pi1541/uspi/lib/dwhcidevice.c
2018-05-20 14:53:34 +10:00

1445 lines
41 KiB
C

//
// dwhcidevice.c
//
// Supports:
// internal DMA only,
// no ISO transfers
// no dynamic attachments
//
// USPi - An USB driver for Raspberry Pi written in C
// Copyright (C) 2014-2017 R. Stange <rsta2@o2online.de>
//
// 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 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
//
#include <uspi/dwhcidevice.h>
#include <uspios.h>
#include <uspi/bcm2835.h>
#include <uspi/synchronize.h>
#include <uspi/assert.h>
#define ARM_IRQ_USB 9 // for ConnectInterrupt()
#define DEVICE_ID_USB_HCD 3 // for SetPowerStateOn()
//
// Configuration
//
#define DWC_CFG_DYNAMIC_FIFO // re-program FIFOs with these sizes:
#define DWC_CFG_HOST_RX_FIFO_SIZE 1024 // number of 32 bit words
#define DWC_CFG_HOST_NPER_TX_FIFO_SIZE 1024 // number of 32 bit words
#define DWC_CFG_HOST_PER_TX_FIFO_SIZE 1024 // number of 32 bit words
#define MSEC2HZ(msec) ((msec) * HZ / 1000)
typedef enum
{
StageStateNoSplitTransfer,
StageStateStartSplit,
StageStateCompleteSplit,
StageStatePeriodicDelay,
StageStateUnknown
}
TStageState;
typedef enum
{
StageSubStateWaitForChannelDisable,
StageSubStateWaitForTransactionComplete,
StageSubStateUnknown
}
TStageSubState;
static const char FromDWHCI[] = "dwhci";
boolean DWHCIDeviceInitCore (TDWHCIDevice *pThis);
boolean DWHCIDeviceInitHost (TDWHCIDevice *pThis);
boolean DWHCIDeviceEnableRootPort (TDWHCIDevice *pThis);
boolean DWHCIDeviceReset (TDWHCIDevice *pThis);
void DWHCIDeviceEnableGlobalInterrupts (TDWHCIDevice *pThis);
void DWHCIDeviceEnableCommonInterrupts (TDWHCIDevice *pThis);
void DWHCIDeviceEnableHostInterrupts (TDWHCIDevice *pThis);
void DWHCIDeviceEnableChannelInterrupt (TDWHCIDevice *pThis, unsigned nChannel);
void DWHCIDeviceDisableChannelInterrupt (TDWHCIDevice *pThis, unsigned nChannel);
void DWHCIDeviceFlushTxFIFO (TDWHCIDevice *pThis, unsigned nFIFO);
void DWHCIDeviceFlushRxFIFO (TDWHCIDevice *pThis);
boolean DWHCIDeviceTransferStage (TDWHCIDevice *pThis, TUSBRequest *pURB, boolean bIn, boolean bStatusStage);
void DWHCIDeviceCompletionRoutine (TUSBRequest *pURB, void *pParam, void *pContext);
boolean DWHCIDeviceTransferStageAsync (TDWHCIDevice *pThis, TUSBRequest *pURB, boolean bIn, boolean bStatusStage);
void DWHCIDeviceStartTransaction (TDWHCIDevice *pThis, TDWHCITransferStageData *pStageData);
void DWHCIDeviceStartChannel (TDWHCIDevice *pThis, TDWHCITransferStageData *pStageData);
void DWHCIDeviceChannelInterruptHandler (TDWHCIDevice *pThis, unsigned nChannel);
void DWHCIDeviceInterruptHandler (void *pParam);
void DWHCIDeviceTimerHandler (unsigned hTimer, void *pParam, void *pContext);
unsigned DWHCIDeviceAllocateChannel (TDWHCIDevice *pThis);
void DWHCIDeviceFreeChannel (TDWHCIDevice *pThis, unsigned nChannel);
boolean DWHCIDeviceWaitForBit (TDWHCIDevice *pThis, TDWHCIRegister *pRegister, u32 nMask,boolean bWaitUntilSet, unsigned nMsTimeout);
#ifndef NDEBUG
