iBoot/apps/EmbeddedIOP/function_audiodsp/AE2_DMA/pio_ae2.c

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2023-07-08 13:03:17 -07:00
/*
* Copyright (C) 2010-2011 Apple Inc. All rights reserved.
*
* This document is the property of Apple Inc.
* It is considered confidential and proprietary.
*
* This document may not be reproduced or transmitted in any form,
* in whole or in part, without the express written permission of
* Apple Inc.
*/
/**
* The PIO object pretends to be a DMA for MCA.
*/
#include "pio_ae2.h"
#include "ae2_i2s.h"
#include "ae2_mca.h"
#include <drivers/audio/audio.h>
#include <debug.h>
#include <stdlib.h>
//Per AE2 Local DMA Controller/Requests
static void* sDMAAddressRX[kAudioDevice_Last] = { (void*)rI2S0_RXDB, (void*)rI2S1_RXDB, (void*)rI2S2_RXDB, (void*)rI2S3_RXDB, (void*)rMCA0_RXDATA, (void*)rMCA1_RXDATA };
static void* sDMAAddressTX[kAudioDevice_Last] = { (void*)rI2S0_TXDB, (void*)rI2S1_TXDB, (void*)rI2S2_TXDB, (void*)rI2S3_TXDB, (void*)rMCA0_TXDATA, (void*)rMCA1_TXDATA };
static internal_pio_object_t* sPIOObjects[kNumPIOs] = { NULL };
static uint32_t sPIORunning = 0;
uint32_t readReg(uint32_t address)
{
return *(volatile uint32_t *)address;
}
void writeReg(uint32_t address, uint32_t value)
{
*(volatile uint32_t *)address = value;
}
uint32_t readMCA0Reg(uint32_t offset)
{
return readReg(rMCA0_BASE + offset);
}
void writeMCA0Reg(uint32_t offset, uint32_t value)
{
writeReg(rMCA0_BASE + offset, value);
}
dma_object_t create_dma_object(void *buffer, AudioDevice_Index device, DMALinkedListItem *chain, DMADirection direction, size_t bytesToTransfer)
{
dprintf(DEBUG_CRITICAL, "Creating a PIO object\n");
// hardcoding to support only MCA right now.
if ((device >= kAudioDevice_Last) || ((direction != kDirectionIn) && (direction != kDirectionOut)) || (device != kMCA_0))
{
dprintf(DEBUG_CRITICAL, "oops, bad arg\n");
return NULL;
}
uint32_t whichPIO = (direction == kDirectionIn) ? kPIOReceive : kPIOTransmit;
// fail if device already exists
if (sPIOObjects[whichPIO])
{
dprintf(DEBUG_CRITICAL, "PIO already exists\n");
return NULL;
}
internal_pio_object_t *This = (internal_pio_object_t*)malloc(sizeof(internal_pio_object_t));
if (This)
{
This->mWhichDevice = whichPIO;
This->mInterruptHandler = NULL;
This->mInterruptHandlerData = NULL;
for (uint32_t i = kFrameError; i < kError_last; ++i)
{
This->mErrorCount[i] = 0;
}
if (direction == kDirectionIn)
{
setupPIO(This, sDMAAddressRX[device], buffer, chain, bytesToTransfer);
}
else
{
setupPIO(This, buffer, sDMAAddressTX[device], chain, bytesToTransfer);
}
sPIOObjects[This->mWhichDevice] = This;
// we can do this here repeatedly
install_int_handler(AE2_INT_MCA0, handleAudioDeviceInterrupt, NULL);
}
return This;
}
void destroy_dma_object(dma_object_t dma)
{
// preliminary stop
stopDMAObject(dma, true);
internal_pio_object_t *This = (internal_pio_object_t*)dma;
if (This)
{
sPIOObjects[This->mWhichDevice] = NULL;
free(This);
}
}
uint32_t getErrorCount(dma_object_t dma, Error_Index which)
{
// preliminary stop
internal_pio_object_t *This = (internal_pio_object_t*)dma;
if (This)
{
return This->mErrorCount[which];
}
return 0;
}
void setupInterruptHandler(dma_object_t dma, int_handler handler, void *arg)
{
internal_pio_object_t *This = (internal_pio_object_t*)dma;
if (This)
{
This->mInterruptHandler = handler;
This->mInterruptHandlerData = arg;
}
}
void setupErrorHandler(dma_object_t dma, int_handler handler, void *arg)
{
}
void startDMAObject(dma_object_t dma)
{
internal_pio_object_t *This = (internal_pio_object_t*)dma;
if (This)
{
startPIO(This);
// we wait until two of them are ready before we unmask the int
sPIORunning |= (1 << This->mWhichDevice);
if (sPIORunning == 3)
{
unmask_int(AE2_INT_MCA0);
}
}
}
void stopDMAObject(dma_object_t dma, bool immediate)
{
internal_pio_object_t *This = (internal_pio_object_t*)dma;
if (This)
{
sPIORunning &= ~(1 << This->mWhichDevice);
if (sPIORunning != 3)
{
mask_int(AE2_INT_MCA0);
}
stopPIO(This);
}
}
bool receivePIOData(DMALinkedListItem * item)
{
// we do burst sizes of 16-bit data
int16_t data[kBurstSize];
volatile uint32_t * src = (volatile uint32_t *)item->source;
for (size_t i = 0; i < sizeof(data)/sizeof(data[0]); ++i)
{
data[i] = *src;
}
uint8_t * dst = (uint8_t*)item->destination;
memcpy(dst, data, sizeof(data));
dst += sizeof(data);
item->destination = (uint32_t) dst;
item->control -= sizeof(data);
return !item->control;
}
bool transmitPIOData(DMALinkedListItem * item)
{
// we do burst sizes of 16-bit data
int16_t data[kBurstSize];
uint8_t * src = (uint8_t*)item->source;
memcpy(data, src, sizeof(data));
volatile uint32_t * dst = (volatile uint32_t *)item->destination;
for (size_t i = 0; i < sizeof(data)/sizeof(data[0]); ++i)
{
*dst = data[i];
}
src += sizeof(data);
item->source = (uint32_t) src;
item->control -= sizeof(data);
return !item->control;
}
void setupNextLLI(DMALinkedListItem * item)
{
*item = *(item->next);
}
void handleAudioDeviceInterrupt()
{
uint32_t status = readMCA0Reg(rMCASTATUS);
// <rdar://problem/13467070> Panic when setting AppleSongbirdDSP sidetone EQ
// clear any sort of sticky-bit errors.
