virtualx-engine/thirdparty/basis_universal/basisu_etc.h

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// basis_etc.h
// Copyright (C) 2019 Binomial LLC. All Rights Reserved.
//
// 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.
#pragma once
#include "transcoder/basisu.h"
#include "basisu_enc.h"
#include <set>
namespace basisu
{
enum etc_constants
{
cETC1BytesPerBlock = 8U,
cETC1SelectorBits = 2U,
cETC1SelectorValues = 1U << cETC1SelectorBits,
cETC1SelectorMask = cETC1SelectorValues - 1U,
cETC1BlockShift = 2U,
cETC1BlockSize = 1U << cETC1BlockShift,
cETC1LSBSelectorIndicesBitOffset = 0,
cETC1MSBSelectorIndicesBitOffset = 16,
cETC1FlipBitOffset = 32,
cETC1DiffBitOffset = 33,
cETC1IntenModifierNumBits = 3,
cETC1IntenModifierValues = 1 << cETC1IntenModifierNumBits,
cETC1RightIntenModifierTableBitOffset = 34,
cETC1LeftIntenModifierTableBitOffset = 37,
// Base+Delta encoding (5 bit bases, 3 bit delta)
cETC1BaseColorCompNumBits = 5,
cETC1BaseColorCompMax = 1 << cETC1BaseColorCompNumBits,
cETC1DeltaColorCompNumBits = 3,
cETC1DeltaColorComp = 1 << cETC1DeltaColorCompNumBits,
cETC1DeltaColorCompMax = 1 << cETC1DeltaColorCompNumBits,
cETC1BaseColor5RBitOffset = 59,
cETC1BaseColor5GBitOffset = 51,
cETC1BaseColor5BBitOffset = 43,
cETC1DeltaColor3RBitOffset = 56,
cETC1DeltaColor3GBitOffset = 48,
cETC1DeltaColor3BBitOffset = 40,
// Absolute (non-delta) encoding (two 4-bit per component bases)
cETC1AbsColorCompNumBits = 4,
cETC1AbsColorCompMax = 1 << cETC1AbsColorCompNumBits,
cETC1AbsColor4R1BitOffset = 60,
cETC1AbsColor4G1BitOffset = 52,
cETC1AbsColor4B1BitOffset = 44,
cETC1AbsColor4R2BitOffset = 56,
cETC1AbsColor4G2BitOffset = 48,
cETC1AbsColor4B2BitOffset = 40,
cETC1ColorDeltaMin = -4,
cETC1ColorDeltaMax = 3,
// Delta3:
// 0 1 2 3 4 5 6 7
// 000 001 010 011 100 101 110 111
// 0 1 2 3 -4 -3 -2 -1
};
extern const int g_etc1_inten_tables[cETC1IntenModifierValues][cETC1SelectorValues];
extern const uint8_t g_etc1_to_selector_index[cETC1SelectorValues];
extern const uint8_t g_selector_index_to_etc1[cETC1SelectorValues];
struct etc_coord2
{
uint8_t m_x, m_y;
};
extern const etc_coord2 g_etc1_pixel_coords[2][2][8]; // [flipped][subblock][subblock_pixel]
extern const uint32_t g_etc1_pixel_indices[2][2][8]; // [flipped][subblock][subblock_pixel]
struct etc_block
{
// big endian uint64:
// bit ofs: 56 48 40 32 24 16 8 0
// byte ofs: b0, b1, b2, b3, b4, b5, b6, b7
union
{
uint64_t m_uint64;
uint8_t m_bytes[8];
};
inline void clear()
{
assert(sizeof(*this) == 8);
clear_obj(*this);
}
inline uint64_t get_all_bits() const
{
return read_be64(&m_uint64);
}
inline uint32_t get_general_bits(uint32_t ofs, uint32_t num) const
{
assert((ofs + num) <= 64U);
assert(num && (num < 32U));
return (read_be64(&m_uint64) >> ofs) & ((1UL << num) - 1UL);
}
inline void set_general_bits(uint32_t ofs, uint32_t num, uint32_t bits)
{
assert((ofs + num) <= 64U);
assert(num && (num < 32U));
uint64_t x = read_be64(&m_uint64);
