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v1.5.0-rc1
libwebp/examples/webpinfo.c
James Zern da0d9c7d4e examples: exit w/failure w/no args 
cwebp, gif2webp, img2webp, vwebp and webpinfo are modified in this
change to align with the other examples. When given no arguments, the
examples print their help output and exit with failure.

Bug: webp:42340557, webp:381372617
Change-Id: Ifed4eb79e98233f7aa780c42e489636d0cf4a035
2024-12-06 14:53:06 -08:00

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// Copyright 2017 Google Inc. All Rights Reserved.
//
// Use of this source code is governed by a BSD-style license
// that can be found in the COPYING file in the root of the source
// tree. An additional intellectual property rights grant can be found
// in the file PATENTS. All contributing project authors may
// be found in the AUTHORS file in the root of the source tree.
// -----------------------------------------------------------------------------
//
// Command-line tool to print out the chunk level structure of WebP files
// along with basic integrity checks.
//
// Author: Hui Su (huisu@google.com)
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#ifdef HAVE_CONFIG_H
#include "webp/config.h"
#endif
#include "../imageio/imageio_util.h"
#include "./unicode.h"
#include "webp/decode.h"
#include "webp/format_constants.h"
#include "webp/mux_types.h"
#if defined(_MSC_VER) && _MSC_VER < 1900
#define snprintf _snprintf
#endif
#define LOG_ERROR(MESSAGE) \
do { \
if (webp_info->show_diagnosis_) { \
fprintf(stderr, "Error: %s\n", MESSAGE); \
} \
} while (0)
#define LOG_WARN(MESSAGE) \
do { \
if (webp_info->show_diagnosis_) { \
fprintf(stderr, "Warning: %s\n", MESSAGE); \
} \
++webp_info->num_warnings_; \
} while (0)
static const char* const kFormats[3] = {
"Unknown",
"Lossy",
"Lossless"
};
static const char* const kLosslessTransforms[4] = {
"Predictor",
"Cross Color",
"Subtract Green",
"Color Indexing"
};
static const char* const kAlphaFilterMethods[4] = {
"None",
"Horizontal",
"Vertical",
"Gradient"
};
typedef enum {
WEBP_INFO_OK = 0,
WEBP_INFO_TRUNCATED_DATA,
WEBP_INFO_PARSE_ERROR,
WEBP_INFO_INVALID_PARAM,
WEBP_INFO_BITSTREAM_ERROR,
WEBP_INFO_MISSING_DATA,
WEBP_INFO_INVALID_COMMAND
} WebPInfoStatus;
typedef enum ChunkID {
CHUNK_VP8,
CHUNK_VP8L,
CHUNK_VP8X,
CHUNK_ALPHA,
CHUNK_ANIM,
CHUNK_ANMF,
CHUNK_ICCP,
CHUNK_EXIF,
CHUNK_XMP,
CHUNK_UNKNOWN,
CHUNK_TYPES = CHUNK_UNKNOWN
} ChunkID;
typedef struct {
size_t start_;
size_t end_;
const uint8_t* buf_;
} MemBuffer;
typedef struct {
size_t offset_;
size_t size_;
const uint8_t* payload_;
ChunkID id_;
} ChunkData;
typedef struct WebPInfo {
int canvas_width_;
int canvas_height_;
int loop_count_;
int num_frames_;
int chunk_counts_[CHUNK_TYPES];
int anmf_subchunk_counts_[3]; // 0 VP8; 1 VP8L; 2 ALPH.
uint32_t bgcolor_;
int feature_flags_;
int has_alpha_;
// Used for parsing ANMF chunks.
int frame_width_, frame_height_;
size_t anim_frame_data_size_;
int is_processing_anim_frame_, seen_alpha_subchunk_, seen_image_subchunk_;
// Print output control.
int quiet_, show_diagnosis_, show_summary_;
int num_warnings_;
int parse_bitstream_;
} WebPInfo;
static void WebPInfoInit(WebPInfo* const webp_info) {
memset(webp_info, 0, sizeof(*webp_info));
}
static const uint32_t kWebPChunkTags[CHUNK_TYPES] = {
MKFOURCC('V', 'P', '8', ' '),
MKFOURCC('V', 'P', '8', 'L'),
MKFOURCC('V', 'P', '8', 'X'),
MKFOURCC('A', 'L', 'P', 'H'),
MKFOURCC('A', 'N', 'I', 'M'),
MKFOURCC('A', 'N', 'M', 'F'),
MKFOURCC('I', 'C', 'C', 'P'),
MKFOURCC('E', 'X', 'I', 'F'),
MKFOURCC('X', 'M', 'P', ' '),
};
// -----------------------------------------------------------------------------
// Data reading.
static int GetLE16(const uint8_t* const data) {
return (data[0] << 0) | (data[1] << 8);
}
static int GetLE24(const uint8_t* const data) {
return GetLE16(data) | (data[2] << 16);
}
static uint32_t GetLE32(const uint8_t* const data) {
return GetLE16(data) | ((uint32_t)GetLE16(data + 2) << 16);
}
static int ReadLE16(const uint8_t** data) {
const int val = GetLE16(*data);
*data += 2;
return val;
}
static int ReadLE24(const uint8_t** data) {
const int val = GetLE24(*data);
*data += 3;
return val;
}
static uint32_t ReadLE32(const uint8_t** data) {
const uint32_t val = GetLE32(*data);
*data += 4;
return val;
}
static int ReadFileToWebPData(const char* const filename,
WebPData* const webp_data) {
const uint8_t* data;
size_t size;
if (!ImgIoUtilReadFile(filename, &data, &size)) return 0;
webp_data->bytes = data;
webp_data->size = size;
return 1;
}
// -----------------------------------------------------------------------------
// MemBuffer object.
