/* * Copyright 2015 Philip Taylor * Copyright 2018 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ /** * \file texcompress_astc.c * * Decompression code for GL_KHR_texture_compression_astc_ldr, which is just * ASTC 2D LDR. * * The ASTC 2D LDR decoder (without the sRGB part) was copied from the OASTC * library written by Philip Taylor. I added sRGB support and adjusted it for * Mesa. - Marek */ #include "texcompress_astc.h" #include "macros.h" #include "util/half_float.h" #include static bool VERBOSE_DECODE = false; static bool VERBOSE_WRITE = false; static inline uint8_t uint16_div_64k_to_half_to_unorm8(uint16_t v) { return _mesa_half_to_unorm8(_mesa_uint16_div_64k_to_half(v)); } class decode_error { public: enum type { ok, unsupported_hdr_void_extent, reserved_block_mode_1, reserved_block_mode_2, dual_plane_and_too_many_partitions, invalid_range_in_void_extent, weight_grid_exceeds_block_size, invalid_colour_endpoints_size, invalid_colour_endpoints_count, invalid_weight_bits, invalid_num_weights, }; }; struct cem_range { uint8_t max; uint8_t t, q, b; }; /* Based on the Color Unquantization Parameters table, * plus the bit-only representations, sorted by increasing size */ static cem_range cem_ranges[] = { { 5, 1, 0, 1 }, { 7, 0, 0, 3 }, { 9, 0, 1, 1 }, { 11, 1, 0, 2 }, { 15, 0, 0, 4 }, { 19, 0, 1, 2 }, { 23, 1, 0, 3 }, { 31, 0, 0, 5 }, { 39, 0, 1, 3 }, { 47, 1, 0, 4 }, { 63, 0, 0, 6 }, { 79, 0, 1, 4 }, { 95, 1, 0, 5 }, { 127, 0, 0, 7 }, { 159, 0, 1, 5 }, { 191, 1, 0, 6 }, { 255, 0, 0, 8 }, }; #define CAT_BITS_2(a, b) ( ((a) << 1) | (b) ) #define CAT_BITS_3(a, b, c) ( ((a) << 2) | ((b) << 1) | (c) ) #define CAT_BITS_4(a, b, c, d) ( ((a) << 3) | ((b) << 2) | ((c) << 1) | (d) ) #define CAT_BITS_5(a, b, c, d, e) ( ((a) << 4) | ((b) << 3) | ((c) << 2) | ((d) << 1) | (e) ) /** * Unpack 5n+8 bits from 'in' into 5 output values. * If n <= 4 then T should be uint32_t, else it must be uint64_t. */ template static void unpack_trit_block(int n, T in, uint8_t *out) { assert(n <= 6); /* else output will overflow uint8_t */ uint8_t T0 = (in >> (n)) & 0x1; uint8_t T1 = (in >> (n+1)) & 0x1; uint8_t T2 = (in >> (2*n+2)) & 0x1; uint8_t T3 = (in >> (2*n+3)) & 0x1; uint8_t T4 = (in >> (3*n+4)) & 0x1; uint8_t T5 = (in >> (4*n+5)) & 0x1; uint8_t T6 = (in >> (4*n+6)) & 0x1; uint8_t T7 = (in >> (5*n+7)) & 0x1; uint8_t mmask = (1 << n) - 1; uint8_t m0 = (in >> (0)) & mmask; uint8_t m1 = (in >> (n+2)) & mmask; uint8_t m2 = (in >> (2*n+4)) & mmask; uint8_t m3 = (in >> (3*n+5)) & mmask; uint8_t m4 = (in >> (4*n+7)) & mmask; uint8_t C; uint8_t t4, t3, t2, t1, t0; if (CAT_BITS_3(T4, T3, T2) == 0x7) { C = CAT_BITS_5(T7, T6, T5, T1, T0); t4 = t3 = 2; } else { C = CAT_BITS_5(T4, T3, T2, T1, T0); if (CAT_BITS_2(T6, T5) == 0x3) { t4 = 2; t3 = T7; } else { t4 = T7; t3 = CAT_BITS_2(T6, T5); } } if ((C & 0x3) == 0x3) { t2 = 2; t1 = (C >> 4) & 0x1; uint8_t C3 = (C >> 3) & 0x1; uint8_t C2 = (C >> 2) & 0x1; t0 = (C3 << 1) | (C2 & ~C3); } else if (((C >> 2) & 0x3) == 0x3) { t2 = 2; t1 = 2; t0 = C & 0x3; } else { t2 = (C >> 4) & 0x1; t1 = (C >> 2) & 0x3; uint8_t C1 = (C >> 1) & 0x1; uint8_t C0 = (C >> 0) & 0x1; t0 = (C1 << 1) | (C0 & ~C1); } out[0] = (t0 << n) | m0; out[1] = (t1 << n) | m1; out[2] = (t2 << n) | m2; out[3] = (t3 << n) | m3; out[4] = (t4 << n) | m4; } /** * Unpack 3n+7 bits from 'in' into 3 output values */ static void unpack_quint_block(int n, uint32_t in, uint8_t *out) { assert(n <= 5); /* else output will overflow uint8_t */ uint8_t Q0 = (in >> (n)) & 0x1; uint8_t Q1 = (in >> (n+1)) & 0x1; uint8_t Q2 = (in >> (n+2)) & 0x1; uint8_t Q3 = (in >> (2*n+3)) & 0x1; uint8_t Q4 = (in >> (2*n+4)) & 0x1; uint8_t Q5 = (in >> (3*n+5)) & 0x1; uint8_t Q6 = (in >> (3*n+6)) & 0x1; uint8_t mmask = (1 << n) - 1; uint8_t m0 = (in >> (0)) & mmask; uint8_t m1 = (in >> (n+3)) & mmask; uint8_t m2 = (in >> (2*n+5)) & mmask; uint8_t C; uint8_t q2, q1, q0; if (CAT_BITS_4(Q6, Q5, Q2, Q1) == 0x3) { q2 = CAT_BITS_3(Q0, Q4 & ~Q0, Q3 & ~Q0); q1 = 4; q0 = 4; } else { if (CAT_BITS_2(Q2, Q1) == 0x3) { q2 = 4; C = CAT_BITS_5(Q4, Q3, 0x1 & ~Q6, 0x1 & ~Q5, Q0); } else { q2 = CAT_BITS_2(Q6, Q5); C = CAT_BITS_5(Q4, Q3, Q2, Q1, Q0); } if ((C & 0x7) == 0x5) { q1 = 4; q0 = (C >> 3) & 0x3; } else { q1 = (C >> 3) & 0x3; q0 = C & 0x7; } } out[0] = (q0 << n) | m0; out[1] = (q1 << n) | m1; out[2] = (q2 << n) | m2; } struct uint8x4_t { uint8_t v[4]; uint8x4_t() { } uint8x4_t(int a, int b, int c, int d) { assert(0 <= a && a <= 255); assert(0 <= b && b <= 255); assert(0 <= c && c <= 255); assert(0 <= d && d <= 255); v[0] = a; v[1] = b; v[2] = c; v[3] = d; } static uint8x4_t clamped(int a, int b, int c, int d) { uint8x4_t r; r.v[0] = MAX2(0, MIN2(255, a)); r.v[1] = MAX2(0, MIN2(255, b)); r.v[2] = MAX2(0, MIN2(255, c)); r.v[3] = MAX2(0, MIN2(255, d)); return r; } }; static uint8x4_t blue_contract(int r, int g, int b, int a) { return uint8x4_t((r+b) >> 1, (g+b) >> 1, b, a); } static uint8x4_t blue_contract_clamped(int r, int g, int b, int a) { return uint8x4_t::clamped((r+b) >> 1, (g+b) >> 1, b, a); } static void bit_transfer_signed(int &a, int &b) { b >>= 1; b |= a & 0x80; a >>= 1; a &= 0x3f; if (a & 0x20) a -= 0x40; } static uint32_t hash52(uint32_t p) { p ^= p >> 15; p -= p << 17; p += p << 7; p += p << 4; p ^= p >> 5; p += p << 16; p ^= p >> 7; p ^= p >> 3; p ^= p << 6; p ^= p >> 17; return p; } static int select_partition(int seed, int x, int y, int z, int partitioncount, int small_block) { if (small_block) { x <<= 1; y <<= 1; z <<= 1; } seed += (partitioncount - 1) * 1024; uint32_t rnum = hash52(seed); uint8_t seed1 = rnum & 0xF; uint8_t seed2 = (rnum >> 4) & 0xF; uint8_t seed3 = (rnum >> 8) & 0xF; uint8_t seed4 = (rnum >> 12) & 0xF; uint8_t seed5 = (rnum >> 16) & 0xF; uint8_t seed6 = (rnum >> 20) & 0xF; uint8_t seed7 = (rnum >> 24) & 0xF; uint8_t seed8 = (rnum >> 28) & 0xF; uint8_t seed9 = (rnum >> 18) & 0xF; uint8_t seed10 = (rnum >> 22) & 0xF; uint8_t seed11 = (rnum >> 26) & 0xF; uint8_t seed12 = ((rnum >> 30) | (rnum << 2)) & 0xF; seed1 *= seed1; seed2 *= seed2; seed3 *= seed3; seed4 *= seed4; seed5 *= seed5; seed6 *= seed6; seed7 *= seed7; seed8 *= seed8; seed9 *= seed9; seed10 *= seed10; seed11 *= seed11; seed12 *= seed12; int sh1, sh2, sh3; if (seed & 1) { sh1 = (seed & 2 ? 4 : 5); sh2 = (partitioncount == 3 ? 6 : 5); } else { sh1 = (partitioncount == 3 ? 6 : 5); sh2 = (seed & 2 ? 4 : 5); } sh3 = (seed & 0x10) ? sh1 : sh2; seed1 >>= sh1; seed2 >>= sh2; seed3 >>= sh1; seed4 >>= sh2; seed5 >>= sh1; seed6 >>= sh2; seed7 >>= sh1; seed8 >>= sh2; seed9 >>= sh3; seed10 >>= sh3; seed11 >>= sh3; seed12 >>= sh3; int a = seed1 * x + seed2 * y + seed11 * z + (rnum >> 14); int b = seed3 * x + seed4 * y + seed12 * z + (rnum >> 10); int c = seed5 * x + seed6 * y + seed9 * z + (rnum >> 6); int d = seed7 * x + seed8 * y + seed10 * z + (rnum >> 2); a &= 0x3F; b &= 0x3F; c &= 0x3F; d &= 0x3F; if (partitioncount < 4) d = 0; if (partitioncount < 3) c = 0; if (a >= b && a >= c && a >= d) return 0; else if (b >= c && b >= d) return 1; else if (c >= d) return 2; else return 3; } struct InputBitVector { uint32_t data[4]; void printf_bits(int offset, int count, const char *fmt = "", ...) { char out[129]; memset(out, '.', 128); out[128] = '\0'; int idx = offset; for (int i = 0; i < count; ++i) { out[127 - idx] = ((data[idx >> 5] >> (idx & 31)) & 1) ? '1' : '0'; ++idx; } printf("%s ", out); va_list ap; va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); } uint32_t get_bits(int offset, int count) { assert(count >= 0 && count < 32); uint32_t out = 0; if (offset < 32) out |= data[0] >> offset; if (0 < offset && offset <= 32) out |= data[1] << (32 - offset); if (32 < offset && offset < 64) out |= data[1] >> (offset - 32); if (32 < offset && offset <= 64) out |= data[2] << (64 - offset); if (64 < offset && offset < 96) out |= data[2] >> (offset - 64); if (64 < offset && offset <= 96) out |= data[3] << (96 - offset); if (96 < offset && offset < 128) out |= data[3] >> (offset - 96); out &= (1 << count) - 1; return out; } uint64_t get_bits64(int offset, int count) { assert(count >= 0 && count < 64); uint64_t out = 0; if (offset < 32) out |= data[0] >> offset; if (offset <= 32) out |= (uint64_t)data[1] << (32 - offset); if (32 < offset && offset < 64) out |= data[1] >> (offset - 32); if (0 < offset && offset <= 64) out |= (uint64_t)data[2] << (64 - offset); if (64 < offset && offset < 96) out |= data[2] >> (offset - 64); if (32 < offset && offset <= 96) out |= (uint64_t)data[3] << (96 - offset); if (96 < offset && offset < 128) out |= data[3] >> (offset - 96); out &= ((uint64_t)1 << count) - 1; return out; } uint32_t get_bits_rev(int offset, int count) { assert(offset >= count); uint32_t tmp = get_bits(offset - count, count); uint32_t out = 0; for (int i = 0; i < count; ++i) out |= ((tmp >> i) & 1) << (count - 1 - i); return out; } }; struct OutputBitVector { uint32_t data[4]; int offset; OutputBitVector() : offset(0) { memset(data, 0, sizeof(data)); } void append(uint32_t value, int size) { if (VERBOSE_WRITE) printf("append offset=%d size=%d values=0x%x\n", offset, size, value); assert(offset + size <= 128); assert(size <= 32); if (size < 32) assert((value >> size) == 0); while (size) { int c = MIN2(size, 32 - (offset & 31)); data[offset >> 5] |= (value << (offset & 31)); offset += c; size -= c; value >>= c; } } void append64(uint64_t value, int size) { if (VERBOSE_WRITE) printf("append offset=%d size=%d values=0x%llx\n", offset, size, (unsigned long long)value); assert(offset + size <= 128); assert(size <= 64); if (size < 64) assert((value >> size) == 0); while (size) { int c = MIN2(size, 32 - (offset & 31)); data[offset >> 5] |= (value << (offset & 31)); offset += c; size -= c; value >>= c; } } void append(OutputBitVector &v, int size) { if (VERBOSE_WRITE) printf("append vector offset=%d size=%d\n", offset, size); assert(offset + size <= 128); int i = 0; while (size >= 32) { append(v.data[i++], 32); size -= 32; } if (size > 0) append(v.data[i] & ((1 << size) - 1), size); } void append_end(OutputBitVector &v, int size) { for (int i = 0; i < size; ++i) data[(127 - i) >> 5] |= ((v.data[i >> 5] >> (i & 31)) & 1) << ((127 - i) & 31); } /* Insert the given number of '1' bits. (We could use 0s instead, but 1s are * more likely to flush out bugs where we accidentally read undefined bits.) */ void skip(int size) { if (VERBOSE_WRITE) printf("skip offset=%d size=%d\n", offset, size); assert(offset + size <= 128); while (size >= 32) { append(0xffffffff, 32); size -= 32; } if (size > 0) append(0xffffffff >> (32 - size), size); } }; class Decoder { public: Decoder(int block_w, int block_h, int block_d, bool srgb, bool output_unorm8) : block_w(block_w), block_h(block_h), block_d(block_d), srgb(srgb), output_unorm8(output_unorm8) {} decode_error::type decode(const uint8_t *in, uint16_t *output) const; int block_w, block_h, block_d; bool srgb, output_unorm8; }; struct Block { bool is_error; bool bogus_colour_endpoints; bool bogus_weights; int high_prec; int dual_plane; int colour_component_selector; int wt_range; int wt_w, wt_h, wt_d; int num_parts; int partition_index; bool is_void_extent; int void_extent_d; int void_extent_min_s; int void_extent_max_s; int void_extent_min_t; int void_extent_max_t; uint16_t void_extent_colour_r; uint16_t void_extent_colour_g; uint16_t void_extent_colour_b; uint16_t void_extent_colour_a; bool is_multi_cem; int num_extra_cem_bits; int colour_endpoint_data_offset; int extra_cem_bits; int cem_base_class; int cems[4]; int num_cem_values; /* Calculated by unpack_weights(): */ uint8_t weights_quant[64 + 4]; /* max 64 values, plus padding for overflows in trit parsing */ /* Calculated by unquantise_weights(): */ uint8_t weights[64 + 18]; /* max 64 values, plus padding for the infill interpolation */ /* Calculated by unpack_colour_endpoints(): */ uint8_t colour_endpoints_quant[18 + 4]; /* max 18 values, plus padding for overflows in trit parsing */ /* Calculated by unquantise_colour_endpoints(): */ uint8_t colour_endpoints[18]; /* Calculated by calculate_from_weights(): */ int wt_trits; int wt_quints; int wt_bits; int wt_max; int num_weights; int weight_bits; /* Calculated by calculate_remaining_bits(): */ int remaining_bits; /* Calculated by calculate_colour_endpoints_size(): */ int colour_endpoint_bits; int ce_max; int ce_trits; int ce_quints; int ce_bits; /* Calculated by compute_infill_weights(); */ uint8_t infill_weights[2][216]; /* large enough for 6x6x6 */ /* Calculated by decode_colour_endpoints(); */ uint8x4_t endpoints_decoded[2][4]; void calculate_from_weights(); void calculate_remaining_bits(); decode_error::type calculate_colour_endpoints_size(); void unquantise_weights(); void unquantise_colour_endpoints(); decode_error::type decode(const Decoder &decoder, InputBitVector in); decode_error::type decode_block_mode(InputBitVector in); decode_error::type decode_void_extent(InputBitVector in); void decode_cem(InputBitVector in); void unpack_colour_endpoints(InputBitVector in); void decode_colour_endpoints(); void unpack_weights(InputBitVector in); void compute_infill_weights(int block_w, int block_h, int block_d); void write_decoded(const Decoder &decoder, uint16_t *output); }; decode_error::type Decoder::decode(const uint8_t *in, uint16_t *output) const { Block blk; InputBitVector in_vec; memcpy(&in_vec.data, in, 16); decode_error::type err = blk.decode(*this, in_vec); if (err == decode_error::ok) { blk.write_decoded(*this, output); } else { /* Fill output with the error colour */ for (int i = 0; i < block_w * block_h * block_d; ++i) { if (output_unorm8) { output[i*4+0] = 0xff; output[i*4+1] = 0; output[i*4+2] = 0xff; output[i*4+3] = 0xff; } else { assert(!srgb); /* srgb must use unorm8 */ output[i*4+0] = FP16_ONE; output[i*4+1] = FP16_ZERO; output[i*4+2] = FP16_ONE; output[i*4+3] = FP16_ONE; } } } return err; } decode_error::type Block::decode_void_extent(InputBitVector block) { /* TODO: 3D */ is_void_extent = true; void_extent_d = block.get_bits(9, 1); void_extent_min_s = block.get_bits(12, 13); void_extent_max_s = block.get_bits(25, 13); void_extent_min_t = block.get_bits(38, 13); void_extent_max_t = block.get_bits(51, 13); void_extent_colour_r = block.get_bits(64, 16); void_extent_colour_g = block.get_bits(80, 16); void_extent_colour_b = block.get_bits(96, 16); void_extent_colour_a = block.get_bits(112, 16); /* TODO: maybe we should do something useful with the extent coordinates? */ if (void_extent_d) { return decode_error::unsupported_hdr_void_extent; } if (void_extent_min_s == 0x1fff && void_extent_max_s == 0x1fff && void_extent_min_t == 0x1fff && void_extent_max_t == 0x1fff) { /* No extents */ } else { /* Check for illegal encoding */ if (void_extent_min_s >= void_extent_max_s || void_extent_min_t >= void_extent_max_t) { return decode_error::invalid_range_in_void_extent; } } return decode_error::ok; } decode_error::type Block::decode_block_mode(InputBitVector in) { dual_plane = in.get_bits(10, 1); high_prec = in.get_bits(9, 1); if (in.get_bits(0, 2) != 0x0) { wt_range = (in.get_bits(0, 2) << 1) | in.get_bits(4, 1); int a = in.get_bits(5, 2); int b = in.get_bits(7, 2); switch (in.get_bits(2, 2)) { case 0x0: if (VERBOSE_DECODE) in.printf_bits(0, 11, "DHBBAAR00RR"); wt_w = b + 4; wt_h = a + 2; break; case 0x1: if (VERBOSE_DECODE) in.printf_bits(0, 11, "DHBBAAR01RR"); wt_w = b + 8; wt_h = a + 2; break; case 0x2: if (VERBOSE_DECODE) in.printf_bits(0, 11, "DHBBAAR10RR"); wt_w = a + 2; wt_h = b + 8; break; case 0x3: if ((b & 0x2) == 0) { if (VERBOSE_DECODE) in.printf_bits(0, 11, "DH0BAAR11RR"); wt_w = a + 2; wt_h = b + 6; } else { if (VERBOSE_DECODE) in.printf_bits(0, 