uint64_t msk = ((1ULL << static_cast<uint64_t>(num)) - 1ULL) << static_cast<uint64_t>(ofs);
x &= ~msk;
x |= (static_cast<uint64_t>(bits) << static_cast<uint64_t>(ofs));
write_be64(&m_uint64, x);
}
inline uint32_t get_byte_bits(uint32_t ofs, uint32_t num) const
{
assert((ofs + num) <= 64U);
assert(num && (num <= 8U));
assert((ofs >> 3) == ((ofs + num - 1) >> 3));
const uint32_t byte_ofs = 7 - (ofs >> 3);
const uint32_t byte_bit_ofs = ofs & 7;
return (m_bytes[byte_ofs] >> byte_bit_ofs) & ((1 << num) - 1);
}
inline void set_byte_bits(uint32_t ofs, uint32_t num, uint32_t bits)
{
assert((ofs + num) <= 64U);
assert(num && (num < 32U));
assert((ofs >> 3) == ((ofs + num - 1) >> 3));
assert(bits < (1U << num));
const uint32_t byte_ofs = 7 - (ofs >> 3);
const uint32_t byte_bit_ofs = ofs & 7;
const uint32_t mask = (1 << num) - 1;
m_bytes[byte_ofs] &= ~(mask << byte_bit_ofs);
m_bytes[byte_ofs] |= (bits << byte_bit_ofs);
}
// false = left/right subblocks
// true = upper/lower subblocks
inline bool get_flip_bit() const
{
return (m_bytes[3] & 1) != 0;
}
inline void set_flip_bit(bool flip)
{
m_bytes[3] &= ~1;
m_bytes[3] |= static_cast<uint8_t>(flip);
}
inline bool get_diff_bit() const
{
return (m_bytes[3] & 2) != 0;
}
inline void set_diff_bit(bool diff)
{
m_bytes[3] &= ~2;
m_bytes[3] |= (static_cast<uint32_t>(diff) << 1);
}
// Returns intensity modifier table (0-7) used by subblock subblock_id.
// subblock_id=0 left/top (CW 1), 1=right/bottom (CW 2)
inline uint32_t get_inten_table(uint32_t subblock_id) const
{
assert(subblock_id < 2);
const uint32_t ofs = subblock_id ? 2 : 5;
return (m_bytes[3] >> ofs) & 7;
}
// Sets intensity modifier table (0-7) used by subblock subblock_id (0 or 1)
inline void set_inten_table(uint32_t subblock_id, uint32_t t)
{
assert(subblock_id < 2);
assert(t < 8);
const uint32_t ofs = subblock_id ? 2 : 5;
m_bytes[3] &= ~(7 << ofs);
m_bytes[3] |= (t << ofs);
}
inline void set_inten_tables_etc1s(uint32_t t)
{
set_inten_table(0, t);
set_inten_table(1, t);
}
inline bool is_etc1s() const
{
if (get_inten_table(0) != get_inten_table(1))
return false;
if (get_diff_bit())
{
if (get_delta3_color() != 0)
return false;
}
else
{
if (get_base4_color(0) != get_base4_color(1))
return false;
}
return true;
}
// Returned encoded selector value ranges from 0-3 (this is NOT a direct index into g_etc1_inten_tables, see get_selector())
inline uint32_t get_raw_selector(uint32_t x, uint32_t y) const
{
assert((x | y) < 4);
const uint32_t bit_index = x * 4 + y;
const uint32_t byte_bit_ofs = bit_index & 7;
const uint8_t *p = &m_bytes[7 - (bit_index >> 3)];
const uint32_t lsb = (p[0] >> byte_bit_ofs) & 1;
const uint32_t msb = (p[-2] >> byte_bit_ofs) & 1;
const uint32_t val = lsb | (msb << 1);
return val;
}
// Returned selector value ranges from 0-3 and is a direct index into g_etc1_inten_tables.
inline uint32_t get_selector(uint32_t x, uint32_t y) const
{
return g_etc1_to_selector_index[get_raw_selector(x, y)];
}
// Selector "val" ranges from 0-3 and is a direct index into g_etc1_inten_tables.
