sdcontrol.c
来自「pxa27x library for windows ce 5.0」· C语言 代码 · 共 1,690 行 · 第 1/5 页
C
1,690 行
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
//
// Use of this source code is subject to the terms of the Microsoft end-user
// license agreement (EULA) under which you licensed this SOFTWARE PRODUCT.
// If you did not accept the terms of the EULA, you are not authorized to use
// this source code. For a copy of the EULA, please see the LICENSE.RTF on your
// install media.
//
//
// Copyright (c) 2002 BSQUARE Corporation. All rights reserved.
// DO NOT REMOVE --- BEGIN EXTERNALLY DEVELOPED SOURCE CODE ID 40973--- DO NOT REMOVE
//
// Module Name:
//
// SDControl.c
//
// Abstract:
//
// PXA27X SDIO controller implementation
//
// Notes:
//
///////////////////////////////////////////////////////////////////////////////
//#define EXTENSIVE_DEBUGGING
#include <windows.h>
#include <nkintr.h>
#include <ceddk.h>
#include "SDCardDDK.h"
#include "SDHCD.h"
#include "SD.h"
// prototypes
PVOID VirtualAllocCopy(unsigned size,char *str,PVOID pVirtualAddress);
DWORD SDControllerIstThread(PSDH_HARDWARE_CONTEXT pHCDevice);
#ifdef DEBUG
void DumpRegisters(PSDH_HARDWARE_CONTEXT pController);
void DumpGPIORegisters(PSDH_HARDWARE_CONTEXT pController);
#endif
#ifdef DEBUG
#define HEXBUFSIZE 1024
char szHexBuf[HEXBUFSIZE];
#define TRANSFER_SIZE(pRequest) ((pRequest)->BlockSize * (pRequest)->NumBlocks)
char* HexDisplay( BYTE *pBuffer, DWORD dwLength )
{
DWORD dwTemp = 0;
while( dwTemp < dwLength && (dwTemp < (HEXBUFSIZE / 2 - 1) ) )
{
szHexBuf[dwTemp*2] = pBuffer[dwTemp] / 16;
szHexBuf[dwTemp*2+1] = pBuffer[dwTemp] % 16;
if( szHexBuf[dwTemp*2] < 10 )
szHexBuf[dwTemp*2] += '0';
else
szHexBuf[dwTemp*2] += 'a' - 10;
if( szHexBuf[dwTemp*2+1] < 10 )
szHexBuf[dwTemp*2+1] += '0';
else
szHexBuf[dwTemp*2+1] += 'a' - 10;
dwTemp++;
}
szHexBuf[dwTemp*2] = 0;
return szHexBuf;
}
#endif
void WRITE_MMC_REGISTER_DWORD(PSDH_HARDWARE_CONTEXT pHc, DWORD RegOffset, DWORD Value)
{
BYTE *pRegBaseAddr, *regAddr;
volatile DWORD *pdwRegAddr;
pRegBaseAddr = (BYTE*)(pHc->pSDMMCRegisters);
regAddr = pRegBaseAddr + RegOffset;
pdwRegAddr = (DWORD*)regAddr;
*pdwRegAddr = Value;
}
DWORD READ_MMC_REGISTER_DWORD(PSDH_HARDWARE_CONTEXT pHc, DWORD RegOffset)
{
BYTE *pRegBaseAddr, *regAddr;
volatile DWORD *pdwRegAddr;
pRegBaseAddr = (BYTE*)(pHc->pSDMMCRegisters);
regAddr = pRegBaseAddr + RegOffset;
pdwRegAddr = (DWORD*)regAddr;
return (*pdwRegAddr);
}
#define IS_PROGRAM_DONE(pHc) (READ_MMC_REGISTER_DWORD((pHc), MMC_STAT) & MMC_STAT_PROGRAM_DONE)
#define IS_TRANSFER_DONE(pHc) (READ_MMC_REGISTER_DWORD((pHc), MMC_STAT) & MMC_STAT_DATA_TRANSFER_DONE)
//#define RX_FIFO_FULL(pHc) (READ_MMC_REGISTER_DWORD((pHc), MMC_STAT) & MMC_STAT_RCV_FIFO_FULL)
//#define TX_FIFO_EMPTY(pHc) (READ_MMC_REGISTER_DWORD((pHc), MMC_STAT) & MMC_STAT_XMIT_FIFO_EMPTY)
#define TRANSFER_IS_WRITE(pRequest) ((SD_WRITE == (pRequest)->TransferClass))
#define TRANSFER_IS_READ(pRequest) ((SD_READ == (pRequest)->TransferClass))
BOOL CLOCK_IS_ON(PSDH_HARDWARE_CONTEXT pHc)
{
if( READ_MMC_REGISTER_DWORD( pHc, MMC_STAT ) & MMC_STAT_CLOCK_ENABLED )
{
return TRUE;
}
else
{
return FALSE;
}
}
void READ_MOD_WRITE_MMC_REGISTER_AND_OR(PSDH_HARDWARE_CONTEXT pHc, DWORD RegOffset, DWORD AndValue, DWORD OrValue)
{
DWORD regValue;
