virtualx-engine/thirdparty/basis_universal/encoder/basisu_bc7enc.cpp

1984 lines
72 KiB
C++

// File: basisu_bc7enc.cpp
// Copyright (C) 2019-2021 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.
#include "basisu_bc7enc.h"
#ifdef _DEBUG
#define BC7ENC_CHECK_OVERALL_ERROR 1
#else
#define BC7ENC_CHECK_OVERALL_ERROR 0
#endif
using namespace basist;
namespace basisu
{
// Helpers
static inline color_quad_u8 *color_quad_u8_set_clamped(color_quad_u8 *pRes, int32_t r, int32_t g, int32_t b, int32_t a) { pRes->m_c[0] = (uint8_t)clampi(r, 0, 255); pRes->m_c[1] = (uint8_t)clampi(g, 0, 255); pRes->m_c[2] = (uint8_t)clampi(b, 0, 255); pRes->m_c[3] = (uint8_t)clampi(a, 0, 255); return pRes; }
static inline color_quad_u8 *color_quad_u8_set(color_quad_u8 *pRes, int32_t r, int32_t g, int32_t b, int32_t a) { assert((uint32_t)(r | g | b | a) <= 255); pRes->m_c[0] = (uint8_t)r; pRes->m_c[1] = (uint8_t)g; pRes->m_c[2] = (uint8_t)b; pRes->m_c[3] = (uint8_t)a; return pRes; }
static inline bc7enc_bool color_quad_u8_notequals(const color_quad_u8 *pLHS, const color_quad_u8 *pRHS) { return (pLHS->m_c[0] != pRHS->m_c[0]) || (pLHS->m_c[1] != pRHS->m_c[1]) || (pLHS->m_c[2] != pRHS->m_c[2]) || (pLHS->m_c[3] != pRHS->m_c[3]); }
static inline bc7enc_vec4F*vec4F_set_scalar(bc7enc_vec4F*pV, float x) { pV->m_c[0] = x; pV->m_c[1] = x; pV->m_c[2] = x; pV->m_c[3] = x; return pV; }
static inline bc7enc_vec4F*vec4F_set(bc7enc_vec4F*pV, float x, float y, float z, float w) { pV->m_c[0] = x; pV->m_c[1] = y; pV->m_c[2] = z; pV->m_c[3] = w; return pV; }
static inline bc7enc_vec4F*vec4F_saturate_in_place(bc7enc_vec4F*pV) { pV->m_c[0] = saturate(pV->m_c[0]); pV->m_c[1] = saturate(pV->m_c[1]); pV->m_c[2] = saturate(pV->m_c[2]); pV->m_c[3] = saturate(pV->m_c[3]); return pV; }
static inline bc7enc_vec4F vec4F_saturate(const bc7enc_vec4F*pV) { bc7enc_vec4F res; res.m_c[0] = saturate(pV->m_c[0]); res.m_c[1] = saturate(pV->m_c[1]); res.m_c[2] = saturate(pV->m_c[2]); res.m_c[3] = saturate(pV->m_c[3]); return res; }
static inline bc7enc_vec4F vec4F_from_color(const color_quad_u8 *pC) { bc7enc_vec4F res; vec4F_set(&res, pC->m_c[0], pC->m_c[1], pC->m_c[2], pC->m_c[3]); return res; }
static inline bc7enc_vec4F vec4F_add(const bc7enc_vec4F*pLHS, const bc7enc_vec4F*pRHS) { bc7enc_vec4F res; vec4F_set(&res, pLHS->m_c[0] + pRHS->m_c[0], pLHS->m_c[1] + pRHS->m_c[1], pLHS->m_c[2] + pRHS->m_c[2], pLHS->m_c[3] + pRHS->m_c[3]); return res; }
static inline bc7enc_vec4F vec4F_sub(const bc7enc_vec4F*pLHS, const bc7enc_vec4F*pRHS) { bc7enc_vec4F res; vec4F_set(&res, pLHS->m_c[0] - pRHS->m_c[0], pLHS->m_c[1] - pRHS->m_c[1], pLHS->m_c[2] - pRHS->m_c[2], pLHS->m_c[3] - pRHS->m_c[3]); return res; }
static inline float vec4F_dot(const bc7enc_vec4F*pLHS, const bc7enc_vec4F*pRHS) { return pLHS->m_c[0] * pRHS->m_c[0] + pLHS->m_c[1] * pRHS->m_c[1] + pLHS->m_c[2] * pRHS->m_c[2] + pLHS->m_c[3] * pRHS->m_c[3]; }
static inline bc7enc_vec4F vec4F_mul(const bc7enc_vec4F*pLHS, float s) { bc7enc_vec4F res; vec4F_set(&res, pLHS->m_c[0] * s, pLHS->m_c[1] * s, pLHS->m_c[2] * s, pLHS->m_c[3] * s); return res; }
static inline bc7enc_vec4F* vec4F_normalize_in_place(bc7enc_vec4F*pV) { float s = pV->m_c[0] * pV->m_c[0] + pV->m_c[1] * pV->m_c[1] + pV->m_c[2] * pV->m_c[2] + pV->m_c[3] * pV->m_c[3]; if (s != 0.0f) { s = 1.0f / sqrtf(s); pV->m_c[0] *= s; pV->m_c[1] *= s; pV->m_c[2] *= s; pV->m_c[3] *= s; } return pV; }
// Precomputed weight constants used during least fit determination. For each entry in g_bc7_weights[]: w * w, (1.0f - w) * w, (1.0f - w) * (1.0f - w), w
const float g_bc7_weights1x[2 * 4] = { 0.000000f, 0.000000f, 1.000000f, 0.000000f, 1.000000f, 0.000000f, 0.000000f, 1.000000f };
const float g_bc7_weights2x[4 * 4] = { 0.000000f, 0.000000f, 1.000000f, 0.000000f, 0.107666f, 0.220459f, 0.451416f, 0.328125f, 0.451416f, 0.220459f, 0.107666f, 0.671875f, 1.000000f, 0.000000f, 0.000000f, 1.000000f };
const float g_bc7_weights3x[8 * 4] = { 0.000000f, 0.000000f, 1.000000f, 0.000000f, 0.019775f, 0.120850f, 0.738525f, 0.140625f, 0.079102f, 0.202148f, 0.516602f, 0.281250f, 0.177979f, 0.243896f, 0.334229f, 0.421875f, 0.334229f, 0.243896f, 0.177979f, 0.578125f, 0.516602f, 0.202148f,
0.079102f, 0.718750f, 0.738525f, 0.120850f, 0.019775f, 0.859375f, 1.000000f, 0.000000f, 0.000000f, 1.000000f };
const float g_bc7_weights4x[16 * 4] = { 0.000000f, 0.000000f, 1.000000f, 0.000000f, 0.003906f, 0.058594f, 0.878906f, 0.062500f, 0.019775f, 0.120850f, 0.738525f, 0.140625f, 0.041260f, 0.161865f, 0.635010f, 0.203125f, 0.070557f, 0.195068f, 0.539307f, 0.265625f, 0.107666f, 0.220459f,
0.451416f, 0.328125f, 0.165039f, 0.241211f, 0.352539f, 0.406250f, 0.219727f, 0.249023f, 0.282227f, 0.468750f, 0.282227f, 0.249023f, 0.219727f, 0.531250f, 0.352539f, 0.241211f, 0.165039f, 0.593750f, 0.451416f, 0.220459f, 0.107666f, 0.671875f, 0.539307f, 0.195068f, 0.070557f, 0.734375f,
0.635010f, 0.161865f, 0.041260f, 0.796875f, 0.738525f, 0.120850f, 0.019775f, 0.859375f, 0.878906f, 0.058594f, 0.003906f, 0.937500f, 1.000000f, 0.000000f, 0.000000f, 1.000000f };
const float g_astc_weights4x[16 * 4] = { 0.000000f, 0.000000f, 1.000000f, 0.000000f, 0.003906f, 0.058594f, 0.878906f, 0.062500f, 0.015625f, 0.109375f, 0.765625f, 0.125000f, 0.035156f, 0.152344f, 0.660156f, 0.187500f, 0.070557f, 0.195068f, 0.539307f, 0.265625f, 0.107666f, 0.220459f,
0.451416f, 0.328125f, 0.152588f, 0.238037f, 0.371338f, 0.390625f, 0.205322f, 0.247803f, 0.299072f, 0.453125f, 0.299072f, 0.247803f, 0.205322f, 0.546875f, 0.371338f, 0.238037f, 0.152588f, 0.609375f, 0.451416f, 0.220459f, 0.107666f, 0.671875f, 0.539307f, 0.195068f, 0.070557f, 0.734375f,
0.660156f, 0.152344f, 0.035156f, 0.812500f, 0.765625f, 0.109375f, 0.015625f, 0.875000f, 0.878906f, 0.058594f, 0.003906f, 0.937500f, 1.000000f, 0.000000f, 0.000000f, 1.000000f };
const float g_astc_weights5x[32 * 4] = { 0.000000f, 0.000000f, 1.000000f, 0.000000f, 0.000977f, 0.030273f, 0.938477f, 0.031250f, 0.003906f, 0.058594f, 0.878906f, 0.062500f, 0.008789f, 0.084961f, 0.821289f,
0.093750f, 0.015625f, 0.109375f, 0.765625f, 0.125000f, 0.024414f, 0.131836f, 0.711914f, 0.156250f, 0.035156f, 0.152344f, 0.660156f, 0.187500f, 0.047852f, 0.170898f, 0.610352f, 0.218750f, 0.062500f, 0.187500f,
0.562500f, 0.250000f, 0.079102f, 0.202148f, 0.516602f, 0.281250f, 0.097656f, 0.214844f, 0.472656f, 0.312500f, 0.118164f, 0.225586f, 0.430664f, 0.343750f, 0.140625f, 0.234375f, 0.390625f, 0.375000f, 0.165039f,
0.241211f, 0.352539f, 0.406250f, 0.191406f, 0.246094f, 0.316406f, 0.437500f, 0.219727f, 0.249023f, 0.282227f, 0.468750f, 0.282227f, 0.249023f, 0.219727f, 0.531250f, 0.316406f, 0.246094f, 0.191406f, 0.562500f,
0.352539f, 0.241211f, 0.165039f, 0.593750f, 0.390625f, 0.234375f, 0.140625f, 0.625000f, 0.430664f, 0.225586f, 0.118164f, 0.656250f, 0.472656f, 0.214844f, 0.097656f, 0.687500f, 0.516602f, 0.202148f, 0.079102f,
0.718750f, 0.562500f, 0.187500f, 0.062500f, 0.750000f, 0.610352f, 0.170898f, 0.047852f, 0.781250f, 0.660156f, 0.152344f, 0.035156f, 0.812500f, 0.711914f, 0.131836f, 0.024414f, 0.843750f, 0.765625f, 0.109375f,
0.015625f, 0.875000f, 0.821289f, 0.084961f, 0.008789f, 0.906250f, 0.878906f, 0.058594f, 0.003906f, 0.937500f, 0.938477f, 0.030273f, 0.000977f, 0.968750f, 1.000000f, 0.000000f, 0.000000f, 1.000000f };
const float g_astc_weights_3levelsx[3 * 4] = {
0.000000f, 0.000000f, 1.000000f, 0.000000f,
.5f * .5f, (1.0f - .5f) * .5f, (1.0f - .5f) * (1.0f - .5f), .5f,
