rockbox/firmware/pcm.c

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/***************************************************************************
* __________ __ ___.
* 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_get_more_callback
* pcm_play_dma_init
* 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_more_ready_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.
*
*/
/* the registered callback function to ask for more mp3 data */
static pcm_play_callback_type pcm_callback_for_more SHAREDBSS_ATTR = NULL;
void (* pcm_play_dma_started)(void) 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;
/* Called internally by functions to reset the state */
static void pcm_play_stopped(void)
{
pcm_callback_for_more = NULL;
pcm_play_dma_started = NULL;
pcm_paused = false;
pcm_playing = false;
}
/**
* Perform peak calculation on a buffer of packed 16-bit samples.
*
* Used for recording and playback.
*/
static void pcm_peak_peeker(const int32_t *addr, int count, int peaks[2])
{
int peak_l = 0, peak_r = 0;
const int32_t * const end = addr + count;
do
{
int32_t value = *addr;
int ch;
#ifdef ROCKBOX_BIG_ENDIAN
ch = value >> 16;
#else
ch = (int16_t)value;
#endif
if (ch < 0)
ch = -ch;
if (ch > peak_l)
peak_l = ch;
#ifdef ROCKBOX_BIG_ENDIAN
ch = (int16_t)value;
#else
ch = value >> 16;
#endif
if (ch < 0)
ch = -ch;
if (ch > peak_r)
peak_r = ch;
addr += 4;
}
while (addr < end);
peaks[0] = peak_l;
peaks[1] = peak_r;
}
void pcm_calculate_peaks(int *left, int *right)
{
static int peaks[2] = { 0, 0 };
static unsigned long last_peak_tick = 0;
static unsigned long frame_period = 0;
long tick = current_tick;
int count;
const void *addr;
/* Throttled peak ahead based on calling period */
long period = tick - last_peak_tick;
/* Keep reasonable limits on period */
if (period < 1)
period = 1;
else if (period > HZ/5)
period = HZ/5;
frame_period = (3*frame_period + period) >> 2;
last_peak_tick = tick;
addr = pcm_play_dma_get_peak_buffer(&count);
if (pcm_playing && !pcm_paused)
{
int framecount;
framecount = frame_period*pcm_curr_sampr / HZ;
count = MIN(framecount, count);
if (count > 0)
pcm_peak_peeker((int32_t *)addr, count, peaks);
/* else keep previous peak values */
}
else
{
peaks[0] = peaks[1] = 0;
}
if (left)
*left = peaks[0];
if (right)
*right = peaks[1];
}
const void* pcm_get_peak_buffer(int * count)
{
return pcm_play_dma_get_peak_buffer(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_play_stopped();
pcm_set_frequency(HW_SAMPR_DEFAULT);
logf(" pcm_play_dma_init");
pcm_play_dma_init();
}
/* Common code to pcm_play_data and pcm_play_pause */
static void pcm_play_data_start(unsigned char *start, size_t size)
{
start = (unsigned char *)(((uintptr_t)start + 3) & ~3);
size &= ~3;
if (!(start && size))
{
pcm_play_callback_type get_more = pcm_callback_for_more;
size = 0;
if (get_more)
{
logf(" get_more");
get_more(&start, &size);
start = (unsigned char *)(((uintptr_t)start + 3) & ~3);
size &= ~3;
}
}
if (start && size)
{
logf(" pcm_play_dma_start");
pcm_apply_settings();
pcm_play_dma_start(start, size);
pcm_playing = true;
pcm_paused = false;
return;
}
/* Force a stop */
logf(" pcm_play_dma_stop");
pcm_play_dma_stop();
pcm_play_stopped();
}
void pcm_play_data(pcm_play_callback_type get_more,
unsigned char *start, size_t size)
{
logf("pcm_play_data");
pcm_play_lock();
pcm_callback_for_more = get_more;
logf(" pcm_play_data_start");
pcm_play_data_start(start, size);
pcm_play_unlock();
}
void pcm_play_get_more_callback(void **start, size_t *size)
{
pcm_play_callback_type get_more = pcm_callback_for_more;
*size = 0;
if (get_more && start)
{
/* Call registered callback */
get_more((unsigned char **)start, size);
