset of the block modes will be used. The actual number of block modes
* stored is indicated in @c block_mode_count, and the @c block_modes array store the active modes
* contiguously at the start of the array. These entries are stored in incrementing "packed" value
* order, which doesn't mean much once unpacked. To allow decompressors to reference the packed data
* efficiently the @c block_mode_packed_index array stores the mapping between physical ID and the
* actual remapped array index.
*/
struct block_size_descriptor
{
/** @brief The block X dimension, in texels. */
uint8_t xdim;
/** @brief The block Y dimension, in texels. */
uint8_t ydim;
/** @brief The block Z dimension, in texels. */
uint8_t zdim;
/** @brief The block total texel count. */
uint8_t texel_count;
/**
* @brief The number of stored decimation modes which are "always" modes.
*
* Always modes are stored at the start of the decimation_modes list.
*/
unsigned int decimation_mode_count_always;
/** @brief The number of stored decimation modes for selected encodings. */
unsigned int decimation_mode_count_selected;
/** @brief The number of stored decimation modes for any encoding. */
unsigned int decimation_mode_count_all;
/**
* @brief The number of stored block modes which are "always" modes.
*
* Always modes are stored at the start of the block_modes list.
*/
unsigned int block_mode_count_1plane_always;
/** @brief The number of stored block modes for active 1 plane encodings. */
unsigned int block_mode_count_1plane_selected;
/** @brief The number of stored block modes for active 1 and 2 plane encodings. */
unsigned int block_mode_count_1plane_2plane_selected;
/** @brief The number of stored block modes for any encoding. */
unsigned int block_mode_count_all;
/** @brief The number of selected partitionings for 1/2/3/4 partitionings. */
unsigned int partitioning_count_selected[BLOCK_MAX_PARTITIONS];
/** @brief The number of partitionings for 1/2/3/4 partitionings. */
unsigned int partitioning_count_all[BLOCK_MAX_PARTITIONS];
/** @brief The active decimation modes, stored in low indices. */
decimation_mode decimation_modes[WEIGHTS_MAX_DECIMATION_MODES];
/** @brief The active decimation tables, stored in low indices. */
ASTCENC_ALIGNAS decimation_info decimation_tables[WEIGHTS_MAX_DECIMATION_MODES];
/** @brief The packed block mode array index, or @c BLOCK_BAD_BLOCK_MODE if not active. */
uint16_t block_mode_packed_index[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The active block modes, stored in low indices. */
block_mode block_modes[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The active partition tables, stored in low indices per-count. */
partition_info partitionings[(3 * BLOCK_MAX_PARTITIONINGS) + 1];
/**
* @brief The packed partition table array index, or @c BLOCK_BAD_PARTITIONING if not active.
*
* Indexed by partition_count - 2, containing 2, 3 and 4 partitions.
*/
uint16_t partitioning_packed_index[3][BLOCK_MAX_PARTITIONINGS];
/** @brief The active texels for k-means partition selection. */
uint8_t kmeans_texels[BLOCK_MAX_KMEANS_TEXELS];
/**
* @brief The canonical 2-partition coverage pattern used during block partition search.
*
* Indexed by remapped index, not physical index.
*/
uint64_t coverage_bitmaps_2[BLOCK_MAX_PARTITIONINGS][2];
/**
* @brief The canonical 3-partition coverage pattern used during block partition search.
*
* Indexed by remapped index, not physical index.
*/
uint64_t coverage_bitmaps_3[BLOCK_MAX_PARTITIONINGS][3];
/**
* @brief The canonical 4-partition coverage pattern used during block partition search.
*
* Indexed by remapped index, not physical index.
*/
uint64_t coverage_bitmaps_4[BLOCK_MAX_PARTITIONINGS][4];
/**
* @brief Get the block mode structure for index @c block_mode.
*
* This function can only return block modes that are enabled by the current compressor config.
* Decompression from an arbitrary source should not use this without first checking that the
* packed block mode index is not @c BLOCK_BAD_BLOCK_MODE.
*
* @param block_mode The packed block mode index.
*
* @return The block mode structure.
*/
const block_mode& get_block_mode(unsigned int block_mode) const
{
unsigned int packed_index = this->block_mode_packed_index[block_mode];
assert(packed_index != BLOCK_BAD_BLOCK_MODE && packed_index < this->block_mode_count_all);
return this->block_modes[packed_index];
}
/**
* @brief Get the decimation mode structure for index @c decimation_mode.
*
* This function can only return decimation modes that are enabled by the current compressor
* config. The mode array is stored packed, but this is only ever indexed by the packed index
* stored in the @c block_mode and never exists in an unpacked form.
*
* @param decimation_mode The packed decimation mode index.
*
* @return The decimation mode structure.
*/
const decimation_mode& get_decimation_mode(unsigned int decimation_mode) const
{
return this->decimation_modes[decimation_mode];
}
/**
* @brief Get the decimation info structure for index @c decimation_mode.
*
* This function can only return decimation modes that are enabled by the current compressor
* config. The mode array is stored packed, but this is only ever indexed by the packed index
* stored in the @c block_mode and never exists in an unpacked form.
*
* @param decimation_mode The packed decimation mode index.
*
* @return The decimation info structure.
*/
const decimation_info& get_decimation_info(unsigned int decimation_mode) const
{
return this->decimation_tables[decimation_mode];
}
/**
* @brief Get the partition info table for a given partition count.
*
* @param partition_count The number of partitions we want the table for.
*
* @return The pointer to the table of 1024 entries (for 2/3/4 parts) or 1 entry (for 1 part).
*/
const partition_info* get_partition_table(unsigned int partition_count) const
{
if (partition_count == 1)
{
partition_count = 5;
}
unsigned int index = (partition_count - 2) * BLOCK_MAX_PARTITIONINGS;
return this->partitionings + index;
}
/**
* @brief Get the partition info structure for a given partition count and seed.
*
* @param partition_count The number of partitions we want the info for.
* @param index The partition seed (between 0 and 1023).
*
* @return The partition info structure.
*/
const partition_info& get_partition_info(unsigned int partition_count, unsigned int index) const
{
unsigned int packed_index = 0;
if (partition_count >= 2)
{
packed_index = this->partitioning_packed_index[partition_count - 2][index];
}
assert(packed_index != BLOCK_BAD_PARTITIONING && packed_index < this->partitioning_count_all[partition_count - 1]);
auto& result = get_partition_table(partition_count)[packed_index];
assert(index == result.partition_index);
return result;
}
/**
* @brief Get the partition info structure for a given partition count and seed.
*
* @param partition_count The number of partitions we want the info for.
* @param packed_index The raw array offset.
*
* @return The partition info structure.
*/
const partition_info& get_raw_partition_info(unsigned int partition_count, unsigned int packed_index) const
{
assert(packed_index != BLOCK_BAD_PARTITIONING && packed_index < this->partitioning_count_all[partition_count - 1]);
auto& result = get_partition_table(partition_count)[packed_index];
return result;
}
};
/**
* @brief The image data for a single block.