1.000000f, 0.000000f, 0.000000f, 1.000000f };
static endpoint_err g_bc7_mode_1_optimal_endpoints[256][2]; // [c][pbit]
static const uint32_t BC7ENC_MODE_1_OPTIMAL_INDEX = 2;
static endpoint_err g_astc_4bit_3bit_optimal_endpoints[256]; // [c]
static const uint32_t BC7ENC_ASTC_4BIT_3BIT_OPTIMAL_INDEX = 2;
static endpoint_err g_astc_4bit_2bit_optimal_endpoints[256]; // [c]
static const uint32_t BC7ENC_ASTC_4BIT_2BIT_OPTIMAL_INDEX = 1;
static endpoint_err g_astc_range7_2bit_optimal_endpoints[256]; // [c]
static const uint32_t BC7ENC_ASTC_RANGE7_2BIT_OPTIMAL_INDEX = 1;
static endpoint_err g_astc_range13_4bit_optimal_endpoints[256]; // [c]
static const uint32_t BC7ENC_ASTC_RANGE13_4BIT_OPTIMAL_INDEX = 2;
static endpoint_err g_astc_range13_2bit_optimal_endpoints[256]; // [c]
static const uint32_t BC7ENC_ASTC_RANGE13_2BIT_OPTIMAL_INDEX = 1;
static endpoint_err g_astc_range11_5bit_optimal_endpoints[256]; // [c]
static const uint32_t BC7ENC_ASTC_RANGE11_5BIT_OPTIMAL_INDEX = 13; // not 1, which is optimal, because 26 losslessly maps to BC7 4-bit weights
astc_quant_bin g_astc_sorted_order_unquant[BC7ENC_TOTAL_ASTC_RANGES][256]; // [sorted unquantized order]
static uint8_t g_astc_nearest_sorted_index[BC7ENC_TOTAL_ASTC_RANGES][256];
static void astc_init()
{
for (uint32_t range = 0; range < BC7ENC_TOTAL_ASTC_RANGES; range++)
{
if (!astc_is_valid_endpoint_range(range))
continue;
const uint32_t levels = astc_get_levels(range);
uint32_t vals[256];
// TODO
for (uint32_t i = 0; i < levels; i++)
vals[i] = (unquant_astc_endpoint_val(i, range) << 8) | i;
std::sort(vals, vals + levels);
for (uint32_t i = 0; i < levels; i++)
{
uint32_t order = vals[i] & 0xFF;
uint32_t unq = vals[i] >> 8;
g_astc_sorted_order_unquant[range][i].m_unquant = (uint8_t)unq;
g_astc_sorted_order_unquant[range][i].m_index = (uint8_t)order;
} // i
#if 0
if (g_astc_bise_range_table[range][1] || g_astc_bise_range_table[range][2])
{
printf("// Range: %u, Levels: %u, Bits: %u, Trits: %u, Quints: %u\n", range, levels, g_astc_bise_range_table[range][0], g_astc_bise_range_table[range][1], g_astc_bise_range_table[range][2]);
printf("{");
for (uint32_t i = 0; i < levels; i++)
{
printf("{%u,%u}", g_astc_sorted_order_unquant[range][i].m_index, g_astc_sorted_order_unquant[range][i].m_unquant);
if (i != (levels - 1))
printf(",");
}
printf("}\n");
}
#endif
#if 0
if (g_astc_bise_range_table[range][1] || g_astc_bise_range_table[range][2])
{
printf("// Range: %u, Levels: %u, Bits: %u, Trits: %u, Quints: %u\n", range, levels, g_astc_bise_range_table[range][0], g_astc_bise_range_table[range][1], g_astc_bise_range_table[range][2]);
printf("{");
for (uint32_t i = 0; i < levels; i++)
{
printf("{%u,%u}", g_astc_unquant[range][i].m_index, g_astc_unquant[range][i].m_unquant);
if (i != (levels - 1))
printf(",");
}
printf("}\n");
}
#endif
for (uint32_t i = 0; i < 256; i++)
{
uint32_t best_index = 0;
int best_err = INT32_MAX;
for (uint32_t j = 0; j < levels; j++)
{
int err = g_astc_sorted_order_unquant[range][j].m_unquant - i;
if (err < 0)
err = -err;
if (err < best_err)
{
best_err = err;
best_index = j;
}
}
g_astc_nearest_sorted_index[range][i] = (uint8_t)best_index;
} // i
} // range
}
static inline uint32_t astc_interpolate(uint32_t l, uint32_t h, uint32_t w)
{
// This is for linear values, not sRGB.
l = (l << 8) | l;
h = (h << 8) | h;
uint32_t k = (l * (64 - w) + h * w + 32) >> 6;
return k >> 8;
}
// Initialize the lookup table used for optimal single color compression in mode 1. Must be called before encoding.
void bc7enc_compress_block_init()
{
astc_init();
// BC7 666.1
for (int c = 0; c < 256; c++)
{
for (uint32_t lp = 0; lp < 2; lp++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 64; l++)
{
uint32_t low = ((l << 1) | lp) << 1;
low |= (low >> 7);
for (uint32_t h = 0; h < 64; h++)
{
uint32_t high = ((h << 1) | lp) << 1;
high |= (high >> 7);
const int k = (low * (64 - g_bc7_weights3[BC7ENC_MODE_1_OPTIMAL_INDEX]) + high * g_bc7_weights3[BC7ENC_MODE_1_OPTIMAL_INDEX] + 32) >> 6;
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_bc7_mode_1_optimal_endpoints[c][lp] = best;
} // lp
} // c
// ASTC [0,15] 3-bit
for (int c = 0; c < 256; c++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 16; l++)
{
uint32_t low = (l << 4) | l;
for (uint32_t h = 0; h < 16; h++)
{
uint32_t high = (h << 4) | h;
const int k = astc_interpolate(low, high, g_bc7_weights3[BC7ENC_ASTC_4BIT_3BIT_OPTIMAL_INDEX]);
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_astc_4bit_3bit_optimal_endpoints[c] = best;
} // c
// ASTC [0,15] 2-bit
for (int c = 0; c < 256; c++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 16; l++)
{
uint32_t low = (l << 4) | l;
for (uint32_t h = 0; h < 16; h++)
{
uint32_t high = (h << 4) | h;
const int k = astc_interpolate(low, high, g_bc7_weights2[BC7ENC_ASTC_4BIT_2BIT_OPTIMAL_INDEX]);
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_astc_4bit_2bit_optimal_endpoints[c] = best;
} // c
// ASTC range 7 [0,11] 2-bit
for (int c = 0; c < 256; c++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 12; l++)
{
uint32_t low = g_astc_sorted_order_unquant[7][l].m_unquant;
for (uint32_t h = 0; h < 12; h++)
{
uint32_t high = g_astc_sorted_order_unquant[7][h].m_unquant;
const int k = astc_interpolate(low, high, g_bc7_weights2[BC7ENC_ASTC_RANGE7_2BIT_OPTIMAL_INDEX]);
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_astc_range7_2bit_optimal_endpoints[c] = best;
} // c
// ASTC range 13 [0,47] 4-bit
for (int c = 0; c < 256; c++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 48; l++)
{
uint32_t low = g_astc_sorted_order_unquant[13][l].m_unquant;
for (uint32_t h = 0; h < 48; h++)
{
uint32_t high = g_astc_sorted_order_unquant[13][h].m_unquant;
const int k = astc_interpolate(low, high, g_astc_weights4[BC7ENC_ASTC_RANGE13_4BIT_OPTIMAL_INDEX]);
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_astc_range13_4bit_optimal_endpoints[c] = best;
} // c
// ASTC range 13 [0,47] 2-bit
for (int c = 0; c < 256; c++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 48; l++)
{
uint32_t low = g_astc_sorted_order_unquant[13][l].m_unquant;
for (uint32_t h = 0; h < 48; h++)
{
uint32_t high = g_astc_sorted_order_unquant[13][h].m_unquant;
const int k = astc_interpolate(low, high, g_bc7_weights2[BC7ENC_ASTC_RANGE13_2BIT_OPTIMAL_INDEX]);
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_astc_range13_2bit_optimal_endpoints[c] = best;
} // c
// ASTC range 11 [0,31] 5-bit
for (int c = 0; c < 256; c++)
{
endpoint_err best;
best.m_error = (uint16_t)UINT16_MAX;
for (uint32_t l = 0; l < 32; l++)
{
uint32_t low = g_astc_sorted_order_unquant[11][l].m_unquant;
for (uint32_t h = 0; h < 32; h++)
{
uint32_t high = g_astc_sorted_order_unquant[11][h].m_unquant;
const int k = astc_interpolate(low, high, g_astc_weights5[BC7ENC_ASTC_RANGE11_5BIT_OPTIMAL_INDEX]);
const int err = (k - c) * (k - c);
if (err < best.m_error)
{
best.m_error = (uint16_t)err;
best.m_lo = (uint8_t)l;
best.m_hi = (uint8_t)h;
}
} // h
} // l
g_astc_range11_5bit_optimal_endpoints[c] = best;
} // c
}
static void compute_least_squares_endpoints_rgba(uint32_t N, const uint8_t *pSelectors, const bc7enc_vec4F* pSelector_weights, bc7enc_vec4F* pXl, bc7enc_vec4F* pXh, const color_quad_u8 *pColors)
{
// Least squares using normal equations: http://www.cs.cornell.edu/~bindel/class/cs3220-s12/notes/lec10.pdf
// I did this in matrix form first, expanded out all the ops, then optimized it a bit.