static void InitMemBuffer(MemBuffer* const mem, const WebPData* webp_data) {
mem->buf_ = webp_data->bytes;
mem->start_ = 0;
mem->end_ = webp_data->size;
}
static size_t MemDataSize(const MemBuffer* const mem) {
return (mem->end_ - mem->start_);
}
static const uint8_t* GetBuffer(MemBuffer* const mem) {
return mem->buf_ + mem->start_;
}
static void Skip(MemBuffer* const mem, size_t size) {
mem->start_ += size;
}
static uint32_t ReadMemBufLE32(MemBuffer* const mem) {
const uint8_t* const data = mem->buf_ + mem->start_;
const uint32_t val = GetLE32(data);
assert(MemDataSize(mem) >= 4);
Skip(mem, 4);
return val;
}
// -----------------------------------------------------------------------------
// Lossy bitstream analysis.
static int GetBits(const uint8_t* const data, size_t data_size, size_t nb,
int* val, uint64_t* const bit_pos) {
*val = 0;
while (nb-- > 0) {
const uint64_t p = (*bit_pos)++;
if ((p >> 3) >= data_size) {
return 0;
} else {
const int bit = !!(data[p >> 3] & (128 >> ((p & 7))));
*val = (*val << 1) | bit;
}
}
return 1;
}
static int GetSignedBits(const uint8_t* const data, size_t data_size, size_t nb,
int* val, uint64_t* const bit_pos) {
int sign;
if (!GetBits(data, data_size, nb, val, bit_pos)) return 0;
if (!GetBits(data, data_size, 1, &sign, bit_pos)) return 0;
if (sign) *val = -(*val);
return 1;
}
#define GET_BITS(v, n) \
do { \
if (!GetBits(data, data_size, n, &(v), bit_pos)) { \
LOG_ERROR("Truncated lossy bitstream."); \
return WEBP_INFO_TRUNCATED_DATA; \
} \
} while (0)
#define GET_SIGNED_BITS(v, n) \
do { \
if (!GetSignedBits(data, data_size, n, &(v), bit_pos)) { \
LOG_ERROR("Truncated lossy bitstream."); \
return WEBP_INFO_TRUNCATED_DATA; \
} \
} while (0)
static WebPInfoStatus ParseLossySegmentHeader(const WebPInfo* const webp_info,
const uint8_t* const data,
size_t data_size,
uint64_t* const bit_pos) {
int use_segment;
GET_BITS(use_segment, 1);
printf(" Use segment: %d\n", use_segment);
if (use_segment) {
int update_map, update_data;
GET_BITS(update_map, 1);
GET_BITS(update_data, 1);
printf(" Update map: %d\n"
" Update data: %d\n",
update_map, update_data);
if (update_data) {
int i, a_delta;
int quantizer[4] = {0, 0, 0, 0};
int filter_strength[4] = {0, 0, 0, 0};
GET_BITS(a_delta, 1);
printf(" Absolute delta: %d\n", a_delta);
for (i = 0; i < 4; ++i) {
int bit;
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(quantizer[i], 7);
}
for (i = 0; i < 4; ++i) {
int bit;
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(filter_strength[i], 6);
}
printf(" Quantizer: %d %d %d %d\n", quantizer[0], quantizer[1],
quantizer[2], quantizer[3]);
printf(" Filter strength: %d %d %d %d\n", filter_strength[0],
filter_strength[1], filter_strength[2], filter_strength[3]);
}
if (update_map) {
int i;
int prob_segment[3] = {255, 255, 255};
for (i = 0; i < 3; ++i) {
int bit;
GET_BITS(bit, 1);
if (bit) GET_BITS(prob_segment[i], 8);
}
printf(" Prob segment: %d %d %d\n",
prob_segment[0], prob_segment[1], prob_segment[2]);
}
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ParseLossyFilterHeader(const WebPInfo* const webp_info,
const uint8_t* const data,
size_t data_size,
uint64_t* const bit_pos) {
int simple_filter, level, sharpness, use_lf_delta;
GET_BITS(simple_filter, 1);
GET_BITS(level, 6);
GET_BITS(sharpness, 3);
GET_BITS(use_lf_delta, 1);
printf(" Simple filter: %d\n", simple_filter);
printf(" Level: %d\n", level);
printf(" Sharpness: %d\n", sharpness);
printf(" Use lf delta: %d\n", use_lf_delta);
if (use_lf_delta) {
int update;
GET_BITS(update, 1);
printf(" Update lf delta: %d\n", update);
if (update) {
int i;
for (i = 0; i < 4 + 4; ++i) {
int temp;
GET_BITS(temp, 1);
if (temp) GET_BITS(temp, 7);
}
}
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ParseLossyHeader(const ChunkData* const chunk_data,
const WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_;
size_t data_size = chunk_data->size_ - CHUNK_HEADER_SIZE;
const uint32_t bits = (uint32_t)data[0] | (data[1] << 8) | (data[2] << 16);
const int key_frame = !(bits & 1);
const int profile = (bits >> 1) & 7;
const int display = (bits >> 4) & 1;
const uint32_t partition0_length = (bits >> 5);
WebPInfoStatus status = WEBP_INFO_OK;
uint64_t bit_position = 0;
uint64_t* const bit_pos = &bit_position;
int colorspace, clamp_type;
printf(" Parsing lossy bitstream...\n");
// Calling WebPGetFeatures() in ProcessImageChunk() should ensure this.
