mpv/libaf/af.c

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C
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#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef HAVE_MALLOC_H
#include <malloc.h>
#endif
#include "af.h"
#include "../config.h"
// Static list of filters
extern af_info_t af_info_dummy;
extern af_info_t af_info_delay;
extern af_info_t af_info_channels;
extern af_info_t af_info_format;
extern af_info_t af_info_resample;
extern af_info_t af_info_volume;
extern af_info_t af_info_equalizer;
extern af_info_t af_info_gate;
extern af_info_t af_info_comp;
extern af_info_t af_info_pan;
extern af_info_t af_info_surround;
extern af_info_t af_info_sub;
extern af_info_t af_info_export;
static af_info_t* filter_list[]={
&af_info_dummy,
&af_info_delay,
&af_info_channels,
&af_info_format,
&af_info_resample,
&af_info_volume,
&af_info_equalizer,
&af_info_gate,
&af_info_comp,
&af_info_pan,
&af_info_surround,
&af_info_sub,
#ifdef HAVE_SYS_MMAN_H
&af_info_export,
#endif
NULL
};
// Message printing
af_msg_cfg_t af_msg_cfg={0,NULL,NULL};
// CPU speed
int* af_cpu_speed = NULL;
/* Find a filter in the static list of filters using it's name. This
function is used internally */
af_info_t* af_find(char*name)
{
int i=0;
while(filter_list[i]){
if(!strcmp(filter_list[i]->name,name))
return filter_list[i];
i++;
}
af_msg(AF_MSG_ERROR,"Couldn't find audio filter '%s'\n",name);
return NULL;
}
/* Find filter in the dynamic filter list using it's name This
function is used for finding already initialized filters */
af_instance_t* af_get(af_stream_t* s, char* name)
{
af_instance_t* af=s->first;
// Find the filter
while(af != NULL){
if(!strcmp(af->info->name,name))
return af;
af=af->next;
}
return NULL;
}
/*/ Function for creating a new filter of type name. The name may
contain the commandline parameters for the filter */
af_instance_t* af_create(af_stream_t* s, char* name)
{
char* cmdline = name;
// Allocate space for the new filter and reset all pointers
af_instance_t* new=malloc(sizeof(af_instance_t));
if(!new){
af_msg(AF_MSG_ERROR,"[libaf] Could not allocate memory\n");
return NULL;
}
memset(new,0,sizeof(af_instance_t));
// Check for commandline parameters
strsep(&cmdline, "=");
// Find filter from name
if(NULL == (new->info=af_find(name)))
return NULL;
/* Make sure that the filter is not already in the list if it is
non-reentrant */
if(new->info->flags & AF_FLAGS_NOT_REENTRANT){
if(af_get(s,name)){
af_msg(AF_MSG_ERROR,"[libaf] There can only be one instance of"
" the filter '%s' in each stream\n",name);
free(new);
return NULL;
}
}
af_msg(AF_MSG_VERBOSE,"[libaf] Adding filter %s \n",name);
// Initialize the new filter
if(AF_OK == new->info->open(new) &&
AF_ERROR < new->control(new,AF_CONTROL_POST_CREATE,&s->cfg)){
if(cmdline){
if(AF_ERROR<new->control(new,AF_CONTROL_COMMAND_LINE,cmdline))
return new;
}
else
return new;
}
free(new);
af_msg(AF_MSG_ERROR,"[libaf] Couldn't create or open audio filter '%s'\n",
name);
return NULL;
}
/* Create and insert a new filter of type name before the filter in the
argument. This function can be called during runtime, the return
value is the new filter */
af_instance_t* af_prepend(af_stream_t* s, af_instance_t* af, char* name)
{
// Create the new filter and make sure it is OK
af_instance_t* new=af_create(s,name);
if(!new)
return NULL;
// Update pointers
new->next=af;
if(af){
new->prev=af->prev;
af->prev=new;
}
else
s->last=new;
if(new->prev)
new->prev->next=new;
else
s->first=new;
return new;
}
/* Create and insert a new filter of type name after the filter in the
argument. This function can be called during runtime, the return
value is the new filter */