11, "DH1BAAR11RR"); wt_w = (b & 0x1) + 2; wt_h = a + 2; } break; } } else { if (in.get_bits(6, 3) == 0x7) { if (in.get_bits(0, 9) == 0x1fc) { if (VERBOSE_DECODE) in.printf_bits(0, 11, "xx111111100 (void extent)"); return decode_void_extent(in); } else { if (VERBOSE_DECODE) in.printf_bits(0, 11, "xx111xxxx00"); return decode_error::reserved_block_mode_1; } } if (in.get_bits(0, 4) == 0x0) { if (VERBOSE_DECODE) in.printf_bits(0, 11, "xxxxxxx0000"); return decode_error::reserved_block_mode_2; } wt_range = in.get_bits(1, 3) | in.get_bits(4, 1); int a = in.get_bits(5, 2); int b; switch (in.get_bits(7, 2)) { case 0x0: if (VERBOSE_DECODE) in.printf_bits(0, 11, "DH00AARRR00"); wt_w = 12; wt_h = a + 2; break; case 0x1: if (VERBOSE_DECODE) in.printf_bits(0, 11, "DH01AARRR00"); wt_w = a + 2; wt_h = 12; break; case 0x3: if (in.get_bits(5, 1) == 0) { if (VERBOSE_DECODE) in.printf_bits(0, 11, "DH1100RRR00"); wt_w = 6; wt_h = 10; } else { if (VERBOSE_DECODE) in.printf_bits(0, 11, "DH1101RRR00"); wt_w = 10; wt_h = 6; } break; case 0x2: if (VERBOSE_DECODE) in.printf_bits(0, 11, "BB10AARRR00"); b = in.get_bits(9, 2); wt_w = a + 6; wt_h = b + 6; dual_plane = 0; high_prec = 0; break; } } return decode_error::ok; } void Block::decode_cem(InputBitVector in) { cems[0] = cems[1] = cems[2] = cems[3] = -1; num_extra_cem_bits = 0; extra_cem_bits = 0; if (num_parts > 1) { partition_index = in.get_bits(13, 10); if (VERBOSE_DECODE) in.printf_bits(13, 10, "partition ID (%d)", partition_index); uint32_t cem = in.get_bits(23, 6); if ((cem & 0x3) == 0x0) { cem >>= 2; cem_base_class = cem >> 2; is_multi_cem = false; for (int i = 0; i < num_parts; ++i) cems[i] = cem; if (VERBOSE_DECODE) in.printf_bits(23, 6, "CEM (single, %d)", cem); } else { cem_base_class = (cem & 0x3) - 1; is_multi_cem = true; if (VERBOSE_DECODE) in.printf_bits(23, 6, "CEM (multi, base class %d)", cem_base_class); int offset = 128 - weight_bits; if (num_parts == 2) { if (VERBOSE_DECODE) { in.printf_bits(25, 4, "M0M0 C1 C0"); in.printf_bits(offset - 2, 2, "M1M1"); } uint32_t c0 = in.get_bits(25, 1); uint32_t c1 = in.get_bits(26, 1); extra_cem_bits = c0 + c1; num_extra_cem_bits = 2; uint32_t m0 = in.get_bits(27, 2); uint32_t m1 = in.get_bits(offset - 2, 2); cems[0] = ((cem_base_class + c0) << 2) | m0; cems[1] = ((cem_base_class + c1) << 2) | m1; } else if (num_parts == 3) { if (VERBOSE_DECODE) { in.printf_bits(25, 4, "M0 C2 C1 C0"); in.printf_bits(offset - 5, 5, "M2M2 M1M1 M0"); } uint32_t c0 = in.get_bits(25, 1); uint32_t c1 = in.get_bits(26, 1); uint32_t c2 = in.get_bits(27, 1); extra_cem_bits = c0 + c1 + c2; num_extra_cem_bits = 5; uint32_t m0 = in.get_bits(28, 1) | (in.get_bits(128 - weight_bits - 5, 1) << 1); uint32_t m1 = in.get_bits(offset - 4, 2); uint32_t m2 = in.get_bits(offset - 2, 2); cems[0] = ((cem_base_class + c0) << 2) | m0; cems[1] = ((cem_base_class + c1) << 2) | m1; cems[2] = ((cem_base_class + c2) << 2) | m2; } else if (num_parts == 4) { if (VERBOSE_DECODE) { in.printf_bits(25, 4, "C3 C2 C1 C0"); in.printf_bits(offset - 8, 8, "M3M3 M2M2 M1M1 M0M0"); } uint32_t c0 = in.get_bits(25, 1); uint32_t c1 = in.get_bits(26, 1); uint32_t c2 = in.get_bits(27, 1); uint32_t c3 = in.get_bits(28, 1); extra_cem_bits = c0 + c1 + c2 + c3; num_extra_cem_bits = 8; uint32_t m0 = in.get_bits(offset - 8, 2); uint32_t m1 = in.get_bits(offset - 6, 2); uint32_t m2 = in.get_bits(offset - 4, 2); uint32_t m3 = in.get_bits(offset - 2, 2); cems[0] = ((cem_base_class + c0) << 2) | m0; cems[1] = ((cem_base_class + c1) << 2) | m1; cems[2] = ((cem_base_class + c2) << 2) | m2; cems[3] = ((cem_base_class + c3) << 2) | m3; } else { unreachable(""); } } colour_endpoint_data_offset = 29; } else { uint32_t cem = in.get_bits(13, 4); cem_base_class = cem >> 2; is_multi_cem = false; cems[0] = cem; partition_index = -1; if (VERBOSE_DECODE) in.printf_bits(13, 4, "CEM = %d (class %d)", cem, cem_base_class); colour_endpoint_data_offset = 17; } } void Block::unpack_colour_endpoints(InputBitVector in) { if (ce_trits) { int offset = colour_endpoint_data_offset; int bits_left = colour_endpoint_bits; for (int i = 0; i < num_cem_values; i += 5) { int bits_to_read = MIN2(bits_left, 8 + ce_bits * 5); /* If ce_trits then ce_bits <= 6, so bits_to_read <= 38 and we have to use uint64_t */ uint64_t raw = in.get_bits64(offset, bits_to_read); unpack_trit_block(ce_bits, raw, &colour_endpoints_quant[i]); if (VERBOSE_DECODE) in.printf_bits(offset, bits_to_read, "trits [%d,%d,%d,%d,%d]", colour_endpoints_quant[i+0], colour_endpoints_quant[i+1], colour_endpoints_quant[i+2], colour_endpoints_quant[i+3], colour_endpoints_quant[i+4]); offset += 8 + ce_bits * 5; bits_left -= 8 + ce_bits * 5; } } else if (ce_quints) { int offset = colour_endpoint_data_offset; int bits_left = colour_endpoint_bits; for (int i = 0; i < num_cem_values; i += 3) { int bits_to_read = MIN2(bits_left, 7 + ce_bits * 3); /* If ce_quints then ce_bits <= 5, so bits_to_read <= 22 and we can use uint32_t */ uint32_t raw = in.get_bits(offset, bits_to_read); unpack_quint_block(ce_bits, raw, &colour_endpoints_quant[i]); if (VERBOSE_DECODE) in.printf_bits(offset, bits_to_read, "quints [%d,%d,%d]", colour_endpoints_quant[i], colour_endpoints_quant[i+1], colour_endpoints_quant[i+2]); offset += 7 + ce_bits * 3; bits_left -= 7 + ce_bits * 3; } } else { assert((colour_endpoint_bits % ce_bits) == 0); int offset = colour_endpoint_data_offset; for (int i = 0; i < num_cem_values; i++) { colour_endpoints_quant[i] = in.get_bits(offset, ce_bits); if (VERBOSE_DECODE) in.printf_bits(offset, ce_bits, "bits [%d]", colour_endpoints_quant[i]); offset += ce_bits; } } } void Block::decode_colour_endpoints() { int cem_values_idx = 0; for (int part = 0; part < num_parts; ++part) { uint8_t *v = &colour_endpoints[cem_values_idx]; int v0 = v[0]; int v1 = v[1]; int v2 = v[2]; int v3 = v[3]; int v4 = v[4]; int v5 = v[5]; int v6 = v[6]; int v7 = v[7]; cem_values_idx += ((cems[part] >> 2) + 1) * 2; uint8x4_t e0, e1; int s0, s1, L0, L1; switch (cems[part]) { case 0: e0 = uint8x4_t(v0, v0, v0, 0xff); e1 = uint8x4_t(v1, v1, v1, 0xff); break; case 1: L0 = (v0 >> 2) | (v1 & 0xc0); L1 = L0 + (v1 & 0x3f); if (L1 > 0xff) L1 = 0xff; e0 = uint8x4_t(L0, L0, L0, 0xff); e1 = uint8x4_t(L1, L1, L1, 0xff); break; case 4: e0 = uint8x4_t(v0, v0, v0, v2); e1 = uint8x4_t(v1, v1, v1, v3); break; case 5: bit_transfer_signed(v1, v0); bit_transfer_signed(v3, v2); e0 = uint8x4_t(v0, v0, v0, v2); e1 = uint8x4_t::clamped(v0+v1, v0+v1, v0+v1, v2+v3); break; case 6: e0 = uint8x4_t(v0*v3 >> 8, v1*v3 >> 8, v2*v3 >> 8, 0xff); e1 = uint8x4_t(v0, v1, v2, 0xff); break; case 8: s0 = v0 + v2 + v4; s1 = v1 + v3 + v5; if (s1 >= s0) { e0 = uint8x4_t(v0, v2, v4, 0xff); e1 = uint8x4_t(v1, v3, v5, 0xff); } else { e0 = blue_contract(v1, v3, v5, 0xff); e1 = blue_contract(v0, v2, v4, 0xff); } break; case 9: bit_transfer_signed(v1, v0); bit_transfer_signed(v3, v2); bit_transfer_signed(v5, v4); if (v1 + v3 + v5 >= 0) { e0 = uint8x4_t(v0, v2, v4, 0xff); e1 = uint8x4_t::clamped(v0+v1, v2+v3, v4+v5, 0xff); } else { e0 = blue_contract_clamped(v0+v1, v2+v3, v4+v5, 0xff); e1 = blue_contract(v0, v2, v4, 0xff); } break; case 10: e0 = uint8x4_t(v0*v3 >> 8, v1*v3 >> 8, v2*v3 >> 8, v4); e1 = uint8x4_t(v0, v1, v2, v5); break; case 12: s0 = v0 + v2 + v4; s1 = v1 + v3 + v5; if (s1 >= s0) { e0 = uint8x4_t(v0, v2, v4, v6); e1 = uint8x4_t(v1, v3, v5, v7); } else { e0 = blue_contract(v1, v3, v5, v7); e1 = blue_contract(v0, v2, v4, v6); } break; case 13: bit_transfer_signed(v1, v0); bit_transfer_signed(v3, v2); bit_transfer_signed(v5, v4); bit_transfer_signed(v7, v6); if (v1 + v3 + v5 >= 0) { e0 = uint8x4_t(v0, v2, v4, v6); e1 = uint8x4_t::clamped(v0+v1, v2+v3, v4+v5, v6+v7); } else { e0 = blue_contract_clamped(v0+v1, v2+v3, v4+v5, v6+v7); e1 = blue_contract(v0, v2, v4, v6); } break; default: /* HDR endpoints not supported; return error colour */ e0 = uint8x4_t(255, 0, 255, 255); e1 = uint8x4_t(255, 0, 255, 255); break; } endpoints_decoded[0][part] = e0; endpoints_decoded[1][part] = e1; if (VERBOSE_DECODE) { printf("cems[%d]=%d v=[", part, cems[part]); for (int i = 0; i < (cems[part] >> 2) + 1; ++i) { if (i) printf(", "); printf("%3d", v[i]); } printf("] e0=[%3d,%4d,%4d,%4d] e1=[%3d,%4d,%4d,%4d]\n", e0.v[0], e0.v[1], e0.v[2], e0.v[3], e1.v[0], e1.v[1], e1.v[2], e1.v[3]); } } } void Block::unpack_weights(InputBitVector in) { if (wt_trits) { int offset = 128; int bits_left = weight_bits; for (int i = 0; i < num_weights; i += 5) { int bits_to_read = MIN2(bits_left, 8 + 5*wt_bits); /* If wt_trits then wt_bits <= 3, so bits_to_read <= 23 and we can use uint32_t */ uint32_t raw = in.get_bits_rev(offset, bits_to_read); unpack_trit_block(wt_bits, raw, &weights_quant[i]); if (VERBOSE_DECODE) in.printf_bits(offset - bits_to_read, bits_to_read, "weight trits [%d,%d,%d,%d,%d]", weights_quant[i+0], weights_quant[i+1], weights_quant[i+2], weights_quant[i+3], weights_quant[i+4]); offset -= 8 + wt_bits * 5; bits_left -= 8 + wt_bits * 5; } } else if (wt_quints) { int offset = 128; int bits_left = weight_bits; for (int i = 0; i < num_weights; i += 3) { int bits_to_read = MIN2(bits_left, 7 + 3*wt_bits); /* If wt_quints then wt_bits <= 2, so bits_to_read <= 13 and we can use uint32_t */ uint32_t raw = in.get_bits_rev(offset, bits_to_read); unpack_quint_block(wt_bits, raw, &weights_quant[i]); if (VERBOSE_DECODE) in.printf_bits(offset - bits_to_read, bits_to_read, "weight quints [%d,%d,%d]", weights_quant[i], weights_quant[i+1], weights_quant[i+2]); offset -= 7 + wt_bits * 3; bits_left -= 7 + wt_bits * 3; } } else { int offset = 128; assert((weight_bits % wt_bits) == 0); for (int i = 0; i < num_weights; ++i) { weights_quant[i] = in.get_bits_rev(offset, wt_bits); if (VERBOSE_DECODE) in.printf_bits(offset - wt_bits, wt_bits, "weight bits [%d]", weights_quant[i]); offset -= wt_bits; } } } void Block::unquantise_weights() { assert(num_weights <= (int)ARRAY_SIZE(weights_quant)); assert(num_weights <= (int)ARRAY_SIZE(weights)); memset(weights, 0, sizeof(weights)); for (int i = 0; i < num_weights; ++i) { uint8_t v = weights_quant[i]; uint8_t w; if (wt_trits) { if (wt_bits == 0) { w = v * 32; } else { uint8_t A, B, C, D; A = (v & 0x1) ? 0x7F : 0x00; switch (wt_bits) { case 1: B = 0; C = 50; D = v >> 1; break; case 2: B = (v & 0x2) ? 