double z00 = 0.0f, z01 = 0.0f, z10 = 0.0f, z11 = 0.0f;
double q00_r = 0.0f, q10_r = 0.0f, t_r = 0.0f;
double q00_g = 0.0f, q10_g = 0.0f, t_g = 0.0f;
double q00_b = 0.0f, q10_b = 0.0f, t_b = 0.0f;
double q00_a = 0.0f, q10_a = 0.0f, t_a = 0.0f;
for (uint32_t i = 0; i < N; i++)
{
const uint32_t sel = pSelectors[i];
z00 += pSelector_weights[sel].m_c[0];
z10 += pSelector_weights[sel].m_c[1];
z11 += pSelector_weights[sel].m_c[2];
float w = pSelector_weights[sel].m_c[3];
q00_r += w * pColors[i].m_c[0]; t_r += pColors[i].m_c[0];
q00_g += w * pColors[i].m_c[1]; t_g += pColors[i].m_c[1];
q00_b += w * pColors[i].m_c[2]; t_b += pColors[i].m_c[2];
q00_a += w * pColors[i].m_c[3]; t_a += pColors[i].m_c[3];
}
q10_r = t_r - q00_r;
q10_g = t_g - q00_g;
q10_b = t_b - q00_b;
q10_a = t_a - q00_a;
z01 = z10;
double det = z00 * z11 - z01 * z10;
if (det != 0.0f)
det = 1.0f / det;
double iz00, iz01, iz10, iz11;
iz00 = z11 * det;
iz01 = -z01 * det;
iz10 = -z10 * det;
iz11 = z00 * det;
pXl->m_c[0] = (float)(iz00 * q00_r + iz01 * q10_r); pXh->m_c[0] = (float)(iz10 * q00_r + iz11 * q10_r);
pXl->m_c[1] = (float)(iz00 * q00_g + iz01 * q10_g); pXh->m_c[1] = (float)(iz10 * q00_g + iz11 * q10_g);
pXl->m_c[2] = (float)(iz00 * q00_b + iz01 * q10_b); pXh->m_c[2] = (float)(iz10 * q00_b + iz11 * q10_b);
pXl->m_c[3] = (float)(iz00 * q00_a + iz01 * q10_a); pXh->m_c[3] = (float)(iz10 * q00_a + iz11 * q10_a);
for (uint32_t c = 0; c < 4; c++)
{
if ((pXl->m_c[c] < 0.0f) || (pXh->m_c[c] > 255.0f))
{
uint32_t lo_v = UINT32_MAX, hi_v = 0;
for (uint32_t i = 0; i < N; i++)
{
lo_v = minimumu(lo_v, pColors[i].m_c[c]);
hi_v = maximumu(hi_v, pColors[i].m_c[c]);
}
if (lo_v == hi_v)
{
pXl->m_c[c] = (float)lo_v;
pXh->m_c[c] = (float)hi_v;
}
}
}
}
static void compute_least_squares_endpoints_rgb(uint32_t N, const uint8_t *pSelectors, const bc7enc_vec4F*pSelector_weights, bc7enc_vec4F*pXl, bc7enc_vec4F*pXh, const color_quad_u8 *pColors)
{
double z00 = 0.0f, z01 = 0.0f, z10 = 0.0f, z11 = 0.0f;
double q00_r = 0.0f, q10_r = 0.0f, t_r = 0.0f;
double q00_g = 0.0f, q10_g = 0.0f, t_g = 0.0f;
double q00_b = 0.0f, q10_b = 0.0f, t_b = 0.0f;
for (uint32_t i = 0; i < N; i++)
{
const uint32_t sel = pSelectors[i];
z00 += pSelector_weights[sel].m_c[0];
z10 += pSelector_weights[sel].m_c[1];
z11 += pSelector_weights[sel].m_c[2];
float w = pSelector_weights[sel].m_c[3];
q00_r += w * pColors[i].m_c[0]; t_r += pColors[i].m_c[0];
q00_g += w * pColors[i].m_c[1]; t_g += pColors[i].m_c[1];
q00_b += w * pColors[i].m_c[2]; t_b += pColors[i].m_c[2];
}
q10_r = t_r - q00_r;
q10_g = t_g - q00_g;
q10_b = t_b - q00_b;
z01 = z10;
double det = z00 * z11 - z01 * z10;
if (det != 0.0f)
det = 1.0f / det;
double iz00, iz01, iz10, iz11;
iz00 = z11 * det;
iz01 = -z01 * det;
iz10 = -z10 * det;
iz11 = z00 * det;
pXl->m_c[0] = (float)(iz00 * q00_r + iz01 * q10_r); pXh->m_c[0] = (float)(iz10 * q00_r + iz11 * q10_r);
pXl->m_c[1] = (float)(iz00 * q00_g + iz01 * q10_g); pXh->m_c[1] = (float)(iz10 * q00_g + iz11 * q10_g);
pXl->m_c[2] = (float)(iz00 * q00_b + iz01 * q10_b); pXh->m_c[2] = (float)(iz10 * q00_b + iz11 * q10_b);
pXl->m_c[3] = 255.0f; pXh->m_c[3] = 255.0f;
for (uint32_t c = 0; c < 3; c++)
{
if ((pXl->m_c[c] < 0.0f) || (pXh->m_c[c] > 255.0f))
{
uint32_t lo_v = UINT32_MAX, hi_v = 0;
for (uint32_t i = 0; i < N; i++)
{
lo_v = minimumu(lo_v, pColors[i].m_c[c]);
hi_v = maximumu(hi_v, pColors[i].m_c[c]);
}
if (lo_v == hi_v)
{
pXl->m_c[c] = (float)lo_v;
pXh->m_c[c] = (float)hi_v;
}
}
}
}
static inline color_quad_u8 scale_color(const color_quad_u8* pC, const color_cell_compressor_params* pParams)
{
color_quad_u8 results;
if (pParams->m_astc_endpoint_range)
{
for (uint32_t i = 0; i < 4; i++)
{
results.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pC->m_c[i]].m_unquant;
}
}
else
{
const uint32_t n = pParams->m_comp_bits + (pParams->m_has_pbits ? 1 : 0);
assert((n >= 4) && (n <= 8));
for (uint32_t i = 0; i < 4; i++)
{
uint32_t v = pC->m_c[i] << (8 - n);
v |= (v >> n);
assert(v <= 255);
results.m_c[i] = (uint8_t)(v);
}
}
return results;
}
static inline uint64_t compute_color_distance_rgb(const color_quad_u8 *pE1, const color_quad_u8 *pE2, bc7enc_bool perceptual, const uint32_t weights[4])
{
int dr, dg, db;
if (perceptual)
{
const int l1 = pE1->m_c[0] * 109 + pE1->m_c[1] * 366 + pE1->m_c[2] * 37;
const int cr1 = ((int)pE1->m_c[0] << 9) - l1;
const int cb1 = ((int)pE1->m_c[2] << 9) - l1;
const int l2 = pE2->m_c[0] * 109 + pE2->m_c[1] * 366 + pE2->m_c[2] * 37;
const int cr2 = ((int)pE2->m_c[0] << 9) - l2;
const int cb2 = ((int)pE2->m_c[2] << 9) - l2;
dr = (l1 - l2) >> 8;
dg = (cr1 - cr2) >> 8;
db = (cb1 - cb2) >> 8;
}
else
{
dr = (int)pE1->m_c[0] - (int)pE2->m_c[0];
dg = (int)pE1->m_c[1] - (int)pE2->m_c[1];
db = (int)pE1->m_c[2] - (int)pE2->m_c[2];
}
return weights[0] * (uint32_t)(dr * dr) + weights[1] * (uint32_t)(dg * dg) + weights[2] * (uint32_t)(db * db);
}
static inline uint64_t compute_color_distance_rgba(const color_quad_u8 *pE1, const color_quad_u8 *pE2, bc7enc_bool perceptual, const uint32_t weights[4])
{
int da = (int)pE1->m_c[3] - (int)pE2->m_c[3];
return compute_color_distance_rgb(pE1, pE2, perceptual, weights) + (weights[3] * (uint32_t)(da * da));
}
static uint64_t pack_mode1_to_one_color(const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults, uint32_t r, uint32_t g, uint32_t b, uint8_t *pSelectors)
{
uint32_t best_err = UINT_MAX;
uint32_t best_p = 0;
for (uint32_t p = 0; p < 2; p++)
{
uint32_t err = g_bc7_mode_1_optimal_endpoints[r][p].m_error + g_bc7_mode_1_optimal_endpoints[g][p].m_error + g_bc7_mode_1_optimal_endpoints[b][p].m_error;
if (err < best_err)
{
best_err = err;
best_p = p;
}
}
const endpoint_err *pEr = &g_bc7_mode_1_optimal_endpoints[r][best_p];
const endpoint_err *pEg = &g_bc7_mode_1_optimal_endpoints[g][best_p];
const endpoint_err *pEb = &g_bc7_mode_1_optimal_endpoints[b][best_p];
color_quad_u8_set(&pResults->m_low_endpoint, pEr->m_lo, pEg->m_lo, pEb->m_lo, 0);
color_quad_u8_set(&pResults->m_high_endpoint, pEr->m_hi, pEg->m_hi, pEb->m_hi, 0);
pResults->m_pbits[0] = best_p;
pResults->m_pbits[1] = 0;
memset(pSelectors, BC7ENC_MODE_1_OPTIMAL_INDEX, pParams->m_num_pixels);
color_quad_u8 p;
for (uint32_t i = 0; i < 3; i++)
{
uint32_t low = ((pResults->m_low_endpoint.m_c[i] << 1) | pResults->m_pbits[0]) << 1;
low |= (low >> 7);
uint32_t high = ((pResults->m_high_endpoint.m_c[i] << 1) | pResults->m_pbits[0]) << 1;
high |= (high >> 7);
p.m_c[i] = (uint8_t)((low * (64 - g_bc7_weights3[BC7ENC_MODE_1_OPTIMAL_INDEX]) + high * g_bc7_weights3[BC7ENC_MODE_1_OPTIMAL_INDEX] + 32) >> 6);
}
p.m_c[3] = 255;
uint64_t total_err = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
total_err += compute_color_distance_rgb(&p, &pParams->m_pPixels[i], pParams->m_perceptual, pParams->m_weights);
pResults->m_best_overall_err = total_err;
return total_err;
}
static uint64_t pack_astc_4bit_3bit_to_one_color(const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults, uint32_t r, uint32_t g, uint32_t b, uint8_t *pSelectors)
{
const endpoint_err *pEr = &g_astc_4bit_3bit_optimal_endpoints[r];
const endpoint_err *pEg = &g_astc_4bit_3bit_optimal_endpoints[g];
const endpoint_err *pEb = &g_astc_4bit_3bit_optimal_endpoints[b];
color_quad_u8_set(&pResults->m_low_endpoint, pEr->m_lo, pEg->m_lo, pEb->m_lo, 0);
color_quad_u8_set(&pResults->m_high_endpoint, pEr->m_hi, pEg->m_hi, pEb->m_hi, 0);
pResults->m_pbits[0] = 0;
pResults->m_pbits[1] = 0;
for (uint32_t i = 0; i < 4; i++)
{
pResults->m_astc_low_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[i]].m_index;
pResults->m_astc_high_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[i]].m_index;
}
memset(pSelectors, BC7ENC_ASTC_4BIT_3BIT_OPTIMAL_INDEX, pParams->m_num_pixels);
color_quad_u8 p;
for (uint32_t i = 0; i < 3; i++)
{
uint32_t low = (pResults->m_low_endpoint.m_c[i] << 4) | pResults->m_low_endpoint.m_c[i];
uint32_t high = (pResults->m_high_endpoint.m_c[i] << 4) | pResults->m_high_endpoint.m_c[i];
p.m_c[i] = (uint8_t)astc_interpolate(low, high, g_bc7_weights3[BC7ENC_ASTC_4BIT_3BIT_OPTIMAL_INDEX]);
}
p.m_c[3] = 255;
uint64_t total_err = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
total_err += compute_color_distance_rgb(&p, &pParams->m_pPixels[i], pParams->m_perceptual, pParams->m_weights);
pResults->m_best_overall_err = total_err;
return total_err;
}
static uint64_t pack_astc_4bit_2bit_to_one_color_rgba(const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults, uint32_t r, uint32_t g, uint32_t b, uint32_t a, uint8_t *pSelectors)
{