*
* The @c data_[rgba] fields store the image data in an encoded SoA float form designed for easy
* vectorization. Input data is converted to float and stored as values between 0 and 65535. LDR
* data is stored as direct UNORM data, HDR data is stored as LNS data. They are allocated SIMD
* elements over-size to allow vectorized stores of unaligned and partial SIMD lanes (e.g. in a
* 6x6x6 block the final row write will read elements 210-217 (vec8) or 214-217 (vec4), which is
* two elements above the last real data element). The overspill values are never written to memory,
* and would be benign, but the padding avoids hitting undefined behavior.
*
* The @c rgb_lns and @c alpha_lns fields that assigned a per-texel use of HDR are only used during
* decompression. The current compressor will always use HDR endpoint formats when in HDR mode.
*/
struct image_block
{
/** @brief The input (compress) or output (decompress) data for the red color component. */
ASTCENC_ALIGNAS float data_r[BLOCK_MAX_TEXELS + ASTCENC_SIMD_WIDTH - 1];
/** @brief The input (compress) or output (decompress) data for the green color component. */
ASTCENC_ALIGNAS float data_g[BLOCK_MAX_TEXELS + ASTCENC_SIMD_WIDTH - 1];
/** @brief The input (compress) or output (decompress) data for the blue color component. */
ASTCENC_ALIGNAS float data_b[BLOCK_MAX_TEXELS + ASTCENC_SIMD_WIDTH - 1];
/** @brief The input (compress) or output (decompress) data for the alpha color component. */
ASTCENC_ALIGNAS float data_a[BLOCK_MAX_TEXELS + ASTCENC_SIMD_WIDTH - 1];
/** @brief The number of texels in the block. */
uint8_t texel_count;
/** @brief The original data for texel 0 for constant color block encoding. */
vfloat4 origin_texel;
/** @brief The min component value of all texels in the block. */
vfloat4 data_min;
/** @brief The mean component value of all texels in the block. */
vfloat4 data_mean;
/** @brief The max component value of all texels in the block. */
vfloat4 data_max;
/** @brief The relative error significance of the color channels. */
vfloat4 channel_weight;
/** @brief Is this grayscale block where R == G == B for all texels? */
bool grayscale;
/** @brief Is the eventual decode using decode_unorm8 rounding? */
bool decode_unorm8;
/** @brief Set to 1 if a texel is using HDR RGB endpoints (decompression only). */
uint8_t rgb_lns[BLOCK_MAX_TEXELS];
/** @brief Set to 1 if a texel is using HDR alpha endpoints (decompression only). */
uint8_t alpha_lns[BLOCK_MAX_TEXELS];
/** @brief The X position of this block in the input or output image. */
unsigned int xpos;
/** @brief The Y position of this block in the input or output image. */
unsigned int ypos;
/** @brief The Z position of this block in the input or output image. */
unsigned int zpos;
/**
* @brief Get an RGBA texel value from the data.
*
* @param index The texel index.
*
* @return The texel in RGBA component ordering.
*/
inline vfloat4 texel(unsigned int index) const
{
return vfloat4(data_r[index],
data_g[index],
data_b[index],
data_a[index]);
}
/**
* @brief Get an RGB texel value from the data.
*
* @param index The texel index.
*
* @return The texel in RGB0 component ordering.
*/
inline vfloat4 texel3(unsigned int index) const
{
return vfloat3(data_r[index],
data_g[index],
data_b[index]);
}
/**
* @brief Get the default alpha value for endpoints that don't store it.
*
* The default depends on whether the alpha endpoint is LDR or HDR.
*
* @return The alpha value in the scaled range used by the compressor.
*/
inline float get_default_alpha() const
{
return this->alpha_lns[0] ? static_cast<float>(0x7800) : static_cast<float>(0xFFFF);
}
/**
* @brief Test if a single color channel is constant across the block.
*
* Constant color channels are easier to compress as interpolating between two identical colors
* always returns the same value, irrespective of the weight used. They therefore can be ignored
* for the purposes of weight selection and use of a second weight plane.
*
* @return @c true if the channel is constant across the block, @c false otherwise.
*/
inline bool is_constant_channel(int channel) const
{
vmask4 lane_mask = vint4::lane_id() == vint4(channel);
vmask4 color_mask = this->data_min == this->data_max;
return any(lane_mask & color_mask);
}
/**
* @brief Test if this block is a luminance block with constant 1.0 alpha.
*
* @return @c true if the block is a luminance block , @c false otherwise.
*/
inline bool is_luminance() const
{
float default_alpha = this->get_default_alpha();
bool alpha1 = (this->data_min.lane<3>() == default_alpha) &&
(this->data_max.lane<3>() == default_alpha);
return this->grayscale && alpha1;
}
/**
* @brief Test if this block is a luminance block with variable alpha.
*
* @return @c true if the block is a luminance + alpha block , @c false otherwise.
*/
inline bool is_luminancealpha() const
{
float default_alpha = this->get_default_alpha();
bool alpha1 = (this->data_min.lane<3>() == default_alpha) &&
(this->data_max.lane<3>() == default_alpha);
return this->grayscale && !alpha1;
}
};
/**
* @brief Data structure storing the color endpoints for a block.
*/
struct endpoints
{
/** @brief The number of partition endpoints stored. */
unsigned int partition_count;
/** @brief The colors for endpoint 0. */
vfloat4 endpt0[BLOCK_MAX_PARTITIONS];
/** @brief The colors for endpoint 1. */
vfloat4 endpt1[BLOCK_MAX_PARTITIONS];
};
/**
* @brief Data structure storing the color endpoints and weights.
*/
struct endpoints_and_weights
{
/** @brief True if all active values in weight_error_scale are the same. */
bool is_constant_weight_error_scale;
/** @brief The color endpoints. */
endpoints ep;
/** @brief The ideal weight for each texel; may be undecimated or decimated. */
ASTCENC_ALIGNAS float weights[BLOCK_MAX_TEXELS];
/** @brief The ideal weight error scaling for each texel; may be undecimated or decimated. */
ASTCENC_ALIGNAS float weight_error_scale[BLOCK_MAX_TEXELS];
};
/**
* @brief Utility storing estimated errors from choosing particular endpoint encodings.
*/
struct encoding_choice_errors
{
/** @brief Error of using LDR RGB-scale instead of complete endpoints. */
float rgb_scale_error;
/** @brief Error of using HDR RGB-scale instead of complete endpoints. */
float rgb_luma_error;
/** @brief Error of using luminance instead of RGB. */
float luminance_error;
/** @brief Error of discarding alpha and using a constant 1.0 alpha. */
float alpha_drop_error;
/** @brief Can we use delta offset encoding? */
bool can_offset_encode;
/** @brief Can we use blue contraction encoding? */
bool can_blue_contract;
};
/**
* @brief Preallocated working buffers, allocated per thread during context creation.
*/
struct ASTCENC_ALIGNAS compression_working_buffers
{
/** @brief Ideal endpoints and weights for plane 1. */
endpoints_and_weights ei1;
/** @brief Ideal endpoints and weights for plane 2. */
endpoints_and_weights ei2;
/**
* @brief Decimated ideal weight values in the ~0-1 range.