*start = (void *)(((uintptr_t)*start + 3) & ~3);
*size &= ~3;
if (*start && *size)
return;
}
/* Error, callback missing or no more DMA to do */
pcm_play_dma_stop();
pcm_play_stopped();
}
void pcm_play_pause(bool play)
{
logf("pcm_play_pause: %s", play ? "play" : "pause");
pcm_play_lock();
if (play == pcm_paused && pcm_playing)
{
if (!play)
{
logf(" pcm_play_dma_pause");
pcm_play_dma_pause(true);
pcm_paused = true;
}
else if (pcm_get_bytes_waiting() > 0)
{
logf(" pcm_play_dma_pause");
pcm_apply_settings();
pcm_play_dma_pause(false);
pcm_paused = false;
}
else
{
logf(" pcm_play_dma_start: no data");
pcm_play_data_start(NULL, 0);
}
}
else
{
logf(" no change");
}
pcm_play_unlock();
}
void pcm_play_stop(void)
{
logf("pcm_play_stop");
pcm_play_lock();
if (pcm_playing)
{
logf(" pcm_play_dma_stop");
pcm_play_dma_stop();
pcm_play_stopped();
}
else
{
logf(" not playing");
}
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
#ifdef HAVE_RECORDING
unsigned int type = samplerate & SAMPR_TYPE_MASK;
#endif
samplerate &= ~SAMPR_TYPE_MASK;
#ifdef HAVE_RECORDING
#if SAMPR_TYPE_REC != 0
/* 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. */
if (type == SAMPR_TYPE_REC)
samplerate = pcm_sampr_type_rec_to_play(samplerate);
#endif
#endif /* HAVE_RECORDING */
#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");
if (pcm_sampr != pcm_curr_sampr)
{
logf(" pcm_dma_apply_settings");
pcm_dma_apply_settings();
pcm_curr_sampr = pcm_sampr;
}
}
/* register callback to buffer more data */
void pcm_play_set_dma_started_callback(void (* callback)(void))
{
pcm_play_dma_started = callback;
}
#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;
/* 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;
}
/**
* 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 int peaks[2];
if (pcm_recording)
{
const void *peak_addr = pcm_rec_peak_addr;
const void *addr = pcm_rec_dma_get_peak_buffer();
if (addr != NULL)
{
int count = (int)(((intptr_t)addr - (intptr_t)peak_addr) >> 2);
if (count > 0)
{
pcm_peak_peeker((int32_t *)peak_addr, count, peaks);
if (peak_addr == pcm_rec_peak_addr)
pcm_rec_peak_addr = addr;
}
}
/* else keep previous peak values */
}
else
{
peaks[0] = peaks[1] = 0;
}
if (left)
*left = peaks[0];
if (right)
*right = peaks[1];
} /* pcm_calculate_rec_peaks */
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");
#ifndef HAVE_PCM_FULL_DUPLEX
/* Stop the beasty before attempting recording */
mixer_reset();
#endif
/* 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,
void *start, size_t size)
{
logf("pcm_record_data");
/* 32-bit aligned and sized data only */
start = (void *)(((uintptr_t)start + 3) & ~3);
size &= ~3;
if (!(start && size))
{
logf(" no buffer");
return;
}
pcm_rec_lock();
pcm_callback_more_ready = more_ready;
#ifdef HAVE_PCM_REC_DMA_ADDRESS
/* Need a physical DMA address translation, if not already physical. */
pcm_rec_peak_addr = pcm_dma_addr(start);
#else
pcm_rec_peak_addr = start;
#endif
logf(" pcm_rec_dma_start");
pcm_apply_settings();
pcm_rec_dma_start(start, 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 */
void pcm_rec_more_ready_callback(int status, void **start, size_t *size)
{
pcm_rec_callback_type have_more = pcm_callback_more_ready;
*size = 0;
if (have_more && start)
{
have_more(status, start, size);
*start = (void *)(((uintptr_t)*start + 3) & ~3);
*size &= ~3;
if (*start && *size)
{
#ifdef HAVE_PCM_REC_DMA_ADDRESS
/* Need a physical DMA address translation, if not already
* physical. */
pcm_rec_peak_addr = pcm_dma_addr(*start);
#else
pcm_rec_peak_addr = *start;
#endif
return;
}
}
/* Error, callback missing or no more DMA to do */
pcm_rec_dma_stop();
pcm_recording_stopped();
}
#endif /* HAVE_RECORDING */