const endpoint_err *pEr = &g_astc_4bit_2bit_optimal_endpoints[r];
const endpoint_err *pEg = &g_astc_4bit_2bit_optimal_endpoints[g];
const endpoint_err *pEb = &g_astc_4bit_2bit_optimal_endpoints[b];
const endpoint_err *pEa = &g_astc_4bit_2bit_optimal_endpoints[a];
color_quad_u8_set(&pResults->m_low_endpoint, pEr->m_lo, pEg->m_lo, pEb->m_lo, pEa->m_lo);
color_quad_u8_set(&pResults->m_high_endpoint, pEr->m_hi, pEg->m_hi, pEb->m_hi, pEa->m_hi);
pResults->m_pbits[0] = 0;
pResults->m_pbits[1] = 0;
for (uint32_t i = 0; i < 4; i++)
{
pResults->m_astc_low_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[i]].m_index;
pResults->m_astc_high_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[i]].m_index;
}
memset(pSelectors, BC7ENC_ASTC_4BIT_2BIT_OPTIMAL_INDEX, pParams->m_num_pixels);
color_quad_u8 p;
for (uint32_t i = 0; i < 4; i++)
{
uint32_t low = (pResults->m_low_endpoint.m_c[i] << 4) | pResults->m_low_endpoint.m_c[i];
uint32_t high = (pResults->m_high_endpoint.m_c[i] << 4) | pResults->m_high_endpoint.m_c[i];
p.m_c[i] = (uint8_t)astc_interpolate(low, high, g_bc7_weights2[BC7ENC_ASTC_4BIT_2BIT_OPTIMAL_INDEX]);
}
uint64_t total_err = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
total_err += compute_color_distance_rgba(&p, &pParams->m_pPixels[i], pParams->m_perceptual, pParams->m_weights);
pResults->m_best_overall_err = total_err;
return total_err;
}
static uint64_t pack_astc_range7_2bit_to_one_color(const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults, uint32_t r, uint32_t g, uint32_t b, uint8_t *pSelectors)
{
assert(pParams->m_astc_endpoint_range == 7 && pParams->m_num_selector_weights == 4);
const endpoint_err *pEr = &g_astc_range7_2bit_optimal_endpoints[r];
const endpoint_err *pEg = &g_astc_range7_2bit_optimal_endpoints[g];
const endpoint_err *pEb = &g_astc_range7_2bit_optimal_endpoints[b];
color_quad_u8_set(&pResults->m_low_endpoint, pEr->m_lo, pEg->m_lo, pEb->m_lo, 0);
color_quad_u8_set(&pResults->m_high_endpoint, pEr->m_hi, pEg->m_hi, pEb->m_hi, 0);
pResults->m_pbits[0] = 0;
pResults->m_pbits[1] = 0;
for (uint32_t i = 0; i < 4; i++)
{
pResults->m_astc_low_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[i]].m_index;
pResults->m_astc_high_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[i]].m_index;
}
memset(pSelectors, BC7ENC_ASTC_RANGE7_2BIT_OPTIMAL_INDEX, pParams->m_num_pixels);
color_quad_u8 p;
for (uint32_t i = 0; i < 3; i++)
{
uint32_t low = g_astc_sorted_order_unquant[7][pResults->m_low_endpoint.m_c[i]].m_unquant;
uint32_t high = g_astc_sorted_order_unquant[7][pResults->m_high_endpoint.m_c[i]].m_unquant;
p.m_c[i] = (uint8_t)astc_interpolate(low, high, g_bc7_weights2[BC7ENC_ASTC_RANGE7_2BIT_OPTIMAL_INDEX]);
}
p.m_c[3] = 255;
uint64_t total_err = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
total_err += compute_color_distance_rgb(&p, &pParams->m_pPixels[i], pParams->m_perceptual, pParams->m_weights);
pResults->m_best_overall_err = total_err;
return total_err;
}
static uint64_t pack_astc_range13_2bit_to_one_color(const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults, uint32_t r, uint32_t g, uint32_t b, uint8_t *pSelectors)
{
assert(pParams->m_astc_endpoint_range == 13 && pParams->m_num_selector_weights == 4 && !pParams->m_has_alpha);
const endpoint_err *pEr = &g_astc_range13_2bit_optimal_endpoints[r];
const endpoint_err *pEg = &g_astc_range13_2bit_optimal_endpoints[g];
const endpoint_err *pEb = &g_astc_range13_2bit_optimal_endpoints[b];
color_quad_u8_set(&pResults->m_low_endpoint, pEr->m_lo, pEg->m_lo, pEb->m_lo, 47);
color_quad_u8_set(&pResults->m_high_endpoint, pEr->m_hi, pEg->m_hi, pEb->m_hi, 47);
pResults->m_pbits[0] = 0;
pResults->m_pbits[1] = 0;
for (uint32_t i = 0; i < 4; i++)
{
pResults->m_astc_low_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[i]].m_index;
pResults->m_astc_high_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[i]].m_index;
}
memset(pSelectors, BC7ENC_ASTC_RANGE13_2BIT_OPTIMAL_INDEX, pParams->m_num_pixels);
color_quad_u8 p;
for (uint32_t i = 0; i < 4; i++)
{
uint32_t low = g_astc_sorted_order_unquant[13][pResults->m_low_endpoint.m_c[i]].m_unquant;
uint32_t high = g_astc_sorted_order_unquant[13][pResults->m_high_endpoint.m_c[i]].m_unquant;
p.m_c[i] = (uint8_t)astc_interpolate(low, high, g_bc7_weights2[BC7ENC_ASTC_RANGE13_2BIT_OPTIMAL_INDEX]);
}
uint64_t total_err = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
total_err += compute_color_distance_rgb(&p, &pParams->m_pPixels[i], pParams->m_perceptual, pParams->m_weights);
pResults->m_best_overall_err = total_err;
return total_err;
}
static uint64_t pack_astc_range11_5bit_to_one_color(const color_cell_compressor_params* pParams, color_cell_compressor_results* pResults, uint32_t r, uint32_t g, uint32_t b, uint8_t* pSelectors)
{
assert(pParams->m_astc_endpoint_range == 11 && pParams->m_num_selector_weights == 32 && !pParams->m_has_alpha);
const endpoint_err* pEr = &g_astc_range11_5bit_optimal_endpoints[r];
const endpoint_err* pEg = &g_astc_range11_5bit_optimal_endpoints[g];
const endpoint_err* pEb = &g_astc_range11_5bit_optimal_endpoints[b];
color_quad_u8_set(&pResults->m_low_endpoint, pEr->m_lo, pEg->m_lo, pEb->m_lo, 31);
color_quad_u8_set(&pResults->m_high_endpoint, pEr->m_hi, pEg->m_hi, pEb->m_hi, 31);
pResults->m_pbits[0] = 0;
pResults->m_pbits[1] = 0;
for (uint32_t i = 0; i < 4; i++)
{
pResults->m_astc_low_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[i]].m_index;
pResults->m_astc_high_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[i]].m_index;
}
memset(pSelectors, BC7ENC_ASTC_RANGE11_5BIT_OPTIMAL_INDEX, pParams->m_num_pixels);
color_quad_u8 p;
for (uint32_t i = 0; i < 4; i++)
{
uint32_t low = g_astc_sorted_order_unquant[11][pResults->m_low_endpoint.m_c[i]].m_unquant;
uint32_t high = g_astc_sorted_order_unquant[11][pResults->m_high_endpoint.m_c[i]].m_unquant;
p.m_c[i] = (uint8_t)astc_interpolate(low, high, g_astc_weights5[BC7ENC_ASTC_RANGE11_5BIT_OPTIMAL_INDEX]);
}
uint64_t total_err = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
total_err += compute_color_distance_rgb(&p, &pParams->m_pPixels[i], pParams->m_perceptual, pParams->m_weights);
pResults->m_best_overall_err = total_err;
return total_err;
}
static uint64_t evaluate_solution(const color_quad_u8 *pLow, const color_quad_u8 *pHigh, const uint32_t pbits[2], const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults)
{
color_quad_u8 quantMinColor = *pLow;
color_quad_u8 quantMaxColor = *pHigh;
if (pParams->m_has_pbits)
{
uint32_t minPBit, maxPBit;
if (pParams->m_endpoints_share_pbit)
maxPBit = minPBit = pbits[0];
else
{
minPBit = pbits[0];
maxPBit = pbits[1];
}
quantMinColor.m_c[0] = (uint8_t)((pLow->m_c[0] << 1) | minPBit);
quantMinColor.m_c[1] = (uint8_t)((pLow->m_c[1] << 1) | minPBit);
quantMinColor.m_c[2] = (uint8_t)((pLow->m_c[2] << 1) | minPBit);
quantMinColor.m_c[3] = (uint8_t)((pLow->m_c[3] << 1) | minPBit);
quantMaxColor.m_c[0] = (uint8_t)((pHigh->m_c[0] << 1) | maxPBit);
quantMaxColor.m_c[1] = (uint8_t)((pHigh->m_c[1] << 1) | maxPBit);
quantMaxColor.m_c[2] = (uint8_t)((pHigh->m_c[2] << 1) | maxPBit);
quantMaxColor.m_c[3] = (uint8_t)((pHigh->m_c[3] << 1) | maxPBit);
}
color_quad_u8 actualMinColor = scale_color(&quantMinColor, pParams);
color_quad_u8 actualMaxColor = scale_color(&quantMaxColor, pParams);
const uint32_t N = pParams->m_num_selector_weights;
assert(N >= 1 && N <= 32);
color_quad_u8 weightedColors[32];
weightedColors[0] = actualMinColor;
weightedColors[N - 1] = actualMaxColor;
const uint32_t nc = pParams->m_has_alpha ? 4 : 3;
if (pParams->m_astc_endpoint_range)
{
for (uint32_t i = 1; i < (N - 1); i++)
{
for (uint32_t j = 0; j < nc; j++)
weightedColors[i].m_c[j] = (uint8_t)(astc_interpolate(actualMinColor.m_c[j], actualMaxColor.m_c[j], pParams->m_pSelector_weights[i]));
}
}
else
{
for (uint32_t i = 1; i < (N - 1); i++)
for (uint32_t j = 0; j < nc; j++)
weightedColors[i].m_c[j] = (uint8_t)((actualMinColor.m_c[j] * (64 - pParams->m_pSelector_weights[i]) + actualMaxColor.m_c[j] * pParams->m_pSelector_weights[i] + 32) >> 6);
}
const int lr = actualMinColor.m_c[0];
const int lg = actualMinColor.m_c[1];
const int lb = actualMinColor.m_c[2];
const int dr = actualMaxColor.m_c[0] - lr;
const int dg = actualMaxColor.m_c[1] - lg;
const int db = actualMaxColor.m_c[2] - lb;
uint64_t total_err = 0;
if (pParams->m_pForce_selectors)
{
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
const color_quad_u8* pC = &pParams->m_pPixels[i];
const uint8_t sel = pParams->m_pForce_selectors[i];