regValue = READ_MMC_REGISTER_DWORD(pHc, RegOffset);
regValue &= (AndValue);
regValue |= (OrValue);
WRITE_MMC_REGISTER_DWORD(pHc, RegOffset, regValue);
}
#define CLOCK_OFF_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_CLOCK_OFF_INT_MASKED)
// macro to turn SDIO interrupts on
#define SDIO_INTERRUPT_ON(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, ~MMC_IMASK_SDIO_INT_MASKED, 0)
// macro to turn SDIO interrupts off
#define SDIO_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_SDIO_INT_MASKED)
// macro to turn RX FIFO interrupts on
#define RX_FIFO_INTERRUPT_ON(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, ~MMC_IMASK_RXFIFO_REQ_INT_MASKED, 0)
// macro to turn RX FIFO interrupts off
#define RX_FIFO_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_RXFIFO_REQ_INT_MASKED)
// macro to turn TX FIFO interrupts on
#define TX_FIFO_INTERRUPT_ON(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK,~MMC_IMASK_TXFIFO_REQ_INT_MASKED, 0)
// macro to turn TX FIFO interrupts off
#define TX_FIFO_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_TXFIFO_REQ_INT_MASKED)
#define TRANSFER_DONE_INTERRUPT_ON(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, ~MMC_IMASK_DATA_TRAN_DONE_INT_MASKED, 0)
#define TRANSFER_DONE_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_DATA_TRAN_DONE_INT_MASKED)
#define END_CMD_INTERRUPT_ON(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, ~MMC_IMASK_END_CMD_INT_MASKED, 0)
#define END_CMD_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_END_CMD_INT_MASKED)
#define PROGRAM_DONE_INTERRUPT_ON(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, ~MMC_IMASK_PROG_DONE_INT_MASKED, 0)
#define PROGRAM_DONE_INTERRUPT_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_PROG_DONE_INT_MASKED)
#define TX_BUFFER_PARTIAL_FULL(pHc) \
WRITE_MMC_REGISTER_DWORD(pHc, MMC_PRTBUF, MMC_PRTBUF_BUFFER_PARTIAL_FULL)
#define TX_BUFFER_PARTIAL_NOT_FULL(pHc) \
WRITE_MMC_REGISTER_DWORD(pHc, MMC_PRTBUF, 0)
#define ALL_INTERRUPTS_OFF(pHc) \
READ_MOD_WRITE_MMC_REGISTER_AND_OR(pHc, MMC_IMASK, 0xffffffff, MMC_IMASK_ALL_INTERRUPTS_MASKED)
// clock rate table
typedef struct _CLOCK_RATE_ENTRY {
DWORD Frequency;
UCHAR ControlValue;
} CLOCK_RATE_ENTRY, *PCLOCK_RATE_ENTRY;
CLOCK_RATE_ENTRY SDClockTable[] =
{ {312500, 0x06},
{625000, 0x05},
{1250000, 0x04},
{2500000, 0x03},
{5000000, 0x02},
{10000000, 0x01},
{20000000, 0x00}, // 20 Mhz
};
#define NUM_CLOCK_ENTRIES sizeof(SDClockTable)/sizeof(CLOCK_RATE_ENTRY)
///////////////////////////////////////////////////////////////////////////////
// SDClockOff - turn off the MMC clock
// Input: pHc - hardware context
// Output:
// Return:
// Notes:
//
///////////////////////////////////////////////////////////////////////////////
VOID SDClockOff(PSDH_HARDWARE_CONTEXT pHc)
{
// check to see if the clock is on
if (!CLOCK_IS_ON(pHc)) {
return;
}
DbgPrintZo(SDH_CLOCK_ZONE, (TEXT("SDClockOff - turning off clock \n")));
// turn off the clock
WRITE_MMC_REGISTER_DWORD(pHc, MMC_STRPCL, MMC_STRPCL_STOP_CLOCK);
while (CLOCK_IS_ON(pHc)) {
// sit here and wait for the clock to turn off
DbgPrintZo(SDH_CLOCK_ZONE, (TEXT("Waiting for clock off\n")));
}
DbgPrintZo(SDH_CLOCK_ZONE, (TEXT("SDClockOff - Clock is now off \n")));
}
///////////////////////////////////////////////////////////////////////////////