void DWHCIDeviceDumpRegister (TDWHCIDevice *pThis, const char *pName, u32 nAddress);
void DWHCIDeviceDumpStatus (TDWHCIDevice *pThis, unsigned nChannel /* = 0 */);
#endif
void DWHCIDevice (TDWHCIDevice *pThis)
{
assert (pThis != 0);
pThis->m_nChannels = 0;
pThis->m_nChannelAllocated = 0;
pThis->m_bWaiting = FALSE;
DWHCIRootPort (&pThis->m_RootPort, pThis);
for (unsigned nChannel = 0; nChannel < DWHCI_MAX_CHANNELS; nChannel++)
{
pThis->m_pStageData[nChannel] = 0;
}
}
void _DWHCIDevice (TDWHCIDevice *pThis)
{
_DWHCIRootPort (&pThis->m_RootPort);
}
boolean DWHCIDeviceInitialize (TDWHCIDevice *pThis)
{
assert (pThis != 0);
DataMemBarrier ();
TDWHCIRegister VendorId;
DWHCIRegister (&VendorId, DWHCI_CORE_VENDOR_ID);
if (DWHCIRegisterRead (&VendorId) != 0x4F54280A)
{
LogWrite (FromDWHCI, LOG_ERROR, "Unknown vendor 0x%0X", DWHCIRegisterGet (&VendorId));
_DWHCIRegister (&VendorId);
return FALSE;
}
if (!SetPowerStateOn (DEVICE_ID_USB_HCD))
{
LogWrite (FromDWHCI, LOG_ERROR, "Cannot power on");
_DWHCIRegister (&VendorId);
return FALSE;
}
// Disable all interrupts
TDWHCIRegister AHBConfig;
DWHCIRegister (&AHBConfig, DWHCI_CORE_AHB_CFG);
DWHCIRegisterRead (&AHBConfig);
DWHCIRegisterAnd (&AHBConfig, ~DWHCI_CORE_AHB_CFG_GLOBALINT_MASK);
DWHCIRegisterWrite (&AHBConfig);
ConnectInterrupt (ARM_IRQ_USB, DWHCIDeviceInterruptHandler, pThis);
if (!DWHCIDeviceInitCore (pThis))
{
LogWrite (FromDWHCI, LOG_ERROR, "Cannot initialize core");
_DWHCIRegister (&AHBConfig);
_DWHCIRegister (&VendorId);
return FALSE;
}
DWHCIDeviceEnableGlobalInterrupts (pThis);
if (!DWHCIDeviceInitHost (pThis))
{
LogWrite (FromDWHCI, LOG_ERROR, "Cannot initialize host");
_DWHCIRegister (&AHBConfig);
_DWHCIRegister (&VendorId);
return FALSE;
}
// The following calls will fail if there is no device or no supported device connected
// to root port. This is not an error because the system may run without an USB device.
if (!DWHCIDeviceEnableRootPort (pThis))
{
LogWrite (FromDWHCI, LOG_WARNING, "No device connected to root port");
_DWHCIRegister (&AHBConfig);
_DWHCIRegister (&VendorId);
return TRUE;
}
if (!DWHCIRootPortInitialize (&pThis->m_RootPort))
{
LogWrite (FromDWHCI, LOG_WARNING, "Cannot initialize root port");
_DWHCIRegister (&AHBConfig);
_DWHCIRegister (&VendorId);
return TRUE;
}
DataMemBarrier ();
_DWHCIRegister (&AHBConfig);
_DWHCIRegister (&VendorId);
return TRUE;
}
int DWHCIDeviceGetDescriptor (TDWHCIDevice *pThis, TUSBEndpoint *pEndpoint,
unsigned char ucType, unsigned char ucIndex,
void *pBuffer, unsigned nBufSize,
unsigned char ucRequestType)
{
assert (pThis != 0);
return DWHCIDeviceControlMessage (pThis, pEndpoint,
ucRequestType, GET_DESCRIPTOR,
(ucType << 8) | ucIndex, 0,
pBuffer, nBufSize);
}
boolean DWHCIDeviceSetAddress (TDWHCIDevice *pThis, TUSBEndpoint *pEndpoint, u8 ucDeviceAddress)
{
assert (pThis != 0);
if (DWHCIDeviceControlMessage (pThis, pEndpoint, REQUEST_OUT, SET_ADDRESS, ucDeviceAddress, 0, 0, 0) < 0)
{
return FALSE;
}
MsDelay (50); // see USB 2.0 spec (tDSETADDR)
return TRUE;
}