assert(sel < N);
total_err += (pParams->m_has_alpha ? compute_color_distance_rgba : compute_color_distance_rgb)(&weightedColors[sel], pC, pParams->m_perceptual, pParams->m_weights);
pResults->m_pSelectors_temp[i] = sel;
}
}
else if (!pParams->m_perceptual)
{
if (pParams->m_has_alpha)
{
const int la = actualMinColor.m_c[3];
const int da = actualMaxColor.m_c[3] - la;
const float f = N / (float)(squarei(dr) + squarei(dg) + squarei(db) + squarei(da) + .00000125f);
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
const color_quad_u8 *pC = &pParams->m_pPixels[i];
int r = pC->m_c[0];
int g = pC->m_c[1];
int b = pC->m_c[2];
int a = pC->m_c[3];
int best_sel = (int)((float)((r - lr) * dr + (g - lg) * dg + (b - lb) * db + (a - la) * da) * f + .5f);
best_sel = clampi(best_sel, 1, N - 1);
uint64_t err0 = compute_color_distance_rgba(&weightedColors[best_sel - 1], pC, BC7ENC_FALSE, pParams->m_weights);
uint64_t err1 = compute_color_distance_rgba(&weightedColors[best_sel], pC, BC7ENC_FALSE, pParams->m_weights);
if (err0 == err1)
{
// Prefer non-interpolation
if ((best_sel - 1) == 0)
best_sel = 0;
}
else if (err1 > err0)
{
err1 = err0;
--best_sel;
}
total_err += err1;
pResults->m_pSelectors_temp[i] = (uint8_t)best_sel;
}
}
else
{
const float f = N / (float)(squarei(dr) + squarei(dg) + squarei(db) + .00000125f);
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
const color_quad_u8 *pC = &pParams->m_pPixels[i];
int r = pC->m_c[0];
int g = pC->m_c[1];
int b = pC->m_c[2];
int sel = (int)((float)((r - lr) * dr + (g - lg) * dg + (b - lb) * db) * f + .5f);
sel = clampi(sel, 1, N - 1);
uint64_t err0 = compute_color_distance_rgb(&weightedColors[sel - 1], pC, BC7ENC_FALSE, pParams->m_weights);
uint64_t err1 = compute_color_distance_rgb(&weightedColors[sel], pC, BC7ENC_FALSE, pParams->m_weights);
int best_sel = sel;
uint64_t best_err = err1;
if (err0 == err1)
{
// Prefer non-interpolation
if ((best_sel - 1) == 0)
best_sel = 0;
}
else if (err0 < best_err)
{
best_err = err0;
best_sel = sel - 1;
}
total_err += best_err;
pResults->m_pSelectors_temp[i] = (uint8_t)best_sel;
}
}
}
else
{
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
uint64_t best_err = UINT64_MAX;
uint32_t best_sel = 0;
if (pParams->m_has_alpha)
{
for (uint32_t j = 0; j < N; j++)
{
uint64_t err = compute_color_distance_rgba(&weightedColors[j], &pParams->m_pPixels[i], BC7ENC_TRUE, pParams->m_weights);
if (err < best_err)
{
best_err = err;
best_sel = j;
}
// Prefer non-interpolation
else if ((err == best_err) && (j == (N - 1)))
best_sel = j;
}
}
else
{
for (uint32_t j = 0; j < N; j++)
{
uint64_t err = compute_color_distance_rgb(&weightedColors[j], &pParams->m_pPixels[i], BC7ENC_TRUE, pParams->m_weights);
if (err < best_err)
{
best_err = err;
best_sel = j;
}
// Prefer non-interpolation
else if ((err == best_err) && (j == (N - 1)))
best_sel = j;
}
}
total_err += best_err;
pResults->m_pSelectors_temp[i] = (uint8_t)best_sel;
}
}
if (total_err < pResults->m_best_overall_err)
{
pResults->m_best_overall_err = total_err;
pResults->m_low_endpoint = *pLow;
pResults->m_high_endpoint = *pHigh;
pResults->m_pbits[0] = pbits[0];
pResults->m_pbits[1] = pbits[1];
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
}
return total_err;
}
static bool areDegenerateEndpoints(color_quad_u8* pTrialMinColor, color_quad_u8* pTrialMaxColor, const bc7enc_vec4F* pXl, const bc7enc_vec4F* pXh)
{
for (uint32_t i = 0; i < 3; i++)
{
if (pTrialMinColor->m_c[i] == pTrialMaxColor->m_c[i])
{
if (fabs(pXl->m_c[i] - pXh->m_c[i]) > 0.0f)
return true;
}
}
return false;
}
static void fixDegenerateEndpoints(uint32_t mode, color_quad_u8 *pTrialMinColor, color_quad_u8 *pTrialMaxColor, const bc7enc_vec4F*pXl, const bc7enc_vec4F*pXh, uint32_t iscale, int flags)
{
if (mode == 255)
{
for (uint32_t i = 0; i < 3; i++)
{
if (pTrialMinColor->m_c[i] == pTrialMaxColor->m_c[i])
{
if (fabs(pXl->m_c[i] - pXh->m_c[i]) > 0.000125f)
{
if (flags & 1)
{
if (pTrialMinColor->m_c[i] > 0)
pTrialMinColor->m_c[i]--;
}
if (flags & 2)
{
if (pTrialMaxColor->m_c[i] < iscale)
pTrialMaxColor->m_c[i]++;
}
}
}
}
}
else if (mode == 1)
{
// fix degenerate case where the input collapses to a single colorspace voxel, and we loose all freedom (test with grayscale ramps)
for (uint32_t i = 0; i < 3; i++)
{
if (pTrialMinColor->m_c[i] == pTrialMaxColor->m_c[i])
{
if (fabs(pXl->m_c[i] - pXh->m_c[i]) > 0.000125f)
{
if (pTrialMinColor->m_c[i] > (iscale >> 1))
{
if (pTrialMinColor->m_c[i] > 0)
pTrialMinColor->m_c[i]--;
else
if (pTrialMaxColor->m_c[i] < iscale)
pTrialMaxColor->m_c[i]++;
}
else
{
if (pTrialMaxColor->m_c[i] < iscale)
pTrialMaxColor->m_c[i]++;
else if (pTrialMinColor->m_c[i] > 0)
pTrialMinColor->m_c[i]--;
}
}
}
}
}
}
static uint64_t find_optimal_solution(uint32_t mode, bc7enc_vec4F xl, bc7enc_vec4F xh, const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults)
{
vec4F_saturate_in_place(&xl); vec4F_saturate_in_place(&xh);
if (pParams->m_astc_endpoint_range)
{
const uint32_t levels = astc_get_levels(pParams->m_astc_endpoint_range);
const float scale = 255.0f;
color_quad_u8 trialMinColor8Bit, trialMaxColor8Bit;
color_quad_u8_set_clamped(&trialMinColor8Bit, (int)(xl.m_c[0] * scale + .5f), (int)(xl.m_c[1] * scale + .5f), (int)(xl.m_c[2] * scale + .5f), (int)(xl.m_c[3] * scale + .5f));
color_quad_u8_set_clamped(&trialMaxColor8Bit, (int)(xh.m_c[0] * scale + .5f), (int)(xh.m_c[1] * scale + .5f), (int)(xh.m_c[2] * scale + .5f), (int)(xh.m_c[3] * scale + .5f));
color_quad_u8 trialMinColor, trialMaxColor;
for (uint32_t i = 0; i < 4; i++)
{
trialMinColor.m_c[i] = g_astc_nearest_sorted_index[pParams->m_astc_endpoint_range][trialMinColor8Bit.m_c[i]];
trialMaxColor.m_c[i] = g_astc_nearest_sorted_index[pParams->m_astc_endpoint_range][trialMaxColor8Bit.m_c[i]];
}
if (areDegenerateEndpoints(&trialMinColor, &trialMaxColor, &xl, &xh))
{
color_quad_u8 trialMinColorOrig(trialMinColor), trialMaxColorOrig(trialMaxColor);
fixDegenerateEndpoints(mode, &trialMinColor, &trialMaxColor, &xl, &xh, levels - 1, 1);
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&trialMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&trialMaxColor, &pResults->m_high_endpoint))
evaluate_solution(&trialMinColor, &trialMaxColor, pResults->m_pbits, pParams, pResults);
trialMinColor = trialMinColorOrig;
trialMaxColor = trialMaxColorOrig;
fixDegenerateEndpoints(mode, &trialMinColor, &trialMaxColor, &xl, &xh, levels - 1, 0);
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&trialMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&trialMaxColor, &pResults->m_high_endpoint))
evaluate_solution(&trialMinColor, &trialMaxColor, pResults->m_pbits, pParams, pResults);
trialMinColor = trialMinColorOrig;
trialMaxColor = trialMaxColorOrig;
fixDegenerateEndpoints(mode, &trialMinColor, &trialMaxColor, &xl, &xh, levels - 1, 2);
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&trialMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&trialMaxColor, &pResults->m_high_endpoint))
evaluate_solution(&trialMinColor, &trialMaxColor, pResults->m_pbits, pParams, pResults);
trialMinColor = trialMinColorOrig;
trialMaxColor = trialMaxColorOrig;
fixDegenerateEndpoints(mode, &trialMinColor, &trialMaxColor, &xl, &xh, levels - 1, 3);
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&trialMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&trialMaxColor, &pResults->m_high_endpoint))
evaluate_solution(&trialMinColor, &trialMaxColor, pResults->m_pbits, pParams, pResults);
}
else
{
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&trialMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&trialMaxColor, &pResults->m_high_endpoint))
{
evaluate_solution(&trialMinColor, &trialMaxColor, pResults->m_pbits, pParams, pResults);
}
}
for (uint32_t i = 0; i < 4; i++)
{
pResults->m_astc_low_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[i]].m_index;
pResults->m_astc_high_endpoint.m_c[i] = g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[i]].m_index;
}
}
else if (pParams->m_has_pbits)
{
const int iscalep = (1 << (pParams->m_comp_bits + 1)) - 1;
const float scalep = (float)iscalep;
const int32_t totalComps = pParams->m_has_alpha ? 4 : 3;
uint32_t best_pbits[2];
color_quad_u8 bestMinColor, bestMaxColor;
if (!pParams->m_endpoints_share_pbit)
{
float best_err0 = 1e+9;
float best_err1 = 1e+9;
for (int p = 0; p < 2; p++)
{
color_quad_u8 xMinColor, xMaxColor;
// Notes: The pbit controls which quantization intervals are selected.
// total_levels=2^(comp_bits+1), where comp_bits=4 for mode 0, etc.
