/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2011 Marcin Bukat * Copyright (C) 2011 Andrew Ryabinin * * 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 "system.h" #include "audio.h" #include "string.h" #include "panic.h" #include "audiohw.h" #include "sound.h" #include "pcm-internal.h" static int locked = 0; /* Mask the DMA interrupt */ void pcm_play_lock(void) { if (++locked == 1) { int old = disable_irq_save(); INTC_IMR &= ~(1<<12); /* mask HDMA interrupt */ restore_irq(old); } } /* Unmask the DMA interrupt if enabled */ void pcm_play_unlock(void) { if(--locked == 0) { int old = disable_irq_save(); INTC_IMR |= (1<<12); /* unmask HDMA interrupt */ restore_irq(old); } } void pcm_play_dma_stop(void) { HDMA_CON0 = 0x00; HDMA_ISR = 0x00; locked = 1; } static void hdma_i2s_transfer(const void *addr, size_t size) { SCU_CLKCFG &= ~(1<<3); /* enable HDMA clock */ commit_discard_dcache_range(addr, size); HDMA_ISRC0 = (uint32_t)addr; /* source address */ HDMA_IDST0 = (uint32_t)&I2S_TXR; /* i2s tx fifo */ HDMA_ICNT0 = (uint16_t)((size>>2) - 1); /* number of dma transactions * of transfer size bytes * (zero based) */ HDMA_ISR = ((1<<13) | /* mask ch1 accumulation overflow irq */ (1<<12) | /* mask ch0 accumulation overflow irq */ (1<<11) | /* mask ch1 page count down irq */ (0<<10) | /* UNMASK ch0 page count down irq */ (1<<9) | /* mask ch0 transfer irq */ (1<<8) | /* mask ch1 transfer irq */ (0<<5) | /* clear ch1 accumulation overflow flag */ (0<<4) | /* clear ch0 accumulation overflow flag */ (0<<3) | /* clear ch1 count down to zero flag */ (0<<2) | /* clear ch0 count down to zero flag */ (0<<1) | /* clear ch1 active flag */ (0<<0)); /* clear ch0 active flag */ HDMA_ISCNT0 = 0x07; /* slice size in transfer size units (zero base) */ HDMA_IPNCNTD0 = 0x01; /* page count */ HDMA_CON0 = ((0<<23) | /* page mode */ (1<<22) | /* slice mode */ (1<<21) | /* DMA enable */ (1<<18) | /* generate interrupt */ (0<<16) | /* on-the-fly is not supported by rk27xx */ (5<<13) | /* transfer mode inc8 */ (6<<9) | /* external hdreq from i2s tx */ (0<<7) | /* increment source address */ (1<<5) | /* fixed destination address */ (2<<3) | /* transfer size = 32bits word */ (0<<1) | /* command of software DMA (not relevant) */ (1<<0)); /* hardware trigger DMA mode */ } void pcm_play_dma_start(const void *addr, size_t size) { /* Stop any DMA in progress */ pcm_play_dma_stop(); /* kick in DMA transfer */ hdma_i2s_transfer(addr, size); } /* pause DMA transfer by disabling clock to DMA module */ void pcm_play_dma_pause(bool pause) { if(pause) { SCU_CLKCFG |= (1<<3); locked = 1; } else { SCU_CLKCFG &= ~(1<<3); locked = 0; } } static void i2s_init(void) { #if defined(HAVE_RK27XX_CODEC) /* iomux I2S internal */ SCU_IOMUXA_CON &= ~(1<<19); /* i2s external bit */ SCU_IOMUXB_CON &= ~((1<<4) | /* i2s_mclk */ (1<<3) | /* i2s_sdo */ (1<<2) | /* i2s_sdi */ (1<<1) | /* i2s_lrck */ (1<<0)); /* i2s_bck */ #else /* iomux I2S external */ SCU_IOMUXA_CON |= (1<<19); /* i2s external bit */ SCU_IOMUXB_CON |= ((1<<4) | /* i2s_mclk */ (1<<3) | /* i2s_sdo */ (1<<2) | /* i2s_sdi */ (1<<1) | /* i2s_lrck */ (1<<0)); /* i2s_bck */ #endif /* enable i2s clocks */ SCU_CLKCFG &= ~((1<<17) | /* i2s_pclk */ (1<<16)); /* i2s_clk */ /* configure I2S module */ I2S_IER = 0; /* disable all i2s interrupts */ I2S_TXCTL = (1<<16) | /* LRCK/SCLK = 64 */ (4<<8) | /* MCLK/SCLK = 4 */ (1<<4) | /* 16bit samples */ (0<<3) | /* stereo */ (0<<1) | /* I2S IF */ #ifdef CODEC_SLAVE (1<<0); /* master mode */ #else (0<<0); /* slave mode */ #endif /* the fifo is 16x32bits according to my tests * while the docs state 32x32bits */ I2S_FIFOSTS = (1<<18) | /* Tx trigger level half full */ (1<<16); /* Rx trigger level half full */ I2S_OPR = (1<<17) | /* reset Tx */ (1<<16) | /* reset Rx */ (0<<6) | /* HDMA Req1 enable */ (1<<5) | /* HDMA Req2 disable */ (0<<4) | /* Req1 for Tx fifo */ (1<<3) | /* Req2 for Rx fifo */ (0<<2) | /* normal operation */ #ifdef CODEC_SLAVE (1<<1) | /* start Tx (master mode) */ (0<<0); /* do not start Rx (master mode) */ /* setting Rx bit to 1 result in choppy audio */ #else (0<<1) | /* not used in slave mode */ (0<<0); /* not used in slave mode */ #endif } #ifdef CODEC_SLAVE /* When codec is slave we need to setup i2s MCLK clock using codec pll. * The MCLK frequency is 256*codec frequency as i2s setup is: * LRCK/SCLK = 64 and MCLK/SCLK = 4 (see i2s_init() for reference) * * PLL output frequency: * Fout = ((Fref / (CLKR+1)) * (CLKF+1)) / (CLKOD+1) * Fref = 24 MHz */ static void set_codec_freq(unsigned int freq) { long timeout; /* {CLKR, CLKF, CLKOD, CODECPLL_DIV} */ static const unsigned int pcm_freq_params[HW_NUM_FREQ][4] = { [HW_FREQ_96] = {24, 255, 4, 1}, [HW_FREQ_48] = {24, 127, 4, 1}, [HW_FREQ_44] = {24, 293, 4, 4}, [HW_FREQ_32] = {24, 127, 4, 2}, [HW_FREQ_24] = {24, 127, 4, 3}, [HW_FREQ_22] = {24, 146, 4, 4}, [HW_FREQ_16] = {24, 127, 5, 4}, [HW_FREQ_12] = {24, 127, 4, 7}, [HW_FREQ_11] = {24, 146, 4, 9}, [HW_FREQ_8] = {24, 127, 5, 9}, }; /* select divider output from codec pll */ SCU_DIVCON1 &= ~((1<<9) | (0xF<<5)); SCU_DIVCON1 |= (pcm_freq_params[freq][3]<<5); /* Codec PLL power up */ SCU_PLLCON3 &= ~(1<<22); SCU_PLLCON3 = (1<<24) | /* Saturation behavior enable */ (1<<23) | /* Enable fast locking circuit */ (pcm_freq_params[freq][0]<<16) | /* CLKR factor */ (pcm_freq_params[freq][1]<<4) | /* CLKF factor */ (pcm_freq_params[freq][2]<<1) ; /* CLKOD factor */ /* wait for CODEC PLL lock with 10 ms timeout * datasheet states that pll lock should take approx. 0.3 ms */ timeout = current_tick + (HZ/100); while (!(SCU_STATUS & (1<<2))) if (TIME_AFTER(current_tick, timeout)) break; } #endif void pcm_play_dma_init(void) { /* unmask HDMA interrupt in INTC */ INTC_IMR |= (1<<12); INTC_IECR |= (1<<12); audiohw_preinit(); i2s_init(); } void pcm_play_dma_postinit(void) { audiohw_postinit(); } void pcm_dma_apply_settings(void) { #ifdef CODEC_SLAVE set_codec_freq(pcm_fsel); #endif audiohw_set_frequency(pcm_fsel); } size_t pcm_get_bytes_waiting(void) { /* current terminate count is in transfer size units (4bytes here) */ return (HDMA_CCNT0 & 0xffff)<<2; } /* audio DMA ISR called when chunk from callers buffer has been transfered */ void INT_HDMA(void) { const void *start; size_t size; if (pcm_play_dma_complete_callback(PCM_DMAST_OK, &start, &size)) { hdma_i2s_transfer(start, size); pcm_play_dma_status_callback(PCM_DMAST_STARTED); } } const void * pcm_play_dma_get_peak_buffer(int *count) { uint32_t addr; int old = disable_irq_save(); addr = HDMA_CSRC0; *count = ((HDMA_CCNT0 & 0xffff)<<2); restore_interrupt(old); return (void*)addr; } /**************************************************************************** ** Recording DMA transfer **/ /* TODO */