assert(chunk_data->size_ >= CHUNK_HEADER_SIZE + 10);
if (profile > 3) {
LOG_ERROR("Unknown profile.");
return WEBP_INFO_BITSTREAM_ERROR;
}
if (!display) {
LOG_ERROR("Frame is not displayable.");
return WEBP_INFO_BITSTREAM_ERROR;
}
data += 3;
data_size -= 3;
printf(
" Key frame: %s\n"
" Profile: %d\n"
" Display: Yes\n"
" Part. 0 length: %d\n",
key_frame ? "Yes" : "No", profile, partition0_length);
if (key_frame) {
if (!(data[0] == 0x9d && data[1] == 0x01 && data[2] == 0x2a)) {
LOG_ERROR("Invalid lossy bitstream signature.");
return WEBP_INFO_BITSTREAM_ERROR;
}
printf(" Width: %d\n"
" X scale: %d\n"
" Height: %d\n"
" Y scale: %d\n",
((data[4] << 8) | data[3]) & 0x3fff, data[4] >> 6,
((data[6] << 8) | data[5]) & 0x3fff, data[6] >> 6);
data += 7;
data_size -= 7;
} else {
LOG_ERROR("Non-keyframe detected in lossy bitstream.");
return WEBP_INFO_BITSTREAM_ERROR;
}
if (partition0_length >= data_size) {
LOG_ERROR("Bad partition length.");
return WEBP_INFO_BITSTREAM_ERROR;
}
GET_BITS(colorspace, 1);
GET_BITS(clamp_type, 1);
printf(" Color space: %d\n", colorspace);
printf(" Clamp type: %d\n", clamp_type);
status = ParseLossySegmentHeader(webp_info, data, data_size, bit_pos);
if (status != WEBP_INFO_OK) return status;
status = ParseLossyFilterHeader(webp_info, data, data_size, bit_pos);
if (status != WEBP_INFO_OK) return status;
{ // Partition number and size.
const uint8_t* part_size = data + partition0_length;
int num_parts, i;
size_t part_data_size;
GET_BITS(num_parts, 2);
num_parts = 1 << num_parts;
if ((int)(data_size - partition0_length) < (num_parts - 1) * 3) {
LOG_ERROR("Truncated lossy bitstream.");
return WEBP_INFO_TRUNCATED_DATA;
}
part_data_size = data_size - partition0_length - (num_parts - 1) * 3;
printf(" Total partitions: %d\n", num_parts);
for (i = 1; i < num_parts; ++i) {
const size_t psize =
part_size[0] | (part_size[1] << 8) | (part_size[2] << 16);
if (psize > part_data_size) {
LOG_ERROR("Truncated partition.");
return WEBP_INFO_TRUNCATED_DATA;
}
printf(" Part. %d length: %d\n", i, (int)psize);
part_data_size -= psize;
part_size += 3;
}
}
// Quantizer.
{
int base_q, bit;
int dq_y1_dc = 0, dq_y2_dc = 0, dq_y2_ac = 0, dq_uv_dc = 0, dq_uv_ac = 0;
GET_BITS(base_q, 7);
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(dq_y1_dc, 4);
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(dq_y2_dc, 4);
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(dq_y2_ac, 4);
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(dq_uv_dc, 4);
GET_BITS(bit, 1);
if (bit) GET_SIGNED_BITS(dq_uv_ac, 4);
printf(" Base Q: %d\n", base_q);
printf(" DQ Y1 DC: %d\n", dq_y1_dc);
printf(" DQ Y2 DC: %d\n", dq_y2_dc);
printf(" DQ Y2 AC: %d\n", dq_y2_ac);
printf(" DQ UV DC: %d\n", dq_uv_dc);
printf(" DQ UV AC: %d\n", dq_uv_ac);
}
if ((*bit_pos >> 3) >= partition0_length) {
LOG_ERROR("Truncated lossy bitstream.");
return WEBP_INFO_TRUNCATED_DATA;
}
return WEBP_INFO_OK;
}
// -----------------------------------------------------------------------------
// Lossless bitstream analysis.
static int LLGetBits(const uint8_t* const data, size_t data_size, size_t nb,
int* val, uint64_t* const bit_pos) {
uint32_t i = 0;
*val = 0;
while (i < nb) {
const uint64_t p = (*bit_pos)++;
if ((p >> 3) >= data_size) {
return 0;
} else {
const int bit = !!(data[p >> 3] & (1 << ((p & 7))));
*val = *val | (bit << i);
++i;
}
}
return 1;
}
#define LL_GET_BITS(v, n) \
do { \
if (!LLGetBits(data, data_size, n, &(v), bit_pos)) { \
LOG_ERROR("Truncated lossless bitstream."); \
return WEBP_INFO_TRUNCATED_DATA; \
} \
} while (0)
static WebPInfoStatus ParseLosslessTransform(WebPInfo* const webp_info,
const uint8_t* const data,
size_t data_size,
uint64_t* const bit_pos) {
int use_transform, block_size, n_colors;
LL_GET_BITS(use_transform, 1);
printf(" Use transform: %s\n", use_transform ? "Yes" : "No");
if (use_transform) {
int type;
LL_GET_BITS(type, 2);
printf(" 1st transform: %s (%d)\n", kLosslessTransforms[type], type);
switch (type) {
case PREDICTOR_TRANSFORM:
case CROSS_COLOR_TRANSFORM:
LL_GET_BITS(block_size, 3);
block_size = 1 << (block_size + 2);
printf(" Tran. block size: %d\n", block_size);
break;
case COLOR_INDEXING_TRANSFORM:
LL_GET_BITS(n_colors, 8);
n_colors += 1;
printf(" No. of colors: %d\n", n_colors);
break;
default: break;
}
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ParseLosslessHeader(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_;
size_t data_size = chunk_data->size_ - CHUNK_HEADER_SIZE;
uint64_t bit_position = 0;
uint64_t* const bit_pos = &bit_position;
WebPInfoStatus status;
printf(" Parsing lossless bitstream...\n");
if (data_size < VP8L_FRAME_HEADER_SIZE) {
LOG_ERROR("Truncated lossless bitstream.");
return WEBP_INFO_TRUNCATED_DATA;
}
if (data[0] != VP8L_MAGIC_BYTE) {
LOG_ERROR("Invalid lossless bitstream signature.");
return WEBP_INFO_BITSTREAM_ERROR;
}
data += 1;
data_size -= 1;
{
int width, height, has_alpha, version;
LL_GET_BITS(width, 14);
LL_GET_BITS(height, 14);
LL_GET_BITS(has_alpha, 1);
LL_GET_BITS(version, 3);
width += 1;
height += 1;
printf(" Width: %d\n", width);
printf(" Height: %d\n", height);
printf(" Alpha: %d\n", has_alpha);
printf(" Version: %d\n", version);
}
status = ParseLosslessTransform(webp_info, data, data_size, bit_pos);
if (status != WEBP_INFO_OK) return status;
return WEBP_INFO_OK;
}
static WebPInfoStatus ParseAlphaHeader(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_;
size_t data_size = chunk_data->size_ - CHUNK_HEADER_SIZE;
if (data_size <= ALPHA_HEADER_LEN) {
LOG_ERROR("Truncated ALPH chunk.");
return WEBP_INFO_TRUNCATED_DATA;
}
printf(" Parsing ALPH chunk...\n");
{
const int compression_method = (data[0] >> 0) & 0x03;
const int filter = (data[0] >> 2) & 0x03;
const int pre_processing = (data[0] >> 4) & 0x03;
const int reserved_bits = (data[0] >> 6) & 0x03;
printf(" Compression: %d\n", compression_method);
printf(" Filter: %s (%d)\n",
kAlphaFilterMethods[filter], filter);
printf(" Pre-processing: %d\n", pre_processing);
if (compression_method > ALPHA_LOSSLESS_COMPRESSION) {
LOG_ERROR("Invalid Alpha compression method.");
return WEBP_INFO_BITSTREAM_ERROR;
}
if (pre_processing > ALPHA_PREPROCESSED_LEVELS) {
LOG_ERROR("Invalid Alpha pre-processing method.");
return WEBP_INFO_BITSTREAM_ERROR;
}
if (reserved_bits != 0) {
LOG_WARN("Reserved bits in ALPH chunk header are not all 0.");
}
data += ALPHA_HEADER_LEN;
data_size -= ALPHA_HEADER_LEN;
if (compression_method == ALPHA_LOSSLESS_COMPRESSION) {
uint64_t bit_pos = 0;
WebPInfoStatus status =
ParseLosslessTransform(webp_info, data, data_size, &bit_pos);
if (status != WEBP_INFO_OK) return status;
}
}
return WEBP_INFO_OK;
}
// -----------------------------------------------------------------------------
// Chunk parsing.
static WebPInfoStatus ParseRIFFHeader(WebPInfo* const webp_info,
MemBuffer* const mem) {
const size_t min_size = RIFF_HEADER_SIZE + CHUNK_HEADER_SIZE;
size_t riff_size;
if (MemDataSize(mem) < min_size) {
LOG_ERROR("Truncated data detected when parsing RIFF header.");
return WEBP_INFO_TRUNCATED_DATA;
}
if (memcmp(GetBuffer(mem), "RIFF", CHUNK_SIZE_BYTES) ||
memcmp(GetBuffer(mem) + CHUNK_HEADER_SIZE, "WEBP", CHUNK_SIZE_BYTES)) {
LOG_ERROR("Corrupted RIFF header.");
return WEBP_INFO_PARSE_ERROR;
}
riff_size = GetLE32(GetBuffer(mem) + TAG_SIZE);
if (riff_size < CHUNK_HEADER_SIZE) {
LOG_ERROR("RIFF size is too small.");
return WEBP_INFO_PARSE_ERROR;
}
if (riff_size > MAX_CHUNK_PAYLOAD) {
LOG_ERROR("RIFF size is over limit.");
return WEBP_INFO_PARSE_ERROR;
}
riff_size += CHUNK_HEADER_SIZE;
if (!webp_info->quiet_) {
printf("RIFF HEADER:\n");
printf(" File size: %6d\n", (int)riff_size);
}
if (riff_size < mem->end_) {
LOG_WARN("RIFF size is smaller than the file size.");
mem->end_ = riff_size;
} else if (riff_size > mem->end_) {
LOG_ERROR("Truncated data detected when parsing RIFF payload.");
return WEBP_INFO_TRUNCATED_DATA;
}
Skip(mem, RIFF_HEADER_SIZE);
return WEBP_INFO_OK;
}
static WebPInfoStatus ParseChunk(const WebPInfo* const webp_info,
MemBuffer* const mem,
ChunkData* const chunk_data) {
memset(chunk_data, 0, sizeof(*chunk_data));
if (MemDataSize(mem) < CHUNK_HEADER_SIZE) {
LOG_ERROR("Truncated data detected when parsing chunk header.");
return WEBP_INFO_TRUNCATED_DATA;
} else {
const size_t chunk_start_offset = mem->start_;
const uint32_t fourcc = ReadMemBufLE32(mem);
const uint32_t payload_size = ReadMemBufLE32(mem);
const uint32_t payload_size_padded = payload_size + (payload_size & 1);
const size_t chunk_size = CHUNK_HEADER_SIZE + payload_size_padded;
int i;
if (payload_size > MAX_CHUNK_PAYLOAD) {
LOG_ERROR("Size of chunk payload is over limit.");
return WEBP_INFO_INVALID_PARAM;
}
if (payload_size_padded > MemDataSize(mem)){
LOG_ERROR("Truncated data detected when parsing chunk payload.");
return WEBP_INFO_TRUNCATED_DATA;
}
for (i = 0; i < CHUNK_TYPES; ++i) {
if (kWebPChunkTags[i] == fourcc) break;
}
chunk_data->offset_ = chunk_start_offset;
chunk_data->size_ = chunk_size;
chunk_data->id_ = (ChunkID)i;
chunk_data->payload_ = GetBuffer(mem);
if (chunk_data->id_ == CHUNK_ANMF) {
if (payload_size != payload_size_padded) {
LOG_ERROR("ANMF chunk size should always be even.");
return WEBP_INFO_PARSE_ERROR;
}
// There are sub-chunks to be parsed in an ANMF chunk.