af_instance_t* af_append(af_stream_t* s, af_instance_t* af, char* name)
{
// Create the new filter and make sure it is OK
af_instance_t* new=af_create(s,name);
if(!new)
return NULL;
// Update pointers
new->prev=af;
if(af){
new->next=af->next;
af->next=new;
}
else
s->first=new;
if(new->next)
new->next->prev=new;
else
s->last=new;
return new;
}
// Uninit and remove the filter "af"
void af_remove(af_stream_t* s, af_instance_t* af)
{
if(!af) return;
// Print friendly message
af_msg(AF_MSG_VERBOSE,"[libaf] Removing filter %s \n",af->info->name);
// Notify filter before changing anything
af->control(af,AF_CONTROL_PRE_DESTROY,0);
// Detach pointers
if(af->prev)
af->prev->next=af->next;
else
s->first=af->next;
if(af->next)
af->next->prev=af->prev;
else
s->last=af->prev;
// Uninitialize af and free memory
af->uninit(af);
free(af);
}
/* Reinitializes all filters downstream from the filter given in the
argument the return value is AF_OK if success and AF_ERROR if
failure */
int af_reinit(af_stream_t* s, af_instance_t* af)
{
if(!af)
return AF_ERROR;
do{
af_data_t in; // Format of the input to current filter
int rv=0; // Return value
// Check if this is the first filter
if(!af->prev)
memcpy(&in,&(s->input),sizeof(af_data_t));
else
memcpy(&in,af->prev->data,sizeof(af_data_t));
// Reset just in case...
in.audio=NULL;
in.len=0;
rv = af->control(af,AF_CONTROL_REINIT,&in);
switch(rv){
case AF_OK:
break;
case AF_FALSE:{ // Configuration filter is needed
// Do auto insertion only if force is not specified
if((AF_INIT_TYPE_MASK & s->cfg.force) != AF_INIT_FORCE){
af_instance_t* new = NULL;
// Insert channels filter
if((af->prev?af->prev->data->nch:s->input.nch) != in.nch){
// Create channels filter
if(NULL == (new = af_prepend(s,af,"channels")))
return AF_ERROR;
// Set number of output channels
if(AF_OK != (rv = new->control(new,AF_CONTROL_CHANNELS,&in.nch)))
return rv;
// Initialize channels filter
if(!new->prev)
memcpy(&in,&(s->input),sizeof(af_data_t));
else
memcpy(&in,new->prev->data,sizeof(af_data_t));
if(AF_OK != (rv = new->control(new,AF_CONTROL_REINIT,&in)))
return rv;
}
// Insert format filter
if(((af->prev?af->prev->data->format:s->input.format) != in.format) ||
((af->prev?af->prev->data->bps:s->input.bps) != in.bps)){
// Create format filter
if(NULL == (new = af_prepend(s,af,"format")))
return AF_ERROR;
// Set output bits per sample
if(AF_OK != (rv = new->control(new,AF_CONTROL_FORMAT_BPS,&in.bps)) ||
AF_OK != (rv = new->control(new,AF_CONTROL_FORMAT_FMT,&in.format)))
return rv;
// Initialize format filter
if(!new->prev)
memcpy(&in,&(s->input),sizeof(af_data_t));
else
memcpy(&in,new->prev->data,sizeof(af_data_t));
if(AF_OK != (rv = new->control(new,AF_CONTROL_REINIT,&in)))
return rv;
}
if(!new){ // Should _never_ happen
af_msg(AF_MSG_ERROR,"[libaf] Unable to correct audio format. "
"This error should never uccur, please send bugreport.\n");
return AF_ERROR;
}
af=new;
}
break;
}
case AF_DETACH:{ // Filter is redundant and wants to be unloaded
// Do auto remove only if force is not specified
if((AF_INIT_TYPE_MASK & s->cfg.force) != AF_INIT_FORCE){
af_instance_t* aft=af->prev;
af_remove(s,af);
if(aft)
af=aft;
else
af=s->first; // Restart configuration
}
break;
}
default:
af_msg(AF_MSG_ERROR,"[libaf] Reinitialization did not work, audio"
" filter '%s' returned error code %i\n",af->info->name,rv);
return AF_ERROR;
}
// Check if there are any filters left in the list
if(NULL == af){
if(!(af=af_append(s,s->first,"dummy")))
return -1;
}
else
af=af->next;
}while(af);
return AF_OK;
}
// Uninit and remove all filters
void af_uninit(af_stream_t* s)
{
while(s->first)
af_remove(s,s->first);
}
/* Initialize the stream "s". This function creates a new filter list