0x45 : 0x00; C = 23; D = v >> 2; break; case 3: B = ((v & 0x6) >> 1) | ((v & 0x6) << 4); C = 11; D = v >> 3; break; default: unreachable(""); } uint16_t T = D * C + B; T = T ^ A; T = (A & 0x20) | (T >> 2); assert(T < 64); if (T > 32) T++; w = T; } } else if (wt_quints) { if (wt_bits == 0) { w = v * 16; } else { uint8_t A, B, C, D; A = (v & 0x1) ? 0x7F : 0x00; switch (wt_bits) { case 1: B = 0; C = 28; D = v >> 1; break; case 2: B = (v & 0x2) ? 0x42 : 0x00; C = 13; D = v >> 2; break; default: unreachable(""); } uint16_t T = D * C + B; T = T ^ A; T = (A & 0x20) | (T >> 2); assert(T < 64); if (T > 32) T++; w = T; } weights[i] = w; } else { switch (wt_bits) { case 1: w = v ? 0x3F : 0x00; break; case 2: w = v | (v << 2) | (v << 4); break; case 3: w = v | (v << 3); break; case 4: w = (v >> 2) | (v << 2); break; case 5: w = (v >> 4) | (v << 1); break; default: unreachable(""); } assert(w < 64); if (w > 32) w++; } weights[i] = w; } } void Block::compute_infill_weights(int block_w, int block_h, int block_d) { int Ds = block_w <= 1 ? 0 : (1024 + block_w / 2) / (block_w - 1); int Dt = block_h <= 1 ? 0 : (1024 + block_h / 2) / (block_h - 1); int Dr = block_d <= 1 ? 0 : (1024 + block_d / 2) / (block_d - 1); for (int r = 0; r < block_d; ++r) { for (int t = 0; t < block_h; ++t) { for (int s = 0; s < block_w; ++s) { int cs = Ds * s; int ct = Dt * t; int cr = Dr * r; int gs = (cs * (wt_w - 1) + 32) >> 6; int gt = (ct * (wt_h - 1) + 32) >> 6; int gr = (cr * (wt_d - 1) + 32) >> 6; assert(gs >= 0 && gs <= 176); assert(gt >= 0 && gt <= 176); assert(gr >= 0 && gr <= 176); int js = gs >> 4; int fs = gs & 0xf; int jt = gt >> 4; int ft = gt & 0xf; int jr = gr >> 4; int fr = gr & 0xf; /* TODO: 3D */ (void)jr; (void)fr; int w11 = (fs * ft + 8) >> 4; int w10 = ft - w11; int w01 = fs - w11; int w00 = 16 - fs - ft + w11; if (dual_plane) { int p00, p01, p10, p11, i0, i1; int v0 = js + jt * wt_w; p00 = weights[(v0) * 2]; p01 = weights[(v0 + 1) * 2]; p10 = weights[(v0 + wt_w) * 2]; p11 = weights[(v0 + wt_w + 1) * 2]; i0 = (p00*w00 + p01*w01 + p10*w10 + p11*w11 + 8) >> 4; p00 = weights[(v0) * 2 + 1]; p01 = weights[(v0 + 1) * 2 + 1]; p10 = weights[(v0 + wt_w) * 2 + 1]; p11 = weights[(v0 + wt_w + 1) * 2 + 1]; assert((v0 + wt_w + 1) * 2 + 1 < (int)ARRAY_SIZE(weights)); i1 = (p00*w00 + p01*w01 + p10*w10 + p11*w11 + 8) >> 4; assert(0 <= i0 && i0 <= 64); infill_weights[0][s + t*block_w + r*block_w*block_h] = i0; infill_weights[1][s + t*block_w + r*block_w*block_h] = i1; } else { int p00, p01, p10, p11, i; int v0 = js + jt * wt_w; p00 = weights[v0]; p01 = weights[v0 + 1]; p10 = weights[v0 + wt_w]; p11 = weights[v0 + wt_w + 1]; assert(v0 + wt_w + 1 < (int)ARRAY_SIZE(weights)); i = (p00*w00 + p01*w01 + p10*w10 + p11*w11 + 8) >> 4; assert(0 <= i && i <= 64); infill_weights[0][s + t*block_w + r*block_w*block_h] = i; } } } } } void Block::unquantise_colour_endpoints() { assert(num_cem_values <= (int)ARRAY_SIZE(colour_endpoints_quant)); assert(num_cem_values <= (int)ARRAY_SIZE(colour_endpoints)); for (int i = 0; i < num_cem_values; ++i) { uint8_t v = colour_endpoints_quant[i]; if (ce_trits) { uint16_t A, B, C, D; uint16_t t; A = (v & 0x1) ? 0x1FF : 0x000; switch (ce_bits) { case 1: B = 0; C = 204; D = v >> 1; break; case 2: B = (v & 0x2) ? 0x116 : 0x000; C = 93; D = v >> 2; break; case 3: t = ((v >> 1) & 0x3); B = t | (t << 2) | (t << 7); C = 44; D = v >> 3; break; case 4: t = ((v >> 1) & 0x7); B = t | (t << 6); C = 22; D = v >> 4; break; case 5: t = ((v >> 1) & 0xF); B = (t >> 2) | (t << 5); C = 11; D = v >> 5; break; case 6: B = ((v & 0x3E) << 3) | ((v >> 5) & 0x1); C = 5; D = v >> 6; break; default: unreachable(""); } uint16_t T = D * C + B; T = T ^ A; T = (A & 0x80) | (T >> 2); assert(T < 256); colour_endpoints[i] = T; } else if (ce_quints) { uint16_t A, B, C, D; uint16_t t; A = (v & 0x1) ? 0x1FF : 0x000; switch (ce_bits) { case 1: B = 0; C = 113; D = v >> 1; break; case 2: B = (v & 0x2) ? 0x10C : 0x000; C = 54; D = v >> 2; break; case 3: t = ((v >> 1) & 0x3); B = (t >> 1) | (t << 1) | (t << 7); C = 26; D = v >> 3; break; case 4: t = ((v >> 1) & 0x7); B = (t >> 1) | (t << 6); C = 13; D = v >> 4; break; case 5: t = ((v >> 1) & 0xF); B = (t >> 4) | (t << 5); C = 6; D = v >> 5; break; default: unreachable(""); } uint16_t T = D * C + B; T = T ^ A; T = (A & 0x80) | (T >> 2); assert(T < 256); colour_endpoints[i] = T; } else { switch (ce_bits) { case 1: v = v ? 0xFF : 0x00; break; case 2: v = (v << 6) | (v << 4) | (v << 2) | v; break; case 3: v = (v << 5) | (v << 2) | (v >> 1); break; case 4: v = (v << 4) | v; break; case 5: v = (v << 3) | (v >> 2); break; case 6: v = (v << 2) | (v >> 4); break; case 7: v = (v << 1) | (v >> 6); break; case 8: break; default: unreachable(""); } colour_endpoints[i] = v; } } } decode_error::type Block::decode(const Decoder &decoder, InputBitVector in) { decode_error::type err; is_error = false; bogus_colour_endpoints = false; bogus_weights = false; is_void_extent = false; wt_d = 1; /* TODO: 3D */ /* TODO: test for all the illegal encodings */ if (VERBOSE_DECODE) in.printf_bits(0, 128); err = decode_block_mode(in); if (err != decode_error::ok) return err; if (is_void_extent) return decode_error::ok; /* TODO: 3D */ calculate_from_weights(); if (VERBOSE_DECODE) printf("weights_grid=%dx%dx%d dual_plane=%d num_weights=%d high_prec=%d r=%d range=0..