Skip(mem, ANMF_CHUNK_SIZE);
} else {
Skip(mem, payload_size_padded);
}
return WEBP_INFO_OK;
}
}
// -----------------------------------------------------------------------------
// Chunk analysis.
static WebPInfoStatus ProcessVP8XChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_;
if (webp_info->chunk_counts_[CHUNK_VP8] ||
webp_info->chunk_counts_[CHUNK_VP8L] ||
webp_info->chunk_counts_[CHUNK_VP8X]) {
LOG_ERROR("Already seen a VP8/VP8L/VP8X chunk when parsing VP8X chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (chunk_data->size_ != VP8X_CHUNK_SIZE + CHUNK_HEADER_SIZE) {
LOG_ERROR("Corrupted VP8X chunk.");
return WEBP_INFO_PARSE_ERROR;
}
++webp_info->chunk_counts_[CHUNK_VP8X];
webp_info->feature_flags_ = *data;
data += 4;
webp_info->canvas_width_ = 1 + ReadLE24(&data);
webp_info->canvas_height_ = 1 + ReadLE24(&data);
if (!webp_info->quiet_) {
printf(" ICCP: %d\n Alpha: %d\n EXIF: %d\n XMP: %d\n Animation: %d\n",
(webp_info->feature_flags_ & ICCP_FLAG) != 0,
(webp_info->feature_flags_ & ALPHA_FLAG) != 0,
(webp_info->feature_flags_ & EXIF_FLAG) != 0,
(webp_info->feature_flags_ & XMP_FLAG) != 0,
(webp_info->feature_flags_ & ANIMATION_FLAG) != 0);
printf(" Canvas size %d x %d\n",
webp_info->canvas_width_, webp_info->canvas_height_);
}
if (webp_info->canvas_width_ > MAX_CANVAS_SIZE) {
LOG_WARN("Canvas width is out of range in VP8X chunk.");
}
if (webp_info->canvas_height_ > MAX_CANVAS_SIZE) {
LOG_WARN("Canvas height is out of range in VP8X chunk.");
}
if ((uint64_t)webp_info->canvas_width_ * webp_info->canvas_height_ >
MAX_IMAGE_AREA) {
LOG_WARN("Canvas area is out of range in VP8X chunk.");
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ProcessANIMChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_;
if (!webp_info->chunk_counts_[CHUNK_VP8X]) {
LOG_ERROR("ANIM chunk detected before VP8X chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (chunk_data->size_ != ANIM_CHUNK_SIZE + CHUNK_HEADER_SIZE) {
LOG_ERROR("Corrupted ANIM chunk.");
return WEBP_INFO_PARSE_ERROR;
}
webp_info->bgcolor_ = ReadLE32(&data);
webp_info->loop_count_ = ReadLE16(&data);
++webp_info->chunk_counts_[CHUNK_ANIM];
if (!webp_info->quiet_) {
printf(" Background color:(ARGB) %02x %02x %02x %02x\n",
(webp_info->bgcolor_ >> 24) & 0xff,
(webp_info->bgcolor_ >> 16) & 0xff,
(webp_info->bgcolor_ >> 8) & 0xff,
webp_info->bgcolor_ & 0xff);
printf(" Loop count : %d\n", webp_info->loop_count_);
}
if (webp_info->loop_count_ > MAX_LOOP_COUNT) {
LOG_WARN("Loop count is out of range in ANIM chunk.");
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ProcessANMFChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_;
int offset_x, offset_y, width, height, duration, blend, dispose, temp;
if (webp_info->is_processing_anim_frame_) {
LOG_ERROR("ANMF chunk detected within another ANMF chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (!webp_info->chunk_counts_[CHUNK_ANIM]) {
LOG_ERROR("ANMF chunk detected before ANIM chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (chunk_data->size_ <= CHUNK_HEADER_SIZE + ANMF_CHUNK_SIZE) {
LOG_ERROR("Truncated data detected when parsing ANMF chunk.");
return WEBP_INFO_TRUNCATED_DATA;
}
offset_x = 2 * ReadLE24(&data);
offset_y = 2 * ReadLE24(&data);
width = 1 + ReadLE24(&data);
height = 1 + ReadLE24(&data);
duration = ReadLE24(&data);
temp = *data;
dispose = temp & 1;
blend = (temp >> 1) & 1;
++webp_info->chunk_counts_[CHUNK_ANMF];
if (!webp_info->quiet_) {
printf(" Offset_X: %d\n Offset_Y: %d\n Width: %d\n Height: %d\n"
" Duration: %d\n Dispose: %d\n Blend: %d\n",
offset_x, offset_y, width, height, duration, dispose, blend);
}
if (duration > MAX_DURATION) {
LOG_ERROR("Invalid duration parameter in ANMF chunk.");
return WEBP_INFO_INVALID_PARAM;
}
if (offset_x > MAX_POSITION_OFFSET || offset_y > MAX_POSITION_OFFSET) {
LOG_ERROR("Invalid offset parameters in ANMF chunk.");
return WEBP_INFO_INVALID_PARAM;
}
if ((uint64_t)offset_x + width > (uint64_t)webp_info->canvas_width_ ||
(uint64_t)offset_y + height > (uint64_t)webp_info->canvas_height_) {
LOG_ERROR("Frame exceeds canvas in ANMF chunk.");
return WEBP_INFO_INVALID_PARAM;
}
webp_info->is_processing_anim_frame_ = 1;
webp_info->seen_alpha_subchunk_ = 0;
