This section describes the API for the encoder and decoder that are included in the WebP library. This API description pertains to version 1.5.0.
Headers and Libraries
When you install libwebp
, a directory named webp/
will be installed at the typical location for your platform. For example, on
Unix platforms, the following header files would be copied to
/usr/local/include/webp/
.
decode.h
encode.h
types.h
The libraries are located in the usual library directories. The static and
dynamic libraries are in /usr/local/lib/
on Unix platforms.
Simple Decoding API
To get started using the decoding API, you must ensure that you have the library and header files installed as described above.
Include the decoding API header in your C/C++ code as follows:
#include "webp/decode.h"
int WebPGetInfo(const uint8_t* data, size_t data_size, int* width, int* height);
This function will validate the WebP image header and retrieve the image width
and height. Pointers *width
and *height
can be passed NULL
if deemed
irrelevant.
Input Attributes
- data
- Pointer to WebP image data
- data_size
- This is the size of the memory block pointed to by
data
containing the image data.
Returns
- false
- Error code returned in the case of (a) formatting error(s).
- true
- On success.
*width
and*height
are only valid on successful return. - width
- Integer value. The range is limited from 1 to 16383.
- height
- Integer value. The range is limited from 1 to 16383.
struct WebPBitstreamFeatures {
int width; // Width in pixels.
int height; // Height in pixels.
int has_alpha; // True if the bitstream contains an alpha channel.
int has_animation; // True if the bitstream is an animation.
int format; // 0 = undefined (/mixed), 1 = lossy, 2 = lossless
}
VP8StatusCode WebPGetFeatures(const uint8_t* data,
size_t data_size,
WebPBitstreamFeatures* features);
This function will retrieve features from the bitstream. The *features
structure is filled with information gathered from the bitstream:
Input Attributes
- data
- Pointer to WebP image data
- data_size
- This is the size of the memory block pointed to by
data
containing the image data.
Returns
VP8_STATUS_OK
- When the features are successfully retrieved.
VP8_STATUS_NOT_ENOUGH_DATA
- When more data is needed to retrieve the features from headers.
Additional VP8StatusCode
error values in other cases.
- features
- Pointer to WebPBitstreamFeatures structure.
uint8_t* WebPDecodeRGBA(const uint8_t* data, size_t data_size, int* width, int* height);
uint8_t* WebPDecodeARGB(const uint8_t* data, size_t data_size, int* width, int* height);
uint8_t* WebPDecodeBGRA(const uint8_t* data, size_t data_size, int* width, int* height);
uint8_t* WebPDecodeRGB(const uint8_t* data, size_t data_size, int* width, int* height);
uint8_t* WebPDecodeBGR(const uint8_t* data, size_t data_size, int* width, int* height);
These functions decode a WebP image pointed to by data
.
WebPDecodeRGBA
returns RGBA image samples in[r0, g0, b0, a0, r1, g1, b1, a1, ...]
order.WebPDecodeARGB
returns ARGB image samples in[a0, r0, g0, b0, a1, r1, g1, b1, ...]
order.WebPDecodeBGRA
returns BGRA image samples in[b0, g0, r0, a0, b1, g1, r1, a1, ...]
order.WebPDecodeRGB
returns RGB image samples in[r0, g0, b0, r1, g1, b1, ...]
order.WebPDecodeBGR
returns BGR image samples in[b0, g0, r0, b1, g1, r1, ...]
order.
The code that calls any of these functions must delete the data buffer
(uint8_t*)
returned by these functions with WebPFree()
.
Input Attributes
- data
- Pointer to WebP image data
- data_size
- This is the size of the memory block pointed to by
data
containing the image data - width
- Integer value. The range is limited currently from 1 to 16383.
- height
- Integer value. The range is limited currently from 1 to 16383.
Returns
- uint8_t*
- Pointer to decoded WebP image samples in linear RGBA/ARGB/BGRA/RGB/BGR order respectively.
uint8_t* WebPDecodeRGBAInto(const uint8_t* data, size_t data_size,
uint8_t* output_buffer, int output_buffer_size, int output_stride);
uint8_t* WebPDecodeARGBInto(const uint8_t* data, size_t data_size,
uint8_t* output_buffer, int output_buffer_size, int output_stride);
uint8_t* WebPDecodeBGRAInto(const uint8_t* data, size_t data_size,
uint8_t* output_buffer, int output_buffer_size, int output_stride);
uint8_t* WebPDecodeRGBInto(const uint8_t* data, size_t data_size,
uint8_t* output_buffer, int output_buffer_size, int output_stride);
uint8_t* WebPDecodeBGRInto(const uint8_t* data, size_t data_size,
uint8_t* output_buffer, int output_buffer_size, int output_stride);
These functions are variants of the above ones and decode the image directly
into a pre-allocated buffer output_buffer
. The maximum storage available in
this buffer is indicated by output_buffer_size
. If this storage is not
sufficient (or an error occurred), NULL
is returned. Otherwise,
output_buffer
is returned, for convenience.