*
* Note that values can be slightly below zero or higher than one due to
* endpoint extents being inside the ideal color representation.
*
* For two planes, second plane starts at @c WEIGHTS_PLANE2_OFFSET offsets.
*/
ASTCENC_ALIGNAS float dec_weights_ideal[WEIGHTS_MAX_DECIMATION_MODES * BLOCK_MAX_WEIGHTS];
/**
* @brief Decimated quantized weight values in the unquantized 0-64 range.
*
* For two planes, second plane starts at @c WEIGHTS_PLANE2_OFFSET offsets.
*/
ASTCENC_ALIGNAS uint8_t dec_weights_uquant[WEIGHTS_MAX_BLOCK_MODES * BLOCK_MAX_WEIGHTS];
/** @brief Error of the best encoding combination for each block mode. */
ASTCENC_ALIGNAS float errors_of_best_combination[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The best color quant for each block mode. */
uint8_t best_quant_levels[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The best color quant for each block mode if modes are the same and we have spare bits. */
uint8_t best_quant_levels_mod[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The best endpoint format for each partition. */
uint8_t best_ep_formats[WEIGHTS_MAX_BLOCK_MODES][BLOCK_MAX_PARTITIONS];
/** @brief The total bit storage needed for quantized weights for each block mode. */
int8_t qwt_bitcounts[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The cumulative error for quantized weights for each block mode. */
float qwt_errors[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The low weight value in plane 1 for each block mode. */
float weight_low_value1[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The high weight value in plane 1 for each block mode. */
float weight_high_value1[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The low weight value in plane 1 for each quant level and decimation mode. */
float weight_low_values1[WEIGHTS_MAX_DECIMATION_MODES][TUNE_MAX_ANGULAR_QUANT + 1];
/** @brief The high weight value in plane 1 for each quant level and decimation mode. */
float weight_high_values1[WEIGHTS_MAX_DECIMATION_MODES][TUNE_MAX_ANGULAR_QUANT + 1];
/** @brief The low weight value in plane 2 for each block mode. */
float weight_low_value2[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The high weight value in plane 2 for each block mode. */
float weight_high_value2[WEIGHTS_MAX_BLOCK_MODES];
/** @brief The low weight value in plane 2 for each quant level and decimation mode. */
float weight_low_values2[WEIGHTS_MAX_DECIMATION_MODES][TUNE_MAX_ANGULAR_QUANT + 1];
/** @brief The high weight value in plane 2 for each quant level and decimation mode. */
float weight_high_values2[WEIGHTS_MAX_DECIMATION_MODES][TUNE_MAX_ANGULAR_QUANT + 1];
};
struct dt_init_working_buffers
{
uint8_t weight_count_of_texel[BLOCK_MAX_TEXELS];
uint8_t grid_weights_of_texel[BLOCK_MAX_TEXELS][4];
uint8_t weights_of_texel[BLOCK_MAX_TEXELS][4];
uint8_t texel_count_of_weight[BLOCK_MAX_WEIGHTS];
uint8_t texels_of_weight[BLOCK_MAX_WEIGHTS][BLOCK_MAX_TEXELS];
uint8_t texel_weights_of_weight[BLOCK_MAX_WEIGHTS][BLOCK_MAX_TEXELS];
};
/**
* @brief Weight quantization transfer table.
*
* ASTC can store texel weights at many quantization levels, so for performance we store essential
* information about each level as a precomputed data structure. Unquantized weights are integers
* or floats in the range [0, 64].
*
* This structure provides a table, used to estimate the closest quantized weight for a given
* floating-point weight. For each quantized weight, the corresponding unquantized values. For each
* quantized weight, a previous-value and a next-value.
*/
struct quant_and_transfer_table
{
/** @brief The unscrambled unquantized value. */
uint8_t quant_to_unquant[32];
/** @brief The scrambling order: scrambled_quant = map[unscrambled_quant]. */
uint8_t scramble_map[32];
/** @brief The unscrambling order: unscrambled_unquant = map[scrambled_quant]. */
uint8_t unscramble_and_unquant_map[32];
/**
* @brief A table of previous-and-next weights, indexed by the current unquantized value.
* * bits 7:0 = previous-index, unquantized
* * bits 15:8 = next-index, unquantized
*/
uint16_t prev_next_values[65];
};
/** @brief The precomputed quant and transfer table. */
extern const quant_and_transfer_table quant_and_xfer_tables[12];
/** @brief The block is an error block, and will return error color or NaN. */
static constexpr uint8_t SYM_BTYPE_ERROR { 0 };
/** @brief The block is a constant color block using FP16 colors. */
static constexpr uint8_t SYM_BTYPE_CONST_F16 { 1 };
/** @brief The block is a constant color block using UNORM16 colors. */
static constexpr uint8_t SYM_BTYPE_CONST_U16 { 2 };
/** @brief The block is a normal non-constant color block. */
static constexpr uint8_t SYM_BTYPE_NONCONST { 3 };
/**
* @brief A symbolic representation of a compressed block.
*
* The symbolic representation stores the unpacked content of a single
* physical compressed block, in a form which is much easier to access for
* the rest of the compressor code.
*/
struct symbolic_compressed_block
{
/** @brief The block type, one of the @c SYM_BTYPE_* constants. */
uint8_t block_type;
/** @brief The number of partitions; valid for @c NONCONST blocks. */
uint8_t partition_count;
/** @brief Non-zero if the color formats matched; valid for @c NONCONST blocks. */
uint8_t color_formats_matched;
/** @brief The plane 2 color component, or -1 if single plane; valid for @c NONCONST blocks. */
int8_t plane2_component;
/** @brief The block mode; valid for @c NONCONST blocks. */
uint16_t block_mode;
/** @brief The partition index; valid for @c NONCONST blocks if 2 or more partitions. */
uint16_t partition_index;
/** @brief The endpoint color formats for each partition; valid for @c NONCONST blocks. */
uint8_t color_formats[BLOCK_MAX_PARTITIONS];
/** @brief The endpoint color quant mode; valid for @c NONCONST blocks. */
quant_method quant_mode;
/** @brief The error of the current encoding; valid for @c NONCONST blocks. */
float errorval;
// We can't have both of these at the same time
union {
/** @brief The constant color; valid for @c CONST blocks. */
int constant_color[BLOCK_MAX_COMPONENTS];
/** @brief The quantized endpoint color pairs; valid for @c NONCONST blocks. */
uint8_t color_values[BLOCK_MAX_PARTITIONS][8];
};
/** @brief The quantized and decimated weights.
*
* Weights are stored in the 0-64 unpacked range allowing them to be used
* directly in encoding passes without per-use unpacking. Packing happens
* when converting to/from the physical bitstream encoding.
*
* If dual plane, the second plane starts at @c weights[WEIGHTS_PLANE2_OFFSET].
*/
ASTCENC_ALIGNAS uint8_t weights[BLOCK_MAX_WEIGHTS];
/**
* @brief Get the weight quantization used by this block mode.