webp_info->seen_image_subchunk_ = 0;
webp_info->frame_width_ = width;
webp_info->frame_height_ = height;
webp_info->anim_frame_data_size_ =
chunk_data->size_ - CHUNK_HEADER_SIZE - ANMF_CHUNK_SIZE;
return WEBP_INFO_OK;
}
static WebPInfoStatus ProcessImageChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
const uint8_t* data = chunk_data->payload_ - CHUNK_HEADER_SIZE;
WebPBitstreamFeatures features;
const VP8StatusCode vp8_status =
WebPGetFeatures(data, chunk_data->size_, &features);
if (vp8_status != VP8_STATUS_OK) {
LOG_ERROR("VP8/VP8L bitstream error.");
return WEBP_INFO_BITSTREAM_ERROR;
}
if (!webp_info->quiet_) {
assert(features.format >= 0 && features.format <= 2);
printf(" Width: %d\n Height: %d\n Alpha: %d\n Animation: %d\n"
" Format: %s (%d)\n",
features.width, features.height, features.has_alpha,
features.has_animation, kFormats[features.format], features.format);
}
if (webp_info->is_processing_anim_frame_) {
++webp_info->anmf_subchunk_counts_[chunk_data->id_ == CHUNK_VP8 ? 0 : 1];
if (chunk_data->id_ == CHUNK_VP8L && webp_info->seen_alpha_subchunk_) {
LOG_ERROR("Both VP8L and ALPH sub-chunks are present in an ANMF chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (webp_info->frame_width_ != features.width ||
webp_info->frame_height_ != features.height) {
LOG_ERROR("Frame size in VP8/VP8L sub-chunk differs from ANMF header.");
return WEBP_INFO_PARSE_ERROR;
}
if (webp_info->seen_image_subchunk_) {
LOG_ERROR("Consecutive VP8/VP8L sub-chunks in an ANMF chunk.");
return WEBP_INFO_PARSE_ERROR;
}
webp_info->seen_image_subchunk_ = 1;
} else {
if (webp_info->chunk_counts_[CHUNK_VP8] ||
webp_info->chunk_counts_[CHUNK_VP8L]) {
LOG_ERROR("Multiple VP8/VP8L chunks detected.");
return WEBP_INFO_PARSE_ERROR;
}
if (chunk_data->id_ == CHUNK_VP8L &&
webp_info->chunk_counts_[CHUNK_ALPHA]) {
LOG_WARN("Both VP8L and ALPH chunks are detected.");
}
if (webp_info->chunk_counts_[CHUNK_ANIM] ||
webp_info->chunk_counts_[CHUNK_ANMF]) {
LOG_ERROR("VP8/VP8L chunk and ANIM/ANMF chunk are both detected.");
return WEBP_INFO_PARSE_ERROR;
}
if (webp_info->chunk_counts_[CHUNK_VP8X]) {
if (webp_info->canvas_width_ != features.width ||
webp_info->canvas_height_ != features.height) {
LOG_ERROR("Image size in VP8/VP8L chunk differs from VP8X chunk.");
return WEBP_INFO_PARSE_ERROR;
}
} else {
webp_info->canvas_width_ = features.width;
webp_info->canvas_height_ = features.height;
if (webp_info->canvas_width_ < 1 || webp_info->canvas_height_ < 1 ||
webp_info->canvas_width_ > MAX_CANVAS_SIZE ||
webp_info->canvas_height_ > MAX_CANVAS_SIZE ||
(uint64_t)webp_info->canvas_width_ * webp_info->canvas_height_ >
MAX_IMAGE_AREA) {
LOG_WARN("Invalid parameters in VP8/VP8L chunk.");
}
}
++webp_info->chunk_counts_[chunk_data->id_];
}
++webp_info->num_frames_;
webp_info->has_alpha_ |= features.has_alpha;
if (webp_info->parse_bitstream_) {
const int is_lossy = (chunk_data->id_ == CHUNK_VP8);
const WebPInfoStatus status =
is_lossy ? ParseLossyHeader(chunk_data, webp_info)
: ParseLosslessHeader(chunk_data, webp_info);
if (status != WEBP_INFO_OK) return status;
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ProcessALPHChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
if (webp_info->is_processing_anim_frame_) {
++webp_info->anmf_subchunk_counts_[2];
if (webp_info->seen_alpha_subchunk_) {
LOG_ERROR("Consecutive ALPH sub-chunks in an ANMF chunk.");
return WEBP_INFO_PARSE_ERROR;
}
webp_info->seen_alpha_subchunk_ = 1;
if (webp_info->seen_image_subchunk_) {
LOG_ERROR("ALPHA sub-chunk detected after VP8 sub-chunk "
"in an ANMF chunk.");
return WEBP_INFO_PARSE_ERROR;
}
} else {
if (webp_info->chunk_counts_[CHUNK_ANIM] ||
webp_info->chunk_counts_[CHUNK_ANMF]) {
LOG_ERROR("ALPHA chunk and ANIM/ANMF chunk are both detected.");
return WEBP_INFO_PARSE_ERROR;
}
if (!webp_info->chunk_counts_[CHUNK_VP8X]) {
LOG_ERROR("ALPHA chunk detected before VP8X chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (webp_info->chunk_counts_[CHUNK_VP8]) {
LOG_ERROR("ALPHA chunk detected after VP8 chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (webp_info->chunk_counts_[CHUNK_ALPHA]) {
LOG_ERROR("Multiple ALPHA chunks detected.");
return WEBP_INFO_PARSE_ERROR;