uint32_t errors = status & ( rMCASTATUS_FRAMEEEROR_MASK | rMCASTATUS_RXOVERRUN_MASK | rMCASTATUS_RXUNDERRUN_MASK | rMCASTATUS_TXOVERRUN_MASK | rMCASTATUS_TXUNDERRUN_MASK );
writeMCA0Reg(rMCASTATUS, errors);
if (errors)
{
if (sPIOObjects[kPIOReceive])
{
if (status & rMCASTATUS_FRAMEEEROR_MASK) ++sPIOObjects[kPIOReceive]->mErrorCount[kFrameError];
if (status & rMCASTATUS_RXOVERRUN_MASK) ++sPIOObjects[kPIOReceive]->mErrorCount[kRXOverrun];
if (status & rMCASTATUS_RXUNDERRUN_MASK) ++sPIOObjects[kPIOReceive]->mErrorCount[kRXUnderrun];
if (status & rMCASTATUS_TXOVERRUN_MASK) ++sPIOObjects[kPIOReceive]->mErrorCount[kTXOverrun];
if (status & rMCASTATUS_TXUNDERRUN_MASK) ++sPIOObjects[kPIOReceive]->mErrorCount[kTXUnderrun];
}
}
if (status & (1 << rMCASTATUS_RXHIGHWATER))
{
if (sPIOObjects[kPIOReceive])
{
if (receivePIOData(&sPIOObjects[kPIOReceive]->mCurrentDMAItem))
{
setupNextLLI(&sPIOObjects[kPIOReceive]->mCurrentDMAItem);
if (sPIOObjects[kPIOReceive]->mInterruptHandler)
{
sPIOObjects[kPIOReceive]->mInterruptHandler(sPIOObjects[kPIOReceive]->mInterruptHandlerData);
}
}
}
}
if (status & (1 << rMCASTATUS_TXLOWWATER))
{
if (sPIOObjects[kPIOTransmit])
{
if (transmitPIOData(&sPIOObjects[kPIOTransmit]->mCurrentDMAItem))
{
setupNextLLI(&sPIOObjects[kPIOTransmit]->mCurrentDMAItem);
if (sPIOObjects[kPIOTransmit]->mInterruptHandler)
{
sPIOObjects[kPIOTransmit]->mInterruptHandler(sPIOObjects[kPIOTransmit]->mInterruptHandlerData);
}
}
}
}
}
void setupPIO(internal_pio_object_t * This, void *src, void *dst, DMALinkedListItem *chain, size_t bytesToTransfer)
{
uint32_t transferSize = bytesToTransfer;
uint32_t control = transferSize;
DMALinkedListItem *chainElement = chain;
while(chainElement != NULL)
{
chainElement->control = (uint32_t)control;
chainElement = chainElement->next;
if(chainElement == chain)
{
//We've populated all of the control values in this circular linked list, we are done here
break;
}
}
This->mCurrentDMAItem.source = (uint32_t)src;
This->mCurrentDMAItem.destination = (uint32_t)dst;
This->mCurrentDMAItem.next = chain;
This->mCurrentDMAItem.control = control;
}
void startPIO(internal_pio_object_t * pio_object)
{
if (pio_object)
{
if (pio_object->mWhichDevice == kPIOReceive)
{
uint32_t MCAUNSRXCFG = readMCA0Reg(rMCAUNSRXCFG);
writeMCA0Reg(rMCAUNSRXCFG, MCAUNSRXCFG | (1 << rMCAUNSRXCFG_IRQ_EN));
}
else
{
uint32_t MCAUNSTXCFG = readMCA0Reg(rMCAUNSTXCFG);
writeMCA0Reg(rMCAUNSTXCFG, MCAUNSTXCFG | (1 << rMCAUNSTXCFG_IRQ_EN));
}
}
}
void stopPIO(internal_pio_object_t * pio_object)
{
if (pio_object)
{
if (pio_object->mWhichDevice == kPIOReceive)
{
uint32_t MCAUNSRXCFG = readMCA0Reg(rMCAUNSRXCFG);
writeMCA0Reg(rMCAUNSRXCFG, MCAUNSRXCFG & ~((1 << rMCAUNSRXCFG_IRQ_EN)));
}
else
{
uint32_t MCAUNSTXCFG = readMCA0Reg(rMCAUNSTXCFG);
writeMCA0Reg(rMCAUNSTXCFG, MCAUNSTXCFG & ~((1 << rMCAUNSTXCFG_IRQ_EN)));
}
}
}