/* vim: tabstop=4 shiftwidth=4 noexpandtab * This file is part of ToaruOS and is released under the terms * of the NCSA / University of Illinois License - see LICENSE.md * Copyright (C) 2018 K. Lange * * libtoaru_jpeg: Decode simple JPEGs. * * Adapted from Raul Aguaviva's Python "micro JPEG visualizer": * * MIT License * * Copyright (c) 2017 Raul Aguaviva * * 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 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. * */ #include #include #include #include #include #include #ifndef NO_SSE #include #include #endif #if 0 #include #define TRACE_APP_NAME "jpeg" #else #define TRACE(...) #endif static sprite_t * sprite = NULL; /* Byte swap short (because JPEG uses big-endian values) */ static void swap16(uint16_t * val) { char * a = (char *)val; char b = a[0]; a[0] = a[1]; a[1] = b; } /* JPEG compontent zig-zag ordering */ static int zigzag[] = { 0, 1, 8, 16, 9, 2, 3, 10, 17, 24, 32, 25, 18, 11, 4, 5, 12, 19, 26, 33, 40, 48, 41, 34, 27, 20, 13, 6, 7, 14, 21, 28, 35, 42, 49, 56, 57, 50, 43, 36, 29, 22, 15, 23, 30, 37, 44, 51, 58, 59, 52, 45, 38, 31, 39, 46, 53, 60, 61, 54, 47, 55, 62, 63 }; static uint8_t quant_mapping[3] = {0}; static uint8_t quant[8][64]; static int clamp(int col) { if (col > 255) return 255; if (col < 0) return 0; return col; } /* YCbCr to RGB conversion */ static void color_conversion( float Y, float Cb, float Cr, int *R, int *G, int *B ) { float r = (Cr*(2.0-2.0*0.299) + Y); float b = (Cb*(2.0-2.0*0.114) + Y); float g = (Y - 0.144 * b - 0.229 * r) / 0.587; *R = clamp(r + 128); *G = clamp(g + 128); *B = clamp(b + 128); } static int xy_to_lin(int x, int y) { return x + y * 8; } struct huffman_table { uint8_t lengths[16]; uint8_t elements[256]; } huffman_tables[256] = {0}; struct stream { FILE * file; uint8_t byte; int have; int pos; }; static void define_quant_table(FILE * f, int len) { TRACE("Defining quant table"); while (len > 0) { uint8_t hdr; fread(&hdr, 1, 1, f); fread(&quant[(hdr) & 0xF], 64, 1, f); len -= 65; } TRACE("Done"); } static void baseline_dct(FILE * f, int len) { struct dct { uint8_t hdr; uint16_t height; uint16_t width; uint8_t components; } __attribute__((packed)) dct; fread(&dct, sizeof(struct dct), 1, f); /* Read image dimensions, each as big-endian 16-bit values */ uint16_t h = dct.height; uint16_t w = dct.width; swap16(&h); swap16(&w); dct.height = h; dct.width = w; /* We read 7 bytes */ len -= sizeof(struct dct); TRACE("Image dimensions are %d×%d", dct.width, dct.height); sprite->width = dct.width; sprite->height = dct.height; sprite->bitmap = malloc(sizeof(uint32_t) * sprite->width * sprite->height); sprite->masks = NULL; sprite->alpha = 0; sprite->blank = 0; TRACE("Loading quantization mappings..."); for (int i = 0; i < dct.components; ++i) { /* Quant mapping */ struct { uint8_t id; uint8_t samp; uint8_t qtb_id; } __attribute__((packed)) tmp; fread(&tmp, sizeof(tmp), 1, f); /* There should only be three of these for the images we support. */ if (i > 3) { abort(); } quant_mapping[i] = tmp.qtb_id; /* 3 bytes were read */ len -= 3; } /* Skip whatever else might be in this section */ if (len > 0) { fseek(f, len, SEEK_CUR); } } static void define_huffman_table(FILE * f, int len) { TRACE("Loading Huffman tables..."); while (len > 0) { /* Read header ID */ uint8_t hdr; fread(&hdr, 1, 1, f); len--; /* Read length table */ fread(huffman_tables[hdr].lengths, 16, 1, f); len -= 16; /* Read Huffman table entries */ int o = 0; for (int i = 0; i < 16; ++i) { int l = huffman_tables[hdr].lengths[i]; fread(&huffman_tables[hdr].elements[o], l, 1, f); o += l; len -= l; } } /* Skip rest of section */ if (len > 0) { fseek(f, len, SEEK_CUR); } } struct idct { float base[64]; }; /** * norm_coeff[0] = 0.35355339059 * norm_coeff[1] = 0.5 */ static float cosines[8][8] = { { 0.35355339059,0.35355339059,0.35355339059,0.35355339059,0.35355339059,0.35355339059,0.35355339059,0.35355339059 }, { 0.490392640202,0.415734806151,0.27778511651,0.0975451610081,-0.0975451610081,-0.27778511651,-0.415734806151,-0.490392640202 }, { 0.461939766256,0.191341716183,-0.191341716183,-0.461939766256,-0.461939766256,-0.191341716183,0.191341716183,0.461939766256 }, { 0.415734806151,-0.0975451610081,-0.490392640202,-0.27778511651,0.27778511651,0.490392640202,0.0975451610081,-0.415734806151 }, { 0.353553390593,-0.353553390593,-0.353553390593,0.353553390593,0.353553390593,-0.353553390593,-0.353553390593,0.353553390593 }, { 0.27778511651,-0.490392640202,0.0975451610081,0.415734806151,-0.415734806151,-0.0975451610081,0.490392640202,-0.27778511651 }, { 0.191341716183,-0.461939766256,0.461939766256,-0.191341716183,-0.191341716183,0.461939766256,-0.461939766256,0.191341716183 }, { 0.0975451610081,-0.27778511651,0.415734806151,-0.490392640202,0.490392640202,-0.415734806151,0.27778511651,-0.0975451610081 }, }; static float premul[8][8][8][8]= {{{{0}}}}; static void add_idc(struct idct * self, int n, int m, int coeff) { #ifdef NO_SSE for (int y = 0; y < 8; ++y) { for (int x = 0; x < 8; ++x) { self->base[xy_to_lin(x, y)] += premul[n][m][y][x] * coeff; } } #else __m128 c = _mm_set_ps(coeff,coeff,coeff,coeff); for (int y = 0; y < 8; ++y) { __m128 a, b; /* base[y][x] = base[y][x] + premul[n][m][y][x] * coeff */ /* x = 0..3 */ a = _mm_load_ps(&premul[n][m][y][0]); a = _mm_mul_ps(a,c); b = _mm_load_ps(&self->base[xy_to_lin(0,y)]); a = _mm_add_ps(a,b); _mm_store_ps(&self->base[xy_to_lin(0,y)], a); /* x = 4..7 */ a = _mm_load_ps(&premul[n][m][y][4]); a = _mm_mul_ps(a,c); b = _mm_load_ps(&self->base[xy_to_lin(4,y)]); a = _mm_add_ps(a,b); _mm_store_ps(&self->base[xy_to_lin(4,y)], a); } #endif } static void add_zigzag(struct idct * self, int zi, int coeff) { int i = zigzag[zi]; int n = i & 0x7; int m = i >> 3; add_idc(self, n, m, coeff); } /* Read a bit from the stream */ static int get_bit(struct stream * st) { while ((st->pos >> 3) >= st->have) { /* We have finished using the current byte and need to read another one */ int t = fgetc(st->file); if (t < 0) { /* EOF */ st->byte = 0; } else { st->byte = t; } if (st->byte == 0xFF) { /* * If we see 0xFF, it's followed by a 0x00 * that should be skipped. */ int tmp = fgetc(st->file); if (tmp != 0) { /* * If it's *not*, we reached the end of the file - but * this shouldn't happen. */ st->byte = 0; } } /* We've seen a new byte */ st->have++; } /* Extract appropriate bit from this byte */ uint8_t b = st->byte; int s = 7 - (st->pos & 0x7); /* We move forward one position in the bit stream */ st->pos += 1; return (b >> s) & 1; } /* Advance forward and get the n'th next bit */ static int get_bitn(struct stream * st, int l) { int val = 0; for (int i = 0; i < l; ++i) { val = val * 2 + get_bit(st); } return val; } /* * Read a Huffman code by reading bits and using * the Huffman table. */ static int get_code(struct huffman_table * table, struct stream * st) { int val = 0; int off = 0; int ini = 0; for (int i = 0; i < 16; ++i) { val = val * 2 + get_bit(st); if (table->lengths[i] > 0) { if (val - ini < table->lengths[i]) { return table->elements[off + val - ini]; } ini = ini + table->lengths[i]; off += table->lengths[i]; } ini *= 2; } /* Invalid */ return -1; } /* Decode Huffman codes to values */ static int decode(int code, int bits) { int l = 1L << (code - 1); if (bits >= l) { return bits; } else { return bits - (2 * l - 1); } } /* Build IDCT matrix */ static struct idct * build_matrix(struct idct * i, struct stream * st, int idx, uint8_t * quant, int oldcoeff, int * outcoeff) { memset(i, 0, sizeof(struct idct)); int code = get_code(&huffman_tables[idx], st); int bits = get_bitn(st, code); int dccoeff = decode(code, bits) + oldcoeff; add_zigzag(i, 0, dccoeff * quant[0]); int l = 1; while (l < 64) { code = get_code(&huffman_tables[16+idx], st); if (code == 0) break; if (code > 15) { l += (code >> 4); code = code & 0xF; } bits = get_bitn(st, code); int coeff = decode(code, bits); add_zigzag(i, l, coeff * quant[l]); l += 1; } *outcoeff = dccoeff; return i; } /* Set pixel in sprite buffer with bounds checking */ static void set_pixel(int x, int y, uint32_t color) { if ((x < sprite->width) && (y < sprite->height)) { SPRITE(sprite,x,y) = color; } } /* Concvert YCbCr values to RGB pixels */ static void draw_matrix(int x, int y, struct idct * L, struct idct * cb, struct idct * cr) { for (int yy = 0; yy < 8; ++yy) { for (int xx = 0; xx < 8; ++xx) { int o = xy_to_lin(xx,yy); int r, g, b; color_conversion(L->base[o], cb->base[o], cr->base[o], &r, &g, &b); uint32_t c = 0xFF000000 | (r << 16) | (g << 8) | b; set_pixel((x * 8 + xx), (y * 8 + yy), c); } } } static void start_of_scan(FILE * f, int len) { TRACE("Reading image data"); /* Skip header */ fseek(f, len, SEEK_CUR); /* Initialize bit stream */ struct stream _st = {0}; _st.file = f; struct stream * st = &_st; int old_lum = 0; int old_crd = 0; int old_cbd = 0; for (int y = 0; y < sprite->height / 8 + !!(sprite->height & 0x7); ++y) { TRACE("Star row %d", y ); for (int x = 0; x < sprite->width / 8 + !!(sprite->width & 0x7); ++x) { if (y >= 134) { TRACE("Start col %d", x); } /* Build matrices */ struct idct matL, matCr, matCb; build_matrix(&matL, st, 0, quant[quant_mapping[0]], old_lum, &old_lum); build_matrix(&matCb, st, 1, quant[quant_mapping[1]], old_cbd, &old_cbd); build_matrix(&matCr, st, 1, quant[quant_mapping[2]], old_crd, &old_crd); if (y >= 134) { TRACE("Draw col %d", x); } draw_matrix(x, y, &matL, &matCb, &matCr); } } TRACE("Done."); } int load_sprite_jpg(sprite_t * tsprite, char * filename) { FILE * f = fopen(filename, "r"); if (!f) { return 1; } sprite = tsprite; memset(huffman_tables, 0, sizeof(huffman_tables)); if (premul[0][0][0][0] == 0.0) { for (int n = 0; n < 8; ++n) { for (int m = 0; m < 8; ++m) { for (int y = 0; y < 8; ++y) { for (int x = 0; x < 8; ++x) { premul[n][m][y][x] = cosines[n][x] * cosines[m][y]; } } } } } while (1) { /* Read a header */ uint16_t hdr; int r = fread(&hdr, 2, 1, f); if (r <= 0) { /* EOF */ break; } /* These headers are stored big-endian */ swap16(&hdr); if (hdr == 0xffd8) { /* No data */ continue; } else if (hdr == 0xffd9) { /* End of file */ break; } else { /* Regular sections with data start with a length */ uint16_t len; fread(&len, 2, 1, f); swap16(&len); /* Subtract two because the length includes itself */ len -= 2; if (hdr == 0xffdb) { define_quant_table(f, len); } else if (hdr == 0xffc0) { baseline_dct(f, len); } else if (hdr == 0xffc4) { define_huffman_table(f, len); } else if (hdr == 0xffda) { start_of_scan(f, len); /* End immediately after reading the data */ break; } else { TRACE("Unknown header\n"); fseek(f, len, SEEK_CUR); } } } fclose(f); return 0; }