}
++webp_info->chunk_counts_[CHUNK_ALPHA];
}
webp_info->has_alpha_ = 1;
if (webp_info->parse_bitstream_) {
const WebPInfoStatus status = ParseAlphaHeader(chunk_data, webp_info);
if (status != WEBP_INFO_OK) return status;
}
return WEBP_INFO_OK;
}
static WebPInfoStatus ProcessICCPChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
(void)chunk_data;
if (!webp_info->chunk_counts_[CHUNK_VP8X]) {
LOG_ERROR("ICCP chunk detected before VP8X chunk.");
return WEBP_INFO_PARSE_ERROR;
}
if (webp_info->chunk_counts_[CHUNK_VP8] ||
webp_info->chunk_counts_[CHUNK_VP8L] ||
webp_info->chunk_counts_[CHUNK_ANIM]) {
LOG_ERROR("ICCP chunk detected after image data.");
return WEBP_INFO_PARSE_ERROR;
}
++webp_info->chunk_counts_[CHUNK_ICCP];
return WEBP_INFO_OK;
}
static WebPInfoStatus ProcessChunk(const ChunkData* const chunk_data,
WebPInfo* const webp_info) {
WebPInfoStatus status = WEBP_INFO_OK;
ChunkID id = chunk_data->id_;
if (chunk_data->id_ == CHUNK_UNKNOWN) {
char error_message[50];
snprintf(error_message, 50, "Unknown chunk at offset %6d, length %6d",
(int)chunk_data->offset_, (int)chunk_data->size_);
LOG_WARN(error_message);
} else {
if (!webp_info->quiet_) {
char tag[4];
uint32_t fourcc = kWebPChunkTags[chunk_data->id_];
#ifdef WORDS_BIGENDIAN
fourcc = (fourcc >> 24) | ((fourcc >> 8) & 0xff00) |
((fourcc << 8) & 0xff0000) | (fourcc << 24);
#endif
memcpy(tag, &fourcc, sizeof(tag));
printf("Chunk %c%c%c%c at offset %6d, length %6d\n",
tag[0], tag[1], tag[2], tag[3], (int)chunk_data->offset_,
(int)chunk_data->size_);
}
}
switch (id) {
case CHUNK_VP8:
case CHUNK_VP8L:
status = ProcessImageChunk(chunk_data, webp_info);
break;
case CHUNK_VP8X:
status = ProcessVP8XChunk(chunk_data, webp_info);
break;
case CHUNK_ALPHA:
status = ProcessALPHChunk(chunk_data, webp_info);
break;
case CHUNK_ANIM:
status = ProcessANIMChunk(chunk_data, webp_info);
break;
case CHUNK_ANMF:
status = ProcessANMFChunk(chunk_data, webp_info);
break;
case CHUNK_ICCP:
status = ProcessICCPChunk(chunk_data, webp_info);
break;
case CHUNK_EXIF:
case CHUNK_XMP:
++webp_info->chunk_counts_[id];
break;
case CHUNK_UNKNOWN:
default:
break;
}
if (webp_info->is_processing_anim_frame_ && id != CHUNK_ANMF) {
if (webp_info->anim_frame_data_size_ == chunk_data->size_) {
if (!webp_info->seen_image_subchunk_) {
LOG_ERROR("No VP8/VP8L chunk detected in an ANMF chunk.");
return WEBP_INFO_PARSE_ERROR;
}
webp_info->is_processing_anim_frame_ = 0;
} else if (webp_info->anim_frame_data_size_ > chunk_data->size_) {
webp_info->anim_frame_data_size_ -= chunk_data->size_;
} else {
LOG_ERROR("Truncated data detected when parsing ANMF chunk.");
return WEBP_INFO_TRUNCATED_DATA;
}
}
return status;
}
static WebPInfoStatus Validate(WebPInfo* const webp_info) {
if (webp_info->num_frames_ < 1) {
LOG_ERROR("No image/frame detected.");
return WEBP_INFO_MISSING_DATA;
}
if (webp_info->chunk_counts_[CHUNK_VP8X]) {
const int iccp = !!(webp_info->feature_flags_ & ICCP_FLAG);
const int exif = !!(webp_info->feature_flags_ & EXIF_FLAG);
const int xmp = !!(webp_info->feature_flags_ & XMP_FLAG);
const int animation = !!(webp_info->feature_flags_ & ANIMATION_FLAG);
const int alpha = !!(webp_info->feature_flags_ & ALPHA_FLAG);
if (!alpha && webp_info->has_alpha_) {
LOG_ERROR("Unexpected alpha data detected.");
return WEBP_INFO_PARSE_ERROR;
}
if (alpha && !webp_info->has_alpha_) {
LOG_WARN("Alpha flag is set with no alpha data present.");
}
if (iccp && !webp_info->chunk_counts_[CHUNK_ICCP]) {
LOG_ERROR("Missing ICCP chunk.");
return WEBP_INFO_MISSING_DATA;
}
if (exif && !webp_info->chunk_counts_[CHUNK_EXIF]) {
LOG_ERROR("Missing EXIF chunk.");
return WEBP_INFO_MISSING_DATA;
}
if (xmp && !webp_info->chunk_counts_[CHUNK_XMP]) {
LOG_ERROR("Missing XMP chunk.");
return WEBP_INFO_MISSING_DATA;
}
if (!iccp && webp_info->chunk_counts_[CHUNK_ICCP]) {
LOG_ERROR("Unexpected ICCP chunk detected.");
return WEBP_INFO_PARSE_ERROR;
}
if (!exif && webp_info->chunk_counts_[CHUNK_EXIF]) {
LOG_ERROR("Unexpected EXIF chunk detected.");
return WEBP_INFO_PARSE_ERROR;
}
if (!xmp && webp_info->chunk_counts_[CHUNK_XMP]) {
LOG_ERROR("Unexpected XMP chunk detected.");
return WEBP_INFO_PARSE_ERROR;
}
// Incomplete animation frame.
if (webp_info->is_processing_anim_frame_) return WEBP_INFO_MISSING_DATA;
if (!animation && webp_info->num_frames_ > 1) {
LOG_ERROR("More than 1 frame detected in non-animation file.");
return WEBP_INFO_PARSE_ERROR;
}
if (animation && (!webp_info->chunk_counts_[CHUNK_ANIM] ||
!webp_info->chunk_counts_[CHUNK_ANMF])) {
LOG_ERROR("No ANIM/ANMF chunk detected in animation file.");
return WEBP_INFO_PARSE_ERROR;
}
}
return WEBP_INFO_OK;
}
static void ShowSummary(const WebPInfo* const webp_info) {
int i;
printf("Summary:\n");
printf("Number of frames: %d\n", webp_info->num_frames_);
printf("Chunk type : VP8 VP8L VP8X ALPH ANIM ANMF(VP8 /VP8L/ALPH) ICCP "
"EXIF XMP\n");
printf("Chunk counts: ");
for (i = 0; i < CHUNK_TYPES; ++i) {
printf("%4d ", webp_info->chunk_counts_[i]);
if (i == CHUNK_ANMF) {
printf("%4d %4d %4d ",
webp_info->anmf_subchunk_counts_[0],
webp_info->anmf_subchunk_counts_[1],
webp_info->anmf_subchunk_counts_[2]);
}
}
printf("\n");
}
static WebPInfoStatus AnalyzeWebP(WebPInfo* const webp_info,
const WebPData* webp_data) {
ChunkData chunk_data;
MemBuffer mem_buffer;
WebPInfoStatus webp_info_status = WEBP_INFO_OK;
InitMemBuffer(&mem_buffer, webp_data);
webp_info_status = ParseRIFFHeader(webp_info, &mem_buffer);
if (webp_info_status != WEBP_INFO_OK) goto Error;
// Loop through all the chunks. Terminate immediately in case of error.
while (webp_info_status == WEBP_INFO_OK && MemDataSize(&mem_buffer) > 0) {
webp_info_status = ParseChunk(webp_info, &mem_buffer, &chunk_data);
if (webp_info_status != WEBP_INFO_OK) goto Error;
webp_info_status = ProcessChunk(&chunk_data, webp_info);
}
if (webp_info_status != WEBP_INFO_OK) goto Error;
if (webp_info->show_summary_) ShowSummary(webp_info);
// Final check.
webp_info_status = Validate(webp_info);
Error:
if (!webp_info->quiet_) {
if (webp_info_status == WEBP_INFO_OK) {
printf("No error detected.\n");
} else {
printf("Errors detected.\n");
}
if (webp_info->num_warnings_ > 0) {
printf("There were %d warning(s).\n", webp_info->num_warnings_);
}
}
return webp_info_status;
}
static void Help(void) {
printf("Usage: webpinfo [options] in_files\n"
"Note: there could be multiple input files;\n"
" options must come before input files.\n"
"Options:\n"
" -version ........... Print version number and exit.\n"
" -quiet ............. Do not show chunk parsing information.\n"
" -diag .............. Show parsing error diagnosis.\n"
" -summary ........... Show chunk stats summary.\n"
" -bitstream_info .... Parse bitstream header.\n");
}
// Returns EXIT_SUCCESS on success, EXIT_FAILURE on failure.
int main(int argc, const char* argv[]) {
int c, quiet = 0, show_diag = 0, show_summary = 0;
int parse_bitstream = 0;
WebPInfoStatus webp_info_status = WEBP_INFO_OK;
WebPInfo webp_info;
INIT_WARGV(argc, argv);
if (argc == 1) {
Help();
FREE_WARGV_AND_RETURN(EXIT_FAILURE);
}
// Parse command-line input.
for (c = 1; c < argc; ++c) {
if (!strcmp(argv[c], "-h") || !strcmp(argv[c], "-help") ||
!strcmp(argv[c], "-H") || !strcmp(argv[c], "-longhelp")) {
Help();
FREE_WARGV_AND_RETURN(EXIT_SUCCESS);
} else if (!strcmp(argv[c], "-quiet")) {
quiet = 1;
} else if (!strcmp(argv[c], "-diag")) {
show_diag = 1;
} else if (!strcmp(argv[c], "-summary")) {
show_summary = 1;
} else if (!strcmp(argv[c], "-bitstream_info")) {
parse_bitstream = 1;
} else if (!strcmp(argv[c], "-version")) {
const int version = WebPGetDecoderVersion();
printf("WebP Decoder version: %d.%d.%d\n",
(version >> 16) & 0xff, (version >> 8) & 0xff, version & 0xff);
FREE_WARGV_AND_RETURN(EXIT_SUCCESS);
} else { // Assume the remaining are all input files.
break;
}
}
if (c == argc) {
Help();
FREE_WARGV_AND_RETURN(EXIT_FAILURE);
}
// Process input files one by one.
for (; c < argc; ++c) {
WebPData webp_data;
const W_CHAR* in_file = NULL;
WebPInfoInit(&webp_info);
webp_info.quiet_ = quiet;
webp_info.show_diagnosis_ = show_diag;
webp_info.show_summary_ = show_summary;
webp_info.parse_bitstream_ = parse_bitstream;
in_file = GET_WARGV(argv, c);
if (in_file == NULL ||
!ReadFileToWebPData((const char*)in_file, &webp_data)) {
webp_info_status = WEBP_INFO_INVALID_COMMAND;
WFPRINTF(stderr, "Failed to open input file %s.\n", in_file);
continue;
}
if (!webp_info.quiet_) WPRINTF("File: %s\n", in_file);
webp_info_status = AnalyzeWebP(&webp_info, &webp_data);
WebPDataClear(&webp_data);
}
FREE_WARGV_AND_RETURN((webp_info_status == WEBP_INFO_OK) ? EXIT_SUCCESS
: EXIT_FAILURE);
}
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