The parameter output_stride
specifies the distance (in bytes) between
scanlines. Hence, output_buffer_size
is expected to be at least
output_stride * picture - height
.
Input Attributes
- data
- Pointer to WebP image data
- data_size
- This is the size of the memory block pointed to by
data
containing the image data - output_buffer_size
- Integer value. Size of allocated buffer
- output_stride
- Integer value. Specifies the distance between scanlines.
Returns
- output_buffer
- Pointer to decoded WebP image.
- uint8_t*
output_buffer
if function succeeds;NULL
otherwise.
Advanced Decoding API
WebP decoding supports an advanced API to provide ability to have on-the-fly cropping and rescaling, something of great usefulness on memory-constrained environments like mobile phones. Basically, the memory usage will scale with the output's size, not the input's when one only needs a quick preview or a zoomed in portion of an otherwise too-large picture. Some CPU can be saved too, incidentally.
WebP decoding comes in two variants viz full image decoding and incremental decoding over small input buffers. Users can optionally provide an external memory buffer for decoding the image. The following code sample will go through the steps of using the advanced decoding API.
First we need to initialize a configuration object:
#include "webp/decode.h"
WebPDecoderConfig config;
CHECK(WebPInitDecoderConfig(&config));
// One can adjust some additional decoding options:
config.options.no_fancy_upsampling = 1;
config.options.use_scaling = 1;
config.options.scaled_width = scaledWidth();
config.options.scaled_height = scaledHeight();
// etc.
The decode options are gathered within the WebPDecoderConfig
structure:
struct WebPDecoderOptions {
int bypass_filtering; // if true, skip the in-loop filtering
int no_fancy_upsampling; // if true, use faster pointwise upsampler
int use_cropping; // if true, cropping is applied first
int crop_left, crop_top; // top-left position for cropping.
// Will be snapped to even values.
int crop_width, crop_height; // dimension of the cropping area
int use_scaling; // if true, scaling is applied afterward
int scaled_width, scaled_height; // final resolution
int use_threads; // if true, use multi-threaded decoding
int dithering_strength; // dithering strength (0=Off, 100=full)
int flip; // if true, flip output vertically
int alpha_dithering_strength; // alpha dithering strength in [0..100]
};
Optionally the bitstream features can be read into config.input
,
in case we need to know them in advance. For instance it can handy to know
whether the picture has some transparency at all. Note that this will
also parse the bitstream's header, and is therefore a good way of knowing
if the bitstream looks like a valid WebP one.
CHECK(WebPGetFeatures(data, data_size, &config.input) == VP8_STATUS_OK);
Then we need to setup the decoding memory buffer in case we want to supply it directly instead of relying on the decoder for its allocation. We only need to supply the pointer to the memory as well as the total size of the buffer and the line stride (distance in bytes between scanlines).
// Specify the desired output colorspace:
config.output.colorspace = MODE_BGRA;
// Have config.output point to an external buffer:
config.output.u.RGBA.rgba = (uint8_t*)memory_buffer;
config.output.u.RGBA.stride = scanline_stride;
config.output.u.RGBA.size = total_size_of_the_memory_buffer;
config.output.is_external_memory = 1;
The image is ready to be decoded. There are two possible variants for decoding the image. We can decode the image in one go using:
CHECK(WebPDecode(data, data_size, &config) == VP8_STATUS_OK);
Alternately, we can use the incremental method to progressively decode the image as fresh bytes become available:
WebPIDecoder* idec = WebPINewDecoder(&config.output);
CHECK(idec != NULL);
while (additional_data_is_available) {
// ... (get additional data in some new_data[] buffer)
VP8StatusCode status = WebPIAppend(idec, new_data, new_data_size);
if (status != VP8_STATUS_OK && status != VP8_STATUS_SUSPENDED) {
break;
}
// The above call decodes the current available buffer.