*
* @return The quantization level.
*/
inline quant_method get_color_quant_mode() const
{
return this->quant_mode;
}
};
/**
* @brief Parameter structure for @c compute_pixel_region_variance().
*
* This function takes a structure to avoid spilling arguments to the stack on every function
* invocation, as there are a lot of parameters.
*/
struct pixel_region_args
{
/** @brief The image to analyze. */
const astcenc_image* img;
/** @brief The component swizzle pattern. */
astcenc_swizzle swz;
/** @brief Should the algorithm bother with Z axis processing? */
bool have_z;
/** @brief The kernel radius for alpha processing. */
unsigned int alpha_kernel_radius;
/** @brief The X dimension of the working data to process. */
unsigned int size_x;
/** @brief The Y dimension of the working data to process. */
unsigned int size_y;
/** @brief The Z dimension of the working data to process. */
unsigned int size_z;
/** @brief The X position of first src and dst data in the data set. */
unsigned int offset_x;
/** @brief The Y position of first src and dst data in the data set. */
unsigned int offset_y;
/** @brief The Z position of first src and dst data in the data set. */
unsigned int offset_z;
/** @brief The working memory buffer. */
vfloat4 *work_memory;
};
/**
* @brief Parameter structure for @c compute_averages_proc().
*/
struct avg_args
{
/** @brief The arguments for the nested variance computation. */
pixel_region_args arg;
/** @brief The image X dimensions. */
unsigned int img_size_x;
/** @brief The image Y dimensions. */
unsigned int img_size_y;
/** @brief The image Z dimensions. */
unsigned int img_size_z;
/** @brief The maximum working block dimensions in X and Y dimensions. */
unsigned int blk_size_xy;
/** @brief The maximum working block dimensions in Z dimensions. */
unsigned int blk_size_z;
/** @brief The working block memory size. */
unsigned int work_memory_size;
};
#if defined(ASTCENC_DIAGNOSTICS)
/* See astcenc_diagnostic_trace header for details. */
class TraceLog;
#endif
/**
* @brief The astcenc compression context.
*/
struct astcenc_contexti
{
/** @brief The configuration this context was created with. */
astcenc_config config;
/** @brief The thread count supported by this context. */
unsigned int thread_count;
/** @brief The block size descriptor this context was created with. */
block_size_descriptor* bsd;
/*
* Fields below here are not needed in a decompress-only build, but some remain as they are
* small and it avoids littering the code with #ifdefs. The most significant contributors to
* large structure size are omitted.
*/
/** @brief The input image alpha channel averages table, may be @c nullptr if not needed. */
float* input_alpha_averages;
/** @brief The scratch working buffers, one per thread (see @c thread_count). */
compression_working_buffers* working_buffers;
#if !defined(ASTCENC_DECOMPRESS_ONLY)
/** @brief The pixel region and variance worker arguments. */
avg_args avg_preprocess_args;
#endif
#if defined(ASTCENC_DIAGNOSTICS)
/**
* @brief The diagnostic trace logger.
*
* Note that this is a singleton, so can only be used in single threaded mode. It only exists
* here so we have a reference to close the file at the end of the capture.
*/
TraceLog* trace_log;
#endif
};
/* ============================================================================
Functionality for managing block sizes and partition tables.
============================================================================ */
/**
* @brief Populate the block size descriptor for the target block size.
*
* This will also initialize the partition table metadata, which is stored as part of the BSD
* structure.
*
* @param x_texels The number of texels in the block X dimension.
* @param y_texels The number of texels in the block Y dimension.
* @param z_texels The number of texels in the block Z dimension.
* @param can_omit_modes Can we discard modes and partitionings that astcenc won't use?
* @param partition_count_cutoff The partition count cutoff to use, if we can omit partitionings.
* @param mode_cutoff The block mode percentile cutoff [0-1].
* @param[out] bsd The descriptor to initialize.
*/
void init_block_size_descriptor(
unsigned int x_texels,
unsigned int y_texels,
unsigned int z_texels,
bool can_omit_modes,
unsigned int partition_count_cutoff,
float mode_cutoff,
block_size_descriptor& bsd);
/**
* @brief Populate the partition tables for the target block size.
*
* Note the @c bsd descriptor must be initialized by calling @c init_block_size_descriptor() before
* calling this function.
*
* @param[out] bsd The block size information structure to populate.
* @param can_omit_partitionings True if we can we drop partitionings that astcenc won't use.
* @param partition_count_cutoff The partition count cutoff to use, if we can omit partitionings.
*/
void init_partition_tables(
block_size_descriptor& bsd,
bool can_omit_partitionings,
unsigned int partition_count_cutoff);
/**
* @brief Get the percentile table for 2D block modes.
*
* This is an empirically determined prioritization of which block modes to use in the search in
* terms of their centile (lower centiles = more useful).
*
* Returns a dynamically allocated array; caller must free with delete[].
*
* @param xdim The block x size.
* @param ydim The block y size.
*
* @return The unpacked table.
*/
const float* get_2d_percentile_table(
unsigned int xdim,
unsigned int ydim);
/**
* @brief Query if a 2D block size is legal.
*
* @return True if legal, false otherwise.
*/
bool is_legal_2d_block_size(
unsigned int xdim,
unsigned int ydim);
/**
* @brief Query if a 3D block size is legal.
*
* @return True if legal, false otherwise.
*/
bool is_legal_3d_block_size(
unsigned int xdim,
unsigned int ydim,
unsigned int zdim);
/* ============================================================================
Functionality for managing BISE quantization and unquantization.
============================================================================ */
/**
* @brief The precomputed table for quantizing color values.
*
* Converts unquant value in 0-255 range into quant value in 0-255 range.
* No BISE scrambling is applied at this stage.
*
* The BISE encoding results in ties where available quant<256> values are
* equidistant the available quant<BISE> values. This table stores two values
* for each input - one for use with a negative residual, and one for use with
* a positive residual.
*
* Indexed by [quant_mode - 4][data_value * 2 + residual].
*/
extern const uint8_t color_unquant_to_uquant_tables[17][512];
/**
* @brief The precomputed table for packing quantized color values.
*
* Converts quant value in 0-255 range into packed quant value in 0-N range,
* with BISE scrambling applied.
*
* Indexed by [quant_mode - 4][data_value].
*/
extern const uint8_t color_uquant_to_scrambled_pquant_tables[17][256];
/**
* @brief The precomputed table for unpacking color values.
*
* Converts quant value in 0-N range into unpacked value in 0-255 range,
* with BISE unscrambling applied.
*
* Indexed by [quant_mode - 4][data_value].
*/
extern const uint8_t* color_scrambled_pquant_to_uquant_tables[17];
/**
* @brief The precomputed quant mode storage table.
*
* Indexing by [integer_count/2][bits] gives us the quantization level for a given integer count and
* number of compressed storage bits. Returns -1 for cases where the requested integer count cannot
* ever fit in the supplied storage size.
*/
extern const int8_t quant_mode_table[10][128];
/**
* @brief Encode a packed string using BISE.