inline void set_selector(uint32_t x, uint32_t y, uint32_t val)
{
assert((x | y | val) < 4);
const uint32_t bit_index = x * 4 + y;
uint8_t *p = &m_bytes[7 - (bit_index >> 3)];
const uint32_t byte_bit_ofs = bit_index & 7;
const uint32_t mask = 1 << byte_bit_ofs;
const uint32_t etc1_val = g_selector_index_to_etc1[val];
const uint32_t lsb = etc1_val & 1;
const uint32_t msb = etc1_val >> 1;
p[0] &= ~mask;
p[0] |= (lsb << byte_bit_ofs);
p[-2] &= ~mask;
p[-2] |= (msb << byte_bit_ofs);
}
inline uint32_t get_raw_selector_bits() const
{
return m_bytes[4] | (m_bytes[5] << 8) | (m_bytes[6] << 16) | (m_bytes[7] << 24);
}
inline void set_raw_selector_bits(uint32_t bits)
{
m_bytes[4] = static_cast<uint8_t>(bits);
m_bytes[5] = static_cast<uint8_t>(bits >> 8);
m_bytes[6] = static_cast<uint8_t>(bits >> 16);
m_bytes[7] = static_cast<uint8_t>(bits >> 24);
}
inline void set_raw_selector_bits(uint8_t byte0, uint8_t byte1, uint8_t byte2, uint8_t byte3)
{
m_bytes[4] = byte0;
m_bytes[5] = byte1;
m_bytes[6] = byte2;
m_bytes[7] = byte3;
}
inline void set_base4_color(uint32_t idx, uint16_t c)
{
if (idx)
{
set_byte_bits(cETC1AbsColor4R2BitOffset, 4, (c >> 8) & 15);
set_byte_bits(cETC1AbsColor4G2BitOffset, 4, (c >> 4) & 15);
set_byte_bits(cETC1AbsColor4B2BitOffset, 4, c & 15);
}
else
{
set_byte_bits(cETC1AbsColor4R1BitOffset, 4, (c >> 8) & 15);
set_byte_bits(cETC1AbsColor4G1BitOffset, 4, (c >> 4) & 15);
set_byte_bits(cETC1AbsColor4B1BitOffset, 4, c & 15);
}
}
inline uint16_t get_base4_color(uint32_t idx) const
{
uint32_t r, g, b;
if (idx)
{
r = get_byte_bits(cETC1AbsColor4R2BitOffset, 4);
g = get_byte_bits(cETC1AbsColor4G2BitOffset, 4);
b = get_byte_bits(cETC1AbsColor4B2BitOffset, 4);
}
else
{
r = get_byte_bits(cETC1AbsColor4R1BitOffset, 4);
g = get_byte_bits(cETC1AbsColor4G1BitOffset, 4);
b = get_byte_bits(cETC1AbsColor4B1BitOffset, 4);
}
return static_cast<uint16_t>(b | (g << 4U) | (r << 8U));
}
inline void set_base5_color(uint16_t c)
{
set_byte_bits(cETC1BaseColor5RBitOffset, 5, (c >> 10) & 31);
set_byte_bits(cETC1BaseColor5GBitOffset, 5, (c >> 5) & 31);
set_byte_bits(cETC1BaseColor5BBitOffset, 5, c & 31);
}
inline uint16_t get_base5_color() const
{
const uint32_t r = get_byte_bits(cETC1BaseColor5RBitOffset, 5);
const uint32_t g = get_byte_bits(cETC1BaseColor5GBitOffset, 5);
const uint32_t b = get_byte_bits(cETC1BaseColor5BBitOffset, 5);
return static_cast<uint16_t>(b | (g << 5U) | (r << 10U));
}
void set_delta3_color(uint16_t c)
{
set_byte_bits(cETC1DeltaColor3RBitOffset, 3, (c >> 6) & 7);
set_byte_bits(cETC1DeltaColor3GBitOffset, 3, (c >> 3) & 7);
set_byte_bits(cETC1DeltaColor3BBitOffset, 3, c & 7);
}
inline uint16_t get_delta3_color() const
{
const uint32_t r = get_byte_bits(cETC1DeltaColor3RBitOffset, 3);
const uint32_t g = get_byte_bits(cETC1DeltaColor3GBitOffset, 3);
const uint32_t b = get_byte_bits(cETC1DeltaColor3BBitOffset, 3);
return static_cast<uint16_t>(b | (g << 3U) | (r << 6U));
}
uint64_t determine_selectors(const color_rgba* pSource_pixels, bool perceptual, uint32_t begin_subblock = 0, uint32_t end_subblock = 2)
{
uint64_t total_error = 0;
for (uint32_t subblock = begin_subblock; subblock < end_subblock; subblock++)
{
color_rgba block_colors[4];
get_block_colors(block_colors, subblock);
if (get_flip_bit())
{
for (uint32_t y = 0; y < 2; y++)
{
for (uint32_t x = 0; x < 4; x++)
{
uint32_t best_selector = 0;
uint64_t best_error = UINT64_MAX;
for (uint32_t s = 0; s < 4; s++)
{