%d (%dt %dq %db) weight_bits=%d\n", wt_w, wt_h, wt_d, dual_plane, num_weights, high_prec, wt_range, wt_max, wt_trits, wt_quints, wt_bits, weight_bits); if (wt_w > decoder.block_w || wt_h > decoder.block_h || wt_d > decoder.block_d) return decode_error::weight_grid_exceeds_block_size; num_parts = in.get_bits(11, 2) + 1; if (VERBOSE_DECODE) in.printf_bits(11, 2, "partitions = %d", num_parts); if (dual_plane && num_parts > 3) return decode_error::dual_plane_and_too_many_partitions; decode_cem(in); if (VERBOSE_DECODE) printf("cem=[%d,%d,%d,%d] base_cem_class=%d\n", cems[0], cems[1], cems[2], cems[3], cem_base_class); int num_cem_pairs = (cem_base_class + 1) * num_parts + extra_cem_bits; num_cem_values = num_cem_pairs * 2; calculate_remaining_bits(); err = calculate_colour_endpoints_size(); if (err != decode_error::ok) return err; if (VERBOSE_DECODE) in.printf_bits(colour_endpoint_data_offset, colour_endpoint_bits, "endpoint data (%d bits, %d vals, %dt %dq %db)", colour_endpoint_bits, num_cem_values, ce_trits, ce_quints, ce_bits); unpack_colour_endpoints(in); if (VERBOSE_DECODE) { printf("cem values raw =["); for (int i = 0; i < num_cem_values; i++) { if (i) printf(", "); printf("%3d", colour_endpoints_quant[i]); } printf("]\n"); } if (num_cem_values > 18) return decode_error::invalid_colour_endpoints_count; unquantise_colour_endpoints(); if (VERBOSE_DECODE) { printf("cem values norm=["); for (int i = 0; i < num_cem_values; i++) { if (i) printf(", "); printf("%3d", colour_endpoints[i]); } printf("]\n"); } decode_colour_endpoints(); if (dual_plane) { int ccs_offset = 128 - weight_bits - num_extra_cem_bits - 2; colour_component_selector = in.get_bits(ccs_offset, 2); if (VERBOSE_DECODE) in.printf_bits(ccs_offset, 2, "colour component selector = %d", colour_component_selector); } else { colour_component_selector = 0; } if (VERBOSE_DECODE) in.printf_bits(128 - weight_bits, weight_bits, "weights (%d bits)", weight_bits); if (num_weights > 64) return decode_error::invalid_num_weights; if (weight_bits < 24 || weight_bits > 96) return decode_error::invalid_weight_bits; unpack_weights(in); unquantise_weights(); if (VERBOSE_DECODE) { printf("weights=["); for (int i = 0; i < num_weights; ++i) { if (i) printf(", "); printf("%d", weights[i]); } printf("]\n"); for (int plane = 0; plane <= dual_plane; ++plane) { printf("weights (plane %d):\n", plane); int i = 0; (void)i; for (int r = 0; r < wt_d; ++r) { for (int t = 0; t < wt_h; ++t) { for (int s = 0; s < wt_w; ++s) { printf("%3d", weights[i++ * (1 + dual_plane) + plane]); } printf("\n"); } if (r < wt_d - 1) printf("\n"); } } } compute_infill_weights(decoder.block_w, decoder.block_h, decoder.block_d); if (VERBOSE_DECODE) { for (int plane = 0; plane <= dual_plane; ++plane) { printf("infilled weights (plane %d):\n", plane); int i = 0; (void)i; for (int r = 0; r < decoder.block_d; ++r) { for (int t = 0; t < decoder.block_h; ++t) { for (int s = 0; s < decoder.block_w; ++s) { printf("%3d", infill_weights[plane][i++]); } printf("\n"); } if (r < decoder.block_d - 1) printf("\n"); } } } if (VERBOSE_DECODE) printf("\n"); return decode_error::ok; } void Block::write_decoded(const Decoder &decoder, uint16_t *output) { /* sRGB can only be stored as unorm8. */ assert(!decoder.srgb || decoder.output_unorm8); if (is_void_extent) { for (int idx = 0; idx < decoder.block_w*decoder.block_h*decoder.block_d; ++idx) { if (decoder.output_unorm8) { if (decoder.srgb) { output[idx*4+0] = void_extent_colour_r >> 8; output[idx*4+1] = void_extent_colour_g >> 8; output[idx*4+2] = void_extent_colour_b >> 8; } else { output[idx*4+0] = uint16_div_64k_to_half_to_unorm8(void_extent_colour_r); output[idx*4+1] = uint16_div_64k_to_half_to_unorm8(void_extent_colour_g); output[idx*4+2] = uint16_div_64k_to_half_to_unorm8(void_extent_colour_b); } output[idx*4+3] = uint16_div_64k_to_half_to_unorm8(void_extent_colour_a); } else { /* Store the color as FP16. */ output[idx*4+0] = _mesa_uint16_div_64k_to_half(void_extent_colour_r); output[idx*4+1] = _mesa_uint16_div_64k_to_half(void_extent_colour_g); output[idx*4+2] = _mesa_uint16_div_64k_to_half(void_extent_colour_b); output[idx*4+3] = _mesa_uint16_div_64k_to_half(void_extent_colour_a); } } return; } int small_block = (decoder.block_w * decoder.block_h * decoder.block_d) < 31; int idx = 0; for (int z = 0; z < decoder.block_d; ++z) { for (int y = 0; y < decoder.block_h; ++y) { for (int x = 0; x < decoder.block_w; ++x) { int partition; if (num_parts > 1) { partition = select_partition(partition_index, x, y, z, num_parts, small_block); assert(partition < num_parts); } else { partition = 0; } /* TODO: HDR */ uint8x4_t e0 = endpoints_decoded[0][partition]; uint8x4_t e1 = endpoints_decoded[1][partition]; uint16_t c0[4], c1[4]; /* Expand to 16 bits. */ if (decoder.srgb) { c0[0] = (uint16_t)((e0.v[0] << 8) | 0x80); c0[1] = (uint16_t)((e0.v[1] << 8) | 0x80); c0[2] = (uint16_t)((e0.v[2] << 8) | 0x80); c0[3] = (uint16_t)((e0.v[3] << 8) | 0x80); c1[0] = (uint16_t)((e1.v[0] << 8) | 0x80); c1[1] = (uint16_t)((e1.v[1] << 8) | 0x80); c1[2] = (uint16_t)((e1.v[2] << 8) | 0x80); c1[3] = (uint16_t)((e1.v[3] << 8) | 0x80); } else { c0[0] = (uint16_t)((e0.v[0] << 8) | e0.v[0]); c0[1] = (uint16_t)((e0.v[1] << 