*
* Note that BISE can return strings that are not a whole number of bytes in length, and ASTC can
* start storing strings in a block at arbitrary bit offsets in the encoded data.
*
* @param quant_level The BISE alphabet size.
* @param character_count The number of characters in the string.
* @param input_data The unpacked string, one byte per character.
* @param[in,out] output_data The output packed string.
* @param bit_offset The starting offset in the output storage.
*/
void encode_ise(
quant_method quant_level,
unsigned int character_count,
const uint8_t* input_data,
uint8_t* output_data,
unsigned int bit_offset);
/**
* @brief Decode a packed string using BISE.
*
* Note that BISE input strings are not a whole number of bytes in length, and ASTC can start
* strings at arbitrary bit offsets in the encoded data.
*
* @param quant_level The BISE alphabet size.
* @param character_count The number of characters in the string.
* @param input_data The packed string.
* @param[in,out] output_data The output storage, one byte per character.
* @param bit_offset The starting offset in the output storage.
*/
void decode_ise(
quant_method quant_level,
unsigned int character_count,
const uint8_t* input_data,
uint8_t* output_data,
unsigned int bit_offset);
/**
* @brief Return the number of bits needed to encode an ISE sequence.
*
* This implementation assumes that the @c quant level is untrusted, given it may come from random
* data being decompressed, so we return an arbitrary unencodable size if that is the case.
*
* @param character_count The number of items in the sequence.
* @param quant_level The desired quantization level.
*
* @return The number of bits needed to encode the BISE string.
*/
unsigned int get_ise_sequence_bitcount(
unsigned int character_count,
quant_method quant_level);
/* ============================================================================
Functionality for managing color partitioning.
============================================================================ */
/**
* @brief Compute averages and dominant directions for each partition in a 2 component texture.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to be compressed.
* @param component1 The first component included in the analysis.
* @param component2 The second component included in the analysis.
* @param[out] pm The output partition metrics.
* - Only pi.partition_count array entries actually get initialized.
* - Direction vectors @c pm.dir are not normalized.
*/
void compute_avgs_and_dirs_2_comp(
const partition_info& pi,
const image_block& blk,
unsigned int component1,
unsigned int component2,
partition_metrics pm[BLOCK_MAX_PARTITIONS]);
/**
* @brief Compute averages and dominant directions for each partition in a 3 component texture.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to be compressed.
* @param omitted_component The component excluded from the analysis.
* @param[out] pm The output partition metrics.
* - Only pi.partition_count array entries actually get initialized.
* - Direction vectors @c pm.dir are not normalized.
*/
void compute_avgs_and_dirs_3_comp(
const partition_info& pi,
const image_block& blk,
unsigned int omitted_component,
partition_metrics pm[BLOCK_MAX_PARTITIONS]);
/**
* @brief Compute averages and dominant directions for each partition in a 3 component texture.
*
* This is a specialization of @c compute_avgs_and_dirs_3_comp where the omitted component is
* always alpha, a common case during partition search.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to be compressed.
* @param[out] pm The output partition metrics.
* - Only pi.partition_count array entries actually get initialized.
* - Direction vectors @c pm.dir are not normalized.
*/
void compute_avgs_and_dirs_3_comp_rgb(
const partition_info& pi,
const image_block& blk,
partition_metrics pm[BLOCK_MAX_PARTITIONS]);
/**
* @brief Compute averages and dominant directions for each partition in a 4 component texture.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to be compressed.
* @param[out] pm The output partition metrics.
* - Only pi.partition_count array entries actually get initialized.
* - Direction vectors @c pm.dir are not normalized.
*/
void compute_avgs_and_dirs_4_comp(
const partition_info& pi,
const image_block& blk,
partition_metrics pm[BLOCK_MAX_PARTITIONS]);
/**
* @brief Compute the RGB error for uncorrelated and same chroma projections.
*
* The output of compute averages and dirs is post processed to define two lines, both of which go
* through the mean-color-value. One line has a direction defined by the dominant direction; this
* is used to assess the error from using an uncorrelated color representation. The other line goes
* through (0,0,0) and is used to assess the error from using an RGBS color representation.
*
* This function computes the squared error when using these two representations.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to be compressed.
* @param[in,out] plines Processed line inputs, and line length outputs.
* @param[out] uncor_error The cumulative error for using the uncorrelated line.
* @param[out] samec_error The cumulative error for using the same chroma line.
*/
void compute_error_squared_rgb(
const partition_info& pi,
const image_block& blk,
partition_lines3 plines[BLOCK_MAX_PARTITIONS],
float& uncor_error,
float& samec_error);
/**
* @brief Compute the RGBA error for uncorrelated and same chroma projections.
*
* The output of compute averages and dirs is post processed to define two lines, both of which go
* through the mean-color-value. One line has a direction defined by the dominant direction; this
* is used to assess the error from using an uncorrelated color representation. The other line goes
* through (0,0,0,1) and is used to assess the error from using an RGBS color representation.
*
* This function computes the squared error when using these two representations.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to be compressed.
* @param uncor_plines Processed uncorrelated partition lines for each partition.
* @param samec_plines Processed same chroma partition lines for each partition.
* @param[out] line_lengths The length of each components deviation from the line.
* @param[out] uncor_error The cumulative error for using the uncorrelated line.
* @param[out] samec_error The cumulative error for using the same chroma line.
*/
void compute_error_squared_rgba(
const partition_info& pi,
const image_block& blk,
const processed_line4 uncor_plines[BLOCK_MAX_PARTITIONS],
const processed_line4 samec_plines[BLOCK_MAX_PARTITIONS],
float line_lengths[BLOCK_MAX_PARTITIONS],
float& uncor_error,
float& samec_error);
/**
* @brief Find the best set of partitions to trial for a given block.
*
* On return the @c best_partitions list will contain the two best partition
* candidates; one assuming data has uncorrelated chroma and one assuming the
* data has correlated chroma. The best candidate is returned first in the list.
*
* @param bsd The block size information.
* @param blk The image block color data to compress.
* @param partition_count The number of partitions in the block.
* @param partition_search_limit The number of candidate partition encodings to trial.
* @param[out] best_partitions The best partition candidates.
* @param requested_candidates The number of requested partitionings. May return fewer if
* candidates are not available.
*
* @return The actual number of candidates returned.
*/
unsigned int find_best_partition_candidates(
const block_size_descriptor& bsd,
const image_block& blk,
unsigned int partition_count,
unsigned int partition_search_limit,
unsigned int best_partitions[TUNE_MAX_PARTITIONING_CANDIDATES],
unsigned int requested_candidates);
/* ============================================================================
Functionality for managing images and image related data.
============================================================================ */
/**
* @brief Get a vector mask indicating lanes decompressing into a UNORM8 value.
*
* @param decode_mode The color profile for LDR_SRGB settings.
* @param blk The image block for output image bitness settings.
*
* @return The component mask vector.