uint64_t err = color_distance(perceptual, block_colors[s], pSource_pixels[x + (subblock * 2 + y) * 4], false);
if (err < best_error)
{
best_error = err;
best_selector = s;
}
}
set_selector(x, subblock * 2 + y, best_selector);
total_error += best_error;
}
}
}
else
{
for (uint32_t y = 0; y < 4; y++)
{
for (uint32_t x = 0; x < 2; x++)
{
uint32_t best_selector = 0;
uint64_t best_error = UINT64_MAX;
for (uint32_t s = 0; s < 4; s++)
{
uint64_t err = color_distance(perceptual, block_colors[s], pSource_pixels[(subblock * 2) + x + y * 4], false);
if (err < best_error)
{
best_error = err;
best_selector = s;
}
}
set_selector(subblock * 2 + x, y, best_selector);
total_error += best_error;
}
}
}
}
return total_error;
}
color_rgba get_block_color(uint32_t subblock_index, bool scaled) const
{
color_rgba b;
if (get_diff_bit())
{
if (subblock_index)
unpack_color5(b, get_base5_color(), get_delta3_color(), scaled);
else
unpack_color5(b, get_base5_color(), scaled);
}
else
{
b = unpack_color4(get_base4_color(subblock_index), scaled);
}
return b;
}
uint32_t get_subblock_index(uint32_t x, uint32_t y) const
{
if (get_flip_bit())
return y >= 2;
else
return x >= 2;
}
bool get_block_colors(color_rgba* pBlock_colors, uint32_t subblock_index) const
{
color_rgba b;
if (get_diff_bit())
{
if (subblock_index)
unpack_color5(b, get_base5_color(), get_delta3_color(), true);
else
unpack_color5(b, get_base5_color(), true);
}
else
{
b = unpack_color4(get_base4_color(subblock_index), true);
}
const int* pInten_table = g_etc1_inten_tables[get_inten_table(subblock_index)];
bool dc = false;
pBlock_colors[0].set(clamp255(b.r + pInten_table[0], dc), clamp255(b.g + pInten_table[0], dc), clamp255(b.b + pInten_table[0], dc), 255);
pBlock_colors[1].set(clamp255(b.r + pInten_table[1], dc), clamp255(b.g + pInten_table[1], dc), clamp255(b.b + pInten_table[1], dc), 255);
pBlock_colors[2].set(clamp255(b.r + pInten_table[2], dc), clamp255(b.g + pInten_table[2], dc), clamp255(b.b + pInten_table[2], dc), 255);
pBlock_colors[3].set(clamp255(b.r + pInten_table[3], dc), clamp255(b.g + pInten_table[3], dc), clamp255(b.b + pInten_table[3], dc), 255);
return dc;
}
void get_block_color(color_rgba& color, uint32_t subblock_index, uint32_t selector_index) const
{
color_rgba b;
if (get_diff_bit())
{
if (subblock_index)
unpack_color5(b, get_base5_color(), get_delta3_color(), true);
else
unpack_color5(b, get_base5_color(), true);
}
else
{
b = unpack_color4(get_base4_color(subblock_index), true);
}
const int* pInten_table = g_etc1_inten_tables[get_inten_table(subblock_index)];
color.set(clamp255(b.r + pInten_table[selector_index]), clamp255(b.g + pInten_table[selector_index]), clamp255(b.b + pInten_table[selector_index]), 255);
}
bool get_block_low_high_colors(color_rgba* pBlock_colors, uint32_t subblock_index) const
{
color_rgba b;
if (get_diff_bit())
{
if (subblock_index)
unpack_color5(b, get_base5_color(), get_delta3_color(), true);
else
unpack_color5(b, get_base5_color(), true);
}
else
{
b = unpack_color4(get_base4_color(subblock_index), true);
}
const int* pInten_table = g_etc1_inten_tables[get_inten_table(subblock_index)];
bool dc = false;
pBlock_colors[0].set(clamp255(b.r + pInten_table[0], dc), clamp255(b.g + pInten_table[0], dc), clamp255(b.b + pInten_table[0], dc), 255);
pBlock_colors[1].set(clamp255(b.r + pInten_table[3], dc), clamp255(b.g + pInten_table[3], dc), clamp255(b.b + pInten_table[3], dc), 255);
return dc;
}
static void get_block_colors5(color_rgba *pBlock_colors, const color_rgba &base_color5, uint32_t inten_table, bool scaled = false)