boolean DWHCIDeviceSetConfiguration (TDWHCIDevice *pThis, TUSBEndpoint *pEndpoint, u8 ucConfigurationValue)
{
assert (pThis != 0);
if (DWHCIDeviceControlMessage (pThis, pEndpoint, REQUEST_OUT, SET_CONFIGURATION, ucConfigurationValue, 0, 0, 0) < 0)
{
return FALSE;
}
MsDelay (50);
return TRUE;
}
int DWHCIDeviceControlMessage (TDWHCIDevice *pThis, TUSBEndpoint *pEndpoint,
u8 ucRequestType, u8 ucRequest, u16 usValue, u16 usIndex,
void *pData, u16 usDataSize)
{
assert (pThis != 0);
TSetupData *pSetup = (TSetupData *) malloc (sizeof (TSetupData));
assert (pSetup != 0);
pSetup->bmRequestType = ucRequestType;
pSetup->bRequest = ucRequest;
pSetup->wValue = usValue;
pSetup->wIndex = usIndex;
pSetup->wLength = usDataSize;
TUSBRequest URB;
USBRequest (&URB, pEndpoint, pData, usDataSize, pSetup);
int nResult = -1;
if (DWHCIDeviceSubmitBlockingRequest (pThis, &URB))
{
nResult = USBRequestGetResultLength (&URB);
}
free (pSetup);
_USBRequest (&URB);
return nResult;
}
int DWHCIDeviceTransfer (TDWHCIDevice *pThis, TUSBEndpoint *pEndpoint, void *pBuffer, unsigned nBufSize)
{
assert (pThis != 0);
TUSBRequest URB;
USBRequest (&URB, pEndpoint, pBuffer, nBufSize, 0);
int nResult = -1;
if (DWHCIDeviceSubmitBlockingRequest (pThis, &URB))
{
nResult = USBRequestGetResultLength (&URB);
}
_USBRequest (&URB);
return nResult;
}
boolean DWHCIDeviceSubmitBlockingRequest (TDWHCIDevice *pThis, TUSBRequest *pURB)
{
assert (pThis != 0);
DataMemBarrier ();
assert (pURB != 0);
USBRequestSetStatus (pURB, 0);
if (USBEndpointGetType (USBRequestGetEndpoint (pURB)) == EndpointTypeControl)
{
TSetupData *pSetup = USBRequestGetSetupData (pURB);
assert (pSetup != 0);
if (pSetup->bmRequestType & REQUEST_IN)
{
assert (USBRequestGetBufLen (pURB) > 0);
if ( !DWHCIDeviceTransferStage (pThis, pURB, FALSE, FALSE)
|| !DWHCIDeviceTransferStage (pThis, pURB, TRUE, FALSE)
|| !DWHCIDeviceTransferStage (pThis, pURB, FALSE, TRUE))
{
return FALSE;
}
}
else
{
if (USBRequestGetBufLen (pURB) == 0)
{
if ( !DWHCIDeviceTransferStage (pThis, pURB, FALSE, FALSE)
|| !DWHCIDeviceTransferStage (pThis, pURB, TRUE, TRUE))
{
return FALSE;
}
}
else
{
if ( !DWHCIDeviceTransferStage (pThis, pURB, FALSE, FALSE)
|| !DWHCIDeviceTransferStage (pThis, pURB, FALSE, FALSE)
|| !DWHCIDeviceTransferStage (pThis, pURB, TRUE, TRUE))
{
return FALSE;
}
}
}
}
else
{
assert ( USBEndpointGetType (USBRequestGetEndpoint (pURB)) == EndpointTypeBulk
|| USBEndpointGetType (USBRequestGetEndpoint (pURB)) == EndpointTypeInterrupt);
assert (USBRequestGetBufLen (pURB) > 0);
if (!DWHCIDeviceTransferStage (pThis, pURB, USBEndpointIsDirectionIn (USBRequestGetEndpoint (pURB)), FALSE))
{
return FALSE;
}
}
DataMemBarrier ();
return TRUE;
}
boolean DWHCIDeviceSubmitAsyncRequest (TDWHCIDevice *pThis, TUSBRequest *pURB)
{
assert (pThis != 0);
DataMemBarrier ();
assert (pURB != 0);
assert ( USBEndpointGetType (USBRequestGetEndpoint (pURB)) == EndpointTypeBulk
|| USBEndpointGetType (USBRequestGetEndpoint (pURB)) == EndpointTypeInterrupt);