*/
static inline vmask4 get_u8_component_mask(
astcenc_profile decode_mode,
const image_block& blk
) {
// Decode mode or sRGB forces writing to unorm8 output value
if (blk.decode_unorm8 || decode_mode == ASTCENC_PRF_LDR_SRGB)
{
return vmask4(true);
}
return vmask4(false);
}
/**
* @brief Setup computation of regional averages in an image.
*
* This must be done by only a single thread per image, before any thread calls
* @c compute_averages().
*
* Results are written back into @c img->input_alpha_averages.
*
* @param img The input image data, also holds output data.
* @param alpha_kernel_radius The kernel radius (in pixels) for alpha mods.
* @param swz Input data component swizzle.
* @param[out] ag The average variance arguments to init.
*
* @return The number of tasks in the processing stage.
*/
unsigned int init_compute_averages(
const astcenc_image& img,
unsigned int alpha_kernel_radius,
const astcenc_swizzle& swz,
avg_args& ag);
/**
* @brief Compute averages for a pixel region.
*
* The routine computes both in a single pass, using a summed-area table to decouple the running
* time from the averaging/variance kernel size.
*
* @param[out] ctx The compressor context storing the output data.
* @param arg The input parameter structure.
*/
void compute_pixel_region_variance(
astcenc_contexti& ctx,
const pixel_region_args& arg);
/**
* @brief Load a single image block from the input image.
*
* @param decode_mode The compression color profile.
* @param img The input image data.
* @param[out] blk The image block to populate.
* @param bsd The block size information.
* @param xpos The block X coordinate in the input image.
* @param ypos The block Y coordinate in the input image.
* @param zpos The block Z coordinate in the input image.
* @param swz The swizzle to apply on load.
*/
void load_image_block(
astcenc_profile decode_mode,
const astcenc_image& img,
image_block& blk,
const block_size_descriptor& bsd,
unsigned int xpos,
unsigned int ypos,
unsigned int zpos,
const astcenc_swizzle& swz);
/**
* @brief Load a single image block from the input image.
*
* This specialized variant can be used only if the block is 2D LDR U8 data,
* with no swizzle.
*
* @param decode_mode The compression color profile.
* @param img The input image data.
* @param[out] blk The image block to populate.
* @param bsd The block size information.
* @param xpos The block X coordinate in the input image.
* @param ypos The block Y coordinate in the input image.
* @param zpos The block Z coordinate in the input image.
* @param swz The swizzle to apply on load.
*/
void load_image_block_fast_ldr(
astcenc_profile decode_mode,
const astcenc_image& img,
image_block& blk,
const block_size_descriptor& bsd,
unsigned int xpos,
unsigned int ypos,
unsigned int zpos,
const astcenc_swizzle& swz);
/**
* @brief Store a single image block to the output image.
*
* @param[out] img The output image data.
* @param blk The image block to export.
* @param bsd The block size information.
* @param xpos The block X coordinate in the input image.
* @param ypos The block Y coordinate in the input image.
* @param zpos The block Z coordinate in the input image.
* @param swz The swizzle to apply on store.
*/
void store_image_block(
astcenc_image& img,
const image_block& blk,
const block_size_descriptor& bsd,
unsigned int xpos,
unsigned int ypos,
unsigned int zpos,
const astcenc_swizzle& swz);
/* ============================================================================
Functionality for computing endpoint colors and weights for a block.
============================================================================ */
/**
* @brief Compute ideal endpoint colors and weights for 1 plane of weights.
*
* The ideal endpoints define a color line for the partition. For each texel the ideal weight
* defines an exact position on the partition color line. We can then use these to assess the error
* introduced by removing and quantizing the weight grid.
*
* @param blk The image block color data to compress.
* @param pi The partition info for the current trial.
* @param[out] ei The endpoint and weight values.
*/
void compute_ideal_colors_and_weights_1plane(
const image_block& blk,
const partition_info& pi,
endpoints_and_weights& ei);
/**
* @brief Compute ideal endpoint colors and weights for 2 planes of weights.
*
* The ideal endpoints define a color line for the partition. For each texel the ideal weight
* defines an exact position on the partition color line. We can then use these to assess the error
* introduced by removing and quantizing the weight grid.
*
* @param bsd The block size information.
* @param blk The image block color data to compress.
* @param plane2_component The component assigned to plane 2.
* @param[out] ei1 The endpoint and weight values for plane 1.
* @param[out] ei2 The endpoint and weight values for plane 2.
*/
void compute_ideal_colors_and_weights_2planes(
const block_size_descriptor& bsd,
const image_block& blk,
unsigned int plane2_component,
endpoints_and_weights& ei1,
endpoints_and_weights& ei2);
/**
* @brief Compute the optimal unquantized weights for a decimation table.
*
* After computing ideal weights for the case for a complete weight grid, we we want to compute the
* ideal weights for the case where weights exist only for some texels. We do this with a
* steepest-descent grid solver which works as follows:
*
* First, for each actual weight, perform a weighted averaging of the texels affected by the weight.
* Then, set step size to <some initial value> and attempt one step towards the original ideal
* weight if it helps to reduce error.
*
* @param ei The non-decimated endpoints and weights.
* @param di The selected weight decimation.
* @param[out] dec_weight_ideal_value The ideal values for the decimated weight set.
*/
void compute_ideal_weights_for_decimation(
const endpoints_and_weights& ei,
const decimation_info& di,
float* dec_weight_ideal_value);
/**
* @brief Compute the optimal quantized weights for a decimation table.
*
* We test the two closest weight indices in the allowed quantization range and keep the weight that
* is the closest match.
*
* @param di The selected weight decimation.
* @param low_bound The lowest weight allowed.
* @param high_bound The highest weight allowed.
* @param dec_weight_ideal_value The ideal weight set.
* @param[out] dec_weight_quant_uvalue The output quantized weight as a float.
* @param[out] dec_weight_uquant The output quantized weight as encoded int.
* @param quant_level The desired weight quant level.
*/
void compute_quantized_weights_for_decimation(
const decimation_info& di,
float low_bound,
float high_bound,
const float* dec_weight_ideal_value,
float* dec_weight_quant_uvalue,
uint8_t* dec_weight_uquant,
quant_method quant_level);
/**
* @brief Compute the error of a decimated weight set for 1 plane.
*
* After computing ideal weights for the case with one weight per texel, we want to compute the
* error for decimated weight grids where weights are stored at a lower resolution. This function
* computes the error of the reduced grid, compared to the full grid.
*
* @param eai The ideal weights for the full grid.
* @param di The selected weight decimation.
* @param dec_weight_quant_uvalue The quantized weights for the decimated grid.
*
* @return The accumulated error.
*/
float compute_error_of_weight_set_1plane(
const endpoints_and_weights& eai,
const decimation_info& di,
const float* dec_weight_quant_uvalue);
/**
* @brief Compute the error of a decimated weight set for 2 planes.
*
* After computing ideal weights for the case with one weight per texel, we want to compute the
* error for decimated weight grids where weights are stored at a lower resolution. This function
* computes the error of the reduced grid, compared to the full grid.
*
* @param eai1 The ideal weights for the full grid and plane 1.