{
color_rgba b(base_color5);
if (!scaled)
{
b.r = (b.r << 3) | (b.r >> 2);
b.g = (b.g << 3) | (b.g >> 2);
b.b = (b.b << 3) | (b.b >> 2);
}
const int* pInten_table = g_etc1_inten_tables[inten_table];
pBlock_colors[0].set(clamp255(b.r + pInten_table[0]), clamp255(b.g + pInten_table[0]), clamp255(b.b + pInten_table[0]), 255);
pBlock_colors[1].set(clamp255(b.r + pInten_table[1]), clamp255(b.g + pInten_table[1]), clamp255(b.b + pInten_table[1]), 255);
pBlock_colors[2].set(clamp255(b.r + pInten_table[2]), clamp255(b.g + pInten_table[2]), clamp255(b.b + pInten_table[2]), 255);
pBlock_colors[3].set(clamp255(b.r + pInten_table[3]), clamp255(b.g + pInten_table[3]), clamp255(b.b + pInten_table[3]), 255);
}
static void get_block_colors4(color_rgba *pBlock_colors, const color_rgba &base_color4, uint32_t inten_table, bool scaled = false)
{
color_rgba b(base_color4);
if (!scaled)
{
b.r = (b.r << 4) | b.r;
b.g = (b.g << 4) | b.g;
b.b = (b.b << 4) | b.b;
}
const int* pInten_table = g_etc1_inten_tables[inten_table];
pBlock_colors[0].set(clamp255(b.r + pInten_table[0]), clamp255(b.g + pInten_table[0]), clamp255(b.b + pInten_table[0]), 255);
pBlock_colors[1].set(clamp255(b.r + pInten_table[1]), clamp255(b.g + pInten_table[1]), clamp255(b.b + pInten_table[1]), 255);
pBlock_colors[2].set(clamp255(b.r + pInten_table[2]), clamp255(b.g + pInten_table[2]), clamp255(b.b + pInten_table[2]), 255);
pBlock_colors[3].set(clamp255(b.r + pInten_table[3]), clamp255(b.g + pInten_table[3]), clamp255(b.b + pInten_table[3]), 255);
}
uint64_t evaluate_etc1_error(const color_rgba* pBlock_pixels, bool perceptual, int subblock_index = -1) const;
void get_subblock_pixels(color_rgba* pPixels, int subblock_index = -1) const;
void get_selector_range(uint32_t& low, uint32_t& high) const
{
low = 3;
high = 0;
for (uint32_t y = 0; y < 4; y++)
{
for (uint32_t x = 0; x < 4; x++)
{
const uint32_t s = get_selector(x, y);
low = minimum(low, s);
high = maximum(high, s);
}
}
}
void set_block_color4(const color_rgba &c0_unscaled, const color_rgba &c1_unscaled)
{
set_diff_bit(false);
set_base4_color(0, pack_color4(c0_unscaled, false));
set_base4_color(1, pack_color4(c1_unscaled, false));
}
void set_block_color5(const color_rgba &c0_unscaled, const color_rgba &c1_unscaled)
{
set_diff_bit(true);
set_base5_color(pack_color5(c0_unscaled, false));
int dr = c1_unscaled.r - c0_unscaled.r;
int dg = c1_unscaled.g - c0_unscaled.g;
int db = c1_unscaled.b - c0_unscaled.b;
set_delta3_color(pack_delta3(dr, dg, db));
}
void set_block_color5_etc1s(const color_rgba &c_unscaled)
{
set_diff_bit(true);
set_base5_color(pack_color5(c_unscaled, false));
set_delta3_color(pack_delta3(0, 0, 0));
}
bool set_block_color5_check(const color_rgba &c0_unscaled, const color_rgba &c1_unscaled)
{
set_diff_bit(true);
set_base5_color(pack_color5(c0_unscaled, false));
int dr = c1_unscaled.r - c0_unscaled.r;
int dg = c1_unscaled.g - c0_unscaled.g;
int db = c1_unscaled.b - c0_unscaled.b;
if (((dr < cETC1ColorDeltaMin) || (dr > cETC1ColorDeltaMax)) ||
((dg < cETC1ColorDeltaMin) || (dg > cETC1ColorDeltaMax)) ||
((db < cETC1ColorDeltaMin) || (db > cETC1ColorDeltaMax)))
return false;
set_delta3_color(pack_delta3(dr, dg, db));
return true;
}
color_rgba get_selector_color(uint32_t x, uint32_t y, uint32_t s) const
{
color_rgba block_colors[4];
get_block_colors(block_colors, get_subblock_index(x, y));
return block_colors[s];
}
// Base color 5
