/* SPDX-License-Identifier: (BSD-2-Clause AND libpng-2.0) */ #define SPNG__BUILD #include "spng.h" #include #include #include #include #define ZLIB_CONST #ifdef __FRAMAC__ #define SPNG_DISABLE_OPT #include "tests/framac_stubs.h" #else #ifdef SPNG_USE_MINIZ #include #else #include #endif #endif #ifdef SPNG_MULTITHREADING #include #endif /* Not build options, edit at your own risk! */ #define SPNG_READ_SIZE (8192) #define SPNG_WRITE_SIZE SPNG_READ_SIZE #define SPNG_MAX_CHUNK_COUNT (1000) #define SPNG_TARGET_CLONES(x) #ifndef SPNG_DISABLE_OPT #if defined(__i386__) || defined(__x86_64__) || defined(_M_IX86) || defined(_M_X64) #define SPNG_X86 #if defined(__x86_64__) || defined(_M_X64) #define SPNG_X86_64 #endif #elif defined(__aarch64__) || defined(_M_ARM64) /* || defined(__ARM_NEON) */ #define SPNG_ARM /* NOTE: only arm64 builds are tested! */ #else #pragma message "disabling SIMD optimizations for unknown target" #define SPNG_DISABLE_OPT #endif #if defined(SPNG_X86_64) && defined(SPNG_ENABLE_TARGET_CLONES) #undef SPNG_TARGET_CLONES #define SPNG_TARGET_CLONES(x) __attribute__((target_clones(x))) #else #define SPNG_TARGET_CLONES(x) #endif #ifndef SPNG_DISABLE_OPT static void defilter_sub3(size_t rowbytes, unsigned char *row); static void defilter_sub4(size_t rowbytes, unsigned char *row); static void defilter_avg3(size_t rowbytes, unsigned char *row, const unsigned char *prev); static void defilter_avg4(size_t rowbytes, unsigned char *row, const unsigned char *prev); static void defilter_paeth3(size_t rowbytes, unsigned char *row, const unsigned char *prev); static void defilter_paeth4(size_t rowbytes, unsigned char *row, const unsigned char *prev); #if defined(SPNG_ARM) static uint32_t expand_palette_rgba8_neon(unsigned char *row, const unsigned char *scanline, const unsigned char *plte, uint32_t width); static uint32_t expand_palette_rgb8_neon(unsigned char *row, const unsigned char *scanline, const unsigned char *plte, uint32_t width); #endif #endif #endif #if defined(_MSC_VER) #pragma warning(push) #pragma warning(disable: 4244) #endif #if (defined(__BYTE_ORDER__) && __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__) || defined(__BIG_ENDIAN__) #define SPNG_BIG_ENDIAN #else #define SPNG_LITTLE_ENDIAN #endif enum spng_state { SPNG_STATE_INVALID = 0, SPNG_STATE_INIT = 1, /* No PNG buffer/stream is set */ SPNG_STATE_INPUT, /* Decoder input PNG was set */ SPNG_STATE_OUTPUT = SPNG_STATE_INPUT, /* Encoder output was set */ SPNG_STATE_IHDR, /* IHDR was read/written */ SPNG_STATE_FIRST_IDAT, /* Encoded up to / reached first IDAT */ SPNG_STATE_DECODE_INIT, /* Decoder is ready for progressive reads */ SPNG_STATE_ENCODE_INIT = SPNG_STATE_DECODE_INIT, SPNG_STATE_EOI, /* Reached the last scanline/row */ SPNG_STATE_LAST_IDAT, /* Reached last IDAT, set at end of decode_image() */ SPNG_STATE_AFTER_IDAT, /* */ SPNG_STATE_IEND, /* Reached IEND */ }; enum spng__internal { SPNG__IO_SIGNAL = 1 << 9, SPNG__CTX_FLAGS_ALL = (SPNG_CTX_IGNORE_ADLER32 | SPNG_CTX_ENCODER) }; #define SPNG_STR(x) _SPNG_STR(x) #define _SPNG_STR(x) #x #define SPNG_VERSION_STRING SPNG_STR(SPNG_VERSION_MAJOR) "." \ SPNG_STR(SPNG_VERSION_MINOR) "." \ SPNG_STR(SPNG_VERSION_PATCH) #define SPNG_GET_CHUNK_BOILERPLATE(chunk) \ if(ctx == NULL) return 1; \ int ret = read_chunks(ctx, 0); \ if(ret) return ret; \ if(!ctx->stored.chunk) return SPNG_ECHUNKAVAIL; \ if(chunk == NULL) return 1 #define SPNG_SET_CHUNK_BOILERPLATE(chunk) \ if(ctx == NULL || chunk == NULL) return 1; \ if(ctx->data == NULL && !ctx->encode_only) return SPNG_ENOSRC; \ int ret = read_chunks(ctx, 0); \ if(ret) return ret /* Determine if the spng_option can be overriden/optimized */ #define spng__optimize(option) (ctx->optimize_option & (1 << option)) struct spng_subimage { uint32_t width; uint32_t height; size_t out_width; /* byte width based on output format */ size_t scanline_width; }; struct spng_text2 { int type; char *keyword; char *text; size_t text_length; uint8_t compression_flag; /* iTXt only */ char *language_tag; /* iTXt only */ char *translated_keyword; /* iTXt only */ size_t cache_usage; char user_keyword_storage[80]; }; struct decode_flags { unsigned apply_trns: 1; unsigned apply_gamma: 1; unsigned use_sbit: 1; unsigned indexed: 1; unsigned do_scaling: 1; unsigned interlaced: 1; unsigned same_layout: 1; unsigned zerocopy: 1; unsigned unpack: 1; }; struct encode_flags { unsigned interlace: 1; unsigned same_layout: 1; unsigned to_bigendian: 1; unsigned progressive: 1; unsigned finalize: 1; enum spng_filter_choice filter_choice; }; struct spng_chunk_bitfield { unsigned ihdr: 1; unsigned plte: 1; unsigned chrm: 1; unsigned iccp: 1; unsigned gama: 1; unsigned sbit: 1; unsigned srgb: 1; unsigned text: 1; unsigned bkgd: 1; unsigned hist: 1; unsigned trns: 1; unsigned phys: 1; unsigned splt: 1; unsigned time: 1; unsigned offs: 1; unsigned exif: 1; unsigned unknown: 1; }; /* Packed sample iterator */ struct spng__iter { const uint8_t mask; unsigned shift_amount; const unsigned initial_shift, bit_depth; const unsigned char *samples; }; union spng__decode_plte { struct spng_plte_entry rgba[256]; unsigned char rgb[256 * 3]; unsigned char raw[256 * 4]; uint32_t align_this; }; struct spng__zlib_options { int compression_level; int window_bits; int mem_level; int strategy; int data_type; }; typedef void spng__undo(spng_ctx *ctx); struct spng_ctx { size_t data_size; size_t bytes_read; size_t stream_buf_size; unsigned char *stream_buf; const unsigned char *data; /* User-defined pointers for streaming */ spng_read_fn *read_fn; spng_write_fn *write_fn; void *stream_user_ptr; /* Used for buffer reads */ const unsigned char *png_base; size_t bytes_left; size_t last_read_size; /* Used for encoding */ int user_owns_out_png; unsigned char *out_png; unsigned char *write_ptr; size_t out_png_size; size_t bytes_encoded; /* These are updated by read/write_header()/read_chunk_bytes() */ struct spng_chunk current_chunk; uint32_t cur_chunk_bytes_left; uint32_t cur_actual_crc; struct spng_alloc alloc; enum spng_ctx_flags flags; enum spng_format fmt; enum spng_state state; unsigned streaming: 1; unsigned internal_buffer: 1; /* encoding to internal buffer */ unsigned inflate: 1; unsigned deflate: 1; unsigned encode_only: 1; unsigned strict: 1; unsigned discard: 1; unsigned skip_crc: 1; unsigned keep_unknown: 1; unsigned prev_was_idat: 1; struct spng__zlib_options image_options; struct spng__zlib_options text_options; spng__undo *undo; /* input file contains this chunk */ struct spng_chunk_bitfield file; /* chunk was stored with spng_set_*() */ struct spng_chunk_bitfield user; /* chunk was stored by reading or with spng_set_*() */ struct spng_chunk_bitfield stored; /* used to reset the above in case of an error */ struct spng_chunk_bitfield prev_stored; struct spng_chunk first_idat, last_idat; uint32_t max_width, max_height; size_t max_chunk_size; size_t chunk_cache_limit; size_t chunk_cache_usage; uint32_t chunk_count_limit; uint32_t chunk_count_total; int crc_action_critical; int crc_action_ancillary; uint32_t optimize_option; struct spng_ihdr ihdr; struct spng_plte plte; struct spng_chrm_int chrm_int; struct spng_iccp iccp; uint32_t gama; struct spng_sbit sbit; uint8_t srgb_rendering_intent; uint32_t n_text; struct spng_text2 *text_list; struct spng_bkgd bkgd; struct spng_hist hist; struct spng_trns trns; struct spng_phys phys; uint32_t n_splt; struct spng_splt *splt_list; struct spng_time time; struct spng_offs offs; struct spng_exif exif; uint32_t n_chunks; struct spng_unknown_chunk *chunk_list; struct spng_subimage subimage[7]; z_stream zstream; unsigned char *scanline_buf, *prev_scanline_buf, *row_buf, *filtered_scanline_buf; unsigned char *scanline, *prev_scanline, *row, *filtered_scanline; /* based on fmt */ size_t image_size; /* may be zero */ size_t image_width; unsigned bytes_per_pixel; /* derived from ihdr */ unsigned pixel_size; /* derived from spng_format+ihdr */ int widest_pass; int last_pass; /* last non-empty pass */ uint16_t *gamma_lut; /* points to either _lut8 or _lut16 */ uint16_t *gamma_lut16; uint16_t gamma_lut8[256]; unsigned char trns_px[8]; union spng__decode_plte decode_plte; struct spng_sbit decode_sb; struct decode_flags decode_flags; struct spng_row_info row_info; struct encode_flags encode_flags; }; static const uint32_t spng_u32max = INT32_MAX; static const uint32_t adam7_x_start[7] = { 0, 4, 0, 2, 0, 1, 0 }; static const uint32_t adam7_y_start[7] = { 0, 0, 4, 0, 2, 0, 1 }; static const uint32_t adam7_x_delta[7] = { 8, 8, 4, 4, 2, 2, 1 }; static const uint32_t adam7_y_delta[7] = { 8, 8, 8, 4, 4, 2, 2 }; static const uint8_t spng_signature[8] = { 137, 80, 78, 71, 13, 10, 26, 10 }; static const uint8_t type_ihdr[4] = { 73, 72, 68, 82 }; static const uint8_t type_plte[4] = { 80, 76, 84, 69 }; static const uint8_t type_idat[4] = { 73, 68, 65, 84 }; static const uint8_t type_iend[4] = { 73, 69, 78, 68 }; static const uint8_t type_trns[4] = { 116, 82, 78, 83 }; static const uint8_t type_chrm[4] = { 99, 72, 82, 77 }; static const uint8_t type_gama[4] = { 103, 65, 77, 65 }; static const uint8_t type_iccp[4] = { 105, 67, 67, 80 }; static const uint8_t type_sbit[4] = { 115, 66, 73, 84 }; static const uint8_t type_srgb[4] = { 115, 82, 71, 66 }; static const uint8_t type_text[4] = { 116, 69, 88, 116 }; static const uint8_t type_ztxt[4] = { 122, 84, 88, 116 }; static const uint8_t type_itxt[4] = { 105, 84, 88, 116 }; static const uint8_t type_bkgd[4] = { 98, 75, 71, 68 }; static const uint8_t type_hist[4] = { 104, 73, 83, 84 }; static const uint8_t type_phys[4] = { 112, 72, 89, 115 }; static const uint8_t type_splt[4] = { 115, 80, 76, 84 }; static const uint8_t type_time[4] = { 116, 73, 77, 69 }; static const uint8_t type_offs[4] = { 111, 70, 70, 115 }; static const uint8_t type_exif[4] = { 101, 88, 73, 102 }; static inline void *spng__malloc(spng_ctx *ctx, size_t size) { return ctx->alloc.malloc_fn(size); } static inline void *spng__calloc(spng_ctx *ctx, size_t nmemb, size_t size) { return ctx->alloc.calloc_fn(nmemb, size); } static inline void *spng__realloc(spng_ctx *ctx, void *ptr, size_t size) { return ctx->alloc.realloc_fn(ptr, size); } static inline void spng__free(spng_ctx *ctx, void *ptr) { ctx->alloc.free_fn(ptr); } #if defined(SPNG_USE_MINIZ) static void *spng__zalloc(void *opaque, size_t items, size_t size) #else static void *spng__zalloc(void *opaque, uInt items, uInt size) #endif { spng_ctx *ctx = opaque; if(size > SIZE_MAX / items) return NULL; size_t len = (size_t)items * size; return spng__malloc(ctx, len); } static void spng__zfree(void *opqaue, void *ptr) { spng_ctx *ctx = opqaue; spng__free(ctx, ptr); } static inline uint16_t read_u16(const void *src) { const unsigned char *data = src; return (data[0] & 0xFFU) << 8 | (data[1] & 0xFFU); } static inline uint32_t read_u32(const void *src) { const unsigned char *data = src; return (data[0] & 0xFFUL) << 24 | (data[1] & 0xFFUL) << 16 | (data[2] & 0xFFUL) << 8 | (data[3] & 0xFFUL); } static inline int32_t read_s32(const void *src) { int32_t ret = (int32_t)read_u32(src); return ret; } static inline void write_u16(void *dest, uint16_t x) { unsigned char *data = dest; data[0] = x >> 8; data[1] = x & 0xFF; } static inline void write_u32(void *dest, uint32_t x) { unsigned char *data = dest; data[0] = (x >> 24); data[1] = (x >> 16) & 0xFF; data[2] = (x >> 8) & 0xFF; data[3] = x & 0xFF; } static inline void write_s32(void *dest, int32_t x) { uint32_t n = x; write_u32(dest, n); } /* Returns an iterator for 1,2,4,8-bit samples */ static struct spng__iter spng__iter_init(unsigned bit_depth, const unsigned char *samples) { struct spng__iter iter = { .mask = (uint32_t)(1 << bit_depth) - 1, .shift_amount = 8 - bit_depth, .initial_shift = 8 - bit_depth, .bit_depth = bit_depth, .samples = samples }; return iter; } /* Returns the current sample unpacked, iterates to the next one */ static inline uint8_t get_sample(struct spng__iter *iter) { uint8_t x = (iter->samples[0] >> iter->shift_amount) & iter->mask; iter->shift_amount -= iter->bit_depth; if(iter->shift_amount > 7) { iter->shift_amount = iter->initial_shift; iter->samples++; } return x; } static void u16_row_to_host(void *row, size_t size) { uint16_t *px = row; size_t i, n = size / 2; for(i=0; i < n; i++) { px[i] = read_u16(&px[i]); } } static void u16_row_to_bigendian(void *row, size_t size) { uint16_t *px = (uint16_t*)row; size_t i, n = size / 2; for(i=0; i < n; i++) { write_u16(&px[i], px[i]); } } static void rgb8_row_to_rgba8(const unsigned char *row, unsigned char *out, uint32_t n) { uint32_t i; for(i=0; i < n; i++) { memcpy(out + i * 4, row + i * 3, 3); out[i*4+3] = 255; } } static unsigned num_channels(const struct spng_ihdr *ihdr) { switch(ihdr->color_type) { case SPNG_COLOR_TYPE_TRUECOLOR: return 3; case SPNG_COLOR_TYPE_GRAYSCALE_ALPHA: return 2; case SPNG_COLOR_TYPE_TRUECOLOR_ALPHA: return 4; case SPNG_COLOR_TYPE_GRAYSCALE: case SPNG_COLOR_TYPE_INDEXED: return 1; default: return 0; } } /* Calculate scanline width in bits, round up to the nearest byte */ static int calculate_scanline_width(const struct spng_ihdr *ihdr, uint32_t width, size_t *scanline_width) { if(ihdr == NULL || !width) return SPNG_EINTERNAL; size_t res = num_channels(ihdr) * ihdr->bit_depth; if(res > SIZE_MAX / width) return SPNG_EOVERFLOW; res = res * width; res += 15; /* Filter byte + 7 for rounding */ if(res < 15) return SPNG_EOVERFLOW; res /= 8; if(res > UINT32_MAX) return SPNG_EOVERFLOW; *scanline_width = res; return 0; } static int calculate_subimages(struct spng_ctx *ctx) { if(ctx == NULL) return SPNG_EINTERNAL; struct spng_ihdr *ihdr = &ctx->ihdr; struct spng_subimage *sub = ctx->subimage; if(ihdr->interlace_method == 1) { sub[0].width = (ihdr->width + 7) >> 3; sub[0].height = (ihdr->height + 7) >> 3; sub[1].width = (ihdr->width + 3) >> 3; sub[1].height = (ihdr->height + 7) >> 3; sub[2].width = (ihdr->width + 3) >> 2; sub[2].height = (ihdr->height + 3) >> 3; sub[3].width = (ihdr->width + 1) >> 2; sub[3].height = (ihdr->height + 3) >> 2; sub[4].width = (ihdr->width + 1) >> 1; sub[4].height = (ihdr->height + 1) >> 2; sub[5].width = ihdr->width >> 1; sub[5].height = (ihdr->height + 1) >> 1; sub[6].width = ihdr->width; sub[6].height = ihdr->height >> 1; } else { sub[0].width = ihdr->width; sub[0].height = ihdr->height; } int i; for(i=0; i < 7; i++) { if(sub[i].width == 0 || sub[i].height == 0) continue; int ret = calculate_scanline_width(ihdr, sub[i].width, &sub[i].scanline_width); if(ret) return ret; if(sub[ctx->widest_pass].scanline_width < sub[i].scanline_width) ctx->widest_pass = i; ctx->last_pass = i; } return 0; } static int check_decode_fmt(const struct spng_ihdr *ihdr, const int fmt) { switch(fmt) { case SPNG_FMT_RGBA8: case SPNG_FMT_RGBA16: case SPNG_FMT_RGB8: case SPNG_FMT_PNG: case SPNG_FMT_RAW: return 0; case SPNG_FMT_G8: case SPNG_FMT_GA8: if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE && ihdr->bit_depth <= 8) return 0; else return SPNG_EFMT; case SPNG_FMT_GA16: if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE && ihdr->bit_depth == 16) return 0; else return SPNG_EFMT; default: return SPNG_EFMT; } } static int calculate_image_width(const struct spng_ihdr *ihdr, int fmt, size_t *len) { if(ihdr == NULL || len == NULL) return SPNG_EINTERNAL; size_t res = ihdr->width; unsigned bytes_per_pixel; switch(fmt) { case SPNG_FMT_RGBA8: case SPNG_FMT_GA16: bytes_per_pixel = 4; break; case SPNG_FMT_RGBA16: bytes_per_pixel = 8; break; case SPNG_FMT_RGB8: bytes_per_pixel = 3; break; case SPNG_FMT_PNG: case SPNG_FMT_RAW: { int ret = calculate_scanline_width(ihdr, ihdr->width, &res); if(ret) return ret; res -= 1; /* exclude filter byte */ bytes_per_pixel = 1; break; } case SPNG_FMT_G8: bytes_per_pixel = 1; break; case SPNG_FMT_GA8: bytes_per_pixel = 2; break; default: return SPNG_EINTERNAL; } if(res > SIZE_MAX / bytes_per_pixel) return SPNG_EOVERFLOW; res = res * bytes_per_pixel; *len = res; return 0; } static int calculate_image_size(const struct spng_ihdr *ihdr, int fmt, size_t *len) { if(ihdr == NULL || len == NULL) return SPNG_EINTERNAL; size_t res = 0; int ret = calculate_image_width(ihdr, fmt, &res); if(ret) return ret; if(res > SIZE_MAX / ihdr->height) return SPNG_EOVERFLOW; res = res * ihdr->height; *len = res; return 0; } static int increase_cache_usage(spng_ctx *ctx, size_t bytes, int new_chunk) { if(ctx == NULL || !bytes) return SPNG_EINTERNAL; if(new_chunk) { ctx->chunk_count_total++; if(ctx->chunk_count_total < 1) return SPNG_EOVERFLOW; if(ctx->chunk_count_total > ctx->chunk_count_limit) return SPNG_ECHUNK_LIMITS; } size_t new_usage = ctx->chunk_cache_usage + bytes; if(new_usage < ctx->chunk_cache_usage) return SPNG_EOVERFLOW; if(new_usage > ctx->chunk_cache_limit) return SPNG_ECHUNK_LIMITS; ctx->chunk_cache_usage = new_usage; return 0; } static int decrease_cache_usage(spng_ctx *ctx, size_t usage) { if(ctx == NULL || !usage) return SPNG_EINTERNAL; if(usage > ctx->chunk_cache_usage) return SPNG_EINTERNAL; ctx->chunk_cache_usage -= usage; return 0; } static int is_critical_chunk(struct spng_chunk *chunk) { if(chunk == NULL) return 0; if((chunk->type[0] & (1 << 5)) == 0) return 1; return 0; } static int decode_err(spng_ctx *ctx, int err) { ctx->state = SPNG_STATE_INVALID; return err; } static int encode_err(spng_ctx *ctx, int err) { ctx->state = SPNG_STATE_INVALID; return err; } static inline int read_data(spng_ctx *ctx, size_t bytes) { if(ctx == NULL) return SPNG_EINTERNAL; if(!bytes) return 0; if(ctx->streaming && (bytes > SPNG_READ_SIZE)) return SPNG_EINTERNAL; int ret = ctx->read_fn(ctx, ctx->stream_user_ptr, ctx->stream_buf, bytes); if(ret) { if(ret > 0 || ret < SPNG_IO_ERROR) ret = SPNG_IO_ERROR; return ret; } ctx->bytes_read += bytes; if(ctx->bytes_read < bytes) return SPNG_EOVERFLOW; return 0; } /* Ensure there is enough space for encoding starting at ctx->write_ptr */ static int require_bytes(spng_ctx *ctx, size_t bytes) { if(ctx == NULL) return SPNG_EINTERNAL; if(ctx->streaming) { if(bytes > ctx->stream_buf_size) { size_t new_size = ctx->stream_buf_size; /* Start at default IDAT size + header + crc */ if(new_size < (SPNG_WRITE_SIZE + 12)) new_size = SPNG_WRITE_SIZE + 12; if(new_size < bytes) new_size = bytes; void *temp = spng__realloc(ctx, ctx->stream_buf, new_size); if(temp == NULL) return encode_err(ctx, SPNG_EMEM); ctx->stream_buf = temp; ctx->stream_buf_size = bytes; ctx->write_ptr = ctx->stream_buf; } return 0; } if(!ctx->internal_buffer) return SPNG_ENODST; size_t required = ctx->bytes_encoded + bytes; if(required < bytes) return SPNG_EOVERFLOW; if(required > ctx->out_png_size) { size_t new_size = ctx->out_png_size; /* Start with a size that doesn't require a realloc() 100% of the time */ if(new_size < (SPNG_WRITE_SIZE * 2)) new_size = SPNG_WRITE_SIZE * 2; /* Prefer the next power of two over the requested size */ while(new_size < required) { if(new_size / SIZE_MAX > 2) return encode_err(ctx, SPNG_EOVERFLOW); new_size *= 2; } void *temp = spng__realloc(ctx, ctx->out_png, new_size); if(temp == NULL) return encode_err(ctx, SPNG_EMEM); ctx->out_png = temp; ctx->out_png_size = new_size; ctx->write_ptr = ctx->out_png + ctx->bytes_encoded; } return 0; } static int write_data(spng_ctx *ctx, const void *data, size_t bytes) { if(ctx == NULL) return SPNG_EINTERNAL; if(!bytes) return 0; if(ctx->streaming) { if(bytes > SPNG_WRITE_SIZE) return SPNG_EINTERNAL; int ret = ctx->write_fn(ctx, ctx->stream_user_ptr, (void*)data, bytes); if(ret) { if(ret > 0 || ret < SPNG_IO_ERROR) ret = SPNG_IO_ERROR; return encode_err(ctx, ret); } } else { int ret = require_bytes(ctx, bytes); if(ret) return encode_err(ctx, ret); memcpy(ctx->write_ptr, data, bytes); ctx->write_ptr += bytes; } ctx->bytes_encoded += bytes; if(ctx->bytes_encoded < bytes) return SPNG_EOVERFLOW; return 0; } static int write_header(spng_ctx *ctx, const uint8_t chunk_type[4], size_t chunk_length, unsigned char **data) { if(ctx == NULL || chunk_type == NULL) return SPNG_EINTERNAL; if(chunk_length > spng_u32max) return SPNG_EINTERNAL; size_t total = chunk_length + 12; int ret = require_bytes(ctx, total); if(ret) return ret; uint32_t crc = crc32(0, NULL, 0); ctx->current_chunk.crc = crc32(crc, chunk_type, 4); memcpy(&ctx->current_chunk.type, chunk_type, 4); ctx->current_chunk.length = (uint32_t)chunk_length; if(!data) return SPNG_EINTERNAL; if(ctx->streaming) *data = ctx->stream_buf + 8; else *data = ctx->write_ptr + 8; return 0; } static int trim_chunk(spng_ctx *ctx, uint32_t length) { if(length > spng_u32max) return SPNG_EINTERNAL; if(length > ctx->current_chunk.length) return SPNG_EINTERNAL; ctx->current_chunk.length = length; return 0; } static int finish_chunk(spng_ctx *ctx) { if(ctx == NULL) return SPNG_EINTERNAL; struct spng_chunk *chunk = &ctx->current_chunk; unsigned char *header; unsigned char *chunk_data; if(ctx->streaming) { chunk_data = ctx->stream_buf + 8; header = ctx->stream_buf; } else { chunk_data = ctx->write_ptr + 8; header = ctx->write_ptr; } write_u32(header, chunk->length); memcpy(header + 4, chunk->type, 4); chunk->crc = crc32(chunk->crc, chunk_data, chunk->length); write_u32(chunk_data + chunk->length, chunk->crc); if(ctx->streaming) { const unsigned char *ptr = ctx->stream_buf; uint32_t bytes_left = chunk->length + 12; uint32_t len = 0; while(bytes_left) { ptr += len; len = SPNG_WRITE_SIZE; if(len > bytes_left) len = bytes_left; int ret = write_data(ctx, ptr, len); if(ret) return ret; bytes_left -= len; } } else { ctx->bytes_encoded += chunk->length; if(ctx->bytes_encoded < chunk->length) return SPNG_EOVERFLOW; ctx->bytes_encoded += 12; if(ctx->bytes_encoded < 12) return SPNG_EOVERFLOW; ctx->write_ptr += chunk->length + 12; } return 0; } static int write_chunk(spng_ctx *ctx, const uint8_t type[4], const void *data, size_t length) { if(ctx == NULL || type == NULL) return SPNG_EINTERNAL; if(length && data == NULL) return SPNG_EINTERNAL; unsigned char *write_ptr; int ret = write_header(ctx, type, length, &write_ptr); if(ret) return ret; if(length) memcpy(write_ptr, data, length); return finish_chunk(ctx); } static int write_iend(spng_ctx *ctx) { unsigned char iend_chunk[12] = { 0, 0, 0, 0, 73, 69, 78, 68, 174, 66, 96, 130 }; return write_data(ctx, iend_chunk, 12); } static int write_unknown_chunks(spng_ctx *ctx, enum spng_location location) { if(!ctx->stored.unknown) return 0; const struct spng_unknown_chunk *chunk = ctx->chunk_list; uint32_t i; for(i=0; i < ctx->n_chunks; i++, chunk++) { if(chunk->location != location) continue; int ret = write_chunk(ctx, chunk->type, chunk->data, chunk->length); if(ret) return ret; } return 0; } /* Read and check the current chunk's crc, returns -SPNG_CRC_DISCARD if the chunk should be discarded */ static inline int read_and_check_crc(spng_ctx *ctx) { if(ctx == NULL) return SPNG_EINTERNAL; int ret; ret = read_data(ctx, 4); if(ret) return ret; ctx->current_chunk.crc = read_u32(ctx->data); if(ctx->skip_crc) return 0; if(ctx->cur_actual_crc != ctx->current_chunk.crc) { if(is_critical_chunk(&ctx->current_chunk)) { if(ctx->crc_action_critical == SPNG_CRC_USE) return 0; } else { if(ctx->crc_action_ancillary == SPNG_CRC_USE) return 0; if(ctx->crc_action_ancillary == SPNG_CRC_DISCARD) return -SPNG_CRC_DISCARD; } return SPNG_ECHUNK_CRC; } return 0; } /* Read and validate the current chunk's crc and the next chunk header */ static inline int read_header(spng_ctx *ctx) { if(ctx == NULL) return SPNG_EINTERNAL; int ret; struct spng_chunk chunk = { 0 }; ret = read_and_check_crc(ctx); if(ret) { if(ret == -SPNG_CRC_DISCARD) { ctx->discard = 1; } else return ret; } ret = read_data(ctx, 8); if(ret) return ret; chunk.offset = ctx->bytes_read - 8; chunk.length = read_u32(ctx->data); memcpy(&chunk.type, ctx->data + 4, 4); if(chunk.length > spng_u32max) return SPNG_ECHUNK_STDLEN; ctx->cur_chunk_bytes_left = chunk.length; if(is_critical_chunk(&chunk) && ctx->crc_action_critical == SPNG_CRC_USE) ctx->skip_crc = 1; else if(ctx->crc_action_ancillary == SPNG_CRC_USE) ctx->skip_crc = 1; else ctx->skip_crc = 0; if(!ctx->skip_crc) { ctx->cur_actual_crc = crc32(0, NULL, 0); ctx->cur_actual_crc = crc32(ctx->cur_actual_crc, chunk.type, 4); } ctx->current_chunk = chunk; return 0; } /* Read chunk bytes and update crc */ static int read_chunk_bytes(spng_ctx *ctx, uint32_t bytes) { if(ctx == NULL) return SPNG_EINTERNAL; if(!ctx->cur_chunk_bytes_left || !bytes) return SPNG_EINTERNAL; if(bytes > ctx->cur_chunk_bytes_left) return SPNG_EINTERNAL; /* XXX: more specific error? */ int ret; ret = read_data(ctx, bytes); if(ret) return ret; if(!ctx->skip_crc) ctx->cur_actual_crc = crc32(ctx->cur_actual_crc, ctx->data, bytes); ctx->cur_chunk_bytes_left -= bytes; return ret; } /* read_chunk_bytes() + read_data() with custom output buffer */ static int read_chunk_bytes2(spng_ctx *ctx, void *out, uint32_t bytes) { if(ctx == NULL) return SPNG_EINTERNAL; if(!ctx->cur_chunk_bytes_left || !bytes) return SPNG_EINTERNAL; if(bytes > ctx->cur_chunk_bytes_left) return SPNG_EINTERNAL; /* XXX: more specific error? */ int ret; uint32_t len = bytes; if(ctx->streaming && len > SPNG_READ_SIZE) len = SPNG_READ_SIZE; while(bytes) { if(len > bytes) len = bytes; ret = ctx->read_fn(ctx, ctx->stream_user_ptr, out, len); if(ret) return ret; if(!ctx->streaming) memcpy(out, ctx->data, len); ctx->bytes_read += len; if(ctx->bytes_read < len) return SPNG_EOVERFLOW; if(!ctx->skip_crc) ctx->cur_actual_crc = crc32(ctx->cur_actual_crc, out, len); ctx->cur_chunk_bytes_left -= len; out = (char*)out + len; bytes -= len; len = SPNG_READ_SIZE; } return 0; } static int discard_chunk_bytes(spng_ctx *ctx, uint32_t bytes) { if(ctx == NULL) return SPNG_EINTERNAL; if(!bytes) return 0; int ret; if(ctx->streaming) /* Do small, consecutive reads */ { while(bytes) { uint32_t len = SPNG_READ_SIZE; if(len > bytes) len = bytes; ret = read_chunk_bytes(ctx, len); if(ret) return ret; bytes -= len; } } else { ret = read_chunk_bytes(ctx, bytes); if(ret) return ret; } return 0; } static int spng__inflate_init(spng_ctx *ctx, int window_bits) { if(ctx->zstream.state) inflateEnd(&ctx->zstream); ctx->inflate = 1; ctx->zstream.zalloc = spng__zalloc; ctx->zstream.zfree = spng__zfree; ctx->zstream.opaque = ctx; if(inflateInit2(&ctx->zstream, window_bits) != Z_OK) return SPNG_EZLIB_INIT; #if ZLIB_VERNUM >= 0x1290 && !defined(SPNG_USE_MINIZ) int validate = 1; if(ctx->flags & SPNG_CTX_IGNORE_ADLER32) validate = 0; if(is_critical_chunk(&ctx->current_chunk)) { if(ctx->crc_action_critical == SPNG_CRC_USE) validate = 0; } else /* ancillary */ { if(ctx->crc_action_ancillary == SPNG_CRC_USE) validate = 0; } if(inflateValidate(&ctx->zstream, validate)) return SPNG_EZLIB_INIT; #else /* This requires zlib >= 1.2.11 */ #pragma message ("inflateValidate() not available, SPNG_CTX_IGNORE_ADLER32 will be ignored") #endif return 0; } static int spng__deflate_init(spng_ctx *ctx, struct spng__zlib_options *options) { if(ctx->zstream.state) deflateEnd(&ctx->zstream); ctx->deflate = 1; z_stream *zstream = &ctx->zstream; zstream->zalloc = spng__zalloc; zstream->zfree = spng__zfree; zstream->opaque = ctx; zstream->data_type = options->data_type; int ret = deflateInit2(zstream, options->compression_level, Z_DEFLATED, options->window_bits, options->mem_level, options->strategy); if(ret != Z_OK) return SPNG_EZLIB_INIT; return 0; } /* Inflate a zlib stream starting with start_buf if non-NULL, continuing from the datastream till an end marker, allocating and writing the inflated stream to *out, leaving "extra" bytes at the end, final buffer length is *len. Takes into account the chunk size and cache limits. */ static int spng__inflate_stream(spng_ctx *ctx, char **out, size_t *len, size_t extra, const void *start_buf, size_t start_len) { int ret = spng__inflate_init(ctx, 15); if(ret) return ret; size_t max = ctx->chunk_cache_limit - ctx->chunk_cache_usage; if(ctx->max_chunk_size < max) max = ctx->max_chunk_size; if(extra > max) return SPNG_ECHUNK_LIMITS; max -= extra; uint32_t read_size; size_t size = 8 * 1024; void *t, *buf = spng__malloc(ctx, size); if(buf == NULL) return SPNG_EMEM; z_stream *stream = &ctx->zstream; if(start_buf != NULL && start_len) { stream->avail_in = (uInt)start_len; stream->next_in = start_buf; } else { stream->avail_in = 0; stream->next_in = NULL; } stream->avail_out = (uInt)size; stream->next_out = buf; while(ret != Z_STREAM_END) { ret = inflate(stream, Z_NO_FLUSH); if(ret == Z_STREAM_END) break; if(ret != Z_OK && ret != Z_BUF_ERROR) { ret = SPNG_EZLIB; goto err; } if(!stream->avail_out) /* Resize buffer */ { /* overflow or reached chunk/cache limit */ if( (2 > SIZE_MAX / size) || (size > max / 2) ) { ret = SPNG_ECHUNK_LIMITS; goto err; } size *= 2; t = spng__realloc(ctx, buf, size); if(t == NULL) goto mem; buf = t; stream->avail_out = (uInt)size / 2; stream->next_out = (unsigned char*)buf + size / 2; } else if(!stream->avail_in) /* Read more chunk bytes */ { read_size = ctx->cur_chunk_bytes_left; if(ctx->streaming && read_size > SPNG_READ_SIZE) read_size = SPNG_READ_SIZE; ret = read_chunk_bytes(ctx, read_size); if(ret) { if(!read_size) ret = SPNG_EZLIB; goto err; } stream->avail_in = read_size; stream->next_in = ctx->data; } } size = stream->total_out; if(!size) { ret = SPNG_EZLIB; goto err; } size += extra; if(size < extra) goto mem; t = spng__realloc(ctx, buf, size); if(t == NULL) goto mem; buf = t; (void)increase_cache_usage(ctx, size, 0); *out = buf; *len = size; return 0; mem: ret = SPNG_EMEM; err: spng__free(ctx, buf); return ret; } /* Read at least one byte from the IDAT stream */ static int read_idat_bytes(spng_ctx *ctx, uint32_t *bytes_read) { if(ctx == NULL || bytes_read == NULL) return SPNG_EINTERNAL; if(memcmp(ctx->current_chunk.type, type_idat, 4)) return SPNG_EIDAT_TOO_SHORT; int ret; uint32_t len; while(!ctx->cur_chunk_bytes_left) { ret = read_header(ctx); if(ret) return ret; if(memcmp(ctx->current_chunk.type, type_idat, 4)) return SPNG_EIDAT_TOO_SHORT; } if(ctx->streaming) {/* TODO: estimate bytes to read for progressive reads */ len = SPNG_READ_SIZE; if(len > ctx->cur_chunk_bytes_left) len = ctx->cur_chunk_bytes_left; } else len = ctx->current_chunk.length; ret = read_chunk_bytes(ctx, len); *bytes_read = len; return ret; } static int read_scanline_bytes(spng_ctx *ctx, unsigned char *dest, size_t len) { if(ctx == NULL || dest == NULL) return SPNG_EINTERNAL; int ret = Z_OK; uint32_t bytes_read; z_stream *zstream = &ctx->zstream; zstream->avail_out = (uInt)len; zstream->next_out = dest; while(zstream->avail_out != 0) { ret = inflate(zstream, Z_NO_FLUSH); if(ret == Z_OK) continue; if(ret == Z_STREAM_END) /* Reached an end-marker */ { if(zstream->avail_out != 0) return SPNG_EIDAT_TOO_SHORT; } else if(ret == Z_BUF_ERROR) /* Read more IDAT bytes */ { ret = read_idat_bytes(ctx, &bytes_read); if(ret) return ret; zstream->avail_in = bytes_read; zstream->next_in = ctx->data; } else return SPNG_EIDAT_STREAM; } return 0; } static uint8_t paeth(uint8_t a, uint8_t b, uint8_t c) { int16_t p = a + b - c; int16_t pa = abs(p - a); int16_t pb = abs(p - b); int16_t pc = abs(p - c); if(pa <= pb && pa <= pc) return a; else if(pb <= pc) return b; return c; } SPNG_TARGET_CLONES("default,avx2") static void defilter_up(size_t bytes, unsigned char *row, const unsigned char *prev) { size_t i; for(i=0; i < bytes; i++) { row[i] += prev[i]; } } /* Defilter *scanline in-place. *prev_scanline and *scanline should point to the first pixel, scanline_width is the width of the scanline including the filter byte. */ static int defilter_scanline(const unsigned char *prev_scanline, unsigned char *scanline, size_t scanline_width, unsigned bytes_per_pixel, unsigned filter) { if(prev_scanline == NULL || scanline == NULL || !scanline_width) return SPNG_EINTERNAL; size_t i; scanline_width--; if(filter == 0) return 0; #ifndef SPNG_DISABLE_OPT if(filter == SPNG_FILTER_UP) goto no_opt; if(bytes_per_pixel == 4) { if(filter == SPNG_FILTER_SUB) defilter_sub4(scanline_width, scanline); else if(filter == SPNG_FILTER_AVERAGE) defilter_avg4(scanline_width, scanline, prev_scanline); else if(filter == SPNG_FILTER_PAETH) defilter_paeth4(scanline_width, scanline, prev_scanline); else return SPNG_EFILTER; return 0; } else if(bytes_per_pixel == 3) { if(filter == SPNG_FILTER_SUB) defilter_sub3(scanline_width, scanline); else if(filter == SPNG_FILTER_AVERAGE) defilter_avg3(scanline_width, scanline, prev_scanline); else if(filter == SPNG_FILTER_PAETH) defilter_paeth3(scanline_width, scanline, prev_scanline); else return SPNG_EFILTER; return 0; } no_opt: #endif if(filter == SPNG_FILTER_UP) { defilter_up(scanline_width, scanline, prev_scanline); return 0; } for(i=0; i < scanline_width; i++) { uint8_t x, a, b, c; if(i >= bytes_per_pixel) { a = scanline[i - bytes_per_pixel]; b = prev_scanline[i]; c = prev_scanline[i - bytes_per_pixel]; } else /* First pixel in row */ { a = 0; b = prev_scanline[i]; c = 0; } x = scanline[i]; switch(filter) { case SPNG_FILTER_SUB: { x = x + a; break; } case SPNG_FILTER_AVERAGE: { uint16_t avg = (a + b) / 2; x = x + avg; break; } case SPNG_FILTER_PAETH: { x = x + paeth(a,b,c); break; } } scanline[i] = x; } return 0; } static int filter_scanline(unsigned char *filtered, const unsigned char *prev_scanline, const unsigned char *scanline, size_t scanline_width, unsigned bytes_per_pixel, const unsigned filter) { if(prev_scanline == NULL || scanline == NULL || scanline_width <= 1) return SPNG_EINTERNAL; if(filter > 4) return SPNG_EFILTER; if(filter == 0) return 0; scanline_width--; uint32_t i; for(i=0; i < scanline_width; i++) { uint8_t x, a, b, c; if(i >= bytes_per_pixel) { a = scanline[i - bytes_per_pixel]; b = prev_scanline[i]; c = prev_scanline[i - bytes_per_pixel]; } else /* first pixel in row */ { a = 0; b = prev_scanline[i]; c = 0; } x = scanline[i]; switch(filter) { case SPNG_FILTER_SUB: { x = x - a; break; } case SPNG_FILTER_UP: { x = x - b; break; } case SPNG_FILTER_AVERAGE: { uint16_t avg = (a + b) / 2; x = x - avg; break; } case SPNG_FILTER_PAETH: { x = x - paeth(a,b,c); break; } } filtered[i] = x; } return 0; } static int32_t filter_sum(const unsigned char *prev_scanline, const unsigned char *scanline, size_t size, unsigned bytes_per_pixel, const unsigned filter) { /* prevent potential over/underflow, bails out at a width of ~8M pixels for RGBA8 */ if(size > (INT32_MAX / 128)) return INT32_MAX; uint32_t i; int32_t sum = 0; uint8_t x, a, b, c; for(i=0; i < size; i++) { if(i >= bytes_per_pixel) { a = scanline[i - bytes_per_pixel]; b = prev_scanline[i]; c = prev_scanline[i - bytes_per_pixel]; } else /* first pixel in row */ { a = 0; b = prev_scanline[i]; c = 0; } x = scanline[i]; switch(filter) { case SPNG_FILTER_NONE: { break; } case SPNG_FILTER_SUB: { x = x - a; break; } case SPNG_FILTER_UP: { x = x - b; break; } case SPNG_FILTER_AVERAGE: { uint16_t avg = (a + b) / 2; x = x - avg; break; } case SPNG_FILTER_PAETH: { x = x - paeth(a,b,c); break; } } sum += 128 - abs((int)x - 128); } return sum; } static unsigned get_best_filter(const unsigned char *prev_scanline, const unsigned char *scanline, size_t scanline_width, unsigned bytes_per_pixel, const int choices) { if(!choices) return SPNG_FILTER_NONE; scanline_width--; int i; unsigned int best_filter = 0; enum spng_filter_choice flag; int32_t sum, best_score = INT32_MAX; int32_t filter_scores[5] = { INT32_MAX, INT32_MAX, INT32_MAX, INT32_MAX, INT32_MAX }; if( !(choices & (choices - 1)) ) {/* only one choice/bit is set */ for(i=0; i < 5; i++) { if(choices == 1 << (i + 3)) return i; } } for(i=0; i < 5; i++) { flag = 1 << (i + 3); if(choices & flag) sum = filter_sum(prev_scanline, scanline, scanline_width, bytes_per_pixel, i); else continue; filter_scores[i] = abs(sum); if(filter_scores[i] < best_score) { best_score = filter_scores[i]; best_filter = i; } } return best_filter; } /* Scale "sbits" significant bits in "sample" from "bit_depth" to "target" "bit_depth" must be a valid PNG depth "sbits" must be less than or equal to "bit_depth" "target" must be between 1 and 16 */ static uint16_t sample_to_target(uint16_t sample, unsigned bit_depth, unsigned sbits, unsigned target) { if(bit_depth == sbits) { if(target == sbits) return sample; /* No scaling */ }/* bit_depth > sbits */ else sample = sample >> (bit_depth - sbits); /* Shift significant bits to bottom */ /* Downscale */ if(target < sbits) return sample >> (sbits - target); /* Upscale using left bit replication */ int8_t shift_amount = target - sbits; uint16_t sample_bits = sample; sample = 0; while(shift_amount >= 0) { sample = sample | (sample_bits << shift_amount); shift_amount -= sbits; } int8_t partial = shift_amount + (int8_t)sbits; if(partial != 0) sample = sample | (sample_bits >> abs(shift_amount)); return sample; } static inline void gamma_correct_row(unsigned char *row, uint32_t pixels, int fmt, const uint16_t *gamma_lut) { uint32_t i; if(fmt == SPNG_FMT_RGBA8) { unsigned char *px; for(i=0; i < pixels; i++) { px = row + i * 4; px[0] = gamma_lut[px[0]]; px[1] = gamma_lut[px[1]]; px[2] = gamma_lut[px[2]]; } } else if(fmt == SPNG_FMT_RGBA16) { for(i=0; i < pixels; i++) { uint16_t px[4]; memcpy(px, row + i * 8, 8); px[0] = gamma_lut[px[0]]; px[1] = gamma_lut[px[1]]; px[2] = gamma_lut[px[2]]; memcpy(row + i * 8, px, 8); } } else if(fmt == SPNG_FMT_RGB8) { unsigned char *px; for(i=0; i < pixels; i++) { px = row + i * 3; px[0] = gamma_lut[px[0]]; px[1] = gamma_lut[px[1]]; px[2] = gamma_lut[px[2]]; } } } /* Apply transparency to output row */ static inline void trns_row(unsigned char *row, const unsigned char *scanline, const unsigned char *trns, unsigned scanline_stride, struct spng_ihdr *ihdr, uint32_t pixels, int fmt) { uint32_t i; unsigned row_stride; unsigned depth = ihdr->bit_depth; if(fmt == SPNG_FMT_RGBA8) { if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE) return; /* already applied in the decoding loop */ row_stride = 4; for(i=0; i < pixels; i++, scanline+=scanline_stride, row+=row_stride) { if(!memcmp(scanline, trns, scanline_stride)) row[3] = 0; } } else if(fmt == SPNG_FMT_RGBA16) { if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE) return; /* already applied in the decoding loop */ row_stride = 8; for(i=0; i < pixels; i++, scanline+=scanline_stride, row+=row_stride) { if(!memcmp(scanline, trns, scanline_stride)) memset(row + 6, 0, 2); } } else if(fmt == SPNG_FMT_GA8) { row_stride = 2; if(depth == 16) { for(i=0; i < pixels; i++, scanline+=scanline_stride, row+=row_stride) { if(!memcmp(scanline, trns, scanline_stride)) memset(row + 1, 0, 1); } } else /* depth <= 8 */ { struct spng__iter iter = spng__iter_init(depth, scanline); for(i=0; i < pixels; i++, row+=row_stride) { if(trns[0] == get_sample(&iter)) row[1] = 0; } } } else if(fmt == SPNG_FMT_GA16) { row_stride = 4; if(depth == 16) { for(i=0; i< pixels; i++, scanline+=scanline_stride, row+=row_stride) { if(!memcmp(scanline, trns, 2)) memset(row + 2, 0, 2); } } else { struct spng__iter iter = spng__iter_init(depth, scanline); for(i=0; i< pixels; i++, row+=row_stride) { if(trns[0] == get_sample(&iter)) memset(row + 2, 0, 2); } } } else return; } static inline void scale_row(unsigned char *row, uint32_t pixels, int fmt, unsigned depth, const struct spng_sbit *sbit) { uint32_t i; if(fmt == SPNG_FMT_RGBA8) { unsigned char px[4]; for(i=0; i < pixels; i++) { memcpy(px, row + i * 4, 4); px[0] = sample_to_target(px[0], depth, sbit->red_bits, 8); px[1] = sample_to_target(px[1], depth, sbit->green_bits, 8); px[2] = sample_to_target(px[2], depth, sbit->blue_bits, 8); px[3] = sample_to_target(px[3], depth, sbit->alpha_bits, 8); memcpy(row + i * 4, px, 4); } } else if(fmt == SPNG_FMT_RGBA16) { uint16_t px[4]; for(i=0; i < pixels; i++) { memcpy(px, row + i * 8, 8); px[0] = sample_to_target(px[0], depth, sbit->red_bits, 16); px[1] = sample_to_target(px[1], depth, sbit->green_bits, 16); px[2] = sample_to_target(px[2], depth, sbit->blue_bits, 16); px[3] = sample_to_target(px[3], depth, sbit->alpha_bits, 