8) | e0.v[1]); c0[2] = (uint16_t)((e0.v[2] << 8) | e0.v[2]); c0[3] = (uint16_t)((e0.v[3] << 8) | e0.v[3]); c1[0] = (uint16_t)((e1.v[0] << 8) | e1.v[0]); c1[1] = (uint16_t)((e1.v[1] << 8) | e1.v[1]); c1[2] = (uint16_t)((e1.v[2] << 8) | e1.v[2]); c1[3] = (uint16_t)((e1.v[3] << 8) | e1.v[3]); } int w[4]; if (dual_plane) { int w0 = infill_weights[0][idx]; int w1 = infill_weights[1][idx]; w[0] = w[1] = w[2] = w[3] = w0; w[colour_component_selector] = w1; } else { int w0 = infill_weights[0][idx]; w[0] = w[1] = w[2] = w[3] = w0; } /* Interpolate to produce UNORM16, applying weights. */ uint16_t c[4] = { (uint16_t)((c0[0] * (64 - w[0]) + c1[0] * w[0] + 32) >> 6), (uint16_t)((c0[1] * (64 - w[1]) + c1[1] * w[1] + 32) >> 6), (uint16_t)((c0[2] * (64 - w[2]) + c1[2] * w[2] + 32) >> 6), (uint16_t)((c0[3] * (64 - w[3]) + c1[3] * w[3] + 32) >> 6), }; if (decoder.output_unorm8) { if (decoder.srgb) { output[idx*4+0] = c[0] >> 8; output[idx*4+1] = c[1] >> 8; output[idx*4+2] = c[2] >> 8; } else { output[idx*4+0] = c[0] == 65535 ? 0xff : uint16_div_64k_to_half_to_unorm8(c[0]); output[idx*4+1] = c[1] == 65535 ? 0xff : uint16_div_64k_to_half_to_unorm8(c[1]); output[idx*4+2] = c[2] == 65535 ? 0xff : uint16_div_64k_to_half_to_unorm8(c[2]); } output[idx*4+3] = c[3] == 65535 ? 0xff : uint16_div_64k_to_half_to_unorm8(c[3]); } else { /* Store the color as FP16. */ output[idx*4+0] = c[0] == 65535 ? FP16_ONE : _mesa_uint16_div_64k_to_half(c[0]); output[idx*4+1] = c[1] == 65535 ? FP16_ONE : _mesa_uint16_div_64k_to_half(c[1]); output[idx*4+2] = c[2] == 65535 ? FP16_ONE : _mesa_uint16_div_64k_to_half(c[2]); output[idx*4+3] = c[3] == 65535 ? FP16_ONE : _mesa_uint16_div_64k_to_half(c[3]); } idx++; } } } } void Block::calculate_from_weights() { wt_trits = 0; wt_quints = 0; wt_bits = 0; switch (high_prec) { case 0: switch (wt_range) { case 0x2: wt_max = 1; wt_bits = 1; break; case 0x3: wt_max = 2; wt_trits = 1; break; case 0x4: wt_max = 3; wt_bits = 2; break; case 0x5: wt_max = 4; wt_quints = 1; break; case 0x6: wt_max = 5; wt_trits = 1; wt_bits = 1; break; case 0x7: wt_max = 7; wt_bits = 3; break; default: abort(); } break; case 1: switch (wt_range) { case 0x2: wt_max = 9; wt_quints = 1; wt_bits = 1; break; case 0x3: wt_max = 11; wt_trits = 1; wt_bits = 2; break; case 0x4: wt_max = 15; wt_bits = 4; break; case 0x5: wt_max = 19; wt_quints = 1; wt_bits = 2; break; case 0x6: wt_max = 23; wt_trits = 1; wt_bits = 3; break; case 0x7: wt_max = 31; wt_bits = 5; break; default: abort(); } break; } assert(wt_trits || wt_quints || wt_bits); num_weights = wt_w * wt_h * wt_d; if (dual_plane) num_weights *= 2; weight_bits = (num_weights * 8 * wt_trits + 4) / 5 + (num_weights * 7 * wt_quints + 2) / 3 + num_weights * wt_bits; } void Block::calculate_remaining_bits() { int config_bits; if (num_parts > 1) { if (!is_multi_cem) config_bits = 29; else config_bits = 25 + 3 * num_parts; } else { config_bits = 17; } if (dual_plane) config_bits += 2; remaining_bits = 128 - config_bits - weight_bits; } decode_error::type Block::calculate_colour_endpoints_size() { /* Specified as illegal */ if (remaining_bits < (13 * num_cem_values + 4) / 5) { colour_endpoint_bits = ce_max = ce_trits = ce_quints = ce_bits = 0; return decode_error::invalid_colour_endpoints_size; } /* Find the largest cem_ranges that fits within remaining_bits */ for (int i = ARRAY_SIZE(cem_ranges)-1; i >= 0; --i) { int cem_bits; cem_bits = (num_cem_values * 8 * cem_ranges[i].t + 4) / 5 + (num_cem_values * 7 * cem_ranges[i].q + 2) / 3 + num_cem_values * cem_ranges[i].b; if (cem_bits <= remaining_bits) { colour_endpoint_bits = cem_bits; ce_max = cem_ranges[i].max; ce_trits = cem_ranges[i].t; ce_quints = cem_ranges[i].q; ce_bits = cem_ranges[i].b; return decode_error::ok; } } assert(0); return decode_error::invalid_colour_endpoints_size; } /** * Decode ASTC 2D LDR texture data. * * \param src_width in pixels * \param src_height in pixels * \param dst_stride in bytes */ extern "C" void _mesa_unpack_astc_2d_ldr(uint8_t *dst_row, unsigned dst_stride, const uint8_t *src_row, unsigned src_stride, unsigned src_width, unsigned src_height, mesa_format format) { assert(_mesa_is_format_astc_2d(format)); bool srgb = _mesa_is_format_srgb(format); unsigned blk_w, blk_h; _mesa_get_format_block_size(format, &blk_w, &blk_h); const unsigned block_size = 16; unsigned x_blocks = (src_width + blk_w - 1) / blk_w; unsigned y_blocks = (src_height + blk_h - 1) / blk_h; Decoder dec(blk_w, blk_h, 1, srgb, true); for (unsigned y = 0; y < y_blocks; ++y) { for (unsigned x = 0; x < x_blocks; ++x) { /* Same size as the largest block. */ uint16_t block_out[12 * 12 * 4]; dec.decode(src_row + x * block_size, block_out); /* This can be smaller with NPOT dimensions. */ unsigned dst_blk_w = MIN2(blk_w, src_width - x*blk_w); unsigned dst_blk_h = MIN2(blk_h, src_height - y*blk_h); for (unsigned sub_y = 0; sub_y < dst_blk_h; ++sub_y) { for (unsigned sub_x = 0; sub_x < dst_blk_w; ++sub_x) { uint8_t *dst = dst_row + sub_y * dst_stride + (x * blk_w + sub_x) * 4; const uint16_t *src = &block_out[(sub_y * blk_w + sub_x) * 4]; dst[0] = src[0]; dst[1] = src[1]; dst[2] = src[2]; dst[3] = src[3]; } } } src_row += src_stride; dst_row += dst_stride * blk_h; } }