// SDClockOn - turn on the MMC Clock
// Input: pHc - hardware context
// pRate - pointer to desired clock rate in Hz
// Output:
// Return:
// Notes:
//
///////////////////////////////////////////////////////////////////////////////
VOID SDSetRate(PSDH_HARDWARE_CONTEXT pHc, PDWORD pRate)
{
ULONG ii; // table index variable
DWORD rate = *pRate;
if( rate > 10000000 )
rate = 10000000;
// check to see if the rate is below the first entry in the table
if (rate <= SDClockTable[0].Frequency) {
ii = 0;
} else {
// scan through the table looking for a frequency that
// is close to the requested rate
for (ii = 0; ii < (NUM_CLOCK_ENTRIES - 1); ii++) {
if ((rate >= SDClockTable[ii].Frequency) &&
(rate < SDClockTable[ii+1].Frequency)) {
break;
}
}
}
DbgPrintZo(SDH_CLOCK_ZONE, (TEXT("SDClockOn - Requested Rate: %d, Setting clock rate to %d Hz \n"),
*pRate, SDClockTable[ii].Frequency ));
// return the actual fruency
*pRate = SDClockTable[ii].Frequency;
// set the clock rate
WRITE_MMC_REGISTER_DWORD(pHc, MMC_CLKRT, SDClockTable[ii].ControlValue);
}
///////////////////////////////////////////////////////////////////////////////
// SDClockOn - turn on the MMC Clock
// Input: pHc - hardware context
// Output:
// Return:
// Notes:
//
//
///////////////////////////////////////////////////////////////////////////////
VOID SDClockOn(PSDH_HARDWARE_CONTEXT pHc)
{
// turn on the clock
WRITE_MMC_REGISTER_DWORD(pHc, MMC_STRPCL, MMC_STRPCL_START_CLOCK);
}
///////////////////////////////////////////////////////////////////////////////
// SDDeInitialize - Deinitialize the the MMC Controller
// Input: pHCContext - Host controller context
//
// Output:
// Return: SD_API_STATUS code
// Notes:
//
//
///////////////////////////////////////////////////////////////////////////////
SD_API_STATUS SDDeinitialize(PSDCARD_HC_CONTEXT pHCContext)
{
PSDH_HARDWARE_CONTEXT pHardwareContext; // hardware context
pHardwareContext = GetExtensionFromHCDContext(PSDH_HARDWARE_CONTEXT, pHCContext);
// make sure all interrupt sources are disabled
InterruptDisable (pHardwareContext->dwSysintrSDMMC);
// mark for shutdown
pHardwareContext->DriverShutdown = TRUE;
// clean up card insertion IST and free card insertion interrupt
CleanupCardDetectIST();
// clean up controller IST
if (NULL != pHardwareContext->hControllerInterruptThread) {
// wake up the IST
SetEvent(pHardwareContext->hControllerInterruptEvent);
// wait for the thread to exit
WaitForSingleObject(pHardwareContext->hControllerInterruptThread, INFINITE);
CloseHandle(pHardwareContext->hControllerInterruptThread);
pHardwareContext->hControllerInterruptThread = NULL;
}
// free controller interrupt event
if (NULL != pHardwareContext->hControllerInterruptEvent) {
CloseHandle(pHardwareContext->hControllerInterruptEvent);
pHardwareContext->hControllerInterruptEvent = NULL;
}
// free memory mapped resources
if (NULL != pHardwareContext->pSDMMCRegisters) {
MmUnmapIoSpace((PVOID)pHardwareContext->pSDMMCRegisters, sizeof(BULVERDE_MMC_REG));
pHardwareContext->pSDMMCRegisters = NULL;
}
if (NULL != pHardwareContext->pGPIORegisters) {
MmUnmapIoSpace((PVOID)pHardwareContext->pGPIORegisters, sizeof(BULVERDE_GPIO_REG));
pHardwareContext->pGPIORegisters = NULL;
}
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