// pbit 0: v=(b*2)/(total_levels-1), pbit 1: v=(b*2+1)/(total_levels-1) where b is the component bin from [0,total_levels/2-1] and v is the [0,1] component value
// rearranging you get for pbit 0: b=floor(v*(total_levels-1)/2+.5)
// rearranging you get for pbit 1: b=floor((v*(total_levels-1)-1)/2+.5)
for (uint32_t c = 0; c < 4; c++)
{
xMinColor.m_c[c] = (uint8_t)(clampi(((int)((xl.m_c[c] * scalep - p) / 2.0f + .5f)) * 2 + p, p, iscalep - 1 + p));
xMaxColor.m_c[c] = (uint8_t)(clampi(((int)((xh.m_c[c] * scalep - p) / 2.0f + .5f)) * 2 + p, p, iscalep - 1 + p));
}
color_quad_u8 scaledLow = scale_color(&xMinColor, pParams);
color_quad_u8 scaledHigh = scale_color(&xMaxColor, pParams);
float err0 = 0, err1 = 0;
for (int i = 0; i < totalComps; i++)
{
err0 += squaref(scaledLow.m_c[i] - xl.m_c[i] * 255.0f);
err1 += squaref(scaledHigh.m_c[i] - xh.m_c[i] * 255.0f);
}
if (err0 < best_err0)
{
best_err0 = err0;
best_pbits[0] = p;
bestMinColor.m_c[0] = xMinColor.m_c[0] >> 1;
bestMinColor.m_c[1] = xMinColor.m_c[1] >> 1;
bestMinColor.m_c[2] = xMinColor.m_c[2] >> 1;
bestMinColor.m_c[3] = xMinColor.m_c[3] >> 1;
}
if (err1 < best_err1)
{
best_err1 = err1;
best_pbits[1] = p;
bestMaxColor.m_c[0] = xMaxColor.m_c[0] >> 1;
bestMaxColor.m_c[1] = xMaxColor.m_c[1] >> 1;
bestMaxColor.m_c[2] = xMaxColor.m_c[2] >> 1;
bestMaxColor.m_c[3] = xMaxColor.m_c[3] >> 1;
}
}
}
else
{
// Endpoints share pbits
float best_err = 1e+9;
for (int p = 0; p < 2; p++)
{
color_quad_u8 xMinColor, xMaxColor;
for (uint32_t c = 0; c < 4; c++)
{
xMinColor.m_c[c] = (uint8_t)(clampi(((int)((xl.m_c[c] * scalep - p) / 2.0f + .5f)) * 2 + p, p, iscalep - 1 + p));
xMaxColor.m_c[c] = (uint8_t)(clampi(((int)((xh.m_c[c] * scalep - p) / 2.0f + .5f)) * 2 + p, p, iscalep - 1 + p));
}
color_quad_u8 scaledLow = scale_color(&xMinColor, pParams);
color_quad_u8 scaledHigh = scale_color(&xMaxColor, pParams);
float err = 0;
for (int i = 0; i < totalComps; i++)
err += squaref((scaledLow.m_c[i] / 255.0f) - xl.m_c[i]) + squaref((scaledHigh.m_c[i] / 255.0f) - xh.m_c[i]);
if (err < best_err)
{
best_err = err;
best_pbits[0] = p;
best_pbits[1] = p;
for (uint32_t j = 0; j < 4; j++)
{
bestMinColor.m_c[j] = xMinColor.m_c[j] >> 1;
bestMaxColor.m_c[j] = xMaxColor.m_c[j] >> 1;
}
}
}
}
fixDegenerateEndpoints(mode, &bestMinColor, &bestMaxColor, &xl, &xh, iscalep >> 1, 0);
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&bestMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&bestMaxColor, &pResults->m_high_endpoint) || (best_pbits[0] != pResults->m_pbits[0]) || (best_pbits[1] != pResults->m_pbits[1]))
evaluate_solution(&bestMinColor, &bestMaxColor, best_pbits, pParams, pResults);
}
else
{
const int iscale = (1 << pParams->m_comp_bits) - 1;
const float scale = (float)iscale;
color_quad_u8 trialMinColor, trialMaxColor;
color_quad_u8_set_clamped(&trialMinColor, (int)(xl.m_c[0] * scale + .5f), (int)(xl.m_c[1] * scale + .5f), (int)(xl.m_c[2] * scale + .5f), (int)(xl.m_c[3] * scale + .5f));
color_quad_u8_set_clamped(&trialMaxColor, (int)(xh.m_c[0] * scale + .5f), (int)(xh.m_c[1] * scale + .5f), (int)(xh.m_c[2] * scale + .5f), (int)(xh.m_c[3] * scale + .5f));
fixDegenerateEndpoints(mode, &trialMinColor, &trialMaxColor, &xl, &xh, iscale, 0);
if ((pResults->m_best_overall_err == UINT64_MAX) || color_quad_u8_notequals(&trialMinColor, &pResults->m_low_endpoint) || color_quad_u8_notequals(&trialMaxColor, &pResults->m_high_endpoint))
evaluate_solution(&trialMinColor, &trialMaxColor, pResults->m_pbits, pParams, pResults);
}
return pResults->m_best_overall_err;
}
void check_best_overall_error(const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults)
{
const uint32_t n = pParams->m_num_selector_weights;
assert(n <= 32);
color_quad_u8 colors[32];
for (uint32_t c = 0; c < 4; c++)
{
colors[0].m_c[c] = g_astc_unquant[pParams->m_astc_endpoint_range][pResults->m_astc_low_endpoint.m_c[c]].m_unquant;
assert(colors[0].m_c[c] == g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_low_endpoint.m_c[c]].m_unquant);
colors[n-1].m_c[c] = g_astc_unquant[pParams->m_astc_endpoint_range][pResults->m_astc_high_endpoint.m_c[c]].m_unquant;
assert(colors[n-1].m_c[c] == g_astc_sorted_order_unquant[pParams->m_astc_endpoint_range][pResults->m_high_endpoint.m_c[c]].m_unquant);
}
for (uint32_t i = 1; i < pParams->m_num_selector_weights - 1; i++)
for (uint32_t c = 0; c < 4; c++)
colors[i].m_c[c] = (uint8_t)astc_interpolate(colors[0].m_c[c], colors[n - 1].m_c[c], pParams->m_pSelector_weights[i]);
uint64_t total_err = 0;
for (uint32_t p = 0; p < pParams->m_num_pixels; p++)
{
const color_quad_u8 &orig = pParams->m_pPixels[p];
const color_quad_u8 &packed = colors[pResults->m_pSelectors[p]];
if (pParams->m_has_alpha)
total_err += compute_color_distance_rgba(&orig, &packed, pParams->m_perceptual, pParams->m_weights);
else
total_err += compute_color_distance_rgb(&orig, &packed, pParams->m_perceptual, pParams->m_weights);
}
assert(total_err == pResults->m_best_overall_err);
// HACK HACK
//if (total_err != pResults->m_best_overall_err)
// printf("X");
}
static bool is_solid_rgb(const color_cell_compressor_params *pParams, uint32_t &r, uint32_t &g, uint32_t &b)
{
r = pParams->m_pPixels[0].m_c[0];
g = pParams->m_pPixels[0].m_c[1];
b = pParams->m_pPixels[0].m_c[2];
bool allSame = true;
for (uint32_t i = 1; i < pParams->m_num_pixels; i++)
{
if ((r != pParams->m_pPixels[i].m_c[0]) || (g != pParams->m_pPixels[i].m_c[1]) || (b != pParams->m_pPixels[i].m_c[2]))
{
allSame = false;
break;
}
}
return allSame;
}
static bool is_solid_rgba(const color_cell_compressor_params *pParams, uint32_t &r, uint32_t &g, uint32_t &b, uint32_t &a)
{
r = pParams->m_pPixels[0].m_c[0];
g = pParams->m_pPixels[0].m_c[1];
b = pParams->m_pPixels[0].m_c[2];
a = pParams->m_pPixels[0].m_c[3];
bool allSame = true;
for (uint32_t i = 1; i < pParams->m_num_pixels; i++)
{
if ((r != pParams->m_pPixels[i].m_c[0]) || (g != pParams->m_pPixels[i].m_c[1]) || (b != pParams->m_pPixels[i].m_c[2]) || (a != pParams->m_pPixels[i].m_c[3]))
{
allSame = false;
break;
}
}
return allSame;
}
uint64_t color_cell_compression(uint32_t mode, const color_cell_compressor_params *pParams, color_cell_compressor_results *pResults, const bc7enc_compress_block_params *pComp_params)
{
if (!pParams->m_astc_endpoint_range)
{
assert((mode == 6) || (!pParams->m_has_alpha));
}
assert(pParams->m_num_selector_weights >= 1 && pParams->m_num_selector_weights <= 32);
assert(pParams->m_pSelector_weights[0] == 0);
assert(pParams->m_pSelector_weights[pParams->m_num_selector_weights - 1] == 64);
pResults->m_best_overall_err = UINT64_MAX;
uint32_t cr, cg, cb, ca;
// If the partition's colors are all the same, then just pack them as a single color.
if (!pParams->m_pForce_selectors)
{
if (mode == 1)
{
if (is_solid_rgb(pParams, cr, cg, cb))
return pack_mode1_to_one_color(pParams, pResults, cr, cg, cb, pResults->m_pSelectors);
}
else if ((pParams->m_astc_endpoint_range == 8) && (pParams->m_num_selector_weights == 8) && (!pParams->m_has_alpha))
{
if (is_solid_rgb(pParams, cr, cg, cb))
return pack_astc_4bit_3bit_to_one_color(pParams, pResults, cr, cg, cb, pResults->m_pSelectors);
}
else if ((pParams->m_astc_endpoint_range == 7) && (pParams->m_num_selector_weights == 4) && (!pParams->m_has_alpha))
{
if (is_solid_rgb(pParams, cr, cg, cb))
return pack_astc_range7_2bit_to_one_color(pParams, pResults, cr, cg, cb, pResults->m_pSelectors);
}
else if ((pParams->m_astc_endpoint_range == 8) && (pParams->m_num_selector_weights == 4) && (pParams->m_has_alpha))
{
if (is_solid_rgba(pParams, cr, cg, cb, ca))
return pack_astc_4bit_2bit_to_one_color_rgba(pParams, pResults, cr, cg, cb, ca, pResults->m_pSelectors);
}
else if ((pParams->m_astc_endpoint_range == 13) && (pParams->m_num_selector_weights == 4) && (!pParams->m_has_alpha))
{
if (is_solid_rgb(pParams, cr, cg, cb))
return pack_astc_range13_2bit_to_one_color(pParams, pResults, cr, cg, cb, pResults->m_pSelectors);
}
else if ((pParams->m_astc_endpoint_range == 11) && (pParams->m_num_selector_weights == 32) && (!pParams->m_has_alpha))
{
if (is_solid_rgb(pParams, cr, cg, cb))
return pack_astc_range11_5bit_to_one_color(pParams, pResults, cr, cg, cb, pResults->m_pSelectors);
}
}
// Compute partition's mean color and principle axis.
bc7enc_vec4F meanColor, axis;
vec4F_set_scalar(&meanColor, 0.0f);
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
bc7enc_vec4F color = vec4F_from_color(&pParams->m_pPixels[i]);
meanColor = vec4F_add(&meanColor, &color);
}
bc7enc_vec4F meanColorScaled = vec4F_mul(&meanColor, 1.0f / (float)(pParams->m_num_pixels));
meanColor = vec4F_mul(&meanColor, 1.0f / (float)(pParams->m_num_pixels * 255.0f));
vec4F_saturate_in_place(&meanColor);
if (pParams->m_has_alpha)
{
// Use incremental PCA for RGBA PCA, because it's simple.
