/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2005 by Linus Nielsen Feltzing * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include "config.h" #include "debug.h" #include "panic.h" #include #ifndef SIMULATOR #include "cpu.h" #include "i2c.h" #if defined(HAVE_UDA1380) #include "uda1380.h" #elif defined(HAVE_TLV320) #include "tlv320.h" #endif #include "system.h" #endif #include "logf.h" #include #include #include #include "pcm_playback.h" #include "lcd.h" #include "button.h" #include "file.h" #include "buffer.h" #include "sprintf.h" #include "button.h" #include #ifdef HAVE_UDA1380 #ifdef HAVE_SPDIF_OUT #define EBU_DEFPARM ((7 << 12) | (3 << 8) | (1 << 5) | (5 << 2)) #endif #define IIS_DEFPARM(freq) ((freq << 12) | 0x300 | 4 << 2) #define IIS_RESET 0x800 static bool pcm_playing; static bool pcm_paused; static int pcm_freq = 0x6; /* 44.1 is default */ static unsigned char *next_start; static long next_size; /* Set up the DMA transfer that kicks in when the audio FIFO gets empty */ static void dma_start(const void *addr, long size) { pcm_playing = true; addr = (void *)((unsigned long)addr & ~3); /* Align data */ size &= ~3; /* Size must be multiple of 4 */ /* Reset the audio FIFO */ #ifdef HAVE_SPDIF_OUT EBU1CONFIG = IIS_RESET; #endif /* Set up DMA transfer */ SAR0 = ((unsigned long)addr); /* Source address */ DAR0 = (unsigned long)&PDOR3; /* Destination address */ BCR0 = size; /* Bytes to transfer */ /* Enable the FIFO and force one write to it */ IIS2CONFIG = IIS_DEFPARM(pcm_freq); /* Also send the audio to S/PDIF */ #ifdef HAVE_SPDIF_OUT EBU1CONFIG = EBU_DEFPARM; #endif DCR0 = DMA_INT | DMA_EEXT | DMA_CS | DMA_SINC | DMA_START; } /* Stops the DMA transfer and interrupt */ static void dma_stop(void) { pcm_playing = false; DCR0 = 0; /* Reset the FIFO */ IIS2CONFIG = IIS_RESET | IIS_DEFPARM(pcm_freq); #ifdef HAVE_SPDIF_OUT EBU1CONFIG = IIS_RESET; #endif next_start = NULL; next_size = 0; pcm_paused = false; } /* * This function goes directly into the DMA buffer to calculate the left and * right peak values. To avoid missing peaks it tries to look forward two full * peek periods (2/HZ sec, 100% overlap), although it's always possible that * the entire period will not be visible. To reduce CPU load it only looks at * every third sample, and this can be reduced even further if needed (even * every tenth sample would still be pretty accurate). */ #define PEAK_SAMPLES (44100*2/HZ) /* 44100 samples * 2 / 100 Hz tick */ #define PEAK_STRIDE 3 /* every 3rd sample is plenty... */ void pcm_calculate_peaks(int *left, int *right) { long samples = (BCR0 & 0xffffff) / 4; short *addr = (short *) (SAR0 & ~3); if (samples > PEAK_SAMPLES) samples = PEAK_SAMPLES; samples /= PEAK_STRIDE; if (left && right) { int left_peak = 0, right_peak = 0, value; while (samples--) { if ((value = addr [0]) > left_peak) left_peak = value; else if (-value > left_peak) left_peak = -value; if ((value = addr [PEAK_STRIDE | 1]) > right_peak) right_peak = value; else if (-value > right_peak) right_peak = -value; addr += PEAK_STRIDE * 2; } *left = left_peak; *right = right_peak; } else if (left || right) { int peak_value = 0, value; if (right) addr += (PEAK_STRIDE | 1); while (samples--) { if ((value = addr [0]) > peak_value) peak_value = value; else if (-value > peak_value) peak_value = -value; addr += PEAK_STRIDE * 2; } if (left) *left = peak_value; else *right = peak_value; } } /* sets frequency of input to DAC */ void pcm_set_frequency(unsigned int frequency) { switch(frequency) { case 11025: pcm_freq = 0x4; uda1380_set_nsorder(3); break; case 22050: pcm_freq = 0x6; uda1380_set_nsorder(3); break; case 44100: default: pcm_freq = 0xC; uda1380_set_nsorder(5); break; } } /* the registered callback function to ask for more mp3 data */ static void (*callback_for_more)(unsigned char**, long*) = NULL; void pcm_play_data(void (*get_more)(unsigned char** start, long* size)) { unsigned char *start; long size; callback_for_more = get_more; get_more((unsigned char **)&start, (long *)&size); get_more(&next_start, &next_size); dma_start(start, size); } long pcm_get_bytes_waiting(void) { return next_size + (BCR0 & 0xffffff); } void pcm_play_stop(void) { if (pcm_playing) { dma_stop(); } } void pcm_play_pause(bool play) { if(pcm_paused && play && next_size) { logf("unpause"); /* Reset chunk size so dma has enough data to fill the fifo. */ /* This shouldn't be needed anymore. */ //SAR0 = (unsigned long)next_start; //BCR0 = next_size; /* Enable the FIFO and force one write to it */ IIS2CONFIG = IIS_DEFPARM(pcm_freq); #ifdef HAVE_SPDIF_OUT EBU1CONFIG = EBU_DEFPARM; #endif DCR0 |= DMA_EEXT | DMA_START; } else if(!pcm_paused && !play) { logf("pause"); /* Disable DMA peripheral request. */ DCR0 &= ~DMA_EEXT; IIS2CONFIG = IIS_RESET | IIS_DEFPARM(pcm_freq); #ifdef HAVE_SPDIF_OUT EBU1CONFIG = IIS_RESET; #endif } pcm_paused = !play; } bool pcm_is_paused(void) { return pcm_paused; } bool pcm_is_playing(void) { return pcm_playing; } /* DMA0 Interrupt is called when the DMA has finished transfering a chunk */ void DMA0(void) __attribute__ ((interrupt_handler, section(".icode"))); void DMA0(void) { int res = DSR0; DSR0 = 1; /* Clear interrupt */ DCR0 &= ~DMA_EEXT; /* Stop on error */ if(res & 0x70) { pcm_play_stop(); logf("DMA Error:0x%04x", res); } else { if(next_size) { SAR0 = (unsigned long)next_start; /* Source address */ BCR0 = next_size; /* Bytes to transfer */ DCR0 |= DMA_EEXT; if (callback_for_more) callback_for_more(&next_start, &next_size); } else { /* Finished playing */ pcm_play_stop(); logf("DMA No Data:0x%04x", res); } } IPR |= (1<<14); /* Clear pending interrupt request */ } void pcm_init(void) { pcm_playing = false; pcm_paused = false; MPARK = 0x81; /* PARK[1,0]=10 + BCR24BIT */ DIVR0 = 54; /* DMA0 is mapped into vector 54 in system.c */ DMAROUTE = (DMAROUTE & 0xffffff00) | DMA0_REQ_AUDIO_1; DMACONFIG = 1; /* DMA0Req = PDOR3 */ /* Reset the audio FIFO */ IIS2CONFIG = IIS_RESET; /* Enable interrupt at level 7, priority 0 */ ICR6 = 0x1c; IMR &= ~(1<<14); /* bit 14 is DMA0 */ pcm_set_frequency(44100); /* Prevent pops (resets DAC to zero point) */ IIS2CONFIG = IIS_DEFPARM(pcm_freq) | IIS_RESET; #if defined(HAVE_UDA1380) /* Initialize default register values. */ uda1380_init(); /* Sleep a while so the power can stabilize (especially a long delay is needed for the line out connector). */ sleep(HZ); /* Power on FSDAC and HP amp. */ uda1380_enable_output(true); /* Unmute the master channel (DAC should be at zero point now). */ uda1380_mute(false); #elif defined(HAVE_TLV320) tlv320_init(); tlv320_enable_output(true); sleep(HZ/4); tlv320_mute(false); #endif /* Call dma_stop to initialize everything. */ dma_stop(); } #elif defined(HAVE_WM8975) /* TODO: Implement for iPod - we should probably move the UDA1380 and WM8975 specific code into separate files. For now, just implement some dummy functions. */ void pcm_init(void) { } void pcm_set_frequency(unsigned int frequency) { (void)frequency; } void pcm_play_data(void (*get_more)(unsigned char** start, long* size)) { (void)get_more; } void pcm_play_stop(void) { } void pcm_play_pause(bool play) { (void)play; } bool pcm_is_paused(void) { return false; } bool pcm_is_playing(void) { return false; } void pcm_calculate_peaks(int *left, int *right) { (void)left; (void)right; } long pcm_get_bytes_waiting(void) { return 0; } #endif