rockbox/firmware/pcm.c
Michael Sevakis 08199cd6cb Provide high resolution volume and prescaler to hosted targets.
HAVE_SW_VOLUME_CONTROL is required and at this time only affects the
SDL targets using pcm-sdl.c.

Enables balance control in SDL targets, unless mono volume is in use.

Compiles software volume control as unbuffered when
PCM_SW_VOLUME_UNBUFFERED is defined. This avoids the overhead and
extra latency introduced by the double buffer when it is not needed.
Use this config when the target's PCM driver is buffered and sufficient
latency exists to perform safely the volume scaling.

Simulated targets that are double-buffered when made as native targets
remain so in the sim in order to run the same code.

Change-Id: Ifa77d2d3ae7376c65afecdfc785a084478cb5ffb
Reviewed-on: http://gerrit.rockbox.org/457
Reviewed-by: Michael Sevakis <jethead71@rockbox.org>
Tested-by: Michael Sevakis <jethead71@rockbox.org>
2013-04-27 06:59:27 +02:00

620 lines
15 KiB
C

/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2007 by Michael Sevakis
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include <stdlib.h>
#include "system.h"
#include "kernel.h"
/* Define LOGF_ENABLE to enable logf output in this file */
/*#define LOGF_ENABLE*/
#include "logf.h"
#include "audio.h"
#include "sound.h"
#include "general.h"
#include "pcm-internal.h"
#include "pcm_mixer.h"
/**
* Aspects implemented in the target-specific portion:
*
* ==Playback==
* Public -
* pcm_postinit
* pcm_get_bytes_waiting
* pcm_play_lock
* pcm_play_unlock
* Semi-private -
* pcm_play_dma_complete_callback
* pcm_play_dma_status_callback
* pcm_play_dma_init
* pcm_play_dma_postinit
* pcm_play_dma_start
* pcm_play_dma_stop
* pcm_play_dma_pause
* pcm_play_dma_get_peak_buffer
* Data Read/Written within TSP -
* pcm_sampr (R)
* pcm_fsel (R)
* pcm_curr_sampr (R)
* pcm_playing (R)
* pcm_paused (R)
*
* ==Playback/Recording==
* Public -
* pcm_dma_addr
* Semi-private -
* pcm_dma_apply_settings
*
* ==Recording==
* Public -
* pcm_rec_lock
* pcm_rec_unlock
* Semi-private -
* pcm_rec_dma_complete_callback
* pcm_rec_dma_status_callback
* pcm_rec_dma_init
* pcm_rec_dma_close
* pcm_rec_dma_start
* pcm_rec_dma_stop
* pcm_rec_dma_get_peak_buffer
* Data Read/Written within TSP -
* pcm_recording (R)
*
* States are set _after_ the target's pcm driver is called so that it may
* know from whence the state is changed. One exception is init.