vec4F_set_scalar(&axis, 0.0f);
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
bc7enc_vec4F color = vec4F_from_color(&pParams->m_pPixels[i]);
color = vec4F_sub(&color, &meanColorScaled);
bc7enc_vec4F a = vec4F_mul(&color, color.m_c[0]);
bc7enc_vec4F b = vec4F_mul(&color, color.m_c[1]);
bc7enc_vec4F c = vec4F_mul(&color, color.m_c[2]);
bc7enc_vec4F d = vec4F_mul(&color, color.m_c[3]);
bc7enc_vec4F n = i ? axis : color;
vec4F_normalize_in_place(&n);
axis.m_c[0] += vec4F_dot(&a, &n);
axis.m_c[1] += vec4F_dot(&b, &n);
axis.m_c[2] += vec4F_dot(&c, &n);
axis.m_c[3] += vec4F_dot(&d, &n);
}
vec4F_normalize_in_place(&axis);
}
else
{
// Use covar technique for RGB PCA, because it doesn't require per-pixel normalization.
float cov[6] = { 0, 0, 0, 0, 0, 0 };
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
const color_quad_u8 *pV = &pParams->m_pPixels[i];
float r = pV->m_c[0] - meanColorScaled.m_c[0];
float g = pV->m_c[1] - meanColorScaled.m_c[1];
float b = pV->m_c[2] - meanColorScaled.m_c[2];
cov[0] += r*r; cov[1] += r*g; cov[2] += r*b; cov[3] += g*g; cov[4] += g*b; cov[5] += b*b;
}
float xr = .9f, xg = 1.0f, xb = .7f;
for (uint32_t iter = 0; iter < 3; iter++)
{
float r = xr * cov[0] + xg * cov[1] + xb * cov[2];
float g = xr * cov[1] + xg * cov[3] + xb * cov[4];
float b = xr * cov[2] + xg * cov[4] + xb * cov[5];
float m = maximumf(maximumf(fabsf(r), fabsf(g)), fabsf(b));
if (m > 1e-10f)
{
m = 1.0f / m;
r *= m; g *= m; b *= m;
}
xr = r; xg = g; xb = b;
}
float len = xr * xr + xg * xg + xb * xb;
if (len < 1e-10f)
vec4F_set_scalar(&axis, 0.0f);
else
{
len = 1.0f / sqrtf(len);
xr *= len; xg *= len; xb *= len;
vec4F_set(&axis, xr, xg, xb, 0);
}
}
if (vec4F_dot(&axis, &axis) < .5f)
{
if (pParams->m_perceptual)
vec4F_set(&axis, .213f, .715f, .072f, pParams->m_has_alpha ? .715f : 0);
else
vec4F_set(&axis, 1.0f, 1.0f, 1.0f, pParams->m_has_alpha ? 1.0f : 0);
vec4F_normalize_in_place(&axis);
}
bc7enc_vec4F minColor, maxColor;
float l = 1e+9f, h = -1e+9f;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
bc7enc_vec4F color = vec4F_from_color(&pParams->m_pPixels[i]);
bc7enc_vec4F q = vec4F_sub(&color, &meanColorScaled);
float d = vec4F_dot(&q, &axis);
l = minimumf(l, d);
h = maximumf(h, d);
}
l *= (1.0f / 255.0f);
h *= (1.0f / 255.0f);
bc7enc_vec4F b0 = vec4F_mul(&axis, l);
bc7enc_vec4F b1 = vec4F_mul(&axis, h);
bc7enc_vec4F c0 = vec4F_add(&meanColor, &b0);
bc7enc_vec4F c1 = vec4F_add(&meanColor, &b1);
minColor = vec4F_saturate(&c0);
maxColor = vec4F_saturate(&c1);
bc7enc_vec4F whiteVec;
vec4F_set_scalar(&whiteVec, 1.0f);
if (vec4F_dot(&minColor, &whiteVec) > vec4F_dot(&maxColor, &whiteVec))
{
#if 1
std::swap(minColor.m_c[0], maxColor.m_c[0]);
std::swap(minColor.m_c[1], maxColor.m_c[1]);
std::swap(minColor.m_c[2], maxColor.m_c[2]);
std::swap(minColor.m_c[3], maxColor.m_c[3]);
#elif 0
// Fails to compile correctly with MSVC 2019 (code generation bug)
std::swap(minColor, maxColor);
#else
// Fails with MSVC 2019
bc7enc_vec4F temp = minColor;
minColor = maxColor;
maxColor = temp;
#endif
}
// First find a solution using the block's PCA.
if (!find_optimal_solution(mode, minColor, maxColor, pParams, pResults))
return 0;
for (uint32_t i = 0; i < pComp_params->m_least_squares_passes; i++)
{
// Now try to refine the solution using least squares by computing the optimal endpoints from the current selectors.
bc7enc_vec4F xl, xh;
vec4F_set_scalar(&xl, 0.0f);
vec4F_set_scalar(&xh, 0.0f);
if (pParams->m_has_alpha)
compute_least_squares_endpoints_rgba(pParams->m_num_pixels, pResults->m_pSelectors, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
else
compute_least_squares_endpoints_rgb(pParams->m_num_pixels, pResults->m_pSelectors, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
xl = vec4F_mul(&xl, (1.0f / 255.0f));
xh = vec4F_mul(&xh, (1.0f / 255.0f));
if (!find_optimal_solution(mode, xl, xh, pParams, pResults))
return 0;
}
if ((!pParams->m_pForce_selectors) && (pComp_params->m_uber_level > 0))
{
// In uber level 1, try varying the selectors a little, somewhat like cluster fit would. First try incrementing the minimum selectors,
// then try decrementing the selectrors, then try both.
uint8_t selectors_temp[16], selectors_temp1[16];
memcpy(selectors_temp, pResults->m_pSelectors, pParams->m_num_pixels);
const int max_selector = pParams->m_num_selector_weights - 1;
uint32_t min_sel = 256;
uint32_t max_sel = 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
uint32_t sel = selectors_temp[i];
min_sel = minimumu(min_sel, sel);
max_sel = maximumu(max_sel, sel);
}
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
uint32_t sel = selectors_temp[i];
if ((sel == min_sel) && (sel < (pParams->m_num_selector_weights - 1)))
sel++;
selectors_temp1[i] = (uint8_t)sel;
}
bc7enc_vec4F xl, xh;
vec4F_set_scalar(&xl, 0.0f);
vec4F_set_scalar(&xh, 0.0f);
if (pParams->m_has_alpha)
compute_least_squares_endpoints_rgba(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
else
compute_least_squares_endpoints_rgb(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
xl = vec4F_mul(&xl, (1.0f / 255.0f));
xh = vec4F_mul(&xh, (1.0f / 255.0f));
if (!find_optimal_solution(mode, xl, xh, pParams, pResults))
return 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
uint32_t sel = selectors_temp[i];
if ((sel == max_sel) && (sel > 0))
sel--;
selectors_temp1[i] = (uint8_t)sel;
}
if (pParams->m_has_alpha)
compute_least_squares_endpoints_rgba(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
else
compute_least_squares_endpoints_rgb(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
xl = vec4F_mul(&xl, (1.0f / 255.0f));
xh = vec4F_mul(&xh, (1.0f / 255.0f));
if (!find_optimal_solution(mode, xl, xh, pParams, pResults))
return 0;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
{
uint32_t sel = selectors_temp[i];
if ((sel == min_sel) && (sel < (pParams->m_num_selector_weights - 1)))
sel++;
else if ((sel == max_sel) && (sel > 0))
sel--;
selectors_temp1[i] = (uint8_t)sel;
}
if (pParams->m_has_alpha)
compute_least_squares_endpoints_rgba(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
else
compute_least_squares_endpoints_rgb(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
xl = vec4F_mul(&xl, (1.0f / 255.0f));
xh = vec4F_mul(&xh, (1.0f / 255.0f));
if (!find_optimal_solution(mode, xl, xh, pParams, pResults))
return 0;
// In uber levels 2+, try taking more advantage of endpoint extrapolation by scaling the selectors in one direction or another.
const uint32_t uber_err_thresh = (pParams->m_num_pixels * 56) >> 4;
if ((pComp_params->m_uber_level >= 2) && (pResults->m_best_overall_err > uber_err_thresh))
{
const int Q = (pComp_params->m_uber_level >= 4) ? (pComp_params->m_uber_level - 2) : 1;
for (int ly = -Q; ly <= 1; ly++)
{
for (int hy = max_selector - 1; hy <= (max_selector + Q); hy++)
{
if ((ly == 0) && (hy == max_selector))
continue;
for (uint32_t i = 0; i < pParams->m_num_pixels; i++)
selectors_temp1[i] = (uint8_t)clampf(floorf((float)max_selector * ((float)selectors_temp[i] - (float)ly) / ((float)hy - (float)ly) + .5f), 0, (float)max_selector);
//bc7enc_vec4F xl, xh;
vec4F_set_scalar(&xl, 0.0f);
vec4F_set_scalar(&xh, 0.0f);
if (pParams->m_has_alpha)
compute_least_squares_endpoints_rgba(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
else
compute_least_squares_endpoints_rgb(pParams->m_num_pixels, selectors_temp1, pParams->m_pSelector_weightsx, &xl, &xh, pParams->m_pPixels);
xl = vec4F_mul(&xl, (1.0f / 255.0f));
xh = vec4F_mul(&xh, (1.0f / 255.0f));
if (!find_optimal_solution(mode, xl, xh, pParams, pResults))
return 0;
}
}
}
}
if (!pParams->m_pForce_selectors)
{
// Try encoding the partition as a single color by using the optimal single colors tables to encode the block to its mean.