16); memcpy(row + i * 8, px, 8); } } else if(fmt == SPNG_FMT_RGB8) { unsigned char px[4]; for(i=0; i < pixels; i++) { memcpy(px, row + i * 3, 3); px[0] = sample_to_target(px[0], depth, sbit->red_bits, 8); px[1] = sample_to_target(px[1], depth, sbit->green_bits, 8); px[2] = sample_to_target(px[2], depth, sbit->blue_bits, 8); memcpy(row + i * 3, px, 3); } } else if(fmt == SPNG_FMT_G8) { for(i=0; i < pixels; i++) { row[i] = sample_to_target(row[i], depth, sbit->grayscale_bits, 8); } } else if(fmt == SPNG_FMT_GA8) { for(i=0; i < pixels; i++) { row[i*2] = sample_to_target(row[i*2], depth, sbit->grayscale_bits, 8); } } } /* Expand to *row using 8-bit palette indices from *scanline */ static void expand_row(unsigned char *row, const unsigned char *scanline, const union spng__decode_plte *decode_plte, uint32_t width, int fmt) { uint32_t i = 0; unsigned char *px; unsigned char entry; const struct spng_plte_entry *plte = decode_plte->rgba; #if defined(SPNG_ARM) if(fmt == SPNG_FMT_RGBA8) i = expand_palette_rgba8_neon(row, scanline, decode_plte->raw, width); else if(fmt == SPNG_FMT_RGB8) { i = expand_palette_rgb8_neon(row, scanline, decode_plte->raw, width); for(; i < width; i++) {/* In this case the LUT is 3 bytes packed */ px = row + i * 3; entry = scanline[i]; px[0] = decode_plte->raw[entry * 3 + 0]; px[1] = decode_plte->raw[entry * 3 + 1]; px[2] = decode_plte->raw[entry * 3 + 2]; } return; } #endif if(fmt == SPNG_FMT_RGBA8) { for(; i < width; i++) { px = row + i * 4; entry = scanline[i]; px[0] = plte[entry].red; px[1] = plte[entry].green; px[2] = plte[entry].blue; px[3] = plte[entry].alpha; } } else if(fmt == SPNG_FMT_RGB8) { for(; i < width; i++) { px = row + i * 3; entry = scanline[i]; px[0] = plte[entry].red; px[1] = plte[entry].green; px[2] = plte[entry].blue; } } } /* Unpack 1/2/4/8-bit samples to G8/GA8/GA16 or G16 -> GA16 */ static void unpack_scanline(unsigned char *out, const unsigned char *scanline, uint32_t width, unsigned bit_depth, int fmt) { struct spng__iter iter = spng__iter_init(bit_depth, scanline); uint32_t i; uint16_t sample, alpha = 65535; if(fmt == SPNG_FMT_GA8) goto ga8; else if(fmt == SPNG_FMT_GA16) goto ga16; /* 1/2/4-bit -> 8-bit */ for(i=0; i < width; i++) out[i] = get_sample(&iter); return; ga8: /* 1/2/4/8-bit -> GA8 */ for(i=0; i < width; i++) { out[i*2] = get_sample(&iter); out[i*2 + 1] = 255; } return; ga16: /* 16 -> GA16 */ if(bit_depth == 16) { for(i=0; i < width; i++) { memcpy(out + i * 4, scanline + i * 2, 2); memcpy(out + i * 4 + 2, &alpha, 2); } return; } /* 1/2/4/8-bit -> GA16 */ for(i=0; i < width; i++) { sample = get_sample(&iter); memcpy(out + i * 4, &sample, 2); memcpy(out + i * 4 + 2, &alpha, 2); } } static int check_ihdr(const struct spng_ihdr *ihdr, uint32_t max_width, uint32_t max_height) { if(ihdr->width > spng_u32max || !ihdr->width) return SPNG_EWIDTH; if(ihdr->height > spng_u32max || !ihdr->height) return SPNG_EHEIGHT; if(ihdr->width > max_width) return SPNG_EUSER_WIDTH; if(ihdr->height > max_height) return SPNG_EUSER_HEIGHT; switch(ihdr->color_type) { case SPNG_COLOR_TYPE_GRAYSCALE: { if( !(ihdr->bit_depth == 1 || ihdr->bit_depth == 2 || ihdr->bit_depth == 4 || ihdr->bit_depth == 8 || ihdr->bit_depth == 16) ) return SPNG_EBIT_DEPTH; break; } case SPNG_COLOR_TYPE_TRUECOLOR: case SPNG_COLOR_TYPE_GRAYSCALE_ALPHA: case SPNG_COLOR_TYPE_TRUECOLOR_ALPHA: { if( !(ihdr->bit_depth == 8 || ihdr->bit_depth == 16) ) return SPNG_EBIT_DEPTH; break; } case SPNG_COLOR_TYPE_INDEXED: { if( !(ihdr->bit_depth == 1 || ihdr->bit_depth == 2 || ihdr->bit_depth == 4 || ihdr->bit_depth == 8) ) return SPNG_EBIT_DEPTH; break; } default: return SPNG_ECOLOR_TYPE; } if(ihdr->compression_method) return SPNG_ECOMPRESSION_METHOD; if(ihdr->filter_method) return SPNG_EFILTER_METHOD; if(ihdr->interlace_method > 1) return SPNG_EINTERLACE_METHOD; return 0; } static int check_plte(const struct spng_plte *plte, const struct spng_ihdr *ihdr) { if(plte == NULL || ihdr == NULL) return 1; if(plte->n_entries == 0) return 1; if(plte->n_entries > 256) return 1; if(ihdr->color_type == SPNG_COLOR_TYPE_INDEXED) { if(plte->n_entries > (1U << ihdr->bit_depth)) return 1; } return 0; } static int check_sbit(const struct spng_sbit *sbit, const struct spng_ihdr *ihdr) { if(sbit == NULL || ihdr == NULL) return 1; if(ihdr->color_type == 0) { if(sbit->grayscale_bits == 0) return SPNG_ESBIT; if(sbit->grayscale_bits > ihdr->bit_depth) return SPNG_ESBIT; } else if(ihdr->color_type == 2 || ihdr->color_type == 3) { if(sbit->red_bits == 0) return SPNG_ESBIT; if(sbit->green_bits == 0) return SPNG_ESBIT; if(sbit->blue_bits == 0) return SPNG_ESBIT; uint8_t bit_depth; if(ihdr->color_type == 3) bit_depth = 8; else bit_depth = ihdr->bit_depth; if(sbit->red_bits > bit_depth) return SPNG_ESBIT; if(sbit->green_bits > bit_depth) return SPNG_ESBIT; if(sbit->blue_bits > bit_depth) return SPNG_ESBIT; } else if(ihdr->color_type == 4) { if(sbit->grayscale_bits == 0) return SPNG_ESBIT; if(sbit->alpha_bits == 0) return SPNG_ESBIT; if(sbit->grayscale_bits > ihdr->bit_depth) return SPNG_ESBIT; if(sbit->alpha_bits > ihdr->bit_depth) return SPNG_ESBIT; } else if(ihdr->color_type == 6) { if(sbit->red_bits == 0) return SPNG_ESBIT; if(sbit->green_bits == 0) return SPNG_ESBIT; if(sbit->blue_bits == 0) return SPNG_ESBIT; if(sbit->alpha_bits == 0) return SPNG_ESBIT; if(sbit->red_bits > ihdr->bit_depth) return SPNG_ESBIT; if(sbit->green_bits > ihdr->bit_depth) return SPNG_ESBIT; if(sbit->blue_bits > ihdr->bit_depth) return SPNG_ESBIT; if(sbit->alpha_bits > ihdr->bit_depth) return SPNG_ESBIT; } return 0; } static int check_chrm_int(const struct spng_chrm_int *chrm_int) { if(chrm_int == NULL) return 1; if(chrm_int->white_point_x > spng_u32max || chrm_int->white_point_y > spng_u32max || chrm_int->red_x > spng_u32max || chrm_int->red_y > spng_u32max || chrm_int->green_x > spng_u32max || chrm_int->green_y > spng_u32max || chrm_int->blue_x > spng_u32max || chrm_int->blue_y > spng_u32max) return SPNG_ECHRM; return 0; } static int check_phys(const struct spng_phys *phys) { if(phys == NULL) return 1; if(phys->unit_specifier > 1) return SPNG_EPHYS; if(phys->ppu_x > spng_u32max) return SPNG_EPHYS; if(phys->ppu_y > spng_u32max) return SPNG_EPHYS; return 0; } static int check_time(const struct spng_time *time) { if(time == NULL) return 1; if(time->month == 0 || time->month > 12) return 1; if(time->day == 0 || time->day > 31) return 1; if(time->hour > 23) return 1; if(time->minute > 59) return 1; if(time->second > 60) return 1; return 0; } static int check_offs(const struct spng_offs *offs) { if(offs == NULL) return 1; if(offs->unit_specifier > 1) return 1; return 0; } static int check_exif(const struct spng_exif *exif) { if(exif == NULL) return 1; if(exif->data == NULL) return 1; if(exif->length < 4) return SPNG_ECHUNK_SIZE; if(exif->length > spng_u32max) return SPNG_ECHUNK_STDLEN; const uint8_t exif_le[4] = { 73, 73, 42, 0 }; const uint8_t exif_be[4] = { 77, 77, 0, 42 }; if(memcmp(exif->data, exif_le, 4) && memcmp(exif->data, exif_be, 4)) return 1; return 0; } /* Validate PNG keyword */ static int check_png_keyword(const char *str) { if(str == NULL) return 1; size_t len = strlen(str); const char *end = str + len; if(!len) return 1; if(len > 79) return 1; if(str[0] == ' ') return 1; /* Leading space */ if(end[-1] == ' ') return 1; /* Trailing space */ if(strstr(str, " ") != NULL) return 1; /* Consecutive spaces */ uint8_t c; while(str != end) { memcpy(&c, str, 1); if( (c >= 32 && c <= 126) || (c >= 161) ) str++; else return 1; /* Invalid character */ } return 0; } /* Validate PNG text *str up to 'len' bytes */ static int check_png_text(const char *str, size_t len) {/* XXX: are consecutive newlines permitted? */ if(str == NULL || len == 0) return 1; uint8_t c; size_t i = 0; while(i < len) { memcpy(&c, str + i, 1); if( (c >= 32 && c <= 126) || (c >= 161) || c == 10) i++; else return 1; /* Invalid character */ } return 0; } /* Returns non-zero for standard chunks which are stored without allocating memory */ static int is_small_chunk(uint8_t type[4]) { if(!memcmp(type, type_plte, 4)) return 1; else if(!memcmp(type, type_chrm, 4)) return 1; else if(!memcmp(type, type_gama, 4)) return 1; else if(!memcmp(type, type_sbit, 4)) return 1; else if(!memcmp(type, type_srgb, 4)) return 1; else if(!memcmp(type, type_bkgd, 4)) return 1; else if(!memcmp(type, type_trns, 4)) return 1; else if(!memcmp(type, type_hist, 4)) return 1; else if(!memcmp(type, type_phys, 4)) return 1; else if(!memcmp(type, type_time, 4)) return 1; else if(!memcmp(type, type_offs, 4)) return 1; else return 0; } static int read_ihdr(spng_ctx *ctx) { int ret; struct spng_chunk *chunk = &ctx->current_chunk; const unsigned char *data; chunk->offset = 8; chunk->length = 13; size_t sizeof_sig_ihdr = 29; ret = read_data(ctx, sizeof_sig_ihdr); if(ret) return ret; data = ctx->data; if(memcmp(data, spng_signature, sizeof(spng_signature))) return SPNG_ESIGNATURE; chunk->length = read_u32(data + 8); memcpy(&chunk->type, data + 12, 4); if(chunk->length != 13) return SPNG_EIHDR_SIZE; if(memcmp(chunk->type, type_ihdr, 4)) return SPNG_ENOIHDR; ctx->cur_actual_crc = crc32(0, NULL, 0); ctx->cur_actual_crc = crc32(ctx->cur_actual_crc, data + 12, 17); ctx->ihdr.width = read_u32(data + 16); ctx->ihdr.height = read_u32(data + 20); ctx->ihdr.bit_depth = data[24]; ctx->ihdr.color_type = data[25]; ctx->ihdr.compression_method = data[26]; ctx->ihdr.filter_method = data[27]; ctx->ihdr.interlace_method = data[28]; ret = check_ihdr(&ctx->ihdr, ctx->max_width, ctx->max_height); if(ret) return ret; ctx->file.ihdr = 1; ctx->stored.ihdr = 1; if(ctx->ihdr.bit_depth < 8) ctx->bytes_per_pixel = 1; else ctx->bytes_per_pixel = num_channels(&ctx->ihdr) * (ctx->ihdr.bit_depth / 8); ret = calculate_subimages(ctx); if(ret) return ret; return 0; } static void splt_undo(spng_ctx *ctx) { struct spng_splt *splt = &ctx->splt_list[ctx->n_splt - 1]; spng__free(ctx, splt->entries); decrease_cache_usage(ctx, sizeof(struct spng_splt)); decrease_cache_usage(ctx, splt->n_entries * sizeof(struct spng_splt_entry)); splt->entries = NULL; ctx->n_splt--; } static void text_undo(spng_ctx *ctx) { struct spng_text2 *text = &ctx->text_list[ctx->n_text - 1]; spng__free(ctx, text->keyword); if(text->compression_flag) spng__free(ctx, text->text); decrease_cache_usage(ctx, text->cache_usage); decrease_cache_usage(ctx, sizeof(struct spng_text2)); text->keyword = NULL; text->text = NULL; ctx->n_text--; } static void chunk_undo(spng_ctx *ctx) { struct spng_unknown_chunk *chunk = &ctx->chunk_list[ctx->n_chunks - 1]; spng__free(ctx, chunk->data); decrease_cache_usage(ctx, chunk->length); decrease_cache_usage(ctx, sizeof(struct spng_unknown_chunk)); chunk->data = NULL; ctx->n_chunks--; } static int read_non_idat_chunks(spng_ctx *ctx) { int ret; struct spng_chunk chunk; const unsigned char *data; ctx->discard = 0; ctx->undo = NULL; ctx->prev_stored = ctx->stored; while( !(ret = read_header(ctx))) { if(ctx->discard) { if(ctx->undo) ctx->undo(ctx); ctx->stored = ctx->prev_stored; } ctx->discard = 0; ctx->undo = NULL; ctx->prev_stored = ctx->stored; chunk = ctx->current_chunk; if(!memcmp(chunk.type, type_idat, 4)) { if(ctx->state < SPNG_STATE_FIRST_IDAT) { if(ctx->ihdr.color_type == 3 && !ctx->stored.plte) return SPNG_ENOPLTE; ctx->first_idat = chunk; return 0; } if(ctx->prev_was_idat) { /* Ignore extra IDAT's */ ret = discard_chunk_bytes(ctx, chunk.length); if(ret) return ret; continue; } else return SPNG_ECHUNK_POS; /* IDAT chunk not at the end of the IDAT sequence */ } ctx->prev_was_idat = 0; if(is_small_chunk(chunk.type)) { /* None of the known chunks can be zero length */ if(!chunk.length) return SPNG_ECHUNK_SIZE; /* The largest of these chunks is PLTE with 256 entries */ ret = read_chunk_bytes(ctx, chunk.length > 768 ? 768 : chunk.length); if(ret) return ret; } data = ctx->data; if(is_critical_chunk(&chunk)) { if(!memcmp(chunk.type, type_plte, 4)) { if(ctx->file.trns || ctx->file.hist || ctx->file.bkgd) return SPNG_ECHUNK_POS; if(chunk.length % 3 != 0) return SPNG_ECHUNK_SIZE; ctx->plte.n_entries = chunk.length / 3; if(check_plte(&ctx->plte, &ctx->ihdr)) return SPNG_ECHUNK_SIZE; /* XXX: EPLTE? */ size_t i; for(i=0; i < ctx->plte.n_entries; i++) { ctx->plte.entries[i].red = data[i * 3]; ctx->plte.entries[i].green = data[i * 3 + 1]; ctx->plte.entries[i].blue = data[i * 3 + 2]; } ctx->file.plte = 1; ctx->stored.plte = 1; } else if(!memcmp(chunk.type, type_iend, 4)) { if(ctx->state == SPNG_STATE_AFTER_IDAT) { if(chunk.length) return SPNG_ECHUNK_SIZE; ret = read_and_check_crc(ctx); if(ret == -SPNG_CRC_DISCARD) ret = 0; return ret; } else return SPNG_ECHUNK_POS; } else if(!memcmp(chunk.type, type_ihdr, 4)) return SPNG_ECHUNK_POS; else return SPNG_ECHUNK_UNKNOWN_CRITICAL; } else if(!memcmp(chunk.type, type_chrm, 4)) /* Ancillary chunks */ { if(ctx->file.plte) return SPNG_ECHUNK_POS; if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.chrm) return SPNG_EDUP_CHRM; if(chunk.length != 32) return SPNG_ECHUNK_SIZE; ctx->chrm_int.white_point_x = read_u32(data); ctx->chrm_int.white_point_y = read_u32(data + 4); ctx->chrm_int.red_x = read_u32(data + 8); ctx->chrm_int.red_y = read_u32(data + 12); ctx->chrm_int.green_x = read_u32(data + 16); ctx->chrm_int.green_y = read_u32(data + 20); ctx->chrm_int.blue_x = read_u32(data + 24); ctx->chrm_int.blue_y = read_u32(data + 28); if(check_chrm_int(&ctx->chrm_int)) return SPNG_ECHRM; ctx->file.chrm = 1; ctx->stored.chrm = 1; } else if(!memcmp(chunk.type, type_gama, 4)) { if(ctx->file.plte) return SPNG_ECHUNK_POS; if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.gama) return SPNG_EDUP_GAMA; if(chunk.length != 4) return SPNG_ECHUNK_SIZE; ctx->gama = read_u32(data); if(!ctx->gama) return SPNG_EGAMA; if(ctx->gama > spng_u32max) return SPNG_EGAMA; ctx->file.gama = 1; ctx->stored.gama = 1; } else if(!memcmp(chunk.type, type_sbit, 4)) { if(ctx->file.plte) return SPNG_ECHUNK_POS; if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.sbit) return SPNG_EDUP_SBIT; if(ctx->ihdr.color_type == 0) { if(chunk.length != 1) return SPNG_ECHUNK_SIZE; ctx->sbit.grayscale_bits = data[0]; } else if(ctx->ihdr.color_type == 2 || ctx->ihdr.color_type == 3) { if(chunk.length != 3) return SPNG_ECHUNK_SIZE; ctx->sbit.red_bits = data[0]; ctx->sbit.green_bits = data[1]; ctx->sbit.blue_bits = data[2]; } else if(ctx->ihdr.color_type == 4) { if(chunk.length != 2) return SPNG_ECHUNK_SIZE; ctx->sbit.grayscale_bits = data[0]; ctx->sbit.alpha_bits = data[1]; } else if(ctx->ihdr.color_type == 6) { if(chunk.length != 4) return SPNG_ECHUNK_SIZE; ctx->sbit.red_bits = data[0]; ctx->sbit.green_bits = data[1]; ctx->sbit.blue_bits = data[2]; ctx->sbit.alpha_bits = data[3]; } if(check_sbit(&ctx->sbit, &ctx->ihdr)) return SPNG_ESBIT; ctx->file.sbit = 1; ctx->stored.sbit = 1; } else if(!memcmp(chunk.type, type_srgb, 4)) { if(ctx->file.plte) return SPNG_ECHUNK_POS; if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.srgb) return SPNG_EDUP_SRGB; if(chunk.length != 1) return SPNG_ECHUNK_SIZE; ctx->srgb_rendering_intent = data[0]; if(ctx->srgb_rendering_intent > 3) return SPNG_ESRGB; ctx->file.srgb = 1; ctx->stored.srgb = 1; } else if(!memcmp(chunk.type, type_bkgd, 4)) { if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.bkgd) return SPNG_EDUP_BKGD; if(ctx->ihdr.color_type == 0 || ctx->ihdr.color_type == 4) { if(chunk.length != 2) return SPNG_ECHUNK_SIZE; ctx->bkgd.gray = read_u16(data); } else if(ctx->ihdr.color_type == 2 || ctx->ihdr.color_type == 6) { if(chunk.length != 6) return SPNG_ECHUNK_SIZE; ctx->bkgd.red = read_u16(data); ctx->bkgd.green = read_u16(data + 2); ctx->bkgd.blue = read_u16(data + 4); } else if(ctx->ihdr.color_type == 3) { if(chunk.length != 1) return SPNG_ECHUNK_SIZE; if(!ctx->file.plte) return SPNG_EBKGD_NO_PLTE; ctx->bkgd.plte_index = data[0]; if(ctx->bkgd.plte_index >= ctx->plte.n_entries) return SPNG_EBKGD_PLTE_IDX; } ctx->file.bkgd = 1; ctx->stored.bkgd = 1; } else if(!memcmp(chunk.type, type_trns, 4)) { if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.trns) return SPNG_EDUP_TRNS; if(!chunk.length) return SPNG_ECHUNK_SIZE; if(ctx->ihdr.color_type == 0) { if(chunk.length != 2) return SPNG_ECHUNK_SIZE; ctx->trns.gray = read_u16(data); } else if(ctx->ihdr.color_type == 2) { if(chunk.length != 6) return SPNG_ECHUNK_SIZE; ctx->trns.red = read_u16(data); ctx->trns.green = read_u16(data + 2); ctx->trns.blue = read_u16(data + 4); } else if(ctx->ihdr.color_type == 3) { if(chunk.length > ctx->plte.n_entries) return SPNG_ECHUNK_SIZE; if(!ctx->file.plte) return SPNG_ETRNS_NO_PLTE; memcpy(ctx->trns.type3_alpha, data, chunk.length); ctx->trns.n_type3_entries = chunk.length; } if(ctx->ihdr.color_type == 4 || ctx->ihdr.color_type == 6) return SPNG_ETRNS_COLOR_TYPE; ctx->file.trns = 1; ctx->stored.trns = 1; } else if(!memcmp(chunk.type, type_hist, 4)) { if(!ctx->file.plte) return SPNG_EHIST_NO_PLTE; if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.hist) return SPNG_EDUP_HIST; if( (chunk.length / 2) != (ctx->plte.n_entries) ) return SPNG_ECHUNK_SIZE; size_t k; for(k=0; k < (chunk.length / 2); k++) { ctx->hist.frequency[k] = read_u16(data + k*2); } ctx->file.hist = 1; ctx->stored.hist = 1; } else if(!memcmp(chunk.type, type_phys, 4)) { if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.phys) return SPNG_EDUP_PHYS; if(chunk.length != 9) return SPNG_ECHUNK_SIZE; ctx->phys.ppu_x = read_u32(data); ctx->phys.ppu_y = read_u32(data + 4); ctx->phys.unit_specifier = data[8]; if(check_phys(&ctx->phys)) return SPNG_EPHYS; ctx->file.phys = 1; ctx->stored.phys = 1; } else if(!memcmp(chunk.type, type_time, 4)) { if(ctx->file.time) return SPNG_EDUP_TIME; if(chunk.length != 7) return SPNG_ECHUNK_SIZE; struct spng_time time; time.year = read_u16(data); time.month = data[2]; time.day = data[3]; time.hour = data[4]; time.minute = data[5]; time.second = data[6]; if(check_time(&time)) return SPNG_ETIME; ctx->file.time = 1; if(!ctx->user.time) ctx->time = time; ctx->stored.time = 1; } else if(!memcmp(chunk.type, type_offs, 4)) { if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.offs) return SPNG_EDUP_OFFS; if(chunk.length != 9) return SPNG_ECHUNK_SIZE; ctx->offs.x = read_s32(data); ctx->offs.y = read_s32(data + 4); ctx->offs.unit_specifier = data[8]; if(check_offs(&ctx->offs)) return SPNG_EOFFS; ctx->file.offs = 1; ctx->stored.offs = 1; } else /* Arbitrary-length chunk */ { if(!memcmp(chunk.type, type_exif, 4)) { if(ctx->file.exif) return SPNG_EDUP_EXIF; if(!chunk.length) return SPNG_EEXIF; ctx->file.exif = 1; if(ctx->user.exif) goto discard; if(increase_cache_usage(ctx, chunk.length, 1)) return SPNG_ECHUNK_LIMITS; struct spng_exif exif; exif.length = chunk.length; exif.data = spng__malloc(ctx, chunk.length); if(exif.data == NULL) return SPNG_EMEM; ret = read_chunk_bytes2(ctx, exif.data, chunk.length); if(ret) { spng__free(ctx, exif.data); return ret; } if(check_exif(&exif)) { spng__free(ctx, exif.data); return SPNG_EEXIF; } ctx->exif = exif; ctx->stored.exif = 1; } else if(!memcmp(chunk.type, type_iccp, 4)) {/* TODO: add test file with color profile */ if(ctx->file.plte) return SPNG_ECHUNK_POS; if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->file.iccp) return SPNG_EDUP_ICCP; if(!chunk.length) return SPNG_ECHUNK_SIZE; ctx->file.iccp = 1; uint32_t peek_bytes = 81 > chunk.length ? chunk.length : 81; ret = read_chunk_bytes(ctx, peek_bytes); if(ret) return ret; unsigned char *keyword_nul = memchr(ctx->data, '\0', peek_bytes); if(keyword_nul == NULL) return SPNG_EICCP_NAME; uint32_t keyword_len = keyword_nul - ctx->data; if(keyword_len > 79) return SPNG_EICCP_NAME; memcpy(ctx->iccp.profile_name, ctx->data, keyword_len); if(check_png_keyword(ctx->iccp.profile_name)) return SPNG_EICCP_NAME; if(chunk.length < (keyword_len + 2)) return SPNG_ECHUNK_SIZE; if(ctx->data[keyword_len + 1] != 0) return SPNG_EICCP_COMPRESSION_METHOD; ret = spng__inflate_stream(ctx, &ctx->iccp.profile, &ctx->iccp.profile_len, 0, ctx->data + keyword_len + 2, peek_bytes - (keyword_len + 2)); if(ret) return ret; ctx->stored.iccp = 1; } else if(!memcmp(chunk.type, type_text, 4) || !memcmp(chunk.type, type_ztxt, 4) || !memcmp(chunk.type, type_itxt, 4)) { if(!chunk.length) return SPNG_ECHUNK_SIZE; ctx->file.text = 1; if(ctx->user.text) goto discard; if(increase_cache_usage(ctx, sizeof(struct spng_text2), 1)) return SPNG_ECHUNK_LIMITS; ctx->n_text++; if(ctx->n_text < 1) return SPNG_EOVERFLOW; if(sizeof(struct spng_text2) > SIZE_MAX / ctx->n_text) return SPNG_EOVERFLOW; void *buf = spng__realloc(ctx, ctx->text_list, ctx->n_text * sizeof(struct spng_text2)); if(buf == NULL) return SPNG_EMEM; ctx->text_list = buf; struct spng_text2 *text = &ctx->text_list[ctx->n_text - 1]; memset(text, 0, sizeof(struct spng_text2)); ctx->undo = text_undo; uint32_t text_offset = 0, language_tag_offset = 0, translated_keyword_offset = 0; uint32_t peek_bytes = 256; /* enough for 3 80-byte keywords and some text bytes */ uint32_t keyword_len; if(peek_bytes > chunk.length) peek_bytes = chunk.length; ret = read_chunk_bytes(ctx, peek_bytes); if(ret) return ret; data = ctx->data; const unsigned char *zlib_stream = NULL; const unsigned char *peek_end = data + peek_bytes; const unsigned char *keyword_nul = memchr(data, 0, chunk.length > 80 ? 