// Part of the image can now be refreshed by calling
// WebPIDecGetRGB()/WebPIDecGetYUVA() etc.
}
WebPIDelete(idec); // the object doesn't own the image memory, so it can
// now be deleted. config.output memory is preserved.
The decoded image is now in config.output (or, rather, in config.output.u.RGBA in this case, since the requested output colorspace was MODE_BGRA). Image can be saved, displayed or otherwise processed. Afterward, we only need to reclaim the memory allocated in config's object. It's safe to call this function even if the memory is external and wasn't allocated by WebPDecode():
WebPFreeDecBuffer(&config.output);
Using this API the image can also be decoded to YUV and YUVA formats, using
MODE_YUV
and MODE_YUVA
respectively. This format is also called
Y'CbCr.
Simple Encoding API
Some very simple functions are supplied for encoding arrays of RGBA samples
in most common layouts. They are declared in the webp/encode.h
header as:
size_t WebPEncodeRGB(const uint8_t* rgb, int width, int height, int stride, float quality_factor, uint8_t** output);
size_t WebPEncodeBGR(const uint8_t* bgr, int width, int height, int stride, float quality_factor, uint8_t** output);
size_t WebPEncodeRGBA(const uint8_t* rgba, int width, int height, int stride, float quality_factor, uint8_t** output);
size_t WebPEncodeBGRA(const uint8_t* bgra, int width, int height, int stride, float quality_factor, uint8_t** output);
The quality factor quality_factor
ranges from 0 to 100 and
controls the loss and quality during compression. The value 0 corresponds to low
quality and small output sizes, whereas 100 is the highest quality and largest
output size.
Upon success, the compressed bytes are placed in the *output
pointer, and the size in bytes is returned (otherwise 0 is returned, in case
of failure). The caller must call WebPFree()
on the *output
pointer to reclaim memory.
The input array should be a packed array of bytes (one for each channel, as
expected by the name of the function). stride
corresponds to the
number of bytes needed to jump from one row to the next. For instance,
BGRA layout is:
There are equivalent functions for lossless encoding, with signatures:
size_t WebPEncodeLosslessRGB(const uint8_t* rgb, int width, int height, int stride, uint8_t** output);
size_t WebPEncodeLosslessBGR(const uint8_t* bgr, int width, int height, int stride, uint8_t** output);
size_t WebPEncodeLosslessRGBA(const uint8_t* rgba, int width, int height, int stride, uint8_t** output);
size_t WebPEncodeLosslessBGRA(const uint8_t* bgra, int width, int height, int stride, uint8_t** output);
Note these functions, like the lossy versions, use the library's default
settings. For lossless this means 'exact' is disabled. RGB values in
transparent areas will be modified to improve compression. To avoid this, use
WebPEncode()
and set WebPConfig::exact
to 1
.
Advanced Encoding API
Under the hood, the encoder comes with numerous advanced encoding parameters.
They can be useful to better balance the trade-off between compression
efficiency and processing time.
These parameters are gathered within the WebPConfig
structure.
The most used fields of this structure are:
struct WebPConfig {
int lossless; // Lossless encoding (0=lossy(default), 1=lossless).
float quality; // between 0 and 100. For lossy, 0 gives the smallest
// size and 100 the largest. For lossless, this
// parameter is the amount of effort put into the
// compression: 0 is the fastest but gives larger
// files compared to the slowest, but best, 100.
int method; // quality/speed trade-off (0=fast, 6=slower-better)
WebPImageHint image_hint; // Hint for image type (lossless only for now).
// Parameters related to lossy compression only:
int target_size; // if non-zero, set the desired target size in bytes.
// Takes precedence over the 'compression' parameter.
float target_PSNR; // if non-zero, specifies the minimal distortion to
// try to achieve. Takes precedence over target_size.
int segments; // maximum number of segments to use, in [1..4]
int sns_strength; // Spatial Noise Shaping. 0=off, 100=maximum.
int filter_strength; // range: [0 = off .. 100 = strongest]
int filter_sharpness; // range: [0 = off .. 7 = least sharp]
int filter_type; // filtering type: 0 = simple, 1 = strong (only used
// if filter_strength > 0 or autofilter > 0)
int autofilter; // Auto adjust filter's strength [0 = off, 1 = on]
int alpha_compression; // Algorithm for encoding the alpha plane (0 = none,
// 1 = compressed with WebP lossless). Default is 1.
int alpha_filtering; // Predictive filtering method for alpha plane.