if (mode == 1)
{
color_cell_compressor_results avg_results = *pResults;
const uint32_t r = (int)(.5f + meanColor.m_c[0] * 255.0f), g = (int)(.5f + meanColor.m_c[1] * 255.0f), b = (int)(.5f + meanColor.m_c[2] * 255.0f);
uint64_t avg_err = pack_mode1_to_one_color(pParams, &avg_results, r, g, b, pResults->m_pSelectors_temp);
if (avg_err < pResults->m_best_overall_err)
{
*pResults = avg_results;
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
pResults->m_best_overall_err = avg_err;
}
}
else if ((pParams->m_astc_endpoint_range == 8) && (pParams->m_num_selector_weights == 8) && (!pParams->m_has_alpha))
{
color_cell_compressor_results avg_results = *pResults;
const uint32_t r = (int)(.5f + meanColor.m_c[0] * 255.0f), g = (int)(.5f + meanColor.m_c[1] * 255.0f), b = (int)(.5f + meanColor.m_c[2] * 255.0f);
uint64_t avg_err = pack_astc_4bit_3bit_to_one_color(pParams, &avg_results, r, g, b, pResults->m_pSelectors_temp);
if (avg_err < pResults->m_best_overall_err)
{
*pResults = avg_results;
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
pResults->m_best_overall_err = avg_err;
}
}
else if ((pParams->m_astc_endpoint_range == 7) && (pParams->m_num_selector_weights == 4) && (!pParams->m_has_alpha))
{
color_cell_compressor_results avg_results = *pResults;
const uint32_t r = (int)(.5f + meanColor.m_c[0] * 255.0f), g = (int)(.5f + meanColor.m_c[1] * 255.0f), b = (int)(.5f + meanColor.m_c[2] * 255.0f);
uint64_t avg_err = pack_astc_range7_2bit_to_one_color(pParams, &avg_results, r, g, b, pResults->m_pSelectors_temp);
if (avg_err < pResults->m_best_overall_err)
{
*pResults = avg_results;
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
pResults->m_best_overall_err = avg_err;
}
}
else if ((pParams->m_astc_endpoint_range == 8) && (pParams->m_num_selector_weights == 4) && (pParams->m_has_alpha))
{
color_cell_compressor_results avg_results = *pResults;
const uint32_t r = (int)(.5f + meanColor.m_c[0] * 255.0f), g = (int)(.5f + meanColor.m_c[1] * 255.0f), b = (int)(.5f + meanColor.m_c[2] * 255.0f), a = (int)(.5f + meanColor.m_c[3] * 255.0f);
uint64_t avg_err = pack_astc_4bit_2bit_to_one_color_rgba(pParams, &avg_results, r, g, b, a, pResults->m_pSelectors_temp);
if (avg_err < pResults->m_best_overall_err)
{
*pResults = avg_results;
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
pResults->m_best_overall_err = avg_err;
}
}
else if ((pParams->m_astc_endpoint_range == 13) && (pParams->m_num_selector_weights == 4) && (!pParams->m_has_alpha))
{
color_cell_compressor_results avg_results = *pResults;
const uint32_t r = (int)(.5f + meanColor.m_c[0] * 255.0f), g = (int)(.5f + meanColor.m_c[1] * 255.0f), b = (int)(.5f + meanColor.m_c[2] * 255.0f);
uint64_t avg_err = pack_astc_range13_2bit_to_one_color(pParams, &avg_results, r, g, b, pResults->m_pSelectors_temp);
if (avg_err < pResults->m_best_overall_err)
{
*pResults = avg_results;
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
pResults->m_best_overall_err = avg_err;
}
}
else if ((pParams->m_astc_endpoint_range == 11) && (pParams->m_num_selector_weights == 32) && (!pParams->m_has_alpha))
{
color_cell_compressor_results avg_results = *pResults;
const uint32_t r = (int)(.5f + meanColor.m_c[0] * 255.0f), g = (int)(.5f + meanColor.m_c[1] * 255.0f), b = (int)(.5f + meanColor.m_c[2] * 255.0f);
uint64_t avg_err = pack_astc_range11_5bit_to_one_color(pParams, &avg_results, r, g, b, pResults->m_pSelectors_temp);
if (avg_err < pResults->m_best_overall_err)
{
*pResults = avg_results;
memcpy(pResults->m_pSelectors, pResults->m_pSelectors_temp, sizeof(pResults->m_pSelectors[0]) * pParams->m_num_pixels);
pResults->m_best_overall_err = avg_err;
}
}
}
#if BC7ENC_CHECK_OVERALL_ERROR
check_best_overall_error(pParams, pResults);
#endif
return pResults->m_best_overall_err;
}
uint64_t color_cell_compression_est_astc(
uint32_t num_weights, uint32_t num_comps, const uint32_t *pWeight_table,
uint32_t num_pixels, const color_quad_u8* pPixels,
uint64_t best_err_so_far, const uint32_t weights[4])
{
assert(num_comps == 3 || num_comps == 4);
assert(num_weights >= 1 && num_weights <= 32);
assert(pWeight_table[0] == 0 && pWeight_table[num_weights - 1] == 64);
// Find RGB bounds as an approximation of the block's principle axis
uint32_t lr = 255, lg = 255, lb = 255, la = 255;
uint32_t hr = 0, hg = 0, hb = 0, ha = 0;
if (num_comps == 4)
{
for (uint32_t i = 0; i < num_pixels; i++)
{
const color_quad_u8* pC = &pPixels[i];
if (pC->m_c[0] < lr) lr = pC->m_c[0];
if (pC->m_c[1] < lg) lg = pC->m_c[1];
if (pC->m_c[2] < lb) lb = pC->m_c[2];
if (pC->m_c[3] < la) la = pC->m_c[3];
if (pC->m_c[0] > hr) hr = pC->m_c[0];
if (pC->m_c[1] > hg) hg = pC->m_c[1];
if (pC->m_c[2] > hb) hb = pC->m_c[2];
if (pC->m_c[3] > ha) ha = pC->m_c[3];
}
}
else
{
for (uint32_t i = 0; i < num_pixels; i++)
{
const color_quad_u8* pC = &pPixels[i];
if (pC->m_c[0] < lr) lr = pC->m_c[0];
if (pC->m_c[1] < lg) lg = pC->m_c[1];
if (pC->m_c[2] < lb) lb = pC->m_c[2];
if (pC->m_c[0] > hr) hr = pC->m_c[0];
if (pC->m_c[1] > hg) hg = pC->m_c[1];
if (pC->m_c[2] > hb) hb = pC->m_c[2];
}
la = 255;
ha = 255;
}
color_quad_u8 lowColor, highColor;
color_quad_u8_set(&lowColor, lr, lg, lb, la);
color_quad_u8_set(&highColor, hr, hg, hb, ha);
// Place endpoints at bbox diagonals and compute interpolated colors
color_quad_u8 weightedColors[32];
weightedColors[0] = lowColor;
weightedColors[num_weights - 1] = highColor;
for (uint32_t i = 1; i < (num_weights - 1); i++)
{
weightedColors[i].m_c[0] = (uint8_t)astc_interpolate(lowColor.m_c[0], highColor.m_c[0], pWeight_table[i]);
weightedColors[i].m_c[1] = (uint8_t)astc_interpolate(lowColor.m_c[1], highColor.m_c[1], pWeight_table[i]);
weightedColors[i].m_c[2] = (uint8_t)astc_interpolate(lowColor.m_c[2], highColor.m_c[2], pWeight_table[i]);
weightedColors[i].m_c[3] = (num_comps == 4) ? (uint8_t)astc_interpolate(lowColor.m_c[3], highColor.m_c[3], pWeight_table[i]) : 255;
}
// Compute dots and thresholds
const int ar = highColor.m_c[0] - lowColor.m_c[0];
const int ag = highColor.m_c[1] - lowColor.m_c[1];
const int ab = highColor.m_c[2] - lowColor.m_c[2];
const int aa = highColor.m_c[3] - lowColor.m_c[3];
int dots[32];
if (num_comps == 4)
{
for (uint32_t i = 0; i < num_weights; i++)
dots[i] = weightedColors[i].m_c[0] * ar + weightedColors[i].m_c[1] * ag + weightedColors[i].m_c[2] * ab + weightedColors[i].m_c[3] * aa;
}
else
{
assert(aa == 0);
for (uint32_t i = 0; i < num_weights; i++)
dots[i] = weightedColors[i].m_c[0] * ar + weightedColors[i].m_c[1] * ag + weightedColors[i].m_c[2] * ab;
}
int thresh[32 - 1];
for (uint32_t i = 0; i < (num_weights - 1); i++)
thresh[i] = (dots[i] + dots[i + 1] + 1) >> 1;
uint64_t total_err = 0;
if ((weights[0] | weights[1] | weights[2] | weights[3]) == 1)
{
if (num_comps == 4)
{
for (uint32_t i = 0; i < num_pixels; i++)
{
const color_quad_u8* pC = &pPixels[i];
int d = ar * pC->m_c[0] + ag * pC->m_c[1] + ab * pC->m_c[2] + aa * pC->m_c[3];
// Find approximate selector
uint32_t s = 0;
for (int j = num_weights - 2; j >= 0; j--)
{
if (d >= thresh[j])
{
s = j + 1;
break;
}
}
// Compute error
const color_quad_u8* pE1 = &weightedColors[s];
int dr = (int)pE1->m_c[0] - (int)pC->m_c[0];
int dg = (int)pE1->m_c[1] - (int)pC->m_c[1];
int db = (int)pE1->m_c[2] - (int)pC->m_c[2];
int da = (int)pE1->m_c[3] - (int)pC->m_c[3];
total_err += (dr * dr) + (dg * dg) + (db * db) + (da * da);
if (total_err > best_err_so_far)
break;
}
}
else
{
for (uint32_t i = 0; i < num_pixels; i++)
{
const color_quad_u8* pC = &pPixels[i];
int d = ar * pC->m_c[0] + ag * pC->m_c[1] + ab * pC->m_c[2];
// Find approximate selector
uint32_t s = 0;
for (int j = num_weights - 2; j >= 0; j--)
{
if (d >= thresh[j])
{
s = j + 1;
break;
}
}
// Compute error
const color_quad_u8* pE1 = &weightedColors[s];
int dr = (int)pE1->m_c[0] - (int)pC->m_c[0];
int dg = (int)pE1->m_c[1] - (int)pC->m_c[1];
int db = (int)pE1->m_c[2] - (int)pC->m_c[2];
total_err += (dr * dr) + (dg * dg) + (db * db);
if (total_err > best_err_so_far)
break;
}
}
}
else
{
if (num_comps == 4)
{
for (uint32_t i = 0; i < num_pixels; i++)
{
const color_quad_u8* pC = &pPixels[i];
int d = ar * pC->m_c[0] + ag * pC->m_c[1] + ab * pC->m_c[2] + aa * pC->m_c[3];
// Find approximate selector
uint32_t s = 0;
for (int j = num_weights - 2; j >= 0; j--)
{
if (d >= thresh[j])
{
s = j + 1;
break;
}
}
// Compute error
const color_quad_u8* pE1 = &weightedColors[s];
int dr = (int)pE1->m_c[0] - (int)pC->m_c[0];
int dg = (int)pE1->m_c[1] - (int)pC->m_c[1];
int db = (int)pE1->m_c[2] - (int)pC->m_c[2];
int da = (int)pE1->m_c[3] - (int)pC->m_c[3];
total_err += weights[0] * (dr * dr) + weights[1] * (dg * dg) + weights[2] * (db * db) + weights[3] * (da * da);
if (total_err > best_err_so_far)
break;
}
}
else
{
for (uint32_t i = 0; i < num_pixels; i++)
{
const color_quad_u8* pC = &pPixels[i];
int d = ar * pC->m_c[0] + ag * pC->m_c[1] + ab * pC->m_c[2];
// Find approximate selector
uint32_t s = 0;
for (int j = num_weights - 2; j >= 0; j--)
{
if (d >= thresh[j])
{
s = j + 1;
break;
}
}
// Compute error
const color_quad_u8* pE1 = &weightedColors[s];
int dr = (int)pE1->m_c[0] - (int)pC->m_c[0];
int dg = (int)pE1->m_c[1] - (int)pC->m_c[1];
int db = (int)pE1->m_c[2] - (int)pC->m_c[2];
total_err += weights[0] * (dr * dr) + weights[1] * (dg * dg) + weights[2] * (db * db);
if (total_err > best_err_so_far)
break;
}
}
}
return total_err;
}
} // namespace basisu