80 : chunk.length); if(keyword_nul == NULL) return SPNG_ETEXT_KEYWORD; keyword_len = keyword_nul - data; if(!memcmp(chunk.type, type_text, 4)) { text->type = SPNG_TEXT; text->text_length = chunk.length - keyword_len - 1; text_offset = keyword_len; /* increment past nul if there is a text field */ if(text->text_length) text_offset++; } else if(!memcmp(chunk.type, type_ztxt, 4)) { text->type = SPNG_ZTXT; if((peek_bytes - keyword_len) <= 2) return SPNG_EZTXT; if(keyword_nul[1]) return SPNG_EZTXT_COMPRESSION_METHOD; text->compression_flag = 1; text_offset = keyword_len + 2; } else if(!memcmp(chunk.type, type_itxt, 4)) { text->type = SPNG_ITXT; /* at least two 1-byte fields, two >=0 length strings, and one byte of (compressed) text */ if((peek_bytes - keyword_len) < 5) return SPNG_EITXT; text->compression_flag = keyword_nul[1]; if(text->compression_flag > 1) return SPNG_EITXT_COMPRESSION_FLAG; if(keyword_nul[2]) return SPNG_EITXT_COMPRESSION_METHOD; language_tag_offset = keyword_len + 3; const unsigned char *term; term = memchr(data + language_tag_offset, 0, peek_bytes - language_tag_offset); if(term == NULL) return SPNG_EITXT_LANG_TAG; if((peek_end - term) < 2) return SPNG_EITXT; translated_keyword_offset = term - data + 1; zlib_stream = memchr(data + translated_keyword_offset, 0, peek_bytes - translated_keyword_offset); if(zlib_stream == NULL) return SPNG_EITXT; if(zlib_stream == peek_end) return SPNG_EITXT; text_offset = zlib_stream - data + 1; text->text_length = chunk.length - text_offset; } else return SPNG_EINTERNAL; if(text->compression_flag) { /* cache usage = peek_bytes + decompressed text size + nul */ if(increase_cache_usage(ctx, peek_bytes, 0)) return SPNG_ECHUNK_LIMITS; text->keyword = spng__calloc(ctx, 1, peek_bytes); if(text->keyword == NULL) return SPNG_EMEM; memcpy(text->keyword, data, peek_bytes); zlib_stream = ctx->data + text_offset; ret = spng__inflate_stream(ctx, &text->text, &text->text_length, 1, zlib_stream, peek_bytes - text_offset); if(ret) return ret; text->text[text->text_length - 1] = '\0'; text->cache_usage = text->text_length + peek_bytes; } else { if(increase_cache_usage(ctx, chunk.length + 1, 0)) return SPNG_ECHUNK_LIMITS; text->keyword = spng__malloc(ctx, chunk.length + 1); if(text->keyword == NULL) return SPNG_EMEM; memcpy(text->keyword, data, peek_bytes); if(chunk.length > peek_bytes) { ret = read_chunk_bytes2(ctx, text->keyword + peek_bytes, chunk.length - peek_bytes); if(ret) return ret; } text->text = text->keyword + text_offset; text->text_length = chunk.length - text_offset; text->text[text->text_length] = '\0'; text->cache_usage = chunk.length + 1; } if(check_png_keyword(text->keyword)) return SPNG_ETEXT_KEYWORD; text->text_length = strlen(text->text); if(text->type != SPNG_ITXT) { language_tag_offset = keyword_len; translated_keyword_offset = keyword_len; if(ctx->strict && check_png_text(text->text, text->text_length)) { if(text->type == SPNG_ZTXT) return SPNG_EZTXT; else return SPNG_ETEXT; } } text->language_tag = text->keyword + language_tag_offset; text->translated_keyword = text->keyword + translated_keyword_offset; ctx->stored.text = 1; } else if(!memcmp(chunk.type, type_splt, 4)) { if(ctx->state == SPNG_STATE_AFTER_IDAT) return SPNG_ECHUNK_POS; if(ctx->user.splt) goto discard; /* XXX: could check profile names for uniqueness */ if(!chunk.length) return SPNG_ECHUNK_SIZE; ctx->file.splt = 1; /* chunk.length + sizeof(struct spng_splt) + splt->n_entries * sizeof(struct spng_splt_entry) */ if(increase_cache_usage(ctx, chunk.length + sizeof(struct spng_splt), 1)) return SPNG_ECHUNK_LIMITS; ctx->n_splt++; if(ctx->n_splt < 1) return SPNG_EOVERFLOW; if(sizeof(struct spng_splt) > SIZE_MAX / ctx->n_splt) return SPNG_EOVERFLOW; void *buf = spng__realloc(ctx, ctx->splt_list, ctx->n_splt * sizeof(struct spng_splt)); if(buf == NULL) return SPNG_EMEM; ctx->splt_list = buf; struct spng_splt *splt = &ctx->splt_list[ctx->n_splt - 1]; memset(splt, 0, sizeof(struct spng_splt)); ctx->undo = splt_undo; void *t = spng__malloc(ctx, chunk.length); if(t == NULL) return SPNG_EMEM; splt->entries = t; /* simplifies error handling */ data = t; ret = read_chunk_bytes2(ctx, t, chunk.length); if(ret) return ret; uint32_t keyword_len = chunk.length < 80 ? chunk.length : 80; const unsigned char *keyword_nul = memchr(data, 0, keyword_len); if(keyword_nul == NULL) return SPNG_ESPLT_NAME; keyword_len = keyword_nul - data; memcpy(splt->name, data, keyword_len); if(check_png_keyword(splt->name)) return SPNG_ESPLT_NAME; uint32_t j; for(j=0; j < (ctx->n_splt - 1); j++) { if(!strcmp(ctx->splt_list[j].name, splt->name)) return SPNG_ESPLT_DUP_NAME; } if( (chunk.length - keyword_len) <= 2) return SPNG_ECHUNK_SIZE; splt->sample_depth = data[keyword_len + 1]; uint32_t entries_len = chunk.length - keyword_len - 2; if(!entries_len) return SPNG_ECHUNK_SIZE; if(splt->sample_depth == 16) { if(entries_len % 10 != 0) return SPNG_ECHUNK_SIZE; splt->n_entries = entries_len / 10; } else if(splt->sample_depth == 8) { if(entries_len % 6 != 0) return SPNG_ECHUNK_SIZE; splt->n_entries = entries_len / 6; } else return SPNG_ESPLT_DEPTH; if(!splt->n_entries) return SPNG_ECHUNK_SIZE; size_t list_size = splt->n_entries; if(list_size > SIZE_MAX / sizeof(struct spng_splt_entry)) return SPNG_EOVERFLOW; list_size *= sizeof(struct spng_splt_entry); if(increase_cache_usage(ctx, list_size, 0)) return SPNG_ECHUNK_LIMITS; splt->entries = spng__malloc(ctx, list_size); if(splt->entries == NULL) { spng__free(ctx, t); return SPNG_EMEM; } data = (unsigned char*)t + keyword_len + 2; uint32_t k; if(splt->sample_depth == 16) { for(k=0; k < splt->n_entries; k++) { splt->entries[k].red = read_u16(data + k * 10); splt->entries[k].green = read_u16(data + k * 10 + 2); splt->entries[k].blue = read_u16(data + k * 10 + 4); splt->entries[k].alpha = read_u16(data + k * 10 + 6); splt->entries[k].frequency = read_u16(data + k * 10 + 8); } } else if(splt->sample_depth == 8) { for(k=0; k < splt->n_entries; k++) { splt->entries[k].red = data[k * 6]; splt->entries[k].green = data[k * 6 + 1]; splt->entries[k].blue = data[k * 6 + 2]; splt->entries[k].alpha = data[k * 6 + 3]; splt->entries[k].frequency = read_u16(data + k * 6 + 4); } } spng__free(ctx, t); decrease_cache_usage(ctx, chunk.length); ctx->stored.splt = 1; } else /* Unknown chunk */ { ctx->file.unknown = 1; if(!ctx->keep_unknown) goto discard; if(ctx->user.unknown) goto discard; if(increase_cache_usage(ctx, chunk.length + sizeof(struct spng_unknown_chunk), 1)) return SPNG_ECHUNK_LIMITS; ctx->n_chunks++; if(ctx->n_chunks < 1) return SPNG_EOVERFLOW; if(sizeof(struct spng_unknown_chunk) > SIZE_MAX / ctx->n_chunks) return SPNG_EOVERFLOW; void *buf = spng__realloc(ctx, ctx->chunk_list, ctx->n_chunks * sizeof(struct spng_unknown_chunk)); if(buf == NULL) return SPNG_EMEM; ctx->chunk_list = buf; struct spng_unknown_chunk *chunkp = &ctx->chunk_list[ctx->n_chunks - 1]; memset(chunkp, 0, sizeof(struct spng_unknown_chunk)); ctx->undo = chunk_undo; memcpy(chunkp->type, chunk.type, 4); if(ctx->state < SPNG_STATE_FIRST_IDAT) { if(ctx->file.plte) chunkp->location = SPNG_AFTER_PLTE; else chunkp->location = SPNG_AFTER_IHDR; } else if(ctx->state >= SPNG_STATE_AFTER_IDAT) chunkp->location = SPNG_AFTER_IDAT; if(chunk.length > 0) { void *t = spng__malloc(ctx, chunk.length); if(t == NULL) return SPNG_EMEM; ret = read_chunk_bytes2(ctx, t, chunk.length); if(ret) { spng__free(ctx, t); return ret; } chunkp->length = chunk.length; chunkp->data = t; } ctx->stored.unknown = 1; } discard: ret = discard_chunk_bytes(ctx, ctx->cur_chunk_bytes_left); if(ret) return ret; } } return ret; } /* Read chunks before or after the IDAT chunks depending on state */ static int read_chunks(spng_ctx *ctx, int only_ihdr) { if(ctx == NULL) return SPNG_EINTERNAL; if(!ctx->state) return SPNG_EBADSTATE; if(ctx->data == NULL) { if(ctx->encode_only) return 0; else return SPNG_EINTERNAL; } int ret = 0; if(ctx->state == SPNG_STATE_INPUT) { ret = read_ihdr(ctx); if(ret) return decode_err(ctx, ret); ctx->state = SPNG_STATE_IHDR; } if(only_ihdr) return 0; if(ctx->state == SPNG_STATE_EOI) { ctx->state = SPNG_STATE_AFTER_IDAT; ctx->prev_was_idat = 1; } while(ctx->state < SPNG_STATE_FIRST_IDAT || ctx->state == SPNG_STATE_AFTER_IDAT) { ret = read_non_idat_chunks(ctx); if(!ret) { if(ctx->state < SPNG_STATE_FIRST_IDAT) ctx->state = SPNG_STATE_FIRST_IDAT; else if(ctx->state == SPNG_STATE_AFTER_IDAT) ctx->state = SPNG_STATE_IEND; } else { switch(ret) { case SPNG_ECHUNK_POS: case SPNG_ECHUNK_SIZE: /* size != expected size, SPNG_ECHUNK_STDLEN = invalid size */ case SPNG_EDUP_PLTE: case SPNG_EDUP_CHRM: case SPNG_EDUP_GAMA: case SPNG_EDUP_ICCP: case SPNG_EDUP_SBIT: case SPNG_EDUP_SRGB: case SPNG_EDUP_BKGD: case SPNG_EDUP_HIST: case SPNG_EDUP_TRNS: case SPNG_EDUP_PHYS: case SPNG_EDUP_TIME: case SPNG_EDUP_OFFS: case SPNG_EDUP_EXIF: case SPNG_ECHRM: case SPNG_ETRNS_COLOR_TYPE: case SPNG_ETRNS_NO_PLTE: case SPNG_EGAMA: case SPNG_EICCP_NAME: case SPNG_EICCP_COMPRESSION_METHOD: case SPNG_ESBIT: case SPNG_ESRGB: case SPNG_ETEXT: case SPNG_ETEXT_KEYWORD: case SPNG_EZTXT: case SPNG_EZTXT_COMPRESSION_METHOD: case SPNG_EITXT: case SPNG_EITXT_COMPRESSION_FLAG: case SPNG_EITXT_COMPRESSION_METHOD: case SPNG_EITXT_LANG_TAG: case SPNG_EITXT_TRANSLATED_KEY: case SPNG_EBKGD_NO_PLTE: case SPNG_EBKGD_PLTE_IDX: case SPNG_EHIST_NO_PLTE: case SPNG_EPHYS: case SPNG_ESPLT_NAME: case SPNG_ESPLT_DUP_NAME: case SPNG_ESPLT_DEPTH: case SPNG_ETIME: case SPNG_EOFFS: case SPNG_EEXIF: case SPNG_EZLIB: { if(!ctx->strict && !is_critical_chunk(&ctx->current_chunk)) { ret = discard_chunk_bytes(ctx, ctx->cur_chunk_bytes_left); if(ret) return decode_err(ctx, ret); if(ctx->undo) ctx->undo(ctx); ctx->stored = ctx->prev_stored; ctx->discard = 0; ctx->undo = NULL; continue; } else return decode_err(ctx, ret); break; } default: return decode_err(ctx, ret); } } } return ret; } static int read_scanline(spng_ctx *ctx) { int ret, pass = ctx->row_info.pass; struct spng_row_info *ri = &ctx->row_info; const struct spng_subimage *sub = ctx->subimage; size_t scanline_width = sub[pass].scanline_width; uint32_t scanline_idx = ri->scanline_idx; uint8_t next_filter = 0; if(scanline_idx == (sub[pass].height - 1) && ri->pass == ctx->last_pass) { ret = read_scanline_bytes(ctx, ctx->scanline, scanline_width - 1); } else { ret = read_scanline_bytes(ctx, ctx->scanline, scanline_width); if(ret) return ret; next_filter = ctx->scanline[scanline_width - 1]; if(next_filter > 4) ret = SPNG_EFILTER; } if(ret) return ret; if(!scanline_idx && ri->filter > 1) { /* prev_scanline is all zeros for the first scanline */ memset(ctx->prev_scanline, 0, scanline_width); } if(ctx->ihdr.bit_depth == 16 && ctx->fmt != SPNG_FMT_RAW) u16_row_to_host(ctx->scanline, scanline_width - 1); ret = defilter_scanline(ctx->prev_scanline, ctx->scanline, scanline_width, ctx->bytes_per_pixel, ri->filter); if(ret) return ret; ri->filter = next_filter; return 0; } static int update_row_info(spng_ctx *ctx) { int interlacing = ctx->ihdr.interlace_method; struct spng_row_info *ri = &ctx->row_info; const struct spng_subimage *sub = ctx->subimage; if(ri->scanline_idx == (sub[ri->pass].height - 1)) /* Last scanline */ { if(ri->pass == ctx->last_pass) { ctx->state = SPNG_STATE_EOI; return SPNG_EOI; } ri->scanline_idx = 0; ri->pass++; /* Skip empty passes */ while( (!sub[ri->pass].width || !sub[ri->pass].height) && (ri->pass < ctx->last_pass)) ri->pass++; } else { ri->row_num++; ri->scanline_idx++; } if(interlacing) ri->row_num = adam7_y_start[ri->pass] + ri->scanline_idx * adam7_y_delta[ri->pass]; return 0; } int spng_decode_scanline(spng_ctx *ctx, void *out, size_t len) { if(ctx == NULL || out == NULL) return 1; if(ctx->state >= SPNG_STATE_EOI) return SPNG_EOI; struct decode_flags f = ctx->decode_flags; struct spng_row_info *ri = &ctx->row_info; const struct spng_subimage *sub = ctx->subimage; const struct spng_ihdr *ihdr = &ctx->ihdr; const uint16_t *gamma_lut = ctx->gamma_lut; unsigned char *trns_px = ctx->trns_px; const struct spng_sbit *sb = &ctx->decode_sb; const struct spng_plte_entry *plte = ctx->decode_plte.rgba; struct spng__iter iter = spng__iter_init(ihdr->bit_depth, ctx->scanline); const unsigned char *scanline; const int pass = ri->pass; const int fmt = ctx->fmt; const size_t scanline_width = sub[pass].scanline_width; const uint32_t width = sub[pass].width; uint32_t k; uint8_t r_8, g_8, b_8, a_8, gray_8; uint16_t r_16, g_16, b_16, a_16, gray_16; r_8=0; g_8=0; b_8=0; a_8=0; gray_8=0; r_16=0; g_16=0; b_16=0; a_16=0; gray_16=0; size_t pixel_size = 4; /* SPNG_FMT_RGBA8 */ size_t pixel_offset = 0; unsigned char *pixel; unsigned processing_depth = ihdr->bit_depth; if(f.indexed) processing_depth = 8; if(fmt == SPNG_FMT_RGBA16) pixel_size = 8; else if(fmt == SPNG_FMT_RGB8) pixel_size = 3; if(len < sub[pass].out_width) return SPNG_EBUFSIZ; int ret = read_scanline(ctx); if(ret) return decode_err(ctx, ret); scanline = ctx->scanline; for(k=0; k < width; k++) { pixel = (unsigned char*)out + pixel_offset; pixel_offset += pixel_size; if(f.same_layout) { if(f.zerocopy) break; memcpy(out, scanline, scanline_width - 1); break; } if(f.unpack) { unpack_scanline(out, scanline, width, ihdr->bit_depth, fmt); break; } if(ihdr->color_type == SPNG_COLOR_TYPE_TRUECOLOR) { if(ihdr->bit_depth == 16) { memcpy(&r_16, scanline + (k * 6), 2); memcpy(&g_16, scanline + (k * 6) + 2, 2); memcpy(&b_16, scanline + (k * 6) + 4, 2); a_16 = 65535; } else /* == 8 */ { if(fmt == SPNG_FMT_RGBA8) { rgb8_row_to_rgba8(scanline, out, width); break; } r_8 = scanline[k * 3]; g_8 = scanline[k * 3 + 1]; b_8 = scanline[k * 3 + 2]; a_8 = 255; } } else if(ihdr->color_type == SPNG_COLOR_TYPE_INDEXED) { uint8_t entry = 0; if(ihdr->bit_depth == 8) { if(fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGB8)) { expand_row(out, scanline, &ctx->decode_plte, width, fmt); break; } entry = scanline[k]; } else /* < 8 */ { entry = get_sample(&iter); } if(fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGB8)) { pixel[0] = plte[entry].red; pixel[1] = plte[entry].green; pixel[2] = plte[entry].blue; if(fmt == SPNG_FMT_RGBA8) pixel[3] = plte[entry].alpha; continue; } else /* RGBA16 */ { r_16 = plte[entry].red; g_16 = plte[entry].green; b_16 = plte[entry].blue; a_16 = plte[entry].alpha; r_16 = (r_16 << 8) | r_16; g_16 = (g_16 << 8) | g_16; b_16 = (b_16 << 8) | b_16; a_16 = (a_16 << 8) | a_16; memcpy(pixel, &r_16, 2); memcpy(pixel + 2, &g_16, 2); memcpy(pixel + 4, &b_16, 2); memcpy(pixel + 6, &a_16, 2); continue; } } else if(ihdr->color_type == SPNG_COLOR_TYPE_TRUECOLOR_ALPHA) { if(ihdr->bit_depth == 16) { memcpy(&r_16, scanline + (k * 8), 2); memcpy(&g_16, scanline + (k * 8) + 2, 2); memcpy(&b_16, scanline + (k * 8) + 4, 2); memcpy(&a_16, scanline + (k * 8) + 6, 2); } else /* == 8 */ { r_8 = scanline[k * 4]; g_8 = scanline[k * 4 + 1]; b_8 = scanline[k * 4 + 2]; a_8 = scanline[k * 4 + 3]; } } else if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE) { if(ihdr->bit_depth == 16) { memcpy(&gray_16, scanline + k * 2, 2); if(f.apply_trns && ctx->trns.gray == gray_16) a_16 = 0; else a_16 = 65535; r_16 = gray_16; g_16 = gray_16; b_16 = gray_16; } else /* <= 8 */ { gray_8 = get_sample(&iter); if(f.apply_trns && ctx->trns.gray == gray_8) a_8 = 0; else a_8 = 255; r_8 = gray_8; g_8 = gray_8; b_8 = gray_8; } } else if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE_ALPHA) { if(ihdr->bit_depth == 16) { memcpy(&gray_16, scanline + (k * 4), 2); memcpy(&a_16, scanline + (k * 4) + 2, 2); r_16 = gray_16; g_16 = gray_16; b_16 = gray_16; } else /* == 8 */ { gray_8 = scanline[k * 2]; a_8 = scanline[k * 2 + 1]; r_8 = gray_8; g_8 = gray_8; b_8 = gray_8; } } if(fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGB8)) { if(ihdr->bit_depth == 16) { r_8 = r_16 >> 8; g_8 = g_16 >> 8; b_8 = b_16 >> 8; a_8 = a_16 >> 8; } pixel[0] = r_8; pixel[1] = g_8; pixel[2] = b_8; if(fmt == SPNG_FMT_RGBA8) pixel[3] = a_8; } else if(fmt == SPNG_FMT_RGBA16) { if(ihdr->bit_depth != 16) { r_16 = r_8; g_16 = g_8; b_16 = b_8; a_16 = a_8; } memcpy(pixel, &r_16, 2); memcpy(pixel + 2, &g_16, 2); memcpy(pixel + 4, &b_16, 2); memcpy(pixel + 6, &a_16, 2); } }/* for(k=0; k < width; k++) */ if(f.apply_trns) trns_row(out, scanline, trns_px, ctx->bytes_per_pixel, &ctx->ihdr, width, fmt); if(f.do_scaling) scale_row(out, width, fmt, processing_depth, sb); if(f.apply_gamma) gamma_correct_row(out, width, fmt, gamma_lut); /* The previous scanline is always defiltered */ void *t = ctx->prev_scanline; ctx->prev_scanline = ctx->scanline; ctx->scanline = t; ret = update_row_info(ctx); if(ret == SPNG_EOI) { if(ctx->cur_chunk_bytes_left) /* zlib stream ended before an IDAT chunk boundary */ {/* Discard the rest of the chunk */ int error = discard_chunk_bytes(ctx, ctx->cur_chunk_bytes_left); if(error) return decode_err(ctx, error); } ctx->last_idat = ctx->current_chunk; } return ret; } int spng_decode_row(spng_ctx *ctx, void *out, size_t len) { if(ctx == NULL || out == NULL) return 1; if(ctx->state >= SPNG_STATE_EOI) return SPNG_EOI; if(len < ctx->image_width) return SPNG_EBUFSIZ; const struct spng_ihdr *ihdr = &ctx->ihdr; int ret, pass = ctx->row_info.pass; unsigned char *outptr = out; if(!ihdr->interlace_method || pass == 6) return spng_decode_scanline(ctx, out, len); ret = spng_decode_scanline(ctx, ctx->row, ctx->image_width); if(ret && ret != SPNG_EOI) return ret; uint32_t k; unsigned pixel_size = 4; /* RGBA8 */ if(ctx->fmt == SPNG_FMT_RGBA16) pixel_size = 8; else if(ctx->fmt == SPNG_FMT_RGB8) pixel_size = 3; else if(ctx->fmt == SPNG_FMT_G8) pixel_size = 1; else if(ctx->fmt == SPNG_FMT_GA8) pixel_size = 2; else if(ctx->fmt & (SPNG_FMT_PNG | SPNG_FMT_RAW)) { if(ihdr->bit_depth < 8) { struct spng__iter iter = spng__iter_init(ihdr->bit_depth, ctx->row); const uint8_t samples_per_byte = 8 / ihdr->bit_depth; uint8_t sample; for(k=0; k < ctx->subimage[pass].width; k++) { sample = get_sample(&iter); size_t ioffset = adam7_x_start[pass] + k * adam7_x_delta[pass]; sample = sample << (iter.initial_shift - ioffset * ihdr->bit_depth % 8); ioffset /= samples_per_byte; outptr[ioffset] |= sample; } return 0; } else pixel_size = ctx->bytes_per_pixel; } for(k=0; k < ctx->subimage[pass].width; k++) { size_t ioffset = (adam7_x_start[pass] + (size_t) k * adam7_x_delta[pass]) * pixel_size; memcpy(outptr + ioffset, ctx->row + k * pixel_size, pixel_size); } return 0; } int spng_decode_chunks(spng_ctx *ctx) { if(ctx == NULL) return 1; if(ctx->encode_only) return SPNG_ECTXTYPE; if(ctx->state < SPNG_STATE_INPUT) return SPNG_ENOSRC; if(ctx->state == SPNG_STATE_IEND) return 0; return read_chunks(ctx, 0); } int spng_decode_image(spng_ctx *ctx, void *out, size_t len, int fmt, int flags) { if(ctx == NULL) return 1; if(ctx->encode_only) return SPNG_ECTXTYPE; if(ctx->state >= SPNG_STATE_EOI) return SPNG_EOI; const struct spng_ihdr *ihdr = &ctx->ihdr; int ret = read_chunks(ctx, 0); if(ret) return decode_err(ctx, ret); ret = check_decode_fmt(ihdr, fmt); if(ret) return ret; ret = calculate_image_width(ihdr, fmt, &ctx->image_width); if(ret) return decode_err(ctx, ret); if(ctx->image_width > SIZE_MAX / ihdr->height) ctx->image_size = 0; /* overflow */ else ctx->image_size = ctx->image_width * ihdr->height; if( !