static uint16_t pack_color5(const color_rgba& color, bool scaled, uint32_t bias = 127U);
static uint16_t pack_color5(uint32_t r, uint32_t g, uint32_t b, bool scaled, uint32_t bias = 127U);
static color_rgba unpack_color5(uint16_t packed_color5, bool scaled, uint32_t alpha = 255U);
static void unpack_color5(uint32_t& r, uint32_t& g, uint32_t& b, uint16_t packed_color, bool scaled);
static void unpack_color5(color_rgba& result, uint16_t packed_color5, bool scaled);
static bool unpack_color5(color_rgba& result, uint16_t packed_color5, uint16_t packed_delta3, bool scaled, uint32_t alpha = 255U);
static bool unpack_color5(uint32_t& r, uint32_t& g, uint32_t& b, uint16_t packed_color5, uint16_t packed_delta3, bool scaled, uint32_t alpha = 255U);
// Delta color 3
// Inputs range from -4 to 3 (cETC1ColorDeltaMin to cETC1ColorDeltaMax)
static uint16_t pack_delta3(const color_rgba_i16& color);
static uint16_t pack_delta3(int r, int g, int b);
// Results range from -4 to 3 (cETC1ColorDeltaMin to cETC1ColorDeltaMax)
static color_rgba_i16 unpack_delta3(uint16_t packed_delta3);
static void unpack_delta3(int& r, int& g, int& b, uint16_t packed_delta3);
static bool try_pack_color5_delta3(const color_rgba *pColor5_unscaled)
{
int dr = pColor5_unscaled[1].r - pColor5_unscaled[0].r;
int dg = pColor5_unscaled[1].g - pColor5_unscaled[0].g;
int db = pColor5_unscaled[1].b - pColor5_unscaled[0].b;
if ((minimum(dr, dg, db) < cETC1ColorDeltaMin) || (maximum(dr, dg, db) > cETC1ColorDeltaMax))
return false;
return true;
}
// Abs color 4
static uint16_t pack_color4(const color_rgba& color, bool scaled, uint32_t bias = 127U);
static uint16_t pack_color4(uint32_t r, uint32_t g, uint32_t b, bool scaled, uint32_t bias = 127U);
static color_rgba unpack_color4(uint16_t packed_color4, bool scaled, uint32_t alpha = 255U);
static void unpack_color4(uint32_t& r, uint32_t& g, uint32_t& b, uint16_t packed_color4, bool scaled);
// subblock colors
static void get_diff_subblock_colors(color_rgba* pDst, uint16_t packed_color5, uint32_t table_idx);
static bool get_diff_subblock_colors(color_rgba* pDst, uint16_t packed_color5, uint16_t packed_delta3, uint32_t table_idx);
static void get_abs_subblock_colors(color_rgba* pDst, uint16_t packed_color4, uint32_t table_idx);
static inline void unscaled_to_scaled_color(color_rgba& dst, const color_rgba& src, bool color4)
{
if (color4)
{
dst.r = src.r | (src.r << 4);
dst.g = src.g | (src.g << 4);
dst.b = src.b | (src.b << 4);
}
else
{
dst.r = (src.r >> 2) | (src.r << 3);
dst.g = (src.g >> 2) | (src.g << 3);
dst.b = (src.b >> 2) | (src.b << 3);
}
dst.a = src.a;
}
private:
static uint8_t clamp255(int x, bool &did_clamp)
{
if (x < 0)
{
did_clamp = true;
return 0;
}
else if (x > 255)
{
did_clamp = true;
return 255;
}
return static_cast<uint8_t>(x);
}
static uint8_t clamp255(int x)
{
if (x < 0)
return 0;
else if (x > 255)
return 255;
return static_cast<uint8_t>(x);
}
};
typedef std::vector<etc_block> etc_block_vec;
// Returns false if the unpack fails (could be bogus data or ETC2)
bool unpack_etc1(const etc_block& block, color_rgba *pDst, bool preserve_alpha = false);
enum basis_etc_quality
{
cETCQualityFast,
cETCQualityMedium,
cETCQualitySlow,
cETCQualityUber,
cETCQualityTotal,
};
struct basis_etc1_pack_params
{
basis_etc_quality m_quality;
bool m_perceptual;
bool m_cluster_fit;
bool m_force_etc1s;
bool m_use_color4;
float m_flip_bias;
inline basis_etc1_pack_params()
{
clear();
}
void clear()
{
m_quality = cETCQualitySlow;
m_perceptual = true;