*
*/
/* 'true' when all stages of pcm initialization have completed */
static bool pcm_is_ready = false;
/* The registered callback function to ask for more mp3 data */
volatile pcm_play_callback_type
pcm_callback_for_more SHAREDBSS_ATTR = NULL;
/* The registered callback function to inform of DMA status */
volatile pcm_status_callback_type
pcm_play_status_callback SHAREDBSS_ATTR = NULL;
/* PCM playback state */
volatile bool pcm_playing SHAREDBSS_ATTR = false;
/* PCM paused state. paused implies playing */
volatile bool pcm_paused SHAREDBSS_ATTR = false;
/* samplerate of currently playing audio - undefined if stopped */
unsigned long pcm_curr_sampr SHAREDBSS_ATTR = 0;
/* samplerate waiting to be set */
unsigned long pcm_sampr SHAREDBSS_ATTR = HW_SAMPR_DEFAULT;
/* samplerate frequency selection index */
int pcm_fsel SHAREDBSS_ATTR = HW_FREQ_DEFAULT;
static void pcm_play_data_start_int(const void *addr, size_t size);
static void pcm_play_pause_int(bool play);
void pcm_play_stop_int(void);
#if !defined(HAVE_SW_VOLUME_CONTROL) || defined(PCM_SW_VOLUME_UNBUFFERED)
/** Standard hw volume/unbuffered control functions - otherwise, see
** pcm_sw_volume.c **/
static inline void pcm_play_dma_start_int(const void *addr, size_t size)
{
pcm_play_dma_start(addr, size);
}
static inline void pcm_play_dma_pause_int(bool pause)
{
if (pause || pcm_get_bytes_waiting() > 0)
{
pcm_play_dma_pause(pause);
}
else
{
logf(" no data");
pcm_play_data_start_int(NULL, 0);
}
}
static inline void pcm_play_dma_stop_int(void)
{
pcm_play_dma_stop();
}
static inline const void * pcm_play_dma_get_peak_buffer_int(int *count)
{
return pcm_play_dma_get_peak_buffer(count);
}
bool pcm_play_dma_complete_callback(enum pcm_dma_status status,
const void **addr, size_t *size)
{
/* Check status callback first if error */
if (status < PCM_DMAST_OK)
status = pcm_play_dma_status_callback(status);
if (status >= PCM_DMAST_OK && pcm_get_more_int(addr, size))
return true;
/* Error, callback missing or no more DMA to do */
pcm_play_stop_int();
return false;
}
#endif /* !HAVE_SW_VOLUME_CONTROL || PCM_SW_VOLUME_UNBUFFERED */
static void pcm_play_data_start_int(const void *addr, size_t size)
{
ALIGN_AUDIOBUF(addr, size);
if ((addr && size) || pcm_get_more_int(&addr, &size))
{
pcm_apply_settings();
logf(" pcm_play_dma_start_int");
pcm_play_dma_start_int(addr, size);
pcm_playing = true;
pcm_paused = false;
}
else
{
/* Force a stop */
logf(" pcm_play_stop_int");
pcm_play_stop_int();
}
}
static void pcm_play_pause_int(bool play)
{
if (play)
pcm_apply_settings();
logf(" pcm_play_dma_pause_int");
pcm_play_dma_pause_int(!play);
pcm_paused = !play && pcm_playing;
}
void pcm_play_stop_int(void)
{
pcm_play_dma_stop_int();
pcm_callback_for_more = NULL;
pcm_play_status_callback = NULL;
pcm_paused = false;
pcm_playing = false;
}
static void pcm_wait_for_init(void)
{
while (!pcm_is_ready)
sleep(0);
}
/**
* Perform peak calculation on a buffer of packed 16-bit samples.
*
* Used for recording and playback.
*/
static void pcm_peak_peeker(const int16_t *p, int count,
struct pcm_peaks *peaks)
{
uint32_t peak_l = 0, peak_r = 0;
const int16_t *pend = p + 2 * count;
do
{
int32_t s;
s = p[0];
if (s < 0)
s = -s;
if ((uint32_t)s > peak_l)
peak_l = s;
s = p[1];
if (s < 0)
s = -s;
if ((uint32_t)s > peak_r)
peak_r = s;
p += 4 * 2; /* Every 4th sample, interleaved */
}
while (p < pend);
peaks->left = peak_l;
peaks->right = peak_r;
}
void pcm_do_peak_calculation(struct pcm_peaks *peaks, bool active,
const void *addr, int count)
{
long tick = current_tick;
/* Peak no farther ahead than expected period to avoid overcalculation */
long period = tick - peaks->tick;
/* Keep reasonable limits on period */
if (period < 1)
period = 1;
else if (period > HZ/5)
period = HZ/5;
peaks->period = (3*peaks->period + period) / 4;
peaks->tick = tick;
if (active)
{
int framecount = peaks->period*pcm_curr_sampr / HZ;
