mpv/libaf/af.h

192 lines
5.8 KiB
C

#ifndef __aop_h__
#define __aop_h__
struct af_instance_s;
// Audio data chunk
typedef struct af_data_s
{
void* audio; // data buffer
int len; // buffer length
int rate; // sample rate
int nch; // number of channels
int format; // format
int bps; // bytes per sample
} af_data_t;
// Fraction, used to calculate buffer lengths
typedef struct frac_s
{
int n; // Numerator
int d; // Denominator
} frac_t;
// Flags used for defining the behavour of an audio filter
#define AF_FLAGS_REENTRANT 0x00000000
#define AF_FLAGS_NOT_REENTRANT 0x00000001
/* Audio filter information not specific for current instance, but for
a specific filter */
typedef struct af_info_s
{
const char *info;
const char *name;
const char *author;
const char *comment;
const int flags;
int (*open)(struct af_instance_s* vf);
} af_info_t;
// Linked list of audio filters
typedef struct af_instance_s
{
af_info_t* info;
int (*control)(struct af_instance_s* af, int cmd, void* arg);
void (*uninit)(struct af_instance_s* af);
af_data_t* (*play)(struct af_instance_s* af, af_data_t* data);
void* setup; // setup data for this specific instance and filter
af_data_t* data; // configuration for outgoing data stream
struct af_instance_s* next;
struct af_instance_s* prev;
frac_t mul; /* length multiplier: how much does this instance change
the length of the buffer. */
}af_instance_t;
// Initialization types
#define SLOW 1
#define FAST 2
#define FORCE 3
// Configuration switches
typedef struct af_cfg_s{
int force; // Initialization type
char** list; /* list of names of plugins that are added to filter
list during first initialization of stream */
}af_cfg_t;
// Current audio stream
typedef struct af_stream_s
{
// The first and last filter in the list
af_instance_t* first;
af_instance_t* last;
// Storage for input and output data formats
af_data_t input;
af_data_t output;
// Cofiguration for this stream
af_cfg_t cfg;
}af_stream_t;
/*********************************************
// Control parameters
*/
/* The control system is divided into 3 levels
mandatory calls - all filters must answer to all of these
optional calls - are optional
filter specific calls - applies only to some filters
*/
#define AF_CONTROL_MANDATORY_BASE 0
#define AF_CONTROL_OPTIONAL_BASE 100
#define AF_CONTROL_FILTER_SPECIFIC_BASE 200
// MANDATORY CALLS
/* Reinitialize filter. The optional argument contains the new
configuration in form of a af_data_t struct. If the filter does not
support the new format the struct should be changed and AF_FALSE
should be returned. If the incoming and outgoing data streams are
identical the filter can return AF_DETACH. This will remove the
filter. */
#define AF_CONTROL_REINIT 1 + AF_CONTROL_MANDATORY_BASE
// OPTIONAL CALLS
// FILTER SPECIFIC CALLS
// Set output rate in resample
#define AF_CONTROL_RESAMPLE 1 + AF_CONTROL_FILTER_SPECIFIC_BASE
// Set output format in format
#define AF_CONTROL_FORMAT 2 + AF_CONTROL_FILTER_SPECIFIC_BASE
// Set number of output channels in channels
#define AF_CONTROL_CHANNELS 3 + AF_CONTROL_FILTER_SPECIFIC_BASE
// Set delay length in delay
#define AF_CONTROL_SET_DELAY_LEN 4 + AF_CONTROL_FILTER_SPECIFIC_BASE
/*********************************************
// Return values
*/
#define AF_DETACH 2
#define AF_OK 1
#define AF_TRUE 1
#define AF_FALSE 0
#define AF_UNKNOWN -1
#define AF_ERROR -2
#define AF_NA -3
// Export functions
/* Initialize the stream "s". This function creates a new fileterlist
if nessesary according to the values set in input and output. Input
and output should contain the format of the current movie and the
formate of the preferred output respectively. The function is
reentreant i.e. if called wit an already initialized stream the
stream will be reinitialized. The return value is 0 if sucess and
-1 if failure */
int af_init(af_stream_t* s);
// Uninit and remove all filters
void af_uninit(af_stream_t* s);
// Filter data chunk through the filters in the list
af_data_t* af_play(af_stream_t* s, af_data_t* data);
/* Calculate how long the output from the filters will be given the
input length "len". The calculated length is >= the actual
length */
int af_outputlen(af_stream_t* s, int len);
/* Calculate how long the input to the filters should be to produce a
certain output length, i.e. the return value of this function is
the input length required to produce the output length "len". The
calculated length is <= the actual length */
int af_inputlen(af_stream_t* s, int len);
/* Calculate how long the input IN to the filters should be to produce
a certain output length OUT but with the following three constraints:
1. IN <= max_insize, where max_insize is the maximum possible input
block length
2. OUT <= max_outsize, where max_outsize is the maximum possible
output block length
3. If possible OUT >= len.
Return -1 in case of error */
int af_calc_insize_constrained(af_stream_t* s, int len,
int max_outsize,int max_insize);
// Helper functions and macros used inside the audio filters
/* Helper function called by the macro with the same name only to be
called from inside filters */
int af_resize_local_buffer(af_instance_t* af, af_data_t* data);
/* Helper function used to calculate the exact buffer length needed
when buffers are resized. The returned length is >= than what is
needed */
int af_lencalc(frac_t mul, af_data_t* data);
/* Memory reallocation macro: if a local buffer is used (i.e. if the
filter doesn't operate on the incoming buffer this macro must be
called to ensure the buffer is big enough. */
#define RESIZE_LOCAL_BUFFER(a,d)\
((a->data->len < af_lencalc(a->mul,d))?af_resize_local_buffer(a,d):AF_OK)
#ifndef min
#define min(a,b)(((a)>(b))?(b):(a))
#endif
#ifndef max
#define max(a,b)(((a)>(b))?(a):(b))
#endif
#endif