m_cluster_fit = true;
m_force_etc1s = false;
m_use_color4 = true;
m_flip_bias = 0.0f;
}
};
struct etc1_solution_coordinates
{
inline etc1_solution_coordinates() :
m_unscaled_color(0, 0, 0, 0),
m_inten_table(0),
m_color4(false)
{
}
inline etc1_solution_coordinates(uint32_t r, uint32_t g, uint32_t b, uint32_t inten_table, bool color4) :
m_unscaled_color((uint8_t)r, (uint8_t)g, (uint8_t)b, 255),
m_inten_table((uint8_t)inten_table),
m_color4(color4)
{
}
inline etc1_solution_coordinates(const color_rgba& c, uint32_t inten_table, bool color4) :
m_unscaled_color(c),
m_inten_table(inten_table),
m_color4(color4)
{
}
inline etc1_solution_coordinates(const etc1_solution_coordinates& other)
{
*this = other;
}
inline etc1_solution_coordinates& operator= (const etc1_solution_coordinates& rhs)
{
m_unscaled_color = rhs.m_unscaled_color;
m_inten_table = rhs.m_inten_table;
m_color4 = rhs.m_color4;
return *this;
}
inline void clear()
{
m_unscaled_color.clear();
m_inten_table = 0;
m_color4 = false;
}
inline void init(const color_rgba& c, uint32_t inten_table, bool color4)
{
m_unscaled_color = c;
m_inten_table = inten_table;
m_color4 = color4;
}
inline color_rgba get_scaled_color() const
{
int br, bg, bb;
if (m_color4)
{
br = m_unscaled_color.r | (m_unscaled_color.r << 4);
bg = m_unscaled_color.g | (m_unscaled_color.g << 4);
bb = m_unscaled_color.b | (m_unscaled_color.b << 4);
}
else
{
br = (m_unscaled_color.r >> 2) | (m_unscaled_color.r << 3);
bg = (m_unscaled_color.g >> 2) | (m_unscaled_color.g << 3);
bb = (m_unscaled_color.b >> 2) | (m_unscaled_color.b << 3);
}
return color_rgba((uint8_t)br, (uint8_t)bg, (uint8_t)bb, 255);
}
// returns true if anything was clamped
inline void get_block_colors(color_rgba* pBlock_colors)
{
int br, bg, bb;
if (m_color4)
{
br = m_unscaled_color.r | (m_unscaled_color.r << 4);
bg = m_unscaled_color.g | (m_unscaled_color.g << 4);
bb = m_unscaled_color.b | (m_unscaled_color.b << 4);
}
else
{
br = (m_unscaled_color.r >> 2) | (m_unscaled_color.r << 3);
bg = (m_unscaled_color.g >> 2) | (m_unscaled_color.g << 3);
bb = (m_unscaled_color.b >> 2) | (m_unscaled_color.b << 3);
}
const int* pInten_table = g_etc1_inten_tables[m_inten_table];
pBlock_colors[0].set((uint8_t)(br + pInten_table[0]), (uint8_t)(bg + pInten_table[0]), (uint8_t)(bb + pInten_table[0]), 255);
pBlock_colors[1].set((uint8_t)(br + pInten_table[1]), (uint8_t)(bg + pInten_table[1]), (uint8_t)(bb + pInten_table[1]), 255);
pBlock_colors[2].set((uint8_t)(br + pInten_table[2]), (uint8_t)(bg + pInten_table[2]), (uint8_t)(bb + pInten_table[2]), 255);
pBlock_colors[3].set((uint8_t)(br + pInten_table[3]), (uint8_t)(bg + pInten_table[3]), (uint8_t)(bb + pInten_table[3]), 255);
}
color_rgba m_unscaled_color;
uint32_t m_inten_table;
bool m_color4;
};
class etc1_optimizer
{
BASISU_NO_EQUALS_OR_COPY_CONSTRUCT(etc1_optimizer);
public:
etc1_optimizer()
{
clear();
}
void clear()
{
m_pParams = nullptr;
m_pResult = nullptr;
m_pSorted_luma = nullptr;
m_pSorted_luma_indices = nullptr;
}
struct params;
typedef bool(*evaluate_solution_override_func)(uint64_t &error, const params &p, const color_rgba* pBlock_colors, const uint8_t* pSelectors, const etc1_solution_coordinates& coords);
struct params : basis_etc1_pack_params
{
params()
{
clear();
}
params(const basis_etc1_pack_params& base_params)
{
clear_optimizer_params();
*static_cast<basis_etc1_pack_params *>(this) = base_params;
}
void clear()
{
clear_optimizer_params();
}
void clear_optimizer_params()
