X-Git-Url: https://git.sesse.net/?a=blobdiff_plain;f=qdc.cpp;h=0339e12af0ad07ba2616530b30bd1b2012258745;hb=5e1d27014149311318e97b8e04a6e05ec858e57c;hp=f1ff2542575f866ae4de3c063b2c57acac1586f3;hpb=2161c821c9c65ebae24eff9c2e4809c11c67cd02;p=narabu diff --git a/qdc.cpp b/qdc.cpp index f1ff254..0339e12 100644 --- a/qdc.cpp +++ b/qdc.cpp @@ -23,8 +23,10 @@ #define HEIGHT_BLOCKS (HEIGHT/8) #define NUM_BLOCKS (WIDTH_BLOCKS * HEIGHT_BLOCKS) #define NUM_BLOCKS_CHROMA (WIDTH_BLOCKS_CHROMA * HEIGHT_BLOCKS) + #define NUM_SYMS 256 #define ESCAPE_LIMIT (NUM_SYMS - 1) +#define BLOCKS_PER_STREAM 320 // If you set this to 1, the program will try to optimize the placement // of coefficients to rANS probability distributions. This is randomized, @@ -214,7 +216,7 @@ public: void init_prob(SymbolStats &s) { for (int i = 0; i < NUM_SYMS; i++) { - printf("%d: cumfreqs=%d freqs=%d prob_bits=%d\n", i, s.cum_freqs[i], s.freqs[i], prob_bits + 1); + //printf("%d: cumfreqs=%d freqs=%d prob_bits=%d\n", i, s.cum_freqs[i], s.freqs[i], prob_bits + 1); RansEncSymbolInit(&esyms[i], s.cum_freqs[i], s.freqs[i], prob_bits + 1); } sign_bias = s.cum_freqs[NUM_SYMS]; @@ -233,22 +235,14 @@ public: //printf("post-flush = %08x\n", rans); uint32_t num_rans_bytes = out_end - ptr; -#if 0 - if (num_rans_bytes == 4) { - uint32_t block; - memcpy(&block, ptr, 4); - - if (block == last_block) { - write_varint(0, codedfp); - clear(); - return 1; - } - - last_block = block; + if (num_rans_bytes == last_block.size() && + memcmp(last_block.data(), ptr, last_block.size()) == 0) { + write_varint(0, codedfp); + clear(); + return 1; } else { - last_block = 0; + last_block = string((const char *)ptr, num_rans_bytes); } -#endif write_varint(num_rans_bytes, codedfp); //fwrite(&num_rans_bytes, 1, 4, codedfp); @@ -259,7 +253,7 @@ public: clear(); - printf("Saving block: %d rANS bytes\n", num_rans_bytes); + //printf("Saving block: %d rANS bytes\n", num_rans_bytes); return num_rans_bytes; //return num_rans_bytes; } @@ -292,7 +286,7 @@ private: RansEncSymbol esyms[NUM_SYMS]; uint32_t sign_bias; - uint32_t last_block = 0; // Not a valid 4-byte rANS block (?) + std::string last_block; }; static constexpr int dc_scalefac = 8; // Matches the FDCT's gain. @@ -505,6 +499,9 @@ int main(int argc, char **argv) //double last_cb_cfl_fac = 0.0; //double last_cr_cfl_fac = 0.0; + int max_val_x[8] = {0}, min_val_x[8] = {0}; + int max_val_y[8] = {0}, min_val_y[8] = {0}; + // DCT and quantize luma for (unsigned yb = 0; yb < HEIGHT; yb += 8) { for (unsigned xb = 0; xb < WIDTH; xb += 8) { @@ -525,6 +522,11 @@ int main(int argc, char **argv) int k = quantize(in_y[coeff_idx], coeff_idx); coeff_y[(yb + y) * WIDTH + (xb + x)] = k; + max_val_x[x] = std::max(max_val_x[x], k); + min_val_x[x] = std::min(min_val_x[x], k); + max_val_y[y] = std::max(max_val_y[y], k); + min_val_y[y] = std::min(min_val_y[y], k); + // Store back for reconstruction / PSNR calculation in_y[coeff_idx] = unquantize(k, coeff_idx); } @@ -720,10 +722,10 @@ int main(int argc, char **argv) #endif // DC coefficient pred from the right to left (within each slice) - for (unsigned block_idx = 0; block_idx < NUM_BLOCKS; block_idx += 320) { - int prev_k = 0; + for (unsigned block_idx = 0; block_idx < NUM_BLOCKS; block_idx += BLOCKS_PER_STREAM) { + int prev_k = 128; - for (unsigned subblock_idx = 320; subblock_idx --> 0; ) { + for (unsigned subblock_idx = BLOCKS_PER_STREAM; subblock_idx --> 0; ) { unsigned yb = (block_idx + subblock_idx) / WIDTH_BLOCKS; unsigned xb = (block_idx + subblock_idx) % WIDTH_BLOCKS; int k = coeff_y[(yb * 8) * WIDTH + (xb * 8)]; @@ -733,11 +735,11 @@ int main(int argc, char **argv) prev_k = k; } } - for (unsigned block_idx = 0; block_idx < NUM_BLOCKS_CHROMA; block_idx += 320) { + for (unsigned block_idx = 0; block_idx < NUM_BLOCKS_CHROMA; block_idx += BLOCKS_PER_STREAM) { int prev_k_cb = 0; int prev_k_cr = 0; - for (unsigned subblock_idx = 320; subblock_idx --> 0; ) { + for (unsigned subblock_idx = BLOCKS_PER_STREAM; subblock_idx --> 0; ) { unsigned yb = (block_idx + subblock_idx) / WIDTH_BLOCKS_CHROMA; unsigned xb = (block_idx + subblock_idx) % WIDTH_BLOCKS_CHROMA; int k_cb = coeff_cb[(yb * 8) * WIDTH/2 + (xb * 8)]; @@ -880,7 +882,7 @@ int main(int argc, char **argv) //printf("encoding coeff %d xb,yb=%d,%d: %d\n", y*8+x, xb, yb, k); rans_encoder.encode_coeff(k); - if (block_idx % 320 == 319 || block_idx == NUM_BLOCKS - 1) { + if (block_idx % BLOCKS_PER_STREAM == (BLOCKS_PER_STREAM - 1) || block_idx == NUM_BLOCKS - 1) { int l = rans_encoder.save_block(codedfp); num_bytes += l; lens.push_back(l); @@ -920,7 +922,7 @@ int main(int argc, char **argv) //printf("encoding coeff %d xb,yb=%d,%d: %d\n", y*8+x, xb, yb, k); rans_encoder.encode_coeff(k); - if (block_idx % 320 == 319 || block_idx == NUM_BLOCKS - 1) { + if (block_idx % BLOCKS_PER_STREAM == (BLOCKS_PER_STREAM - 1) || block_idx == NUM_BLOCKS - 1) { num_bytes += rans_encoder.save_block(codedfp); } } @@ -945,7 +947,7 @@ int main(int argc, char **argv) //printf("encoding coeff %d xb,yb=%d,%d: %d\n", y*8+x, xb, yb, k); rans_encoder.encode_coeff(k); - if (block_idx % 320 == 319 || block_idx == NUM_BLOCKS - 1) { + if (block_idx % BLOCKS_PER_STREAM == (BLOCKS_PER_STREAM - 1) || block_idx == NUM_BLOCKS - 1) { num_bytes += rans_encoder.save_block(codedfp); } } @@ -959,4 +961,18 @@ int main(int argc, char **argv) extra_bits, extra_bits / 8, tot_bytes); + +#if 0 + printf("Max coefficient ranges (as a function of x):\n\n"); + for (unsigned x = 0; x < 8; ++x) { + int range = std::max(max_val_x[x], -min_val_x[x]); + printf(" [%4d, %4d] (%.2f bits)\n", min_val_x[x], max_val_x[x], log2(range * 2 + 1)); + } + + printf("Max coefficient ranges (as a function of y):\n\n"); + for (unsigned y = 0; y < 8; ++y) { + int range = std::max(max_val_y[y], -min_val_y[y]); + printf(" [%4d, %4d] (%.2f bits)\n", min_val_y[y], max_val_y[y], log2(range * 2 + 1)); + } +#endif }