(flags & SPNG_DECODE_PROGRESSIVE) ) { if(out == NULL) return 1; if(!ctx->image_size) return SPNG_EOVERFLOW; if(len < ctx->image_size) return SPNG_EBUFSIZ; } uint32_t bytes_read = 0; ret = read_idat_bytes(ctx, &bytes_read); if(ret) return decode_err(ctx, ret); if(bytes_read > 1) { int valid = read_u16(ctx->data) % 31 ? 0 : 1; unsigned flg = ctx->data[1]; unsigned flevel = flg >> 6; int compression_level = Z_DEFAULT_COMPRESSION; if(flevel == 0) compression_level = 0; /* fastest */ else if(flevel == 1) compression_level = 1; /* fast */ else if(flevel == 2) compression_level = 6; /* default */ else if(flevel == 3) compression_level = 9; /* slowest, max compression */ if(valid) ctx->image_options.compression_level = compression_level; } ret = spng__inflate_init(ctx, ctx->image_options.window_bits); if(ret) return decode_err(ctx, ret); ctx->zstream.avail_in = bytes_read; ctx->zstream.next_in = ctx->data; size_t scanline_buf_size = ctx->subimage[ctx->widest_pass].scanline_width; scanline_buf_size += 32; if(scanline_buf_size < 32) return SPNG_EOVERFLOW; ctx->scanline_buf = spng__malloc(ctx, scanline_buf_size); ctx->prev_scanline_buf = spng__malloc(ctx, scanline_buf_size); ctx->scanline = ctx->scanline_buf; ctx->prev_scanline = ctx->prev_scanline_buf; struct decode_flags f = {0}; ctx->fmt = fmt; if(ihdr->color_type == SPNG_COLOR_TYPE_INDEXED) f.indexed = 1; unsigned processing_depth = ihdr->bit_depth; if(f.indexed) processing_depth = 8; if(ihdr->interlace_method) { f.interlaced = 1; ctx->row_buf = spng__malloc(ctx, ctx->image_width); ctx->row = ctx->row_buf; if(ctx->row == NULL) return decode_err(ctx, SPNG_EMEM); } if(ctx->scanline == NULL || ctx->prev_scanline == NULL) { return decode_err(ctx, SPNG_EMEM); } f.do_scaling = 1; if(f.indexed) f.do_scaling = 0; unsigned depth_target = 8; /* FMT_RGBA8, G8 */ if(fmt == SPNG_FMT_RGBA16) depth_target = 16; if(flags & SPNG_DECODE_TRNS && ctx->stored.trns) f.apply_trns = 1; else flags &= ~SPNG_DECODE_TRNS; if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE_ALPHA || ihdr->color_type == SPNG_COLOR_TYPE_TRUECOLOR_ALPHA) flags &= ~SPNG_DECODE_TRNS; if(flags & SPNG_DECODE_GAMMA && ctx->stored.gama) f.apply_gamma = 1; else flags &= ~SPNG_DECODE_GAMMA; if(flags & SPNG_DECODE_USE_SBIT && ctx->stored.sbit) f.use_sbit = 1; else flags &= ~SPNG_DECODE_USE_SBIT; if(fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGBA16)) { if(ihdr->color_type == SPNG_COLOR_TYPE_TRUECOLOR_ALPHA && ihdr->bit_depth == depth_target) f.same_layout = 1; } else if(fmt == SPNG_FMT_RGB8) { if(ihdr->color_type == SPNG_COLOR_TYPE_TRUECOLOR && ihdr->bit_depth == depth_target) f.same_layout = 1; f.apply_trns = 0; /* not applicable */ } else if(fmt & (SPNG_FMT_PNG | SPNG_FMT_RAW)) { f.same_layout = 1; f.do_scaling = 0; f.apply_gamma = 0; /* for now */ f.apply_trns = 0; } else if(fmt == SPNG_FMT_G8 && ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE && ihdr->bit_depth <= 8) { if(ihdr->bit_depth == depth_target) f.same_layout = 1; else if(ihdr->bit_depth < 8) f.unpack = 1; f.apply_trns = 0; } else if(fmt == SPNG_FMT_GA8 && ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE && ihdr->bit_depth <= 8) { if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE_ALPHA && ihdr->bit_depth == depth_target) f.same_layout = 1; else if(ihdr->bit_depth <= 8) f.unpack = 1; } else if(fmt == SPNG_FMT_GA16 && ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE && ihdr->bit_depth == 16) { if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE_ALPHA && ihdr->bit_depth == depth_target) f.same_layout = 1; else if(ihdr->bit_depth == 16) f.unpack = 1; } /*if(f.same_layout && !flags && !f.interlaced) f.zerocopy = 1;*/ uint16_t *gamma_lut = NULL; if(f.apply_gamma) { float file_gamma = (float)ctx->gama / 100000.0f; float max; unsigned lut_entries; if(fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGB8)) { lut_entries = 256; max = 255.0f; gamma_lut = ctx->gamma_lut8; ctx->gamma_lut = ctx->gamma_lut8; } else /* SPNG_FMT_RGBA16 */ { lut_entries = 65536; max = 65535.0f; ctx->gamma_lut16 = spng__malloc(ctx, lut_entries * sizeof(uint16_t)); if(ctx->gamma_lut16 == NULL) return decode_err(ctx, SPNG_EMEM); gamma_lut = ctx->gamma_lut16; ctx->gamma_lut = ctx->gamma_lut16; } float screen_gamma = 2.2f; float exponent = file_gamma * screen_gamma; if(FP_ZERO == fpclassify(exponent)) return decode_err(ctx, SPNG_EGAMA); exponent = 1.0f / exponent; unsigned i; for(i=0; i < lut_entries; i++) { float c = pow((float)i / max, exponent) * max; if(c > max) c = max; gamma_lut[i] = (uint16_t)c; } } struct spng_sbit *sb = &ctx->decode_sb; sb->red_bits = processing_depth; sb->green_bits = processing_depth; sb->blue_bits = processing_depth; sb->alpha_bits = processing_depth; sb->grayscale_bits = processing_depth; if(f.use_sbit) { if(ihdr->color_type == 0) { sb->grayscale_bits = ctx->sbit.grayscale_bits; sb->alpha_bits = ihdr->bit_depth; } else if(ihdr->color_type == 2 || ihdr->color_type == 3) { sb->red_bits = ctx->sbit.red_bits; sb->green_bits = ctx->sbit.green_bits; sb->blue_bits = ctx->sbit.blue_bits; sb->alpha_bits = ihdr->bit_depth; } else if(ihdr->color_type == 4) { sb->grayscale_bits = ctx->sbit.grayscale_bits; sb->alpha_bits = ctx->sbit.alpha_bits; } else /* == 6 */ { sb->red_bits = ctx->sbit.red_bits; sb->green_bits = ctx->sbit.green_bits; sb->blue_bits = ctx->sbit.blue_bits; sb->alpha_bits = ctx->sbit.alpha_bits; } } if(ihdr->bit_depth == 16 && fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGB8)) {/* samples are scaled down by 8 bits in the decode loop */ sb->red_bits -= 8; sb->green_bits -= 8; sb->blue_bits -= 8; sb->alpha_bits -= 8; sb->grayscale_bits -= 8; processing_depth = 8; } /* Prevent infinite loops in sample_to_target() */ if(!depth_target || depth_target > 16 || !processing_depth || processing_depth > 16 || !sb->grayscale_bits || sb->grayscale_bits > processing_depth || !sb->alpha_bits || sb->alpha_bits > processing_depth || !sb->red_bits || sb->red_bits > processing_depth || !sb->green_bits || sb->green_bits > processing_depth || !sb->blue_bits || sb->blue_bits > processing_depth) { return decode_err(ctx, SPNG_ESBIT); } if(sb->red_bits == sb->green_bits && sb->green_bits == sb->blue_bits && sb->blue_bits == sb->alpha_bits && sb->alpha_bits == processing_depth && processing_depth == depth_target) f.do_scaling = 0; struct spng_plte_entry *plte = ctx->decode_plte.rgba; /* Pre-process palette entries */ if(f.indexed) { uint8_t red, green, blue, alpha; uint32_t i; for(i=0; i < 256; i++) { if(f.apply_trns && i < ctx->trns.n_type3_entries) ctx->plte.entries[i].alpha = ctx->trns.type3_alpha[i]; else ctx->plte.entries[i].alpha = 255; red = sample_to_target(ctx->plte.entries[i].red, 8, sb->red_bits, 8); green = sample_to_target(ctx->plte.entries[i].green, 8, sb->green_bits, 8); blue = sample_to_target(ctx->plte.entries[i].blue, 8, sb->blue_bits, 8); alpha = sample_to_target(ctx->plte.entries[i].alpha, 8, sb->alpha_bits, 8); #if defined(SPNG_ARM) if(fmt == SPNG_FMT_RGB8 && ihdr->bit_depth == 8) {/* Working with 3 bytes at a time is more of an ARM thing */ ctx->decode_plte.rgb[i * 3 + 0] = red; ctx->decode_plte.rgb[i * 3 + 1] = green; ctx->decode_plte.rgb[i * 3 + 2] = blue; continue; } #endif plte[i].red = red; plte[i].green = green; plte[i].blue = blue; plte[i].alpha = alpha; } f.apply_trns = 0; } unsigned char *trns_px = ctx->trns_px; if(f.apply_trns) { uint16_t mask = ~0; if(ctx->ihdr.bit_depth < 16) mask = (1 << ctx->ihdr.bit_depth) - 1; if(fmt & (SPNG_FMT_RGBA8 | SPNG_FMT_RGBA16)) { if(ihdr->color_type == SPNG_COLOR_TYPE_TRUECOLOR) { if(ihdr->bit_depth == 16) { memcpy(trns_px, &ctx->trns.red, 2); memcpy(trns_px + 2, &ctx->trns.green, 2); memcpy(trns_px + 4, &ctx->trns.blue, 2); } else { trns_px[0] = ctx->trns.red & mask; trns_px[1] = ctx->trns.green & mask; trns_px[2] = ctx->trns.blue & mask; } } } else if(ihdr->color_type == SPNG_COLOR_TYPE_GRAYSCALE) // fmt == SPNG_FMT_GA8 && { if(ihdr->bit_depth == 16) { memcpy(trns_px, &ctx->trns.gray, 2); } else { trns_px[0] = ctx->trns.gray & mask; } } } ctx->decode_flags = f; ctx->state = SPNG_STATE_DECODE_INIT; struct spng_row_info *ri = &ctx->row_info; struct spng_subimage *sub = ctx->subimage; while(!sub[ri->pass].width || !sub[ri->pass].height) ri->pass++; if(f.interlaced) ri->row_num = adam7_y_start[ri->pass]; unsigned pixel_size = 4; /* SPNG_FMT_RGBA8 */ if(fmt == SPNG_FMT_RGBA16) pixel_size = 8; else if(fmt == SPNG_FMT_RGB8) pixel_size = 3; else if(fmt == SPNG_FMT_G8) pixel_size = 1; else if(fmt == SPNG_FMT_GA8) pixel_size = 2; int i; for(i=ri->pass; i <= ctx->last_pass; i++) { if(!sub[i].scanline_width) continue; if(fmt & (SPNG_FMT_PNG | SPNG_FMT_RAW)) sub[i].out_width = sub[i].scanline_width - 1; else sub[i].out_width = (size_t)sub[i].width * pixel_size; if(sub[i].out_width > UINT32_MAX) return decode_err(ctx, SPNG_EOVERFLOW); } /* Read the first filter byte, offsetting all reads by 1 byte. The scanlines will be aligned with the start of the array with the next scanline's filter byte at the end, the last scanline will end up being 1 byte "shorter". */ ret = read_scanline_bytes(ctx, &ri->filter, 1); if(ret) return decode_err(ctx, ret); if(ri->filter > 4) return decode_err(ctx, SPNG_EFILTER); if(flags & SPNG_DECODE_PROGRESSIVE) { return 0; } do { size_t ioffset = ri->row_num * ctx->image_width; ret = spng_decode_row(ctx, (unsigned char*)out + ioffset, ctx->image_width); }while(!ret); if(ret != SPNG_EOI) return decode_err(ctx, ret); return 0; } int spng_get_row_info(spng_ctx *ctx, struct spng_row_info *row_info) { if(ctx == NULL || row_info == NULL || ctx->state < SPNG_STATE_DECODE_INIT) return 1; if(ctx->state >= SPNG_STATE_EOI) return SPNG_EOI; *row_info = ctx->row_info; return 0; } static int write_chunks_before_idat(spng_ctx *ctx) { if(ctx == NULL) return SPNG_EINTERNAL; if(!ctx->encode_only) return SPNG_EINTERNAL; if(!ctx->stored.ihdr) return SPNG_EINTERNAL; int ret; uint32_t i; size_t length; const struct spng_ihdr *ihdr = &ctx->ihdr; unsigned char *data = ctx->decode_plte.raw; ret = write_data(ctx, spng_signature, 8); if(ret) return ret; write_u32(data, ihdr->width); write_u32(data + 4, ihdr->height); data[8] = ihdr->bit_depth; data[9] = ihdr->color_type; data[10] = ihdr->compression_method; data[11] = ihdr->filter_method; data[12] = ihdr->interlace_method; ret = write_chunk(ctx, type_ihdr, data, 13); if(ret) return ret; if(ctx->stored.chrm) { write_u32(data, ctx->chrm_int.white_point_x); write_u32(data + 4, ctx->chrm_int.white_point_y); write_u32(data + 8, ctx->chrm_int.red_x); write_u32(data + 12, ctx->chrm_int.red_y); write_u32(data + 16, ctx->chrm_int.green_x); write_u32(data + 20, ctx->chrm_int.green_y); write_u32(data + 24, ctx->chrm_int.blue_x); write_u32(data + 28, ctx->chrm_int.blue_y); ret = write_chunk(ctx, type_chrm, data, 32); if(ret) return ret; } if(ctx->stored.gama) { write_u32(data, ctx->gama); ret = write_chunk(ctx, type_gama, data, 4); if(ret) return ret; } if(ctx->stored.iccp) { uLongf dest_len = compressBound((uLong)ctx->iccp.profile_len); Bytef *buf = spng__malloc(ctx, dest_len); if(buf == NULL) return SPNG_EMEM; ret = compress2(buf, &dest_len, (void*)ctx->iccp.profile, (uLong)ctx->iccp.profile_len, Z_DEFAULT_COMPRESSION); if(ret != Z_OK) { spng__free(ctx, buf); return SPNG_EZLIB; } size_t name_len = strlen(ctx->iccp.profile_name); length = name_len + 2; length += dest_len; if(dest_len > length) return SPNG_EOVERFLOW; unsigned char *cdata = NULL; ret = write_header(ctx, type_iccp, length, &cdata); if(ret) { spng__free(ctx, buf); return ret; } memcpy(cdata, ctx->iccp.profile_name, name_len + 1); cdata[name_len + 1] = 0; /* compression method */ memcpy(cdata + name_len + 2, buf, dest_len); spng__free(ctx, buf); ret = finish_chunk(ctx); if(ret) return ret; } if(ctx->stored.sbit) { switch(ctx->ihdr.color_type) { case SPNG_COLOR_TYPE_GRAYSCALE: { length = 1; data[0] = ctx->sbit.grayscale_bits; break; } case SPNG_COLOR_TYPE_TRUECOLOR: case SPNG_COLOR_TYPE_INDEXED: { length = 3; data[0] = ctx->sbit.red_bits; data[1] = ctx->sbit.green_bits; data[2] = ctx->sbit.blue_bits; break; } case SPNG_COLOR_TYPE_GRAYSCALE_ALPHA: { length = 2; data[0] = ctx->sbit.grayscale_bits; data[1] = ctx->sbit.alpha_bits; break; } case SPNG_COLOR_TYPE_TRUECOLOR_ALPHA: { length = 4; data[0] = ctx->sbit.red_bits; data[1] = ctx->sbit.green_bits; data[2] = ctx->sbit.blue_bits; data[3] = ctx->sbit.alpha_bits; break; } default: return SPNG_EINTERNAL; } ret = write_chunk(ctx, type_sbit, data, length); if(ret) return ret; } if(ctx->stored.srgb) { ret = write_chunk(ctx, type_srgb, &ctx->srgb_rendering_intent, 1); if(ret) return ret; } ret = write_unknown_chunks(ctx, SPNG_AFTER_IHDR); if(ret) return ret; if(ctx->stored.plte) { for(i=0; i < ctx->plte.n_entries; i++) { data[i * 3 + 0] = ctx->plte.entries[i].red; data[i * 3 + 1] = ctx->plte.entries[i].green; data[i * 3 + 2] = ctx->plte.entries[i].blue; } ret = write_chunk(ctx, type_plte, data, ctx->plte.n_entries * 3); if(ret) return ret; } if(ctx->stored.bkgd) { switch(ctx->ihdr.color_type) { case SPNG_COLOR_TYPE_GRAYSCALE: case SPNG_COLOR_TYPE_GRAYSCALE_ALPHA: { length = 2; write_u16(data, ctx->bkgd.gray); break; } case SPNG_COLOR_TYPE_TRUECOLOR: case SPNG_COLOR_TYPE_TRUECOLOR_ALPHA: { length = 6; write_u16(data, ctx->bkgd.red); write_u16(data + 2, ctx->bkgd.green); write_u16(data + 4, ctx->bkgd.blue); break; } case SPNG_COLOR_TYPE_INDEXED: { length = 1; data[0] = ctx->bkgd.plte_index; break; } default: return SPNG_EINTERNAL; } ret = write_chunk(ctx, type_bkgd, data, length); if(ret) return ret; } if(ctx->stored.hist) { length = ctx->plte.n_entries * 2; for(i=0; i < ctx->plte.n_entries; i++) { write_u16(data + i * 2, ctx->hist.frequency[i]); } ret = write_chunk(ctx, type_hist, data, length); if(ret) return ret; } if(ctx->stored.trns) { if(ctx->ihdr.color_type == SPNG_COLOR_TYPE_GRAYSCALE) { write_u16(data, ctx->trns.gray); ret = write_chunk(ctx, type_trns, data, 2); } else if(ctx->ihdr.color_type == SPNG_COLOR_TYPE_TRUECOLOR) { write_u16(data, ctx->trns.red); write_u16(data + 2, ctx->trns.green); write_u16(data + 4, ctx->trns.blue); ret = write_chunk(ctx, type_trns, data, 6); } else if(ctx->ihdr.color_type == SPNG_COLOR_TYPE_INDEXED) { ret = write_chunk(ctx, type_trns, ctx->trns.type3_alpha, ctx->trns.n_type3_entries); } if(ret) return ret; } if(ctx->stored.phys) { write_u32(data, ctx->phys.ppu_x); write_u32(data + 4, ctx->phys.ppu_y); data[8] = ctx->phys.unit_specifier; ret = write_chunk(ctx, type_phys, data, 9); if(ret) return ret; } if(ctx->stored.splt) { const struct spng_splt *splt; unsigned char *cdata = NULL; uint32_t k; for(i=0; i < ctx->n_splt; i++) { splt = &ctx->splt_list[i]; size_t name_len = strlen(splt->name); length = name_len + 1; if(splt->sample_depth == 8) length += splt->n_entries * 6 + 1; else if(splt->sample_depth == 16) length += splt->n_entries * 10 + 1; ret = write_header(ctx, type_splt, length, &cdata); if(ret) return ret; memcpy(cdata, splt->name, name_len + 1); cdata += name_len + 2; cdata[-1] = splt->sample_depth; if(splt->sample_depth == 8) { for(k=0; k < splt->n_entries; k++) { cdata[k * 6 + 0] = splt->entries[k].red; cdata[k * 6 + 1] = splt->entries[k].green; cdata[k * 6 + 2] = splt->entries[k].blue; cdata[k * 6 + 3] = splt->entries[k].alpha; write_u16(cdata + k * 6 + 4, splt->entries[k].frequency); } } else if(splt->sample_depth == 16) { for(k=0; k < splt->n_entries; k++) { write_u16(cdata + k * 10 + 0, splt->entries[k].red); write_u16(cdata + k * 10 + 2, splt->entries[k].green); write_u16(cdata + k * 10 + 4, splt->entries[k].blue); write_u16(cdata + k * 10 + 6, splt->entries[k].alpha); write_u16(cdata + k * 10 + 8, splt->entries[k].frequency); } } ret = finish_chunk(ctx); if(ret) return ret; } } if(ctx->stored.time) { write_u16(data, ctx->time.year); data[2] = ctx->time.month; data[3] = ctx->time.day; data[4] = ctx->time.hour; data[5] = ctx->time.minute; data[6] = ctx->time.second; ret = write_chunk(ctx, type_time, data, 7); if(ret) return ret; } if(ctx->stored.text) { unsigned char *cdata = NULL; const struct spng_text2 *text; const uint8_t *text_type_array[4] = { 0, type_text, type_ztxt, type_itxt }; for(i=0; i < ctx->n_text; i++) { text = &ctx->text_list[i]; const uint8_t *text_chunk_type = text_type_array[text->type]; Bytef *compressed_text = NULL; size_t keyword_len = 0; size_t language_tag_len = 0; size_t translated_keyword_len = 0; size_t compressed_length = 0; size_t text_length = 0; keyword_len = strlen(text->keyword); text_length = strlen(text->text); length = keyword_len + 1; if(text->type == SPNG_ZTXT) { length += 1; /* compression method */ } else if(text->type == SPNG_ITXT) { if(!text->language_tag || !text->translated_keyword) return SPNG_EINTERNAL; language_tag_len = strlen(text->language_tag); translated_keyword_len = strlen(text->translated_keyword); length += language_tag_len; if(length < language_tag_len) return SPNG_EOVERFLOW; length += translated_keyword_len; if(length < translated_keyword_len) return SPNG_EOVERFLOW; length += 4; /* compression flag + method + nul for the two strings */ if(length < 4) return SPNG_EOVERFLOW; } if(text->compression_flag) { ret = spng__deflate_init(ctx, &ctx->text_options); if(ret) return ret; z_stream *zstream = &ctx->zstream; uLongf dest_len = deflateBound(zstream, (uLong)text_length); compressed_text = spng__malloc(ctx, dest_len); if(compressed_text == NULL) return SPNG_EMEM; zstream->next_in = (void*)text->text; zstream->avail_in = (uInt)text_length; zstream->next_out = compressed_text; zstream->avail_out = dest_len; ret = deflate(zstream, Z_FINISH); if(ret != Z_STREAM_END) { spng__free(ctx, compressed_text); return SPNG_EZLIB; } compressed_length = zstream->total_out; length += compressed_length; if(length < compressed_length) return SPNG_EOVERFLOW; } else { text_length = strlen(text->text); length += text_length; if(length < text_length) return SPNG_EOVERFLOW; } ret = write_header(ctx, text_chunk_type, length, &cdata); if(ret) { spng__free(ctx, compressed_text); return ret; } memcpy(cdata, text->keyword, keyword_len + 1); cdata += keyword_len + 1; if(text->type == SPNG_ITXT) { cdata[0] = text->compression_flag; cdata[1] = 0; /* compression method */ cdata += 2; memcpy(cdata, text->language_tag, language_tag_len + 1); cdata += language_tag_len + 1; memcpy(cdata, text->translated_keyword, translated_keyword_len + 1); cdata += translated_keyword_len + 1; } else if(text->type == SPNG_ZTXT) { cdata[0] = 0; /* compression method */ cdata++; } if(text->compression_flag) memcpy(cdata, compressed_text, compressed_length); else memcpy(cdata, text->text, text_length); spng__free(ctx, compressed_text); ret = finish_chunk(ctx); if(ret) return ret; } } if(ctx->stored.offs) { write_s32(data, ctx->offs.x); write_s32(data + 4, ctx->offs.y); data[8] = ctx->offs.unit_specifier; ret = write_chunk(ctx, type_offs, data, 9); if(ret) return ret; } if(ctx->stored.exif) { ret = write_chunk(ctx, type_exif, ctx->exif.data, ctx->exif.length); if(ret) return ret; } ret = write_unknown_chunks(ctx, SPNG_AFTER_PLTE); if(ret) return ret; return 0; } static int write_chunks_after_idat(spng_ctx *ctx) { if(ctx == NULL) return SPNG_EINTERNAL; int ret = write_unknown_chunks(ctx, SPNG_AFTER_IDAT); if(ret) return ret; return write_iend(ctx); } /* Compress and write scanline to IDAT stream */ static int write_idat_bytes(spng_ctx *ctx, const