{
basis_etc1_pack_params::clear();
m_num_src_pixels = 0;
m_pSrc_pixels = 0;
m_use_color4 = false;
static const int s_default_scan_delta[] = { 0 };
m_pScan_deltas = s_default_scan_delta;
m_scan_delta_size = 1;
m_base_color5.clear();
m_constrain_against_base_color5 = false;
m_refinement = true;
m_pForce_selectors = nullptr;
m_pEval_solution_override = nullptr;
m_pEval_solution_override_data = nullptr;
}
uint32_t m_num_src_pixels;
const color_rgba* m_pSrc_pixels;
bool m_use_color4;
const int* m_pScan_deltas;
uint32_t m_scan_delta_size;
color_rgba m_base_color5;
bool m_constrain_against_base_color5;
bool m_refinement;
const uint8_t* m_pForce_selectors;
evaluate_solution_override_func m_pEval_solution_override;
void *m_pEval_solution_override_data;
};
struct results
{
uint64_t m_error;
color_rgba m_block_color_unscaled;
uint32_t m_block_inten_table;
uint32_t m_n;
uint8_t* m_pSelectors;
bool m_block_color4;
inline results& operator= (const results& rhs)
{
m_block_color_unscaled = rhs.m_block_color_unscaled;
m_block_color4 = rhs.m_block_color4;
m_block_inten_table = rhs.m_block_inten_table;
m_error = rhs.m_error;
memcpy(m_pSelectors, rhs.m_pSelectors, minimum(rhs.m_n, m_n));
return *this;
}
};
void init(const params& params, results& result);
bool compute();
const params* get_params() const { return m_pParams; }
private:
struct potential_solution
{
potential_solution() : m_coords(), m_error(UINT64_MAX), m_valid(false)
{
}
etc1_solution_coordinates m_coords;
std::vector<uint8_t> m_selectors;
uint64_t m_error;
bool m_valid;
void clear()
{
m_coords.clear();
m_selectors.resize(0);
m_error = UINT64_MAX;
m_valid = false;
}
bool are_selectors_all_equal() const
{
if (!m_selectors.size())
return false;
const uint32_t s = m_selectors[0];
for (uint32_t i = 1; i < m_selectors.size(); i++)
if (m_selectors[i] != s)
return false;
return true;
}
};
const params* m_pParams;
results* m_pResult;
int m_limit;
vec3F m_avg_color;
int m_br, m_bg, m_bb;
std::vector<uint16_t> m_luma;
std::vector<uint32_t> m_sorted_luma;
std::vector<uint32_t> m_sorted_luma_indices;
const uint32_t* m_pSorted_luma_indices;
uint32_t* m_pSorted_luma;
std::vector<uint8_t> m_selectors;
std::vector<uint8_t> m_best_selectors;
potential_solution m_best_solution;
potential_solution m_trial_solution;
std::vector<uint8_t> m_temp_selectors;
std::set<uint32_t> m_solutions_tried;
void get_nearby_inten_tables(uint32_t idx, int &first_inten_table, int &last_inten_table)
{
first_inten_table = maximum<int>(idx - 1, 0);
last_inten_table = minimum<int>(cETC1IntenModifierValues, idx + 1);
}
bool evaluate_solution_slow(const etc1_solution_coordinates& coords, potential_solution& trial_solution, potential_solution* pBest_solution);
bool evaluate_solution_fast(const etc1_solution_coordinates& coords, potential_solution& trial_solution, potential_solution* pBest_solution);
inline bool evaluate_solution(const etc1_solution_coordinates& coords, potential_solution& trial_solution, potential_solution* pBest_solution)
{
if (m_pParams->m_quality >= cETCQualitySlow)
return evaluate_solution_slow(coords, trial_solution, pBest_solution);
else
return evaluate_solution_fast(coords, trial_solution, pBest_solution);
}
void refine_solution(uint32_t max_refinement_trials);
void compute_internal_neighborhood(int scan_r, int scan_g, int scan_b);
void compute_internal_cluster_fit(uint32_t total_perms_to_try);
};
struct pack_etc1_block_context
{
etc1_optimizer m_optimizer;
};
} // namespace basisu