count = MIN(framecount, count);
if (count > 0)
pcm_peak_peeker(addr, count, peaks);
/* else keep previous peak values */
}
else
{
/* peaks are zero */
peaks->left = peaks->right = 0;
}
}
void pcm_calculate_peaks(int *left, int *right)
{
/* peak data for the global peak values - i.e. what the final output is */
static struct pcm_peaks peaks;
int count;
const void *addr = pcm_play_dma_get_peak_buffer_int(&count);
pcm_do_peak_calculation(&peaks, pcm_playing && !pcm_paused,
addr, count);
if (left)
*left = peaks.left;
if (right)
*right = peaks.right;
}
const void * pcm_get_peak_buffer(int *count)
{
return pcm_play_dma_get_peak_buffer_int(count);
}
bool pcm_is_playing(void)
{
return pcm_playing;
}
bool pcm_is_paused(void)
{
return pcm_paused;
}
/****************************************************************************
* Functions that do not require targeted implementation but only a targeted
* interface
*/
/* This should only be called at startup before any audio playback or
recording is attempted */
void pcm_init(void)
{
logf("pcm_init");
pcm_set_frequency(HW_SAMPR_DEFAULT);
logf(" pcm_play_dma_init");
pcm_play_dma_init();
}
/* Finish delayed init */
void pcm_postinit(void)
{
logf("pcm_postinit");
logf(" pcm_play_dma_postinit");
pcm_play_dma_postinit();
pcm_is_ready = true;
}
bool pcm_is_initialized(void)
{
return pcm_is_ready;
}
void pcm_play_data(pcm_play_callback_type get_more,
pcm_status_callback_type status_cb,
const void *start, size_t size)
{
logf("pcm_play_data");
pcm_play_lock();
pcm_callback_for_more = get_more;
pcm_play_status_callback = status_cb;
logf(" pcm_play_data_start_int");
pcm_play_data_start_int(start, size);
pcm_play_unlock();
}
void pcm_play_pause(bool play)
{
logf("pcm_play_pause: %s", play ? "play" : "pause");
pcm_play_lock();
if (play == pcm_paused && pcm_playing)
{
logf(" pcm_play_pause_int");
pcm_play_pause_int(play);
}
pcm_play_unlock();
}
void pcm_play_stop(void)
{
logf("pcm_play_stop");
pcm_play_lock();
if (pcm_playing)
{
logf(" pcm_play_stop_int");
pcm_play_stop_int();
}
pcm_play_unlock();
}
/**/
/* set frequency next frequency used by the audio hardware -
* what pcm_apply_settings will set */
void pcm_set_frequency(unsigned int samplerate)
{
logf("pcm_set_frequency");
int index;
#ifdef CONFIG_SAMPR_TYPES
unsigned int type = samplerate & SAMPR_TYPE_MASK;
samplerate &= ~SAMPR_TYPE_MASK;
/* For now, supported targets have direct conversion when configured with
* CONFIG_SAMPR_TYPES.
* Some hypothetical target with independent rates would need slightly
* different handling throughout this source. */
samplerate = pcm_sampr_to_hw_sampr(samplerate, type);
#endif /* CONFIG_SAMPR_TYPES */
index = round_value_to_list32(samplerate, hw_freq_sampr,
HW_NUM_FREQ, false);
if (samplerate != hw_freq_sampr[index])
index = HW_FREQ_DEFAULT; /* Invalid = default */
pcm_sampr = hw_freq_sampr[index];
pcm_fsel = index;
}
/* apply pcm settings to the hardware */
void pcm_apply_settings(void)
{
logf("pcm_apply_settings");
pcm_wait_for_init();
if (pcm_sampr != pcm_curr_sampr)
{
logf(" pcm_dma_apply_settings");
pcm_dma_apply_settings();
pcm_curr_sampr = pcm_sampr;
}
}
#ifdef HAVE_RECORDING
/** Low level pcm recording apis **/
/* Next start for recording peaks */
static const void * volatile pcm_rec_peak_addr SHAREDBSS_ATTR = NULL;
/* the registered callback function for when more data is available */
static volatile pcm_rec_callback_type
pcm_callback_more_ready SHAREDBSS_ATTR = NULL;
volatile pcm_status_callback_type
pcm_rec_status_callback SHAREDBSS_ATTR = NULL;
/* DMA transfer in is currently active */
volatile bool pcm_recording SHAREDBSS_ATTR = false;
/* Called internally by functions to reset the state */
static void pcm_recording_stopped(void)
{
pcm_recording = false;
pcm_callback_more_ready = NULL;
pcm_rec_status_callback = NULL;
}
/**
* Return recording peaks - From the end of the last peak up to
* current write position.