assert (USBRequestGetBufLen (pURB) > 0);
USBRequestSetStatus (pURB, 0);
boolean bOK = DWHCIDeviceTransferStageAsync (pThis, pURB, USBEndpointIsDirectionIn (USBRequestGetEndpoint (pURB)), FALSE);
DataMemBarrier ();
return bOK;
}
boolean DWHCIDeviceInitCore (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister USBConfig;
DWHCIRegister (&USBConfig, DWHCI_CORE_USB_CFG);
DWHCIRegisterRead (&USBConfig);
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_ULPI_EXT_VBUS_DRV);
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_TERM_SEL_DL_PULSE);
DWHCIRegisterWrite (&USBConfig);
if (!DWHCIDeviceReset (pThis))
{
LogWrite (FromDWHCI, LOG_ERROR, "Reset failed");
return FALSE;
}
DWHCIRegisterRead (&USBConfig);
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_ULPI_UTMI_SEL); // select UTMI+
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_PHYIF); // UTMI width is 8
DWHCIRegisterWrite (&USBConfig);
// Internal DMA mode only
TDWHCIRegister HWConfig2;
DWHCIRegister (&HWConfig2, DWHCI_CORE_HW_CFG2);
DWHCIRegisterRead (&HWConfig2);
assert (DWHCI_CORE_HW_CFG2_ARCHITECTURE (DWHCIRegisterGet (&HWConfig2)) == 2);
DWHCIRegisterRead (&USBConfig);
if ( DWHCI_CORE_HW_CFG2_HS_PHY_TYPE (DWHCIRegisterGet (&HWConfig2)) == DWHCI_CORE_HW_CFG2_HS_PHY_TYPE_ULPI
&& DWHCI_CORE_HW_CFG2_FS_PHY_TYPE (DWHCIRegisterGet (&HWConfig2)) == DWHCI_CORE_HW_CFG2_FS_PHY_TYPE_DEDICATED)
{
DWHCIRegisterOr (&USBConfig, DWHCI_CORE_USB_CFG_ULPI_FSLS);
DWHCIRegisterOr (&USBConfig, DWHCI_CORE_USB_CFG_ULPI_CLK_SUS_M);
}
else
{
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_ULPI_FSLS);
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_ULPI_CLK_SUS_M);
}
DWHCIRegisterWrite (&USBConfig);
assert (pThis->m_nChannels == 0);
pThis->m_nChannels = DWHCI_CORE_HW_CFG2_NUM_HOST_CHANNELS (DWHCIRegisterGet (&HWConfig2));
assert (4 <= pThis->m_nChannels && pThis->m_nChannels <= DWHCI_MAX_CHANNELS);
TDWHCIRegister AHBConfig;
DWHCIRegister (&AHBConfig, DWHCI_CORE_AHB_CFG);
DWHCIRegisterRead (&AHBConfig);
DWHCIRegisterOr (&AHBConfig, DWHCI_CORE_AHB_CFG_DMAENABLE);
//DWHCIRegisterOr (&AHBConfig, DWHCI_CORE_AHB_CFG_AHB_SINGLE); // if DMA single mode should be used
DWHCIRegisterOr (&AHBConfig, DWHCI_CORE_AHB_CFG_WAIT_AXI_WRITES);
DWHCIRegisterAnd (&AHBConfig, ~DWHCI_CORE_AHB_CFG_MAX_AXI_BURST__MASK);
//DWHCIRegisterOr (&AHBConfig, 0 << DWHCI_CORE_AHB_CFG_MAX_AXI_BURST__SHIFT); // max. AXI burst length 4
DWHCIRegisterWrite (&AHBConfig);
// HNP and SRP are not used
DWHCIRegisterRead (&USBConfig);
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_HNP_CAPABLE);
DWHCIRegisterAnd (&USBConfig, ~DWHCI_CORE_USB_CFG_SRP_CAPABLE);
DWHCIRegisterWrite (&USBConfig);
DWHCIDeviceEnableCommonInterrupts (pThis);
_DWHCIRegister (&AHBConfig);
_DWHCIRegister (&HWConfig2);
_DWHCIRegister (&USBConfig);
return TRUE;
}
boolean DWHCIDeviceInitHost (TDWHCIDevice *pThis)
{
assert (pThis != 0);
// Restart the PHY clock
TDWHCIRegister Power;
DWHCIRegister2 (&Power, ARM_USB_POWER, 0);
DWHCIRegisterWrite (&Power);
TDWHCