/* Copyright (c) 2018, June McEnroe * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #include #include #include #include #include #include #include #include #include #include #include #define PACKED __attribute__((packed)) #define CRC_INIT (crc32(0, Z_NULL, 0)) static const char *path; static FILE *file; static uint32_t crc; static void readExpect(void *ptr, size_t size, const char *expect) { fread(ptr, size, 1, file); if (ferror(file)) err(EX_IOERR, "%s", path); if (feof(file)) errx(EX_DATAERR, "%s: missing %s", path, expect); crc = crc32(crc, ptr, size); } static void writeExpect(const void *ptr, size_t size) { fwrite(ptr, size, 1, file); if (ferror(file)) err(EX_IOERR, "%s", path); crc = crc32(crc, ptr, size); } static const uint8_t Signature[8] = "\x89PNG\r\n\x1A\n"; static void readSignature(void) { uint8_t signature[8]; readExpect(signature, 8, "signature"); if (0 != memcmp(signature, Signature, 8)) { errx(EX_DATAERR, "%s: invalid signature", path); } } static void writeSignature(void) { writeExpect(Signature, sizeof(Signature)); } struct PACKED Chunk { uint32_t size; char type[4]; }; static const char *typeStr(struct Chunk chunk) { static char buf[5]; memcpy(buf, chunk.type, 4); return buf; } static struct Chunk readChunk(void) { struct Chunk chunk; readExpect(&chunk, sizeof(chunk), "chunk"); chunk.size = ntohl(chunk.size); crc = crc32(CRC_INIT, (Byte *)chunk.type, sizeof(chunk.type)); return chunk; } static void writeChunk(struct Chunk chunk) { chunk.size = htonl(chunk.size); writeExpect(&chunk, sizeof(chunk)); crc = crc32(CRC_INIT, (Byte *)chunk.type, sizeof(chunk.type)); } static void readCrc(void) { uint32_t expected = crc; uint32_t found; readExpect(&found, sizeof(found), "CRC32"); found = ntohl(found); if (found != expected) { errx( EX_DATAERR, "%s: expected CRC32 %08X, found %08X", path, expected, found ); } } static void writeCrc(void) { uint32_t net = htonl(crc); writeExpect(&net, sizeof(net)); } static void skipChunk(struct Chunk chunk) { uint8_t discard[chunk.size]; readExpect(discard, sizeof(discard), "chunk data"); readCrc(); } static struct PACKED { uint32_t width; uint32_t height; uint8_t depth; enum PACKED { Grayscale = 0, Truecolor = 2, Indexed = 3, GrayscaleAlpha = 4, TruecolorAlpha = 6, } color; uint8_t compression; uint8_t filter; uint8_t interlace; } header; static_assert(13 == sizeof(header), "header size"); static size_t lineSize(void) { switch (header.color) { case Grayscale: return (header.width * 1 * header.depth + 7) / 8; case Truecolor: return (header.width * 3 * header.depth + 7) / 8; case Indexed: return (header.width * 1 * header.depth + 7) / 8; case GrayscaleAlpha: return (header.width * 2 * header.depth + 7) / 8; case TruecolorAlpha: return (header.width * 4 * header.depth + 7) / 8; default: abort(); } } static size_t dataSize(void) { return (1 + lineSize()) * header.height; } static void readHeader(void) { struct Chunk ihdr = readChunk(); if (0 != memcmp(ihdr.type, "IHDR", 4)) { errx(EX_DATAERR, "%s: expected IHDR, found %s", path, typeStr(ihdr)); } if (ihdr.size != sizeof(header)) { errx( EX_DATAERR, "%s: expected IHDR size %zu, found %u", path, sizeof(header), ihdr.size ); } readExpect(&header, sizeof(header), "header"); readCrc(); header.width = ntohl(header.width); header.height = ntohl(header.height); if (!header.width) errx(EX_DATAERR, "%s: invalid width 0", path); if (!header.height) errx(EX_DATAERR, "%s: invalid height 0", path); } static void writeHeader(void) { struct Chunk ihdr = { .size = sizeof(header), .type = "IHDR" }; writeChunk(ihdr); header.width = htonl(header.width); header.height = htonl(header.height); writeExpect(&header, sizeof(header)); writeCrc(); header.width = ntohl(header.width); header.height = ntohl(header.height); } static struct { uint32_t len; uint8_t entries[256][3]; } palette; static void readPalette(void) { struct Chunk chunk; for (;;) { chunk = readChunk(); if (0 == memcmp(chunk.type, "PLTE", 4)) break; skipChunk(chunk); } palette.len = chunk.size / 3; readExpect(palette.entries, chunk.size, "palette data"); readCrc(); } static void writePalette(void) { struct Chunk plte = { .size = 3 * palette.len, .type = "PLTE" }; writeChunk(plte); writeExpect(palette.entries, plte.size); writeCrc(); } static uint8_t *data; static void readData(void) { data = malloc(dataSize()); if (!data) err(EX_OSERR, "malloc(%zu)", dataSize()); struct z_stream_s stream = { .next_out = data, .avail_out = dataSize() }; int error = inflateInit(&stream); if (error != Z_OK) errx(EX_SOFTWARE, "%s: inflateInit: %s", path, stream.msg); for (;;) { struct Chunk chunk = readChunk(); if (0 == memcmp(chunk.type, "IDAT", 4)) { uint8_t *idat = malloc(chunk.size); if (!idat) err(EX_OSERR, "malloc"); readExpect(idat, chunk.size, "image data"); readCrc(); stream.next_in = idat; stream.avail_in = chunk.size; int error = inflate(&stream, Z_SYNC_FLUSH); free(idat); if (error == Z_STREAM_END) break; if (error != Z_OK) errx(EX_DATAERR, "%s: inflate: %s", path, stream.msg); } else if (0 == memcmp(chunk.type, "IEND", 4)) { errx(EX_DATAERR, "%s: missing IDAT chunk", path); } else { skipChunk(chunk); } } inflateEnd(&stream); if (stream.total_out != dataSize()) { errx( EX_DATAERR, "%s: expected data size %zu, found %lu", path, dataSize(), stream.total_out ); } } static void writeData(void) { uLong size = compressBound(dataSize()); uint8_t *deflate = malloc(size); if (!deflate) err(EX_OSERR, "malloc"); int error = compress2(deflate, &size, data, dataSize(), Z_BEST_SPEED); if (error != Z_OK) errx(EX_SOFTWARE, "%s: compress2: %d", path, error); struct Chunk idat = { .size = size, .type = "IDAT" }; writeChunk(idat); writeExpect(deflate, size); writeCrc(); free(deflate); } static void writeEnd(void) { struct Chunk iend = { .size = 0, .type = "IEND" }; writeChunk(iend); writeCrc(); } enum PACKED Filter { None, Sub, Up, Average, Paeth, FilterCount, }; static struct { bool brokenPaeth; bool filt; bool recon; uint8_t declareFilter; uint8_t applyFilter; enum Filter declareFilters[255]; enum Filter applyFilters[255]; bool invert; bool mirror; bool zeroX; bool zeroY; } options; struct Bytes { uint8_t x; uint8_t a; uint8_t b; uint8_t c; }; static uint8_t paethPredictor(struct Bytes f) { int32_t p = (int32_t)f.a + (int32_t)f.b - (int32_t)f.c; int32_t pa = abs(p - (int32_t)f.a); int32_t pb = abs(p - (int32_t)f.b); int32_t pc = abs(p - (int32_t)f.c); if (pa <= pb && pa <= pc) return f.a; if (options.brokenPaeth) { if (pb < pc) return f.b; } else { if (pb <= pc) return f.b; } return f.c; } static uint8_t recon(enum Filter type, struct Bytes f) { switch (type) { case None: return f.x; case Sub: return f.x + f.a; case Up: return f.x + f.b; case Average: return f.x + ((uint32_t)f.a + (uint32_t)f.b) / 2; case Paeth: return f.x + paethPredictor(f); default: abort(); } } static uint8_t filt(enum Filter type, struct Bytes f) { switch (type) { case None: return f.x; case Sub: return f.x - f.a; case Up: return f.x - f.b; case Average: return f.x - ((uint32_t)f.a + (uint32_t)f.b) / 2; case Paeth: return f.x - paethPredictor(f); default: abort(); } } static struct Line { enum Filter type; uint8_t data[]; } **lines; static void scanlines(void) { lines = calloc(header.height, sizeof(*lines)); if (!lines) err(EX_OSERR, "calloc(%u, %zu)", header.height, sizeof(*lines)); size_t stride = 1 + lineSize(); for (uint32_t y = 0; y < header.height; ++y) { lines[y] = (struct Line *)&data[y * stride]; if (lines[y]->type >= FilterCount) { errx(EX_DATAERR, "%s: invalid filter type %hhu", path, lines[y]->type); } } } static struct Bytes origBytes(uint32_t y, size_t i) { size_t pixelSize = lineSize() / header.width; if (!pixelSize) pixelSize = 1; bool a = (i >= pixelSize), b = (y > 0), c = (a && b); return (struct Bytes) { .x = lines[y]->data[i], .a = a ? lines[y]->data[i - pixelSize] : 0, .b = b ? lines[y - 1]->data[i] : 0, .c = c ? lines[y - 1]->data[i - pixelSize] : 0, }; } static void