* @param eai2 The ideal weights for the full grid and plane 2.
* @param di The selected weight decimation.
* @param dec_weight_quant_uvalue_plane1 The quantized weights for the decimated grid plane 1.
* @param dec_weight_quant_uvalue_plane2 The quantized weights for the decimated grid plane 2.
*
* @return The accumulated error.
*/
float compute_error_of_weight_set_2planes(
const endpoints_and_weights& eai1,
const endpoints_and_weights& eai2,
const decimation_info& di,
const float* dec_weight_quant_uvalue_plane1,
const float* dec_weight_quant_uvalue_plane2);
/**
* @brief Pack a single pair of color endpoints as effectively as possible.
*
* The user requests a base color endpoint mode in @c format, but the quantizer may choose a
* delta-based representation. It will report back the format variant it actually used.
*
* @param color0 The input unquantized color0 endpoint for absolute endpoint pairs.
* @param color1 The input unquantized color1 endpoint for absolute endpoint pairs.
* @param rgbs_color The input unquantized RGBS variant endpoint for same chroma endpoints.
* @param rgbo_color The input unquantized RGBS variant endpoint for HDR endpoints.
* @param format The desired base format.
* @param[out] output The output storage for the quantized colors/
* @param quant_level The quantization level requested.
*
* @return The actual endpoint mode used.
*/
uint8_t pack_color_endpoints(
vfloat4 color0,
vfloat4 color1,
vfloat4 rgbs_color,
vfloat4 rgbo_color,
int format,
uint8_t* output,
quant_method quant_level);
/**
* @brief Unpack a single pair of encoded endpoints.
*
* Endpoints must be unscrambled and converted into the 0-255 range before calling this functions.
*
* @param decode_mode The decode mode (LDR, HDR, etc).
* @param format The color endpoint mode used.
* @param input The raw array of encoded input integers. The length of this array
* depends on @c format; it can be safely assumed to be large enough.
* @param[out] rgb_hdr Is the endpoint using HDR for the RGB channels?
* @param[out] alpha_hdr Is the endpoint using HDR for the A channel?
* @param[out] output0 The output color for endpoint 0.
* @param[out] output1 The output color for endpoint 1.
*/
void unpack_color_endpoints(
astcenc_profile decode_mode,
int format,
const uint8_t* input,
bool& rgb_hdr,
bool& alpha_hdr,
vint4& output0,
vint4& output1);
/**
* @brief Unpack an LDR RGBA color that uses delta encoding.
*
* @param input0 The packed endpoint 0 color.
* @param input1 The packed endpoint 1 color deltas.
* @param[out] output0 The unpacked endpoint 0 color.
* @param[out] output1 The unpacked endpoint 1 color.
*/
void rgba_delta_unpack(
vint4 input0,
vint4 input1,
vint4& output0,
vint4& output1);
/**
* @brief Unpack an LDR RGBA color that uses direct encoding.
*
* @param input0 The packed endpoint 0 color.
* @param input1 The packed endpoint 1 color.
* @param[out] output0 The unpacked endpoint 0 color.
* @param[out] output1 The unpacked endpoint 1 color.
*/
void rgba_unpack(
vint4 input0,
vint4 input1,
vint4& output0,
vint4& output1);
/**
* @brief Unpack a set of quantized and decimated weights.
*
* TODO: Can we skip this for non-decimated weights now that the @c scb is
* already storing unquantized weights?
*
* @param bsd The block size information.
* @param scb The symbolic compressed encoding.
* @param di The weight grid decimation table.
* @param is_dual_plane @c true if this is a dual plane block, @c false otherwise.
* @param[out] weights_plane1 The output array for storing the plane 1 weights.
* @param[out] weights_plane2 The output array for storing the plane 2 weights.
*/
void unpack_weights(
const block_size_descriptor& bsd,
const symbolic_compressed_block& scb,
const decimation_info& di,
bool is_dual_plane,
int weights_plane1[BLOCK_MAX_TEXELS],
int weights_plane2[BLOCK_MAX_TEXELS]);
/**
* @brief Identify, for each mode, which set of color endpoint produces the best result.
*
* Returns the best @c tune_candidate_limit best looking modes, along with the ideal color encoding
* combination for each. The modified quantization level can be used when all formats are the same,
* as this frees up two additional bits of storage.
*
* @param pi The partition info for the current trial.
* @param blk The image block color data to compress.
* @param ep The ideal endpoints.
* @param qwt_bitcounts Bit counts for different quantization methods.
* @param qwt_errors Errors for different quantization methods.
* @param tune_candidate_limit The max number of candidates to return, may be less.
* @param start_block_mode The first block mode to inspect.
* @param end_block_mode The last block mode to inspect.
* @param[out] partition_format_specifiers The best formats per partition.
* @param[out] block_mode The best packed block mode indexes.
* @param[out] quant_level The best color quant level.
* @param[out] quant_level_mod The best color quant level if endpoints are the same.
* @param[out] tmpbuf Preallocated scratch buffers for the compressor.
*
* @return The actual number of candidate matches returned.
*/
unsigned int compute_ideal_endpoint_formats(
const partition_info& pi,
const image_block& blk,
const endpoints& ep,
const int8_t* qwt_bitcounts,
const float* qwt_errors,
unsigned int tune_candidate_limit,
unsigned int start_block_mode,
unsigned int end_block_mode,
uint8_t partition_format_specifiers[TUNE_MAX_TRIAL_CANDIDATES][BLOCK_MAX_PARTITIONS],
int block_mode[TUNE_MAX_TRIAL_CANDIDATES],
quant_method quant_level[TUNE_MAX_TRIAL_CANDIDATES],
quant_method quant_level_mod[TUNE_MAX_TRIAL_CANDIDATES],
compression_working_buffers& tmpbuf);
/**
* @brief For a given 1 plane weight set recompute the endpoint colors.
*
* As we quantize and decimate weights the optimal endpoint colors may change slightly, so we must
* recompute the ideal colors for a specific weight set.
*
* @param blk The image block color data to compress.
* @param pi The partition info for the current trial.
* @param di The weight grid decimation table.
* @param dec_weights_uquant The quantized weight set.
* @param[in,out] ep The color endpoints (modifed in place).
* @param[out] rgbs_vectors The RGB+scale vectors for LDR blocks.
* @param[out] rgbo_vectors The RGB+offset vectors for HDR blocks.
*/
void recompute_ideal_colors_1plane(
const image_block& blk,
const partition_info& pi,
const decimation_info& di,
const uint8_t* dec_weights_uquant,
endpoints& ep,
vfloat4 rgbs_vectors[BLOCK_MAX_PARTITIONS],
vfloat4 rgbo_vectors[BLOCK_MAX_PARTITIONS]);
/**
* @brief For a given 2 plane weight set recompute the endpoint colors.
*
* As we quantize and decimate weights the optimal endpoint colors may change slightly, so we must
* recompute the ideal colors for a specific weight set.
*
* @param blk The image block color data to compress.
* @param bsd The block_size descriptor.
* @param di The weight grid decimation table.