*/
void pcm_calculate_rec_peaks(int *left, int *right)
{
static struct pcm_peaks peaks;
if (pcm_recording)
{
const int16_t *peak_addr = pcm_rec_peak_addr;
const int16_t *addr = pcm_rec_dma_get_peak_buffer();
if (addr != NULL)
{
int count = (addr - peak_addr) / 2; /* Interleaved L+R */
if (count > 0)
{
pcm_peak_peeker(peak_addr, count, &peaks);
if (peak_addr == pcm_rec_peak_addr)
pcm_rec_peak_addr = addr;
}
}
/* else keep previous peak values */
}
else
{
peaks.left = peaks.right = 0;
}
if (left)
*left = peaks.left;
if (right)
*right = peaks.right;
}
bool pcm_is_recording(void)
{
return pcm_recording;
}
/****************************************************************************
* Functions that do not require targeted implementation but only a targeted
* interface
*/
void pcm_init_recording(void)
{
logf("pcm_init_recording");
pcm_wait_for_init();
/* Stop the beasty before attempting recording */
mixer_reset();
/* Recording init is locked unlike general pcm init since this is not
* just a one-time event at startup and it should and must be safe by
* now. */
pcm_rec_lock();
logf(" pcm_rec_dma_init");
pcm_recording_stopped();
pcm_rec_dma_init();
pcm_rec_unlock();
}
void pcm_close_recording(void)
{
logf("pcm_close_recording");
pcm_rec_lock();
if (pcm_recording)
{
logf(" pcm_rec_dma_stop");
pcm_rec_dma_stop();
pcm_recording_stopped();
}
logf(" pcm_rec_dma_close");
pcm_rec_dma_close();
pcm_rec_unlock();
}
void pcm_record_data(pcm_rec_callback_type more_ready,
pcm_status_callback_type status_cb,
void *addr, size_t size)
{
logf("pcm_record_data");
ALIGN_AUDIOBUF(addr, size);
if (!(addr && size))
{
logf(" no buffer");
return;
}
pcm_rec_lock();
pcm_callback_more_ready = more_ready;
pcm_rec_status_callback = status_cb;
/* Need a physical DMA address translation, if not already physical. */
pcm_rec_peak_addr = pcm_rec_dma_addr(addr);
logf(" pcm_rec_dma_start");
pcm_apply_settings();
pcm_rec_dma_start(addr, size);
pcm_recording = true;
pcm_rec_unlock();
} /* pcm_record_data */
void pcm_stop_recording(void)
{
logf("pcm_stop_recording");
pcm_rec_lock();
if (pcm_recording)
{
logf(" pcm_rec_dma_stop");
pcm_rec_dma_stop();
pcm_recording_stopped();
}
pcm_rec_unlock();
} /* pcm_stop_recording */
bool pcm_rec_dma_complete_callback(enum pcm_dma_status status,
void **addr, size_t *size)
{
/* Check status callback first if error */
if (status < PCM_DMAST_OK)
status = pcm_rec_dma_status_callback(status);
pcm_rec_callback_type have_more = pcm_callback_more_ready;
if (have_more && status >= PCM_DMAST_OK)
{
/* Call registered callback to obtain next buffer */
have_more(addr, size);
ALIGN_AUDIOBUF(*addr, *size);
if (*addr && *size)
{
/* Need a physical DMA address translation, if not already
* physical. */
pcm_rec_peak_addr = pcm_rec_dma_addr(*addr);
return true;
}
}
/* Error, callback missing or no more DMA to do */
pcm_rec_dma_stop();
pcm_recording_stopped();
return false;
}
#endif /* HAVE_RECORDING */