reconData(void) { for (uint32_t y = 0; y < header.height; ++y) { for (size_t i = 0; i < lineSize(); ++i) { if (options.filt) { lines[y]->data[i] = filt(lines[y]->type, origBytes(y, i)); } else { lines[y]->data[i] = recon(lines[y]->type, origBytes(y, i)); } } lines[y]->type = None; } } static void filterData(void) { for (uint32_t y = header.height - 1; y < header.height; --y) { uint8_t filter[FilterCount][lineSize()]; uint32_t heuristic[FilterCount] = {0}; enum Filter minType = None; for (enum Filter type = None; type < FilterCount; ++type) { for (size_t i = 0; i < lineSize(); ++i) { if (options.recon) { filter[type][i] = recon(type, origBytes(y, i)); } else { filter[type][i] = filt(type, origBytes(y, i)); } heuristic[type] += abs((int8_t)filter[type][i]); } if (heuristic[type] < heuristic[minType]) minType = type; } if (options.declareFilter) { lines[y]->type = options.declareFilters[y % options.declareFilter]; } else { lines[y]->type = minType; } if (options.applyFilter) { enum Filter type = options.applyFilters[y % options.applyFilter]; memcpy(lines[y]->data, filter[type], lineSize()); } else { memcpy(lines[y]->data, filter[minType], lineSize()); } } } static void invert(void) { for (uint32_t y = 0; y < header.height; ++y) { for (size_t i = 0; i < lineSize(); ++i) { lines[y]->data[i] ^= 0xFF; } } } static void mirror(void) { for (uint32_t y = 0; y < header.height; ++y) { for (size_t i = 0, j = lineSize() - 1; i < j; ++i, --j) { uint8_t t = lines[y]->data[i]; lines[y]->data[i] = lines[y]->data[j]; lines[y]->data[j] = t; } } } static void zeroX(void) { size_t pixelSize = lineSize() / header.width; for (uint32_t y = 0; y < header.height; ++y) { memset(lines[y]->data, 0, pixelSize); } } static void zeroY(void) { memset(lines[0]->data, 0, lineSize()); } static void glitch(const char *inPath, const char *outPath) { if (inPath) { path = inPath; file = fopen(path, "r"); if (!file) err(EX_NOINPUT, "%s", path); } else { path = "(stdin)"; file = stdin; } readSignature(); readHeader(); if (header.color == Indexed) readPalette(); readData(); fclose(file); scanlines(); reconData(); filterData(); if (options.invert) invert(); if (options.mirror) mirror(); if (options.zeroX) zeroX(); if (options.zeroY) zeroY(); free(lines); if (outPath) { path = outPath; file = fopen(path, "w"); if (!file) err(EX_CANTCREAT, "%s", path); } else { path = "(stdout)"; file = stdout; } writeSignature(); writeHeader(); if (header.color == Indexed) writePalette(); writeData(); writeEnd(); free(data); int error = fclose(file); if (error) err(EX_IOERR, "%s", path); } static enum Filter parseFilter(const char *s) { switch (s[0]) { case 'N': case 'n': return None; case 'S': case 's': return Sub; case 'U': case 'u': return Up; case 'A': case 'a': return Average; case 'P': case 'p': return Paeth; default: errx(EX_USAGE, "invalid filter type %s", s); } } static uint8_t parseFilters(enum Filter *filters, const char *s) { uint8_t len = 0; do { filters[len++] = parseFilter(s); s = strchr(s, ','); } while (s++); return len; } int main(int argc, char *argv[]) { bool stdio = false; char *output = NULL; int opt; while (0 < (opt = getopt(argc, argv, "a:cd:fimo:prxy"))) { switch (opt) { break; case 'a': options.applyFilter = parseFilters(options.applyFilters, optarg); break; case 'c': stdio = true; break; case 'd': options.declareFilter = parseFilters(options.declareFilters, optarg); break; case 'f': options.filt = true; break; case 'i': options.invert = true; break; case 'm': options.mirror = true; break; case 'o': output = optarg; break; case 'p': options.brokenPaeth = true; break; case 'r': options.recon = true; break; case 'x': options.zeroX = true; break; case 'y': options.zeroY = true; break; default: return EX_USAGE; } } if (argc - optind == 1 && (output || stdio)) { glitch(argv[optind], output); } else if (optind < argc) { for (int i = optind; i < argc; ++i) { glitch(argv[i], argv[i]); } } else { glitch(NULL, output); } return EX_OK; }