* @param dec_weights_uquant_plane1 The quantized weight set for plane 1.
* @param dec_weights_uquant_plane2 The quantized weight set for plane 2.
* @param[in,out] ep The color endpoints (modifed in place).
* @param[out] rgbs_vector The RGB+scale color for LDR blocks.
* @param[out] rgbo_vector The RGB+offset color for HDR blocks.
* @param plane2_component The component assigned to plane 2.
*/
void recompute_ideal_colors_2planes(
const image_block& blk,
const block_size_descriptor& bsd,
const decimation_info& di,
const uint8_t* dec_weights_uquant_plane1,
const uint8_t* dec_weights_uquant_plane2,
endpoints& ep,
vfloat4& rgbs_vector,
vfloat4& rgbo_vector,
int plane2_component);
/**
* @brief Expand the angular tables needed for the alternative to PCA that we use.
*/
void prepare_angular_tables();
/**
* @brief Compute the angular endpoints for one plane for each block mode.
*
* @param only_always Only consider block modes that are always enabled.
* @param bsd The block size descriptor for the current trial.
* @param dec_weight_ideal_value The ideal decimated unquantized weight values.
* @param max_weight_quant The maximum block mode weight quantization allowed.
* @param[out] tmpbuf Preallocated scratch buffers for the compressor.
*/
void compute_angular_endpoints_1plane(
bool only_always,
const block_size_descriptor& bsd,
const float* dec_weight_ideal_value,
unsigned int max_weight_quant,
compression_working_buffers& tmpbuf);
/**
* @brief Compute the angular endpoints for two planes for each block mode.
*
* @param bsd The block size descriptor for the current trial.
* @param dec_weight_ideal_value The ideal decimated unquantized weight values.
* @param max_weight_quant The maximum block mode weight quantization allowed.
* @param[out] tmpbuf Preallocated scratch buffers for the compressor.
*/
void compute_angular_endpoints_2planes(
const block_size_descriptor& bsd,
const float* dec_weight_ideal_value,
unsigned int max_weight_quant,
compression_working_buffers& tmpbuf);
/* ============================================================================
Functionality for high level compression and decompression access.
============================================================================ */
/**
* @brief Compress an image block into a physical block.
*
* @param ctx The compressor context and configuration.
* @param blk The image block color data to compress.
* @param[out] pcb The physical compressed block output.
* @param[out] tmpbuf Preallocated scratch buffers for the compressor.
*/
void compress_block(
const astcenc_contexti& ctx,
const image_block& blk,
uint8_t pcb[16],
compression_working_buffers& tmpbuf);
/**
* @brief Decompress a symbolic block in to an image block.
*
* @param decode_mode The decode mode (LDR, HDR, etc).
* @param bsd The block size information.
* @param xpos The X coordinate of the block in the overall image.
* @param ypos The Y coordinate of the block in the overall image.
* @param zpos The Z coordinate of the block in the overall image.
* @param[out] blk The decompressed image block color data.
*/
void decompress_symbolic_block(
astcenc_profile decode_mode,
const block_size_descriptor& bsd,
int xpos,
int ypos,
int zpos,
const symbolic_compressed_block& scb,
image_block& blk);
/**
* @brief Compute the error between a symbolic block and the original input data.
*
* This function is specialized for 2 plane and 1 partition search.
*
* In RGBM mode this will reject blocks that attempt to encode a zero M value.
*
* @param config The compressor config.
* @param bsd The block size information.
* @param scb The symbolic compressed encoding.
* @param blk The original image block color data.
*
* @return Returns the computed error, or a negative value if the encoding
* should be rejected for any reason.
*/
float compute_symbolic_block_difference_2plane(
const astcenc_config& config,
const block_size_descriptor& bsd,
const symbolic_compressed_block& scb,
const image_block& blk);
/**
* @brief Compute the error between a symbolic block and the original input data.
*
* This function is specialized for 1 plane and N partition search.
*
* In RGBM mode this will reject blocks that attempt to encode a zero M value.
*
* @param config The compressor config.
* @param bsd The block size information.
* @param scb The symbolic compressed encoding.
* @param blk The original image block color data.
*
* @return Returns the computed error, or a negative value if the encoding
* should be rejected for any reason.
*/
float compute_symbolic_block_difference_1plane(
const astcenc_config& config,
const block_size_descriptor& bsd,
const symbolic_compressed_block& scb,
const image_block& blk);
/**
* @brief Compute the error between a symbolic block and the original input data.
*
* This function is specialized for 1 plane and 1 partition search.
*
* In RGBM mode this will reject blocks that attempt to encode a zero M value.
*
* @param config The compressor config.
* @param bsd The block size information.
* @param scb The symbolic compressed encoding.
* @param blk The original image block color data.
*
* @return Returns the computed error, or a negative value if the encoding
* should be rejected for any reason.
*/
float compute_symbolic_block_difference_1plane_1partition(
const astcenc_config& config,
const block_size_descriptor& bsd,
const symbolic_compressed_block& scb,
const image_block& blk);
/**
* @brief Convert a symbolic representation into a binary physical encoding.
*
* It is assumed that the symbolic encoding is valid and encodable, or
* previously flagged as an error block if an error color it to be encoded.
*
* @param bsd The block size information.
* @param scb The symbolic representation.
* @param[out] pcb The physical compressed block output.
*/
void symbolic_to_physical(
const block_size_descriptor& bsd,
const symbolic_compressed_block& scb,
uint8_t pcb[16]);
/**
* @brief Convert a binary physical encoding into a symbolic representation.
*
* This function can cope with arbitrary input data; output blocks will be
* flagged as an error block if the encoding is invalid.
*
* @param bsd The block size information.
* @param pcb The physical compresesd block input.
* @param[out] scb The output symbolic representation.
*/
void physical_to_symbolic(
const block_size_descriptor& bsd,
const uint8_t pcb[16],
symbolic_compressed_block& scb);
/* ============================================================================
Platform-specific functions.
============================================================================ */
/**
* @brief Allocate an aligned memory buffer.
*
* Allocated memory must be freed by aligned_free.
*
* @param size The desired buffer size.
* @param align The desired buffer alignment; must be 2^N, may be increased
* by the implementation to a minimum allowable alignment.
*
* @return The memory buffer pointer or nullptr on allocation failure.
*/
template<typename T>
T* aligned_malloc(size_t size, size_t align)
{
void* ptr;
int error = 0;
// Don't allow this to under-align a type
size_t min_align = astc::max(alignof(T), sizeof(void*));
size_t real_align = astc::max(min_align, align);
#if defined(_WIN32)
ptr = _aligned_malloc(size, real_align);
#else
error = posix_memalign(&ptr, real_align, size);
#endif
if (error || (!ptr))
{
return nullptr;
}
return static_cast<T*>(ptr);
}
/**
* @brief Free an aligned memory buffer.
*
* @param ptr The buffer to free.
*/
template<typename T>
void aligned_free(T* ptr)
{
#if defined(_WIN32)
_aligned_free(ptr);
#else
free(ptr);
#endif
}
#endif
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