void *scanline, size_t len, int flush) { if(ctx == NULL || scanline == NULL) return SPNG_EINTERNAL; if(len > UINT_MAX) return SPNG_EINTERNAL; int ret = 0; unsigned char *data = NULL; z_stream *zstream = &ctx->zstream; uint32_t idat_length = SPNG_WRITE_SIZE; zstream->next_in = scanline; zstream->avail_in = (uInt)len; do { ret = deflate(zstream, flush); if(zstream->avail_out == 0) { ret = finish_chunk(ctx); if(ret) return encode_err(ctx, ret); ret = write_header(ctx, type_idat, idat_length, &data); if(ret) return encode_err(ctx, ret); zstream->next_out = data; zstream->avail_out = idat_length; } }while(zstream->avail_in); if(ret != Z_OK) return SPNG_EZLIB; return 0; } static int finish_idat(spng_ctx *ctx) { int ret = 0; unsigned char *data = NULL; z_stream *zstream = &ctx->zstream; uint32_t idat_length = SPNG_WRITE_SIZE; while(ret != Z_STREAM_END) { ret = deflate(zstream, Z_FINISH); if(ret) { if(ret == Z_STREAM_END) break; if(ret != Z_BUF_ERROR) return SPNG_EZLIB; } if(zstream->avail_out == 0) { ret = finish_chunk(ctx); if(ret) return encode_err(ctx, ret); ret = write_header(ctx, type_idat, idat_length, &data); if(ret) return encode_err(ctx, ret); zstream->next_out = data; zstream->avail_out = idat_length; } } uint32_t trimmed_length = idat_length - zstream->avail_out; ret = trim_chunk(ctx, trimmed_length); if(ret) return ret; return finish_chunk(ctx); } static int encode_scanline(spng_ctx *ctx, const void *scanline, size_t len) { if(ctx == NULL || scanline == NULL) return SPNG_EINTERNAL; int ret, pass = ctx->row_info.pass; uint8_t filter = 0; struct spng_row_info *ri = &ctx->row_info; const struct spng_subimage *sub = ctx->subimage; struct encode_flags f = ctx->encode_flags; unsigned char *filtered_scanline = ctx->filtered_scanline; size_t scanline_width = sub[pass].scanline_width; if(len < scanline_width - 1) return SPNG_EINTERNAL; /* encode_row() interlaces directly to ctx->scanline */ if(scanline != ctx->scanline) memcpy(ctx->scanline, scanline, scanline_width - 1); if(f.to_bigendian) u16_row_to_bigendian(ctx->scanline, scanline_width - 1); const int requires_previous = f.filter_choice & (SPNG_FILTER_CHOICE_UP | SPNG_FILTER_CHOICE_AVG | SPNG_FILTER_CHOICE_PAETH); /* XXX: exclude 'requires_previous' filters by default for first scanline? */ if(!ri->scanline_idx && requires_previous) { /* prev_scanline is all zeros for the first scanline */ memset(ctx->prev_scanline, 0, scanline_width); } filter = get_best_filter(ctx->prev_scanline, ctx->scanline, scanline_width, ctx->bytes_per_pixel, f.filter_choice); if(!filter) filtered_scanline = ctx->scanline; filtered_scanline[-1] = filter; if(filter) { ret = filter_scanline(filtered_scanline, ctx->prev_scanline, ctx->scanline, scanline_width, ctx->bytes_per_pixel, filter); if(ret) return encode_err(ctx, ret); } ret = write_idat_bytes(ctx, filtered_scanline - 1, scanline_width, Z_NO_FLUSH); if(ret) return encode_err(ctx, ret); /* The previous scanline is always unfiltered */ void *t = ctx->prev_scanline; ctx->prev_scanline = ctx->scanline; ctx->scanline = t; ret = update_row_info(ctx); if(ret == SPNG_EOI) { int error = finish_idat(ctx); if(error) encode_err(ctx, error); if(f.finalize) { error = spng_encode_chunks(ctx); if(error) return encode_err(ctx, error); } } return ret; } static int encode_row(spng_ctx *ctx, const void *row, size_t len) { if(ctx == NULL || row == NULL) return SPNG_EINTERNAL; const int pass = ctx->row_info.pass; if(!ctx->ihdr.interlace_method || pass == 6) return encode_scanline(ctx, row, len); uint32_t k; const unsigned pixel_size = ctx->pixel_size; const unsigned bit_depth = ctx->ihdr.bit_depth; if(bit_depth < 8) { const unsigned samples_per_byte = 8 / bit_depth; const uint8_t mask = (1 << bit_depth) - 1; const unsigned initial_shift = 8 - bit_depth; unsigned shift_amount = initial_shift; unsigned char *scanline = ctx->scanline; const unsigned char *row_uc = row; uint8_t sample; memset(scanline, 0, ctx->subimage[pass].scanline_width); for(k=0; k < ctx->subimage[pass].width; k++) { size_t ioffset = adam7_x_start[pass] + k * adam7_x_delta[pass]; sample = row_uc[ioffset / samples_per_byte]; sample = sample >> (initial_shift - ioffset * bit_depth % 8); sample = sample & mask; sample = sample << shift_amount; scanline[0] |= sample; shift_amount -= bit_depth; if(shift_amount > 7) { shift_amount = initial_shift; scanline++; } } return encode_scanline(ctx, ctx->scanline, len); } for(k=0; k < ctx->subimage[pass].width; k++) { size_t ioffset = (adam7_x_start[pass] + (size_t) k * adam7_x_delta[pass]) * pixel_size; memcpy(ctx->scanline + k * pixel_size, (unsigned char*)row + ioffset, pixel_size); } return encode_scanline(ctx, ctx->scanline, len); } int spng_encode_scanline(spng_ctx *ctx, const void *scanline, size_t len) { if(ctx == NULL || scanline == NULL) return SPNG_EINVAL; if(ctx->state >= SPNG_STATE_EOI) return SPNG_EOI; if(len < (ctx->subimage[ctx->row_info.pass].scanline_width -1) ) return SPNG_EBUFSIZ; return encode_scanline(ctx, scanline, len); } int spng_encode_row(spng_ctx *ctx, const void *row, size_t len) { if(ctx == NULL || row == NULL) return SPNG_EINVAL; if(ctx->state >= SPNG_STATE_EOI) return SPNG_EOI; if(len < ctx->image_width) return SPNG_EBUFSIZ; return encode_row(ctx, row, len); } int spng_encode_chunks(spng_ctx *ctx) { if(ctx == NULL) return 1; if(!ctx->state) return SPNG_EBADSTATE; if(ctx->state < SPNG_STATE_OUTPUT) return SPNG_ENODST; if(!ctx->encode_only) return SPNG_ECTXTYPE; int ret = 0; if(ctx->state < SPNG_STATE_FIRST_IDAT) { if(!ctx->stored.ihdr) return SPNG_ENOIHDR; ret = write_chunks_before_idat(ctx); if(ret) return encode_err(ctx, ret); ctx->state = SPNG_STATE_FIRST_IDAT; } else if(ctx->state == SPNG_STATE_FIRST_IDAT) { return 0; } else if(ctx->state == SPNG_STATE_EOI) { ret = write_chunks_after_idat(ctx); if(ret) return encode_err(ctx, ret); ctx->state = SPNG_STATE_IEND; } else return SPNG_EOPSTATE; return 0; } int spng_encode_image(spng_ctx *ctx, const void *img, size_t len, int fmt, int flags) { if(ctx == NULL) return 1; if(!ctx->state) return SPNG_EBADSTATE; if(!ctx->encode_only) return SPNG_ECTXTYPE; if(!ctx->stored.ihdr) return SPNG_ENOIHDR; if( !(fmt == SPNG_FMT_PNG || fmt == SPNG_FMT_RAW) ) return SPNG_EFMT; int ret = 0; const struct spng_ihdr *ihdr = &ctx->ihdr; struct encode_flags *encode_flags = &ctx->encode_flags; if(ihdr->color_type == SPNG_COLOR_TYPE_INDEXED && !ctx->stored.plte) return SPNG_ENOPLTE; ret = calculate_image_width(ihdr, fmt, &ctx->image_width); if(ret) return encode_err(ctx, ret); if(ctx->image_width > SIZE_MAX / ihdr->height) ctx->image_size = 0; /* overflow */ else ctx->image_size = ctx->image_width * ihdr->height; if( !(flags & SPNG_ENCODE_PROGRESSIVE) ) { if(img == NULL) return 1; if(!ctx->image_size) return SPNG_EOVERFLOW; if(len != ctx->image_size) return SPNG_EBUFSIZ; } ret = spng_encode_chunks(ctx); if(ret) return encode_err(ctx, ret); ret = calculate_subimages(ctx); if(ret) return encode_err(ctx, ret); if(ihdr->bit_depth < 8) ctx->bytes_per_pixel = 1; else ctx->bytes_per_pixel = num_channels(ihdr) * (ihdr->bit_depth / 8); if(spng__optimize(SPNG_FILTER_CHOICE)) { /* Filtering would make no difference */ if(!ctx->image_options.compression_level) { encode_flags->filter_choice = SPNG_DISABLE_FILTERING; } /* Palette indices and low bit-depth images do not benefit from filtering */ if(ihdr->color_type == SPNG_COLOR_TYPE_INDEXED || ihdr->bit_depth < 8) { encode_flags->filter_choice = SPNG_DISABLE_FILTERING; } } /* This is technically the same as disabling filtering */ if(encode_flags->filter_choice == SPNG_FILTER_CHOICE_NONE) { encode_flags->filter_choice = SPNG_DISABLE_FILTERING; } if(!encode_flags->filter_choice && spng__optimize(SPNG_IMG_COMPRESSION_STRATEGY)) { ctx->image_options.strategy = Z_DEFAULT_STRATEGY; } ret = spng__deflate_init(ctx, &ctx->image_options); if(ret) return encode_err(ctx, ret); size_t scanline_buf_size = ctx->subimage[ctx->widest_pass].scanline_width; scanline_buf_size += 32; if(scanline_buf_size < 32) return SPNG_EOVERFLOW; ctx->scanline_buf = spng__malloc(ctx, scanline_buf_size); ctx->prev_scanline_buf = spng__malloc(ctx, scanline_buf_size); if(ctx->scanline_buf == NULL || ctx->prev_scanline_buf == NULL) return encode_err(ctx, SPNG_EMEM); /* Maintain alignment for pixels, filter at [-1] */ ctx->scanline = ctx->scanline_buf + 16; ctx->prev_scanline = ctx->prev_scanline_buf + 16; if(encode_flags->filter_choice) { ctx->filtered_scanline_buf = spng__malloc(ctx, scanline_buf_size); if(ctx->filtered_scanline_buf == NULL) return encode_err(ctx, SPNG_EMEM); ctx->filtered_scanline = ctx->filtered_scanline_buf + 16; } struct spng_subimage *sub = ctx->subimage; struct spng_row_info *ri = &ctx->row_info; ctx->fmt = fmt; z_stream *zstream = &ctx->zstream; zstream->avail_out = SPNG_WRITE_SIZE; ret = write_header(ctx, type_idat, zstream->avail_out, &zstream->next_out); if(ret) return encode_err(ctx, ret); if(ihdr->interlace_method) encode_flags->interlace = 1; if(fmt & (SPNG_FMT_PNG | SPNG_FMT_RAW) ) encode_flags->same_layout = 1; if(ihdr->bit_depth == 16 && fmt != SPNG_FMT_RAW) encode_flags->to_bigendian = 1; if(flags & SPNG_ENCODE_FINALIZE) encode_flags->finalize = 1; while(!sub[ri->pass].width || !sub[ri->pass].height) ri->pass++; if(encode_flags->interlace) ri->row_num = adam7_y_start[ri->pass]; ctx->pixel_size = 4; /* SPNG_FMT_RGBA8 */ if(fmt == SPNG_FMT_RGBA16) ctx->pixel_size = 8; else if(fmt == SPNG_FMT_RGB8) ctx->pixel_size = 3; else if(fmt == SPNG_FMT_G8) ctx->pixel_size = 1; else if(fmt == SPNG_FMT_GA8) ctx->pixel_size = 2; else if(fmt & (SPNG_FMT_PNG | SPNG_FMT_RAW)) ctx->pixel_size = ctx->bytes_per_pixel; ctx->state = SPNG_STATE_ENCODE_INIT; if(flags & SPNG_ENCODE_PROGRESSIVE) { encode_flags->progressive = 1; return 0; } do { size_t ioffset = ri->row_num * ctx->image_width; ret = encode_row(ctx, (unsigned char*)img + ioffset, ctx->image_width); }while(!ret); if(ret != SPNG_EOI) return encode_err(ctx, ret); return 0; } spng_ctx *spng_ctx_new(int flags) { struct spng_alloc alloc = { .malloc_fn = malloc, .realloc_fn = realloc, .calloc_fn = calloc, .free_fn = free }; return spng_ctx_new2(&alloc, flags); } spng_ctx *spng_ctx_new2(struct spng_alloc *alloc, int flags) { if(alloc == NULL) return NULL; if(flags != (flags & SPNG__CTX_FLAGS_ALL)) return NULL; if(alloc->malloc_fn == NULL) return NULL; if(alloc->realloc_fn == NULL) return NULL; if(alloc->calloc_fn == NULL) return NULL; if(alloc->free_fn == NULL) return NULL; spng_ctx *ctx = alloc->calloc_fn(1, sizeof(spng_ctx)); if(ctx == NULL) return NULL; ctx->alloc = *alloc; ctx->max_width = spng_u32max; ctx->max_height = spng_u32max; ctx->max_chunk_size = spng_u32max; ctx->chunk_cache_limit = SIZE_MAX; ctx->chunk_count_limit = SPNG_MAX_CHUNK_COUNT; ctx->state = SPNG_STATE_INIT; ctx->crc_action_critical = SPNG_CRC_ERROR; ctx->crc_action_ancillary = SPNG_CRC_DISCARD; const struct spng__zlib_options image_defaults = { .compression_level = Z_DEFAULT_COMPRESSION, .window_bits = 15, .mem_level = 8, .strategy = Z_FILTERED, .data_type = 0 /* Z_BINARY */ }; const struct spng__zlib_options text_defaults = { .compression_level = Z_DEFAULT_COMPRESSION, .window_bits = 15, .mem_level = 8, .strategy = Z_DEFAULT_STRATEGY, .data_type = 1 /* Z_TEXT */ }; ctx->image_options = image_defaults; ctx->text_options = text_defaults; ctx->optimize_option = ~0; ctx->encode_flags.filter_choice = SPNG_FILTER_CHOICE_ALL; ctx->flags = flags; if(flags & SPNG_CTX_ENCODER) ctx->encode_only = 1; return ctx; } void spng_ctx_free(spng_ctx *ctx) { if(ctx == NULL) return; if(ctx->streaming && ctx->stream_buf != NULL) spng__free(ctx, ctx->stream_buf); if(!ctx->user.exif) spng__free(ctx, ctx->exif.data); if(!ctx->user.iccp) spng__free(ctx, ctx->iccp.profile); uint32_t i; if(ctx->splt_list != NULL && !ctx->user.splt) { for(i=0; i < ctx->n_splt; i++) { spng__free(ctx, ctx->splt_list[i].entries); } spng__free(ctx, ctx->splt_list); } if(ctx->text_list != NULL) { for(i=0; i< ctx->n_text; i++) { if(ctx->user.text) break; spng__free(ctx, ctx->text_list[i].keyword); if(ctx->text_list[i].compression_flag) spng__free(ctx, ctx->text_list[i].text); } spng__free(ctx, ctx->text_list); } if(ctx->chunk_list != NULL && !ctx->user.unknown) { for(i=0; i< ctx->n_chunks; i++) { spng__free(ctx, ctx->chunk_list[i].data); } spng__free(ctx, ctx->chunk_list); } if(ctx->deflate) deflateEnd(&ctx->zstream); else inflateEnd(&ctx->zstream); if(!ctx->user_owns_out_png) spng__free(ctx, ctx->out_png); spng__free(ctx, ctx->gamma_lut16); spng__free(ctx, ctx->row_buf); spng__free(ctx, ctx->scanline_buf); spng__free(ctx, ctx->prev_scanline_buf); spng__free(ctx, ctx->filtered_scanline_buf); spng_free_fn *free_fn = ctx->alloc.free_fn; memset(ctx, 0, sizeof(spng_ctx)); free_fn(ctx); } static int buffer_read_fn(spng_ctx *ctx, void *user, void *data, size_t n) { if(n > ctx->bytes_left) return SPNG_IO_EOF; (void)user; (void)data; ctx->data = ctx->data + ctx->last_read_size; ctx->last_read_size = n; ctx->bytes_left -= n; return 0; } static int file_read_fn(spng_ctx *ctx, void *user, void *data, size_t n) { FILE *file = user; (void)ctx; if(fread(data, n, 1, file) != 1) { if(feof(file)) return SPNG_IO_EOF; else return SPNG_IO_ERROR; } return 0; } static int file_write_fn(spng_ctx *ctx, void *user, void *data, size_t n) { FILE *file = user; (void)ctx; if(fwrite(data, n, 1, file) != 1) return SPNG_IO_ERROR; return 0; } int spng_set_png_buffer(spng_ctx *ctx, const void *buf, size_t size) { if(ctx == NULL || buf == NULL) return 1; if(!ctx->state) return SPNG_EBADSTATE; if(ctx->encode_only) return SPNG_ECTXTYPE; /* not supported */ if(ctx->data != NULL) return SPNG_EBUF_SET; ctx->data = buf; ctx->png_base = buf; ctx->data_size = size; ctx->bytes_left = size; ctx->read_fn = buffer_read_fn; ctx->state = SPNG_STATE_INPUT; return 0; } int spng_set_png_stream(spng_ctx *ctx, spng_rw_fn *rw_func, void *user) { if(ctx == NULL || rw_func == NULL) return 1; if(!ctx->state) return SPNG_EBADSTATE; /* SPNG_STATE_OUTPUT shares the same value */ if(ctx->state >= SPNG_STATE_INPUT) return SPNG_EBUF_SET; if(ctx->encode_only) { if(ctx->out_png != NULL) return SPNG_EBUF_SET; ctx->write_fn = rw_func; ctx->write_ptr = ctx->stream_buf; ctx->state = SPNG_STATE_OUTPUT; } else { ctx->stream_buf = spng__malloc(ctx, SPNG_READ_SIZE); if(ctx->stream_buf == NULL) return SPNG_EMEM; ctx->read_fn = rw_func; ctx->data = ctx->stream_buf; ctx->data_size = SPNG_READ_SIZE; ctx->state = SPNG_STATE_INPUT; } ctx->stream_user_ptr = user; ctx->streaming = 1; return 0; } int spng_set_png_file(spng_ctx *ctx, FILE *file) { if(file == NULL) return 1; if(ctx->encode_only) return spng_set_png_stream(ctx, file_write_fn, file); return spng_set_png_stream(ctx, file_read_fn, file); } void *spng_get_png_buffer(spng_ctx *ctx, size_t *len, int *error) { int tmp = 0; error = error ? error : &tmp; *error = 0; if(ctx == NULL || !len) *error = SPNG_EINVAL; if(*error) return NULL; if(!ctx->encode_only) *error = SPNG_ECTXTYPE; else if(!ctx->state) *error = SPNG_EBADSTATE; else if(!ctx->internal_buffer) *error = SPNG_EOPSTATE; else if(ctx->state < SPNG_STATE_EOI) *error = SPNG_EOPSTATE; else if(ctx->state != SPNG_STATE_IEND) *error = SPNG_ENOTFINAL; if(*error) return NULL; ctx->user_owns_out_png = 1; *len = ctx->bytes_encoded; return ctx->out_png; } int spng_set_image_limits(spng_ctx *ctx, uint32_t width, uint32_t height) { if(ctx == NULL) return 1; if(width > spng_u32max || height > spng_u32max) return 1; ctx->max_width = width; ctx->max_height = height; return 0; } int spng_get_image_limits(spng_ctx *ctx, uint32_t *width, uint32_t *height) { if(ctx == NULL || width == NULL || height == NULL) return 1; *width = ctx->max_width; *height = ctx->max_height; return 0; } int spng_set_chunk_limits(spng_ctx *ctx, size_t chunk_size, size_t cache_limit) { if(ctx == NULL || chunk_size > spng_u32max || chunk_size > cache_limit) return 1; ctx->max_chunk_size = chunk_size; ctx->chunk_cache_limit = cache_limit; return 0; } int spng_get_chunk_limits(spng_ctx *ctx, size_t *chunk_size, size_t *cache_limit) { if(ctx == NULL || chunk_size == NULL || cache_limit == NULL) return 1; *chunk_size = ctx->max_chunk_size; *cache_limit = ctx->chunk_cache_limit; return 0; } int spng_set_crc_action(spng_ctx *ctx, int critical, int ancillary) { if(ctx == NULL) return 1; if(ctx->encode_only) return SPNG_ECTXTYPE; if(critical > 2 || critical < 0) return 1; if(ancillary > 2 || ancillary < 0) return 1; if(critical == SPNG_CRC_DISCARD) return 1; ctx->crc_action_critical = critical; ctx->crc_action_ancillary = ancillary; return 0; } int spng_set_option(spng_ctx *ctx, enum spng_option option, int value) { if(ctx == NULL) return 1; if(!ctx->state) return SPNG_EBADSTATE; switch(option) { case SPNG_KEEP_UNKNOWN_CHUNKS: { ctx->keep_unknown = value ? 1 : 0; break; } case SPNG_IMG_COMPRESSION_LEVEL: { ctx->image_options.compression_level = value; break; } case SPNG_IMG_WINDOW_BITS: { ctx->image_options.window_bits = value; break; } case SPNG_IMG_MEM_LEVEL: { ctx->image_options.mem_level = value; break; } case SPNG_IMG_COMPRESSION_STRATEGY: { ctx->image_options.strategy = value; break; } case SPNG_TEXT_COMPRESSION_LEVEL: { ctx->text_options.compression_level = value; break; } case SPNG_TEXT_WINDOW_BITS: { ctx->text_options.window_bits = value; break; } case SPNG_TEXT_MEM_LEVEL: { ctx->text_options.mem_level = value; break; } case SPNG_TEXT_COMPRESSION_STRATEGY: { ctx->text_options.strategy = value; break; } case SPNG_FILTER_CHOICE: { if(value & ~SPNG_FILTER_CHOICE_ALL) return 1; ctx->encode_flags.filter_choice = value; break; } case SPNG_CHUNK_COUNT_LIMIT: { if(value < 0) return 1; if(value > (int)ctx->chunk_count_total) return 1; ctx->chunk_count_limit = value; break; } case SPNG_ENCODE_TO_BUFFER: { if(value < 0) return 1; if(!ctx->encode_only) return SPNG_ECTXTYPE; if(ctx->state >= SPNG_STATE_OUTPUT) return SPNG_EOPSTATE; if(!value) break; ctx->internal_buffer = 1; ctx->state = SPNG_STATE_OUTPUT; break; } default: return 1; } /* Option can no longer be overriden by the library */ if(option < 32) ctx->optimize_option &= ~(1 << option); return 0; } int spng_get_option(spng_ctx *ctx, enum spng_option option, int *value) { if(ctx == NULL || value == NULL) return 1; if(!ctx->state) return SPNG_EBADSTATE; switch(option) { case SPNG_KEEP_UNKNOWN_CHUNKS: { *value = ctx->keep_unknown; break; } case SPNG_IMG_COMPRESSION_LEVEL: { *value = ctx->image_options.compression_level; break; } case SPNG_IMG_WINDOW_BITS: { *value = ctx->image_options.window_bits; break; } case SPNG_IMG_MEM_LEVEL: { *value = ctx->image_options.mem_level; break; } case SPNG_IMG_COMPRESSION_STRATEGY: { *value = ctx->image_options.strategy; break; } case SPNG_TEXT_COMPRESSION_LEVEL: { *value = ctx->text_options.compression_level; break; } case SPNG_TEXT_WINDOW_BITS: { *value = ctx->text_options.window_bits; break; } case SPNG_TEXT_MEM_LEVEL: { *value = ctx->text_options.mem_level; break; } case SPNG_TEXT_COMPRESSION_STRATEGY: { *value = ctx->text_options.strategy; break; } case SPNG_FILTER_CHOICE: { *value = ctx->encode_flags.filter_choice; break; } case SPNG_CHUNK_COUNT_LIMIT: { *value = ctx->chunk_count_limit; break; } case SPNG_ENCODE_TO_BUFFER: { if(ctx->internal_buffer) *value = 1; else *value = 0; break; } default: return 1; } return 0; } int spng_decoded_image_size(spng_ctx *ctx, int fmt, size_t *len) { if(ctx == NULL || len == NULL) return 1; int ret = read_chunks(ctx, 1); if(ret) return ret; ret = check_decode_fmt(&ctx->ihdr, fmt); if(ret) return ret; return calculate_image_size(&ctx->ihdr, fmt, len); } int spng_get_ihdr(spng_ctx *ctx, struct spng_ihdr *ihdr) { if(ctx == NULL) return 1; int ret = read_chunks(ctx, 1); if(ret) return ret; if(ihdr == NULL) return 1; *ihdr = ctx->ihdr; return 0; } int spng_get_plte(spng_ctx *ctx, struct spng_plte *plte) { SPNG_GET_CHUNK_BOILERPLATE(plte); *plte = ctx->plte; return 0; } int spng_get_trns(spng_ctx *ctx, struct spng_trns *trns) { SPNG_GET_CHUNK_BOILERPLATE(trns); *trns = ctx->trns; return 0; } int spng_get_chrm(spng_ctx *ctx, struct spng_chrm *chrm) { SPNG_GET_CHUNK_BOILERPLATE(chrm); chrm->white_point_x = (double)ctx->chrm_int.white_point_x / 100000.0; chrm->white_point_y = (double)ctx->chrm_int.white_point_y / 100000.0; chrm->red_x = (double)ctx->chrm_int.red_x / 100000.0; chrm->red_y = (double)ctx->chrm_int.red_y / 100000.0; chrm->blue_y = (double)ctx->chrm_int.blue_y / 100000.0; chrm->blue_x = (double)ctx->chrm_int.blue_x / 100000.0; chrm->green_x = (double)ctx->chrm_int.green_x / 100000.0; chrm->green_y = (double)ctx->chrm_int.green_y / 100000.0; return 0; } int spng_get_chrm_int(spng_ctx *ctx, struct spng_chrm_int *chrm) { SPNG_GET_CHUNK_BOILERPLATE(chrm); *chrm = ctx->chrm_int; return 0; } int spng_get_gama(spng_ctx *ctx, double *gamma) { double *gama = gamma; SPNG_GET_CHUNK_BOILERPLATE(gama); *gama = (double)ctx->gama / 100000.0; return 0; } int spng_get_gama_int(spng_ctx *ctx, uint32_t *gama_int) { uint32_t *gama = gama_int; SPNG_GET_CHUNK_BOILERPLATE(gama); *gama_int = ctx->gama; return 0; } int spng_get_iccp(spng_ctx *ctx, struct spng_iccp *iccp) { SPNG_GET_CHUNK_BOILERPLATE(iccp); *iccp = ctx->iccp; return 0; } int spng_get_sbit(spng_ctx *ctx, struct spng_sbit *sbit) { SPNG_GET_CHUNK_BOILERPLATE(sbit); *sbit = ctx->sbit; return 0; } int spng_get_srgb(spng_ctx *ctx, uint8_t *rendering_intent) { uint8_t *srgb = rendering_intent; SPNG_GET_CHUNK_BOILERPLATE(srgb); *srgb = ctx->srgb_rendering_intent; return 0; } int spng_get_text(spng_ctx *ctx, struct spng_text *text, uint32_t *n_text) { if(ctx == NULL) return 1; int ret = read_chunks(ctx, 0); if(ret) return ret; if(!ctx->stored.text) return SPNG_ECHUNKAVAIL; if(n_text == NULL) return 1; if(text == NULL) { *n_text = ctx->n_text; return 0; } if(*n_text < ctx->n_text) return 1; uint32_t i; for(i=0; i< ctx->n_text; i++) { text[i].type = ctx->text_list[i].type; memcpy(&text[i].keyword, ctx->text_list[i].keyword, strlen(ctx->text_list[i].keyword) + 1); text[i].compression_method = 0; text[i].compression_flag = ctx->text_list[i].compression_flag; text[i].language_tag = ctx->text_list[i].language_tag; text[i].translated_keyword = ctx->text_list[i].translated_keyword; text[i].length = ctx->text_list[i].text_length; text[i].text = ctx->text_list[i].text; } return ret; } int spng_get_bkgd(spng_ctx *ctx, struct spng_bkgd *bkgd) { SPNG_GET_CHUNK_BOILERPLATE(bkgd); *bkgd = ctx->bkgd; return 0; } int spng_get_hist(spng_ctx *ctx, struct spng_hist *hist) { SPNG_GET_CHUNK_BOILERPLATE(hist); *hist = ctx->hist; return 0; } int spng_get_phys(spng_ctx *ctx, struct spng_phys *phys) { SPNG_GET_CHUNK_BOILERPLATE(phys); *phys = ctx->phys; return 0; } int spng_get_splt(spng_ctx *ctx, struct spng_splt *splt, uint32_t *n_splt) { if(ctx == NULL) return 1; int ret = read_chunks(ctx, 0); if(ret) return ret; if(!ctx->stored.splt) return SPNG_ECHUNKAVAIL; if(n_splt == NULL) return 1; if(splt == NULL) { *n_splt = ctx->n_splt; return 0; } if(*n_splt < ctx->n_splt) return 1; memcpy(splt, ctx->splt_list, ctx->n_splt * sizeof(struct spng_splt)); return 0; } int spng_get_time(spng_ctx *ctx, struct spng_time *time) { SPNG_GET_CHUNK_BOILERPLATE(time); *time = ctx->time; return 0; } int spng_get_unknown_chunks(spng_ctx *ctx, struct spng_unknown_chunk *chunks, uint32_t *n_chunks) { if(ctx == NULL) return 1; int ret = read_chunks(ctx, 0); if(ret) return ret; if(!ctx->stored.unknown) return SPNG_ECHUNKAVAIL; if(n_chunks == NULL) return 1; if(chunks == NULL) { *n_chunks = ctx->n_chunks; return 0; } if(*n_chunks < ctx->n_chunks) return 1; memcpy(chunks, ctx->chunk_list, sizeof(struct spng_unknown_chunk)); return 0; } int spng_get_offs(spng_ctx *ctx, struct spng_offs *offs) { SPNG_GET_CHUNK_BOILERPLATE(offs); *offs = ctx->offs; return 0; } int spng_get_exif(spng_ctx *ctx, struct spng_exif *exif) { SPNG_GET_CHUNK_BOILERPLATE(exif); *exif = ctx->exif; return 0; } int spng_set_ihdr(spng_ctx *ctx, struct spng_ihdr *ihdr) { SPNG_SET_CHUNK_BOILERPLATE(ihdr); if(ctx->stored.ihdr) return 1; ret = check_ihdr(ihdr, ctx->max_width, ctx->max_height); if(ret) return ret; ctx->ihdr = *ihdr; ctx->stored.ihdr = 1; ctx->user.ihdr = 1; return 0; } int spng_set_plte(spng_ctx *ctx, struct spng_plte *plte) { SPNG_SET_CHUNK_BOILERPLATE(plte); if(!ctx->stored.ihdr) return 1; if(check_plte(plte, &ctx->ihdr)) return 1; ctx->plte.n_entries = plte->n_entries; memcpy(ctx->plte.entries, plte->entries, plte->n_entries * sizeof(struct spng_plte_entry)); ctx->stored.plte = 1; ctx->user.plte = 1; return 0; } int spng_set_trns(spng_ctx *ctx, struct spng_trns *trns) { SPNG_SET_CHUNK_BOILERPLATE(trns); if(!ctx->stored.ihdr) return SPNG_ENOIHDR; if(ctx->ihdr.color_type == SPNG_COLOR_TYPE_GRAYSCALE) { ctx->trns.gray = trns->gray; } else if(ctx->ihdr.color_type == SPNG_COLOR_TYPE_TRUECOLOR) { ctx->trns.red = trns->red; ctx->trns.green = trns->green; ctx->trns.blue = trns->blue; } else if(ctx->ihdr.color_type == SPNG_COLOR_TYPE_INDEXED) { if(!ctx->stored.plte) return SPNG_ETRNS_NO_PLTE; if(trns->n_type3_entries > ctx->plte.n_entries) return 1; ctx->trns.n_type3_entries = trns->n_type3_entries; memcpy(ctx->trns.type3_alpha, trns->type3_alpha, trns->n_type3_entries); } else return SPNG_ETRNS_COLOR_TYPE; ctx->stored.trns = 1; ctx->user.trns = 1; return 0; } int spng_set_chrm(spng_ctx *ctx, struct spng_chrm *chrm) { SPNG_SET_CHUNK_BOILERPLATE(chrm); struct spng_chrm_int chrm_int; chrm_int.white_point_x = (uint32_t)(chrm->white_point_x * 100000.0); chrm_int.white_point_y = (uint32_t)(chrm->white_point_y * 100000.0); chrm_int.red_x = (uint32_t)(chrm->red_x * 100000.0); chrm_int.red_y = (uint32_t)(chrm->red_y * 100000.0); chrm_int.green_x = (uint32_t)(chrm->green_x * 100000.0); chrm_int.green_y = (uint32_t)(chrm->green_y * 100000.0); chrm_int.blue_x = (uint32_t)(chrm->blue_x * 100000.0); chrm_int.blue_y = (uint32_t)(chrm->blue_y * 100000.0); if(check_chrm_int(&chrm_int)) return SPNG_ECHRM; ctx->chrm_int = chrm_int; ctx->stored.chrm = 1; ctx->user.chrm = 1; return 0; } int spng_set_chrm_int(spng_ctx *ctx, struct spng_chrm_int *chrm_int) { SPNG_SET_CHUNK_BOILERPLATE(chrm_int); if(check_chrm_int(chrm_int)) return SPNG_ECHRM; ctx->chrm_int = *chrm_int; ctx->stored.chrm = 1; ctx->user.chrm = 1; return 0; } int spng_set_gama(spng_ctx *ctx, double gamma) { SPNG_SET_CHUNK_BOILERPLATE(ctx); uint32_t gama = gamma * 100000.0; if(!gama) return 1; if(gama > spng_u32max) return 1; ctx->gama = gama; ctx->stored.gama = 1; ctx->user.gama = 1; return 0; } int spng_set_gama_int(spng_ctx *ctx, uint32_t gamma) { SPNG_SET_CHUNK_BOILERPLATE(ctx); if(!gamma) return 1; if(gamma > spng_u32max) return 1; ctx->gama = gamma; ctx->stored.gama = 1; ctx->user.gama = 1; return 0; } int spng_set_iccp(spng_ctx *ctx, struct spng_iccp *iccp) { SPNG_SET_CHUNK_BOILERPLATE(iccp); if(check_png_keyword(iccp->profile_name)) return SPNG_EICCP_NAME; if(!iccp->profile_len) return SPNG_ECHUNK_SIZE; if(iccp->profile_len > spng_u32max) return SPNG_ECHUNK_STDLEN; if(ctx->iccp.profile && !ctx->user.iccp) spng__free(ctx, ctx->iccp.profile); ctx->iccp = *iccp; ctx->stored.iccp = 1; ctx->user.iccp = 1; return 0; } int spng_set_sbit(spng_ctx *ctx, struct spng_sbit *sbit) { SPNG_SET_CHUNK_BOILERPLATE(sbit); if(check_sbit(sbit, &ctx->ihdr)) return 1; if(!ctx->stored.ihdr) return 1; ctx->sbit = *sbit; ctx->stored.sbit = 1; ctx->user.sbit = 1; return 0; } int spng_set_srgb(spng_ctx *ctx, uint8_t rendering_intent) { SPNG_SET_CHUNK_BOILERPLATE(ctx); if(rendering_intent > 3) return 1; ctx->srgb_rendering_intent = rendering_intent; ctx->stored.srgb = 1; ctx->user.srgb = 1; return 0; } int spng_set_text(spng_ctx *ctx, struct spng_text *text, uint32_t n_text) { if(!n_text) return 1; SPNG_SET_CHUNK_BOILERPLATE(text); uint32_t i; for(i=0; i < n_text; i++) { if(check_png_keyword(text[i].keyword)) return SPNG_ETEXT_KEYWORD; if(!text[i].length) return 1; if(text[i].length > UINT_MAX) return 1; if(text[i].text == NULL) return 1; if(text[i].type == SPNG_TEXT) { if(ctx->strict && check_png_text(text[i].text, text[i].length)) return 1; } else if(text[i].type == SPNG_ZTXT) { if(ctx->strict && check_png_text(text[i].text, text[i].length)) return 1; if(text[i].compression_method != 0) return SPNG_EZTXT_COMPRESSION_METHOD; } else if(text[i].type == SPNG_ITXT) { if(text[i].compression_flag > 1) return SPNG_EITXT_COMPRESSION_FLAG; if(text[i].compression_method != 0) return SPNG_EITXT_COMPRESSION_METHOD; if(text[i].language_tag == NULL) return SPNG_EITXT_LANG_TAG; if(text[i].translated_keyword == NULL) return SPNG_EITXT_TRANSLATED_KEY; } else return 1; } struct spng_text2 *text_list = spng__calloc(ctx, sizeof(struct spng_text2), n_text); if(!text_list) return SPNG_EMEM; if(ctx->text_list != NULL) { for(i=0; i < ctx->n_text; i++) { if(ctx->user.text) break; spng__free(ctx, ctx->text_list[i].keyword); if(ctx->text_list[i].compression_flag) spng__free(ctx, ctx->text_list[i].text); } spng__free(ctx, ctx->text_list); } for(i=0; i < n_text; i++) { text_list[i].type = text[i].type; /* Prevent issues with spng_text.keyword[80] going out of scope */ text_list[i].keyword = text_list[i].user_keyword_storage; memcpy(text_list[i].user_keyword_storage, text[i].keyword, strlen(text[i].keyword)); text_list[i].text = text[i].text; text_list[i].text_length = text[i].length; if(text[i].type == SPNG_ZTXT) { text_list[i].compression_flag = 1; } else if(text[i].type == SPNG_ITXT) { text_list[i].compression_flag = text[i].compression_flag; text_list[i].language_tag = text[i].language_tag; text_list[i].translated_keyword = text[i].translated_keyword; } } ctx->text_list = text_list; ctx->n_text = n_text; ctx->stored.text = 1; ctx->user.text = 1; return 0; } int spng_set_bkgd(spng_ctx *ctx, struct spng_bkgd *bkgd) { SPNG_SET_CHUNK_BOILERPLATE(bkgd); if(!ctx->stored.ihdr) return 1; if(ctx->ihdr.color_type == 0 || ctx->ihdr.color_type == 4) { ctx->bkgd.gray = bkgd->gray; } else if(ctx->ihdr.color_type == 2 || ctx->ihdr.color_type == 6) { ctx->bkgd.red = bkgd->red; ctx->bkgd.green = bkgd->green; ctx->bkgd.blue = bkgd->blue; } else if(ctx->ihdr.color_type == 3) { if(!ctx->stored.plte) return SPNG_EBKGD_NO_PLTE; if(bkgd->plte_index >= ctx->plte.n_entries) return SPNG_EBKGD_PLTE_IDX; ctx->bkgd.plte_index = bkgd->plte_index; } ctx->stored.bkgd = 1; ctx->user.bkgd = 1; return 0; } int spng_set_hist(spng_ctx *ctx, struct spng_hist *hist) { SPNG_SET_CHUNK_BOILERPLATE(hist); if(!ctx->stored.plte) return SPNG_EHIST_NO_PLTE; ctx->hist = *hist; ctx->stored.hist = 1; ctx->user.hist = 1; return 0; } int spng_set_phys(spng_ctx *ctx, struct spng_phys *phys) { SPNG_SET_CHUNK_BOILERPLATE(phys); if(check_phys(phys)) return SPNG_EPHYS; ctx->phys = *phys; ctx->stored.phys = 1; ctx->user.phys = 1; return 0; } int spng_set_splt(spng_ctx *ctx, struct spng_splt *splt, uint32_t n_splt) { if(!n_splt) return 1; SPNG_SET_CHUNK_BOILERPLATE(splt); uint32_t i; for(i=0; i < n_splt; i++) { if(check_png_keyword(splt[i].name)) return SPNG_ESPLT_NAME; if( !(splt[i].sample_depth == 8 || splt[i].sample_depth == 16) ) return SPNG_ESPLT_DEPTH; } if(ctx->stored.splt && !ctx->user.splt) { for(i=0; i < ctx->n_splt; i++) { if(ctx->splt_list[i].entries != NULL) spng__free(ctx, ctx->splt_list[i].entries); } spng__free(ctx, ctx->splt_list); } ctx->splt_list = splt; ctx->n_splt = n_splt; ctx->stored.splt = 1; ctx->user.splt = 1; return 0; } int spng_set_time(spng_ctx *ctx, struct spng_time *time) { SPNG_SET_CHUNK_BOILERPLATE(time); if(check_time(time)) return SPNG_ETIME; ctx->time = *time; ctx->stored.time = 1; ctx->user.time = 1; return 0; } int spng_set_unknown_chunks(spng_ctx *ctx, struct spng_unknown_chunk *chunks, uint32_t n_chunks) { if(!n_chunks) return 1; SPNG_SET_CHUNK_BOILERPLATE(chunks); uint32_t i; for(i=0; i < n_chunks; i++) { if(chunks[i].length > spng_u32max) return SPNG_ECHUNK_STDLEN; if(chunks[i].length && chunks[i].data == NULL) return 1; switch(chunks[i].location) { case SPNG_AFTER_IHDR: case SPNG_AFTER_PLTE: case SPNG_AFTER_IDAT: break; default: return SPNG_ECHUNK_POS; } } if(ctx->stored.unknown && !ctx->user.unknown) { for(i=0; i < ctx->n_chunks; i++) { spng__free(ctx, ctx->chunk_list[i].data); } spng__free(ctx, ctx->chunk_list); } ctx->chunk_list = chunks; ctx->n_chunks = n_chunks; ctx->stored.unknown = 1; ctx->user.unknown = 1; return 0; } int spng_set_offs(spng_ctx *ctx, struct spng_offs *offs) { SPNG_SET_CHUNK_BOILERPLATE(offs); if(check_offs(offs)) return SPNG_EOFFS; ctx->offs = *offs; ctx->stored.offs = 1; ctx->user.offs = 1; return 0; } int spng_set_exif(spng_ctx *ctx, struct spng_exif *exif) { SPNG_SET_CHUNK_BOILERPLATE(exif); if(check_exif(exif)) return SPNG_EEXIF; if(ctx->exif.data != NULL && !ctx->user.exif) spng__free(ctx, ctx->exif.data); ctx->exif = *exif; ctx->stored.exif = 1; ctx->user.exif = 1; return 0; } const char *spng_strerror(int err) { switch(err) { case SPNG_IO_EOF: return "end of stream"; case SPNG_IO_ERROR: return "stream error"; case SPNG_OK: return "success"; case SPNG_EINVAL: return "invalid argument"; case SPNG_EMEM: return "out of memory"; case SPNG_EOVERFLOW: return "arithmetic overflow"; case SPNG_ESIGNATURE: return "invalid signature"; case SPNG_EWIDTH: return "invalid image width"; case SPNG_EHEIGHT: return "invalid image height"; case SPNG_EUSER_WIDTH: return "image width exceeds user limit"; case SPNG_EUSER_HEIGHT: return "image height exceeds user limit"; case SPNG_EBIT_DEPTH: return "invalid bit depth"; case SPNG_ECOLOR_TYPE: return "invalid color type"; case SPNG_ECOMPRESSION_METHOD: return "invalid compression method"; case SPNG_EFILTER_METHOD: return "invalid filter method"; case SPNG_EINTERLACE_METHOD: return "invalid interlace method"; case SPNG_EIHDR_SIZE: return "invalid IHDR chunk size"; case SPNG_ENOIHDR: return "missing IHDR chunk"; case SPNG_ECHUNK_POS: return "invalid chunk position"; case SPNG_ECHUNK_SIZE: return "invalid chunk length"; case SPNG_ECHUNK_CRC: return "invalid chunk checksum"; case SPNG_ECHUNK_TYPE: return "invalid chunk type"; case SPNG_ECHUNK_UNKNOWN_CRITICAL: return "unknown critical chunk"; case SPNG_EDUP_PLTE: return "duplicate PLTE chunk"; case SPNG_EDUP_CHRM: return "duplicate cHRM chunk"; case SPNG_EDUP_GAMA: return "duplicate gAMA chunk"; case SPNG_EDUP_ICCP: return "duplicate iCCP chunk"; case SPNG_EDUP_SBIT: return "duplicate sBIT chunk"; case SPNG_EDUP_SRGB: return "duplicate sRGB chunk"; case SPNG_EDUP_BKGD: return "duplicate bKGD chunk"; case SPNG_EDUP_HIST: return "duplicate hIST chunk"; case SPNG_EDUP_TRNS: return "duplicate tRNS chunk"; case SPNG_EDUP_PHYS: return "duplicate pHYs chunk"; case SPNG_EDUP_TIME: return "duplicate tIME chunk"; case SPNG_EDUP_OFFS: return "duplicate oFFs chunk"; case SPNG_EDUP_EXIF: return "duplicate eXIf chunk"; case SPNG_ECHRM: return "invalid cHRM chunk"; case SPNG_EPLTE_IDX: return "invalid palette (PLTE) index"; case SPNG_ETRNS_COLOR_TYPE: return "tRNS chunk with incompatible color type"; case SPNG_ETRNS_NO_PLTE: return "missing palette (PLTE) for tRNS chunk"; case SPNG_EGAMA: return "invalid gAMA chunk"; case SPNG_EICCP_NAME: return "invalid iCCP profile name"; case SPNG_EICCP_COMPRESSION_METHOD: return "invalid iCCP compression method"; case SPNG_ESBIT: return "invalid sBIT chunk"; case SPNG_ESRGB: return "invalid sRGB chunk"; case SPNG_ETEXT: return "invalid tEXt chunk"; case SPNG_ETEXT_KEYWORD: return "invalid tEXt keyword"; case SPNG_EZTXT: return "invalid zTXt chunk"; case SPNG_EZTXT_COMPRESSION_METHOD: return "invalid zTXt compression method"; case SPNG_EITXT: return "invalid iTXt chunk"; case SPNG_EITXT_COMPRESSION_FLAG: return "invalid iTXt compression flag"; case SPNG_EITXT_COMPRESSION_METHOD: return "invalid iTXt compression method"; case SPNG_EITXT_LANG_TAG: return "invalid iTXt language tag"; case SPNG_EITXT_TRANSLATED_KEY: return "invalid iTXt translated key"; case SPNG_EBKGD_NO_PLTE: return "missing palette for bKGD chunk"; case SPNG_EBKGD_PLTE_IDX: return "invalid palette index for bKGD chunk"; case SPNG_EHIST_NO_PLTE: return "missing palette for hIST chunk"; case SPNG_EPHYS: return "invalid pHYs chunk"; case SPNG_ESPLT_NAME: return "invalid suggested palette name"; case SPNG_ESPLT_DUP_NAME: return "duplicate suggested palette (sPLT) name"; case SPNG_ESPLT_DEPTH: return "invalid suggested palette (sPLT) sample depth"; case SPNG_ETIME: return "invalid tIME chunk"; case SPNG_EOFFS: return "invalid oFFs chunk"; case SPNG_EEXIF: return "invalid eXIf chunk"; case SPNG_EIDAT_TOO_SHORT: return "IDAT stream too short"; case SPNG_EIDAT_STREAM: return "IDAT stream error"; case SPNG_EZLIB: return "zlib error"; case SPNG_EFILTER: return "invalid scanline filter"; case SPNG_EBUFSIZ: return "invalid buffer size"; case SPNG_EIO: return "i/o error"; case SPNG_EOF: return "end of file"; case SPNG_EBUF_SET: return "buffer already set"; case SPNG_EBADSTATE: return "non-recoverable state"; case SPNG_EFMT: return "invalid format"; case SPNG_EFLAGS: return "invalid flags"; case SPNG_ECHUNKAVAIL: return "chunk not available"; case SPNG_ENCODE_ONLY: return "encode only context"; case SPNG_EOI: return "reached end-of-image state"; case SPNG_ENOPLTE: return "missing PLTE for indexed image"; case SPNG_ECHUNK_LIMITS: return "reached chunk/cache limits"; case SPNG_EZLIB_INIT: return "zlib init error"; case SPNG_ECHUNK_STDLEN: return "chunk exceeds maximum standard length"; case SPNG_EINTERNAL: return "internal error"; case SPNG_ECTXTYPE: return "invalid operation for context type"; case SPNG_ENOSRC: return "source PNG not set"; case SPNG_ENODST: return "PNG output not set"; case SPNG_EOPSTATE: return "invalid operation for state"; case SPNG_ENOTFINAL: return "PNG not finalized"; default: return "unknown error"; } } const char *spng_version_string(void) { return SPNG_VERSION_STRING; } #if defined(_MSC_VER) #pragma warning(pop) #endif /* The following SIMD optimizations are derived from libpng source code. */ /* * PNG Reference Library License version 2 * * Copyright (c) 1995-2019 The PNG Reference Library Authors. * Copyright (c) 2018-2019 Cosmin Truta. * Copyright (c) 2000-2002, 2004, 2006-2018 Glenn Randers-Pehrson. * Copyright (c) 1996-1997 Andreas Dilger. * Copyright (c) 1995-1996 Guy Eric Schalnat, Group 42, Inc. * * The software is supplied "as is", without warranty of any kind, * express or implied, including, without limitation, the warranties * of merchantability, fitness for a particular purpose, title, and * non-infringement. In no event shall the Copyright owners, or * anyone distributing the software, be liable for any damages or * other liability, whether in contract, tort or otherwise, arising * from, out of, or in connection with the software, or the use or * other dealings in the software, even if advised of the possibility * of such damage. * * Permission is hereby granted to use, copy, modify, and distribute * this software, or portions hereof, for any purpose, without fee, * subject to the following restrictions: * * 1. The origin of this software must not be misrepresented; you * must not claim that you wrote the original software. If you * use this software in a product, an acknowledgment in the product * documentation would be appreciated, but is not required. * * 2. Altered source versions must be plainly marked as such, and must * not be misrepresented as being the original software. * * 3. This Copyright notice may not be removed or altered from any * source or altered source distribution. */ #if defined(SPNG_X86) #ifndef SPNG_SSE #define SPNG_SSE 1 #endif #if defined(__GNUC__) && !defined(__clang__) #if SPNG_SSE == 3 #pragma GCC target("ssse3") #elif SPNG_SSE == 4 #pragma GCC target("sse4.1") #else #pragma GCC target("sse2") #endif #endif /* SSE2 optimised filter functions * Derived from filter_neon_intrinsics.c * * Copyright (c) 2018 Cosmin Truta * Copyright (c) 2016-2017 Glenn Randers-Pehrson * Written by Mike Klein and Matt Sarett * Derived from arm/filter_neon_intrinsics.c * * This code is