// 0: none, 1: fast, 2: best. Default if 1.
int alpha_quality; // Between 0 (smallest size) and 100 (lossless).
// Default is 100.
int pass; // number of entropy-analysis passes (in [1..10]).
int show_compressed; // if true, export the compressed picture back.
// In-loop filtering is not applied.
int preprocessing; // preprocessing filter (0=none, 1=segment-smooth)
int partitions; // log2(number of token partitions) in [0..3]
// Default is set to 0 for easier progressive decoding.
int partition_limit; // quality degradation allowed to fit the 512k limit on
// prediction modes coding (0: no degradation,
// 100: maximum possible degradation).
int use_sharp_yuv; // if needed, use sharp (and slow) RGB->YUV conversion
};
Note that most of these parameters are accessible for experimentation
using the cwebp
command line tool.
The input samples should be wrapped into a WebPPicture
structure.
This structure can store input samples in either RGBA or YUVA format, depending
on the value of the use_argb
flag.
The structure is organized as follows:
struct WebPPicture {
int use_argb; // To select between ARGB and YUVA input.
// YUV input, recommended for lossy compression.
// Used if use_argb = 0.
WebPEncCSP colorspace; // colorspace: should be YUVA420 or YUV420 for now (=Y'CbCr).
int width, height; // dimensions (less or equal to WEBP_MAX_DIMENSION)
uint8_t *y, *u, *v; // pointers to luma/chroma planes.
int y_stride, uv_stride; // luma/chroma strides.
uint8_t* a; // pointer to the alpha plane
int a_stride; // stride of the alpha plane
// Alternate ARGB input, recommended for lossless compression.
// Used if use_argb = 1.
uint32_t* argb; // Pointer to argb (32 bit) plane.
int argb_stride; // This is stride in pixels units, not bytes.
// Byte-emission hook, to store compressed bytes as they are ready.
WebPWriterFunction writer; // can be NULL
void* custom_ptr; // can be used by the writer.
// Error code for the latest error encountered during encoding
WebPEncodingError error_code;
};
This structure also has a function to emit the compressed bytes as they
are made available. See below for an example with an in-memory writer.
Other writers can directly store data to a file (see
examples/cwebp.c
for such an example).
The general flow for encoding using the advanced API looks like the following:
First, we need to set up an encoding configuration containing the compression parameters. Note that the same configuration can be used for compressing several different images afterward.
#include "webp/encode.h"
WebPConfig config;
if (!WebPConfigPreset(&config, WEBP_PRESET_PHOTO, quality_factor)) return 0; // version error
// Add additional tuning:
config.sns_strength = 90;
config.filter_sharpness = 6;
config.alpha_quality = 90;
config_error = WebPValidateConfig(&config); // will verify parameter ranges (always a good habit)
Then, the input samples need to be referenced into a WebPPicture
either
by reference or copy. Here is an example allocating the buffer for holding
the samples. But one can easily set up a "view" to an already-allocated
sample array. See the WebPPictureView()
function.
// Setup the input data, allocating a picture of width x height dimension
WebPPicture pic;
if (!WebPPictureInit(&pic)) return 0; // version error
pic.width = width;
pic.height = height;
if (!WebPPictureAlloc(&pic)) return 0; // memory error
// At this point, 'pic' has been initialized as a container, and can receive the YUVA or RGBA samples.
// Alternatively, one could use ready-made import functions like WebPPictureImportRGBA(), which will take
// care of memory allocation. In any case, past this point, one will have to call WebPPictureFree(&pic)
// to reclaim allocated memory.
To emit the compressed bytes, a hook is called every time new bytes are
available. Here's a simple example with the memory-writer declared in
webp/encode.h
. This initialization is likely to be needed for
each picture to compress:
// Set up a byte-writing method (write-to-memory, in this case):
WebPMemoryWriter writer;
WebPMemoryWriterInit(&writer);
pic.writer = WebPMemoryWrite;
pic.custom_ptr = &writer;
We are now ready to compress the input samples (and free their memory afterward):
int ok = WebPEncode(&config, &pic);
WebPPictureFree(&pic); // Always free the memory associated with the input.
if (!ok) {
printf("Encoding error: %d\n", pic.error_code);
} else {
printf("Output size: %d\n", writer.size);
}
For more advanced use of the API and structure, it is recommended to look
at the documentation available in the webp/encode.h
header.
Reading the example code examples/cwebp.c
can prove useful
for discovering less used parameters.