if necessary 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
reentrant i.e. if called with an already initialized stream the
stream will be reinitialized. If the binary parameter
"force_output" is set, the output format will be converted to the
format given in "s", otherwise the output fromat in the last filter
will be copied "s". The return value is 0 if success and -1 if
failure */
int af_init(af_stream_t* s, int force_output)
{
int i=0;
// Sanity check
if(!s) return -1;
// Precaution in case caller is misbehaving
s->input.audio = s->output.audio = NULL;
s->input.len = s->output.len = 0;
// Figure out how fast the machine is
if(AF_INIT_AUTO == (AF_INIT_TYPE_MASK & s->cfg.force))
s->cfg.force = (s->cfg.force & ~AF_INIT_TYPE_MASK) | AF_INIT_TYPE;
// Check if this is the first call
if(!s->first){
// Add all filters in the list (if there are any)
if(!s->cfg.list){ // To make automatic format conversion work
if(!af_append(s,s->first,"dummy"))
return -1;
}
else{
while(s->cfg.list[i]){
if(!af_append(s,s->last,s->cfg.list[i++]))
return -1;
}
}
}
// Init filters
if(AF_OK != af_reinit(s,s->first))
return -1;
// If force_output isn't set do not compensate for output format
if(!force_output){
memcpy(&s->output, s->last->data, sizeof(af_data_t));
return 0;
}
// Check output format
if((AF_INIT_TYPE_MASK & s->cfg.force) != AF_INIT_FORCE){
af_instance_t* af = NULL; // New filter
// Check output frequency if not OK fix with resample
if(s->last->data->rate!=s->output.rate){
if(NULL==(af=af_get(s,"resample"))){
if((AF_INIT_TYPE_MASK & s->cfg.force) == AF_INIT_SLOW){
if(!strcmp(s->first->info->name,"format"))
af = af_append(s,s->first,"resample");
else
af = af_prepend(s,s->first,"resample");
}
else{
if(!strcmp(s->last->info->name,"format"))
af = af_prepend(s,s->last,"resample");
else
af = af_append(s,s->last,"resample");
}
}
// Init the new filter
if(!af || (AF_OK != af->control(af,AF_CONTROL_RESAMPLE_RATE,
&(s->output.rate))))
return -1;
// Use lin int if the user wants fast
if ((AF_INIT_TYPE_MASK & s->cfg.force) == AF_INIT_FAST) {
char args[32];
sprintf(args, "%d:0:0", s->output.rate);
af->control(af, AF_CONTROL_COMMAND_LINE, args);
}
if(AF_OK != af_reinit(s,af))
return -1;
}
// Check number of output channels fix if not OK
// If needed always inserted last -> easy to screw up other filters
if(s->last->data->nch!=s->output.nch){
if(!strcmp(s->last->info->name,"format"))
af = af_prepend(s,s->last,"channels");
else
af = af_append(s,s->last,"channels");
// Init the new filter
if(!af || (AF_OK != af->control(af,AF_CONTROL_CHANNELS,&(s->output.nch))))
return -1;
if(AF_OK != af_reinit(s,af))
return -1;
}
// Check output format fix if not OK
if((s->last->data->format != s->output.format) ||
(s->last->data->bps != s->output.bps)){
if(strcmp(s->last->info->name,"format"))
af = af_append(s,s->last,"format");
else
af = s->last;
// Init the new filter
if(!af ||(AF_OK != af->control(af,AF_CONTROL_FORMAT_BPS,&(s->output.bps)))
|| (AF_OK != af->control(af,AF_CONTROL_FORMAT_FMT,&(s->output.format))))
return -1;
if(AF_OK != af_reinit(s,af))
return -1;
}
// Re init again just in case
if(AF_OK != af_reinit(s,s->first))
return -1;
if((s->last->data->format != s->output.format) ||
(s->last->data->bps != s->output.bps) ||
(s->last->data->nch != s->output.nch) ||
(s->last->data->rate != s->output.rate)) {
// Something is stuffed audio out will not work
af_msg(AF_MSG_ERROR,"[libaf] Unable to setup filter system can not"
" meet sound-card demands, please send bugreport. \n");
af_uninit(s);
return -1;
}
}
return 0;
}
/* Add filter during execution. This function adds the filter "name"
to the stream s. The filter will be inserted somewhere nice in the