derived from libpng source code. * For conditions of distribution and use, see the disclaimer * and license above. */ #include #include #include /* Functions in this file look at most 3 pixels (a,b,c) to predict the 4th (d). * They're positioned like this: * prev: c b * row: a d * The Sub filter predicts d=a, Avg d=(a+b)/2, and Paeth predicts d to be * whichever of a, b, or c is closest to p=a+b-c. */ static __m128i load4(const void* p) { int tmp; memcpy(&tmp, p, sizeof(tmp)); return _mm_cvtsi32_si128(tmp); } static void store4(void* p, __m128i v) { int tmp = _mm_cvtsi128_si32(v); memcpy(p, &tmp, sizeof(int)); } static __m128i load3(const void* p) { uint32_t tmp = 0; memcpy(&tmp, p, 3); return _mm_cvtsi32_si128(tmp); } static void store3(void* p, __m128i v) { int tmp = _mm_cvtsi128_si32(v); memcpy(p, &tmp, 3); } static void defilter_sub3(size_t rowbytes, unsigned char *row) { /* The Sub filter predicts each pixel as the previous pixel, a. * There is no pixel to the left of the first pixel. It's encoded directly. * That works with our main loop if we just say that left pixel was zero. */ size_t rb = rowbytes; __m128i a, d = _mm_setzero_si128(); while(rb >= 4) { a = d; d = load4(row); d = _mm_add_epi8(d, a); store3(row, d); row += 3; rb -= 3; } if(rb > 0) { a = d; d = load3(row); d = _mm_add_epi8(d, a); store3(row, d); } } static void defilter_sub4(size_t rowbytes, unsigned char *row) { /* The Sub filter predicts each pixel as the previous pixel, a. * There is no pixel to the left of the first pixel. It's encoded directly. * That works with our main loop if we just say that left pixel was zero. */ size_t rb = rowbytes+4; __m128i a, d = _mm_setzero_si128(); while(rb > 4) { a = d; d = load4(row); d = _mm_add_epi8(d, a); store4(row, d); row += 4; rb -= 4; } } static void defilter_avg3(size_t rowbytes, unsigned char *row, const unsigned char *prev) { /* The Avg filter predicts each pixel as the (truncated) average of a and b. * There's no pixel to the left of the first pixel. Luckily, it's * predicted to be half of the pixel above it. So again, this works * perfectly with our loop if we make sure a starts at zero. */ size_t rb = rowbytes; const __m128i zero = _mm_setzero_si128(); __m128i b; __m128i a, d = zero; while(rb >= 4) { __m128i avg; b = load4(prev); a = d; d = load4(row ); /* PNG requires a truncating average, so we can't just use _mm_avg_epu8 */ avg = _mm_avg_epu8(a,b); /* ...but we can fix it up by subtracting off 1 if it rounded up. */ avg = _mm_sub_epi8(avg, _mm_and_si128(_mm_xor_si128(a, b), _mm_set1_epi8(1))); d = _mm_add_epi8(d, avg); store3(row, d); prev += 3; row += 3; rb -= 3; } if(rb > 0) { __m128i avg; b = load3(prev); a = d; d = load3(row ); /* PNG requires a truncating average, so we can't just use _mm_avg_epu8 */ avg = _mm_avg_epu8(a, b); /* ...but we can fix it up by subtracting off 1 if it rounded up. */ avg = _mm_sub_epi8(avg, _mm_and_si128(_mm_xor_si128(a, b), _mm_set1_epi8(1))); d = _mm_add_epi8(d, avg); store3(row, d); } } static void defilter_avg4(size_t rowbytes, unsigned char *row, const unsigned char *prev) { /* The Avg filter predicts each pixel as the (truncated) average of a and b. * There's no pixel to the left of the first pixel. Luckily, it's * predicted to be half of the pixel above it. So again, this works * perfectly with our loop if we make sure a starts at zero. */ size_t rb = rowbytes+4; const __m128i zero = _mm_setzero_si128(); __m128i b; __m128i a, d = zero; while(rb > 4) { __m128i avg; b = load4(prev); a = d; d = load4(row ); /* PNG requires a truncating average, so we can't just use _mm_avg_epu8 */ avg = _mm_avg_epu8(a,b); /* ...but we can fix it up by subtracting off 1 if it rounded up. */ avg = _mm_sub_epi8(avg, _mm_and_si128(_mm_xor_si128(a, b), _mm_set1_epi8(1))); d = _mm_add_epi8(d, avg); store4(row, d); prev += 4; row += 4; rb -= 4; } } /* Returns |x| for 16-bit lanes. */ #if (SPNG_SSE >= 3) && !defined(_MSC_VER) __attribute__((target("ssse3"))) #endif static __m128i abs_i16(__m128i x) { #if SPNG_SSE >= 3 return _mm_abs_epi16(x); #else /* Read this all as, return x<0 ? -x : x. * To negate two's complement, you flip all the bits then add 1. */ __m128i is_negative = _mm_cmplt_epi16(x, _mm_setzero_si128()); /* Flip negative lanes. */ x = _mm_xor_si128(x, is_negative); /* +1 to negative lanes, else +0. */ x = _mm_sub_epi16(x, is_negative); return x; #endif } /* Bytewise c ? t : e. */ static __m128i if_then_else(__m128i c, __m128i t, __m128i e) { #if SPNG_SSE >= 4 return _mm_blendv_epi8(e, t, c); #else return _mm_or_si128(_mm_and_si128(c, t), _mm_andnot_si128(c, e)); #endif } static void defilter_paeth3(size_t rowbytes, unsigned char *row, const unsigned char *prev) { /* Paeth tries to predict pixel d using the pixel to the left of it, a, * and two pixels from the previous row, b and c: * prev: c b * row: a d * The Paeth function predicts d to be whichever of a, b, or c is nearest to * p=a+b-c. * * The first pixel has no left context, and so uses an Up filter, p = b. * This works naturally with our main loop's p = a+b-c if we force a and c * to zero. * Here we zero b and d, which become c and a respectively at the start of * the loop. */ size_t rb = rowbytes; const __m128i zero = _mm_setzero_si128(); __m128i c, b = zero, a, d = zero; while(rb >= 4) { /* It's easiest to do this math (particularly, deal with pc) with 16-bit * intermediates. */ __m128i pa,pb,pc,smallest,nearest; c = b; b = _mm_unpacklo_epi8(load4(prev), zero); a = d; d = _mm_unpacklo_epi8(load4(row ), zero); /* (p-a) == (a+b-c - a) == (b-c) */ pa = _mm_sub_epi16(b, c); /* (p-b) == (a+b-c - b) == (a-c) */ pb = _mm_sub_epi16(a, c); /* (p-c) == (a+b-c - c) == (a+b-c-c) == (b-c)+(a-c) */ pc = _mm_add_epi16(pa, pb); pa = abs_i16(pa); /* |p-a| */ pb = abs_i16(pb); /* |p-b| */ pc = abs_i16(pc); /* |p-c| */ smallest = _mm_min_epi16(pc, _mm_min_epi16(pa, pb)); /* Paeth breaks ties favoring a over b over c. */ nearest = if_then_else(_mm_cmpeq_epi16(smallest, pa), a, if_then_else(_mm_cmpeq_epi16(smallest, pb), b, c)); /* Note `_epi8`: we need addition to wrap modulo 255. */ d = _mm_add_epi8(d, nearest); store3(row, _mm_packus_epi16(d, d)); prev += 3; row += 3; rb -= 3; } if(rb > 0) { /* It's easiest to do this math (particularly, deal with pc) with 16-bit * intermediates. */ __m128i pa, pb, pc, smallest, nearest; c = b; b = _mm_unpacklo_epi8(load3(prev), zero); a = d; d = _mm_unpacklo_epi8(load3(row ), zero); /* (p-a) == (a+b-c - a) == (b-c) */ pa = _mm_sub_epi16(b, c); /* (p-b) == (a+b-c - b) == (a-c) */ pb = _mm_sub_epi16(a, c); /* (p-c) == (a+b-c - c) == (a+b-c-c) == (b-c)+(a-c) */ pc = _mm_add_epi16(pa, pb); pa = abs_i16(pa); /* |p-a| */ pb = abs_i16(pb); /* |p-b| */ pc = abs_i16(pc); /* |p-c| */ smallest = _mm_min_epi16(pc, _mm_min_epi16(pa, pb)); /* Paeth breaks ties favoring a over b over c. */ nearest = if_then_else(_mm_cmpeq_epi16(smallest, pa), a, if_then_else(_mm_cmpeq_epi16(smallest, pb), b, c)); /* Note `_epi8`: we need addition to wrap modulo 255. */ d = _mm_add_epi8(d, nearest); store3(row, _mm_packus_epi16(d, d)); } } static void defilter_paeth4(size_t rowbytes, unsigned char *row, const unsigned char *prev) { /* Paeth tries to predict pixel d using the pixel to the left of it, a, * and two pixels from the previous row, b and c: * prev: c b * row: a d * The Paeth function predicts d to be whichever of a, b, or c is nearest to * p=a+b-c. * * The first pixel has no left context, and so uses an Up filter, p = b. * This works naturally with our main loop's p = a+b-c if we force a and c * to zero. * Here we zero b and d, which become c and a respectively at the start of * the loop. */ size_t rb = rowbytes+4; const __m128i zero = _mm_setzero_si128(); __m128i pa, pb, pc, smallest, nearest; __m128i c, b = zero, a, d = zero; while(rb > 4) { /* It's easiest to do this math (particularly, deal with pc) with 16-bit * intermediates. */ c = b; b = _mm_unpacklo_epi8(load4(prev), zero); a = d; d = _mm_unpacklo_epi8(load4(row ), zero); /* (p-a) == (a+b-c - a) == (b-c) */ pa = _mm_sub_epi16(b, c); /* (p-b) == (a+b-c - b) == (a-c) */ pb = _mm_sub_epi16(a, c); /* (p-c) == (a+b-c - c) == (a+b-c-c) == (b-c)+(a-c) */ pc = _mm_add_epi16(pa, pb); pa = abs_i16(pa); /* |p-a| */ pb = abs_i16(pb); /* |p-b| */ pc = abs_i16(pc); /* |p-c| */ smallest = _mm_min_epi16(pc, _mm_min_epi16(pa, pb)); /* Paeth breaks ties favoring a over b over c. */ nearest = if_then_else(_mm_cmpeq_epi16(smallest, pa), a, if_then_else(_mm_cmpeq_epi16(smallest, pb), b, c)); /* Note `_epi8`: we need addition to wrap modulo 255. */ d = _mm_add_epi8(d, nearest); store4(row, _mm_packus_epi16(d, d)); prev += 4; row += 4; rb -= 4; } } #endif /* SPNG_X86 */ #if defined(SPNG_ARM) /* NEON optimised filter functions * Derived from filter_neon_intrinsics.c * * Copyright (c) 2018 Cosmin Truta * Copyright (c) 2014,2016 Glenn Randers-Pehrson * Written by James Yu , October 2013. * Based on filter_neon.S, written by Mans Rullgard, 2011. * * This code is derived from libpng source code. * For conditions of distribution and use, see the disclaimer * and license in this file. */ #define png_aligncast(type, value) ((void*)(value)) #define png_aligncastconst(type, value) ((const void*)(value)) /* libpng row pointers are not necessarily aligned to any particular boundary, * however this code will only work with appropriate alignment. mips/mips_init.c * checks for this (and will not compile unless it is done). This code uses * variants of png_aligncast to avoid compiler warnings. */ #define png_ptr(type,pointer) png_aligncast(type *,pointer) #define png_ptrc(type,pointer) png_aligncastconst(const type *,pointer) /* The following relies on a variable 'temp_pointer' being declared with type * 'type'. This is written this way just to hide the GCC strict aliasing * warning; note that the code is safe because there never is an alias between * the input and output pointers. */ #define png_ldr(type,pointer)\ (temp_pointer = png_ptr(type,pointer), *temp_pointer) #if defined(_MSC_VER) && !defined(__clang__) && defined(_M_ARM64) #include #else #include #endif static void defilter_sub3(size_t rowbytes, unsigned char *row) { unsigned char *rp = row; unsigned char *rp_stop = row + rowbytes; uint8x16_t vtmp = vld1q_u8(rp); uint8x8x2_t *vrpt = png_ptr(uint8x8x2_t, &vtmp); uint8x8x2_t vrp = *vrpt; uint8x8x4_t vdest; vdest.val[3] = vdup_n_u8(0); for (; rp < rp_stop;) { uint8x8_t vtmp1, vtmp2; uint32x2_t *temp_pointer; vtmp1 = vext_u8(vrp.val[0], vrp.val[1], 3); vdest.val[0] = vadd_u8(vdest.val[3], vrp.val[0]); vtmp2 = vext_u8(vrp.val[0], vrp.val[1], 6); vdest.val[1] = vadd_u8(vdest.val[0], vtmp1); vtmp1 = vext_u8(vrp.val[1], vrp.val[1], 1); vdest.val[2] = vadd_u8(vdest.val[1], vtmp2); vdest.val[3] = vadd_u8(vdest.val[2], vtmp1); vtmp = vld1q_u8(rp + 12); vrpt = png_ptr(uint8x8x2_t, &vtmp); vrp = *vrpt; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[0]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[1]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[2]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[3]), 0); rp += 3; } } static void defilter_sub4(size_t rowbytes, unsigned char *row) { unsigned char *rp = row; unsigned char *rp_stop = row + rowbytes; uint8x8x4_t vdest; vdest.val[3] = vdup_n_u8(0); for (; rp < rp_stop; rp += 16) { uint32x2x4_t vtmp = vld4_u32(png_ptr(uint32_t,rp)); uint8x8x4_t *vrpt = png_ptr(uint8x8x4_t,&vtmp); uint8x8x4_t vrp = *vrpt; uint32x2x4_t *temp_pointer; uint32x2x4_t vdest_val; vdest.val[0] = vadd_u8(vdest.val[3], vrp.val[0]); vdest.val[1] = vadd_u8(vdest.val[0], vrp.val[1]); vdest.val[2] = vadd_u8(vdest.val[1], vrp.val[2]); vdest.val[3] = vadd_u8(vdest.val[2], vrp.val[3]); vdest_val = png_ldr(uint32x2x4_t, &vdest); vst4_lane_u32(png_ptr(uint32_t,rp), vdest_val, 0); } } static void defilter_avg3(size_t rowbytes, unsigned char *row, const unsigned char *prev_row) { unsigned char *rp = row; const unsigned char *pp = prev_row; unsigned char *rp_stop = row + rowbytes; uint8x16_t vtmp; uint8x8x2_t *vrpt; uint8x8x2_t vrp; uint8x8x4_t vdest; vdest.val[3] = vdup_n_u8(0); vtmp = vld1q_u8(rp); vrpt = png_ptr(uint8x8x2_t,&vtmp); vrp = *vrpt; for (; rp < rp_stop; pp += 12) { uint8x8_t vtmp1, vtmp2, vtmp3; uint8x8x2_t *vppt; uint8x8x2_t vpp; uint32x2_t *temp_pointer; vtmp = vld1q_u8(pp); vppt = png_ptr(uint8x8x2_t,&vtmp); vpp = *vppt; vtmp1 = vext_u8(vrp.val[0], vrp.val[1], 3); vdest.val[0] = vhadd_u8(vdest.val[3], vpp.val[0]); vdest.val[0] = vadd_u8(vdest.val[0], vrp.val[0]); vtmp2 = vext_u8(vpp.val[0], vpp.val[1], 3); vtmp3 = vext_u8(vrp.val[0], vrp.val[1], 6); vdest.val[1] = vhadd_u8(vdest.val[0], vtmp2); vdest.val[1] = vadd_u8(vdest.val[1], vtmp1); vtmp2 = vext_u8(vpp.val[0], vpp.val[1], 6); vtmp1 = vext_u8(vrp.val[1], vrp.val[1], 1); vtmp = vld1q_u8(rp + 12); vrpt = png_ptr(uint8x8x2_t,&vtmp); vrp = *vrpt; vdest.val[2] = vhadd_u8(vdest.val[1], vtmp2); vdest.val[2] = vadd_u8(vdest.val[2], vtmp3); vtmp2 = vext_u8(vpp.val[1], vpp.val[1], 1); vdest.val[3] = vhadd_u8(vdest.val[2], vtmp2); vdest.val[3] = vadd_u8(vdest.val[3], vtmp1); vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[0]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[1]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[2]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[3]), 0); rp += 3; } } static void defilter_avg4(size_t rowbytes, unsigned char *row, const unsigned char *prev_row) { unsigned char *rp = row; unsigned char *rp_stop = row + rowbytes; const unsigned char *pp = prev_row; uint8x8x4_t vdest; vdest.val[3] = vdup_n_u8(0); for (; rp < rp_stop; rp += 16, pp += 16) { uint32x2x4_t vtmp; uint8x8x4_t *vrpt, *vppt; uint8x8x4_t vrp, vpp; uint32x2x4_t *temp_pointer; uint32x2x4_t vdest_val; vtmp = vld4_u32(png_ptr(uint32_t,rp)); vrpt = png_ptr(uint8x8x4_t,&vtmp); vrp = *vrpt; vtmp = vld4_u32(png_ptrc(uint32_t,pp)); vppt = png_ptr(uint8x8x4_t,&vtmp); vpp = *vppt; vdest.val[0] = vhadd_u8(vdest.val[3], vpp.val[0]); vdest.val[0] = vadd_u8(vdest.val[0], vrp.val[0]); vdest.val[1] = vhadd_u8(vdest.val[0], vpp.val[1]); vdest.val[1] = vadd_u8(vdest.val[1], vrp.val[1]); vdest.val[2] = vhadd_u8(vdest.val[1], vpp.val[2]); vdest.val[2] = vadd_u8(vdest.val[2], vrp.val[2]); vdest.val[3] = vhadd_u8(vdest.val[2], vpp.val[3]); vdest.val[3] = vadd_u8(vdest.val[3], vrp.val[3]); vdest_val = png_ldr(uint32x2x4_t, &vdest); vst4_lane_u32(png_ptr(uint32_t,rp), vdest_val, 0); } } static uint8x8_t paeth_arm(uint8x8_t a, uint8x8_t b, uint8x8_t c) { uint8x8_t d, e; uint16x8_t p1, pa, pb, pc; p1 = vaddl_u8(a, b); /* a + b */ pc = vaddl_u8(c, c); /* c * 2 */ pa = vabdl_u8(b, c); /* pa */ pb = vabdl_u8(a, c); /* pb */ pc = vabdq_u16(p1, pc); /* pc */ p1 = vcleq_u16(pa, pb); /* pa <= pb */ pa = vcleq_u16(pa, pc); /* pa <= pc */ pb = vcleq_u16(pb, pc); /* pb <= pc */ p1 = vandq_u16(p1, pa); /* pa <= pb && pa <= pc */ d = vmovn_u16(pb); e = vmovn_u16(p1); d = vbsl_u8(d, b, c); e = vbsl_u8(e, a, d); return e; } static void defilter_paeth3(size_t rowbytes, unsigned char *row, const unsigned char *prev_row) { unsigned char *rp = row; const unsigned char *pp = prev_row; unsigned char *rp_stop = row + rowbytes; uint8x16_t vtmp; uint8x8x2_t *vrpt; uint8x8x2_t vrp; uint8x8_t vlast = vdup_n_u8(0); uint8x8x4_t vdest; vdest.val[3] = vdup_n_u8(0); vtmp = vld1q_u8(rp); vrpt = png_ptr(uint8x8x2_t,&vtmp); vrp = *vrpt; for (; rp < rp_stop; pp += 12) { uint8x8x2_t *vppt; uint8x8x2_t vpp; uint8x8_t vtmp1, vtmp2, vtmp3; uint32x2_t *temp_pointer; vtmp = vld1q_u8(pp); vppt = png_ptr(uint8x8x2_t,&vtmp); vpp = *vppt; vdest.val[0] = paeth_arm(vdest.val[3], vpp.val[0], vlast); vdest.val[0] = vadd_u8(vdest.val[0], vrp.val[0]); vtmp1 = vext_u8(vrp.val[0], vrp.val[1], 3); vtmp2 = vext_u8(vpp.val[0], vpp.val[1], 3); vdest.val[1] = paeth_arm(vdest.val[0], vtmp2, vpp.val[0]); vdest.val[1] = vadd_u8(vdest.val[1], vtmp1); vtmp1 = vext_u8(vrp.val[0], vrp.val[1], 6); vtmp3 = vext_u8(vpp.val[0], vpp.val[1], 6); vdest.val[2] = paeth_arm(vdest.val[1], vtmp3, vtmp2); vdest.val[2] = vadd_u8(vdest.val[2], vtmp1); vtmp1 = vext_u8(vrp.val[1], vrp.val[1], 1); vtmp2 = vext_u8(vpp.val[1], vpp.val[1], 1); vtmp = vld1q_u8(rp + 12); vrpt = png_ptr(uint8x8x2_t,&vtmp); vrp = *vrpt; vdest.val[3] = paeth_arm(vdest.val[2], vtmp2, vtmp3); vdest.val[3] = vadd_u8(vdest.val[3], vtmp1); vlast = vtmp2; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[0]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[1]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[2]), 0); rp += 3; vst1_lane_u32(png_ptr(uint32_t,rp), png_ldr(uint32x2_t,&vdest.val[3]), 0); rp += 3; } } static void defilter_paeth4(size_t rowbytes, unsigned char *row, const unsigned char *prev_row) { unsigned char *rp = row; unsigned char *rp_stop = row + rowbytes; const unsigned char *pp = prev_row; uint8x8_t vlast = vdup_n_u8(0); uint8x8x4_t vdest; vdest.val[3] = vdup_n_u8(0); for (; rp < rp_stop; rp += 16, pp += 16) { uint32x2x4_t vtmp; uint8x8x4_t *vrpt, *vppt; uint8x8x4_t vrp, vpp; uint32x2x4_t *temp_pointer; uint32x2x4_t vdest_val; vtmp = vld4_u32(png_ptr(uint32_t,rp)); vrpt = png_ptr(uint8x8x4_t,&vtmp); vrp = *vrpt; vtmp = vld4_u32(png_ptrc(uint32_t,pp)); vppt = png_ptr(uint8x8x4_t,&vtmp); vpp = *vppt; vdest.val[0] = paeth_arm(vdest.val[3], vpp.val[0], vlast); vdest.val[0] = vadd_u8(vdest.val[0], vrp.val[0]); vdest.val[1] = paeth_arm(vdest.val[0], vpp.val[1], vpp.val[0]); vdest.val[1] = vadd_u8(vdest.val[1], vrp.val[1]); vdest.val[2] = paeth_arm(vdest.val[1], vpp.val[2], vpp.val[1]); vdest.val[2] = vadd_u8(vdest.val[2], vrp.val[2]); vdest.val[3] = paeth_arm(vdest.val[2], vpp.val[3], vpp.val[2]); vdest.val[3] = vadd_u8(vdest.val[3], vrp.val[3]); vlast = vpp.val[3]; vdest_val = png_ldr(uint32x2x4_t, &vdest); vst4_lane_u32(png_ptr(uint32_t,rp), vdest_val, 0); } } /* NEON optimised palette expansion functions * Derived from palette_neon_intrinsics.c * * Copyright (c) 2018-2019 Cosmin Truta * Copyright (c) 2017-2018 Arm Holdings. All rights reserved. * Written by Richard Townsend , February 2017. * * This code is derived from libpng source code. * For conditions of distribution and use, see the disclaimer * and license in this file. * * Related: https://developer.arm.com/documentation/101964/latest/Color-palette-expansion * * The functions were refactored to iterate forward. * */ /* Expands a palettized row into RGBA8. */ static uint32_t expand_palette_rgba8_neon(unsigned char *row, const unsigned char *scanline, const unsigned char *plte, uint32_t width) { const uint32_t scanline_stride = 4; const uint32_t row_stride = scanline_stride * 4; const uint32_t count = width / scanline_stride; const uint32_t *palette = (const uint32_t*)plte; if(!count) return 0; uint32_t i; uint32x4_t cur; for(i=0; i < count; i++, scanline += scanline_stride) { cur = vld1q_dup_u32 (palette + scanline[0]); cur = vld1q_lane_u32(palette + scanline[1], cur, 1); cur = vld1q_lane_u32(palette + scanline[2], cur, 2); cur = vld1q_lane_u32(palette + scanline[3], cur, 3); vst1q_u32((uint32_t*)(row + i * row_stride), cur); } return count * scanline_stride; } /* Expands a palettized row into RGB8. */ static uint32_t expand_palette_rgb8_neon(unsigned char *row, const unsigned char *scanline, const unsigned char *plte, uint32_t width) { const uint32_t scanline_stride = 8; const uint32_t row_stride = scanline_stride * 3; const uint32_t count = width / scanline_stride; if(!count) return 0; uint32_t i; uint8x8x3_t cur; for(i=0; i < count; i++, scanline += scanline_stride) { cur = vld3_dup_u8 (plte + 3 * scanline[0]); cur = vld3_lane_u8(plte + 3 * scanline[1], cur, 1); cur = vld3_lane_u8(plte + 3 * scanline[2], cur, 2); cur = vld3_lane_u8(plte + 3 * scanline[3], cur, 3); cur = vld3_lane_u8(plte + 3 * scanline[4], cur, 4); cur = vld3_lane_u8(plte + 3 * scanline[5], cur, 5); cur = vld3_lane_u8(plte + 3 * scanline[6], cur, 6); cur = vld3_lane_u8(plte + 3 * scanline[7], cur, 7); vst3_u8(row + i * row_stride, cur); } return count * scanline_stride; } #endif /* SPNG_ARM */