list of filters. The return value is a pointer to the new filter,
If the filter couldn't be added the return value is NULL. */
af_instance_t* af_add(af_stream_t* s, char* name){
af_instance_t* new;
// Sanity check
if(!s || !s->first || !name)
return NULL;
// Insert the filter somwhere nice
if(!strcmp(s->first->info->name,"format"))
new = af_append(s, s->first, name);
else
new = af_prepend(s, s->first, name);
if(!new)
return NULL;
// Reinitalize the filter list
if(AF_OK != af_reinit(s, s->first)){
free(new);
return NULL;
}
return new;
}
// Filter data chunk through the filters in the list
af_data_t* af_play(af_stream_t* s, af_data_t* data)
{
af_instance_t* af=s->first;
// Iterate through all filters
do{
data=af->play(af,data);
af=af->next;
}while(af);
return data;
}
/* Helper function used to calculate the exact buffer length needed
when buffers are resized. The returned length is >= than what is
needed */
inline int af_lencalc(frac_t mul, af_data_t* d){
register int t = d->bps*d->nch;
return t*(((d->len/t)*mul.n)/mul.d + 1);
}
/* 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)
{
int t = s->input.bps*s->input.nch;
af_instance_t* af=s->first;
register frac_t mul = {1,1};
// Iterate through all filters
do{
mul.n *= af->mul.n;
mul.d *= af->mul.d;
af=af->next;
}while(af);
return t * (((len/t)*mul.n + 1)/mul.d);
}
/* 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)
{
int t = s->input.bps*s->input.nch;
af_instance_t* af=s->first;
register frac_t mul = {1,1};
// Iterate through all filters
do{
mul.n *= af->mul.n;
mul.d *= af->mul.d;
af=af->next;
}while(af);
return t * (((len/t) * mul.d - 1)/mul.n);
}
/* 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)
{
int t = s->input.bps*s->input.nch;
int in = 0;
int out = 0;
af_instance_t* af=s->first;
register frac_t mul = {1,1};
// Iterate through all filters and calculate total multiplication factor
do{
mul.n *= af->mul.n;
mul.d *= af->mul.d;
af=af->next;
}while(af);
// Sanity check
if(!mul.n || !mul.d)
return -1;
in = t * (((len/t) * mul.d - 1)/mul.n);
if(in>max_insize) in=t*(max_insize/t);
// Try to meet constraint nr 3.
while((out=t * (((in/t+1)*mul.n - 1)/mul.d)) <= max_outsize && in<=max_insize){
if( (t * (((in/t)*mul.n))/mul.d) >= len) return in;
in+=t;
}
// Could no meet constraint nr 3.
while(out > max_outsize || in > max_insize){
in-=t;
if(in<t) return -1; // Input parameters are probably incorrect
out = t * (((in/t)*mul.n + 1)/mul.d);
}
return in;
}
/* Calculate the total delay [ms] caused by the filters */
double af_calc_delay(af_stream_t* s)
{
af_instance_t* af=s->first;
register double delay = 0.0;
// Iterate through all filters
while(af){
delay += af->delay;
af=af->next;
}
return delay;
}
/* Helper function called by the macro with the same name this
function should not be called directly */
inline int af_resize_local_buffer(af_instance_t* af, af_data_t* data)
{
// Calculate new length
register int len = af_lencalc(af->mul,data);
af_msg(AF_MSG_VERBOSE,"[libaf] Reallocating memory in module %s, "
"old len = %i, new len = %i\n",af->info->name,af->data->len,len);
// If there is a buffer free it
if(af->data->audio)
free(af->data->audio);
// Create new buffer and check that it is OK
af->data->audio = malloc(len);
if(!af->data->audio){
af_msg(AF_MSG_FATAL,"[libaf] Could not allocate memory \n");
return AF_ERROR;
}
af->data->len=len;
return AF_OK;
}
// send control to all filters, starting with the last until
// one responds with AF_OK
int af_control_any_rev (af_stream_t* s, int cmd, void* arg) {
int res = AF_UNKNOWN;
af_instance_t* filt = s->last;
while (filt && res != AF_OK) {
res = filt->control(filt, cmd, arg);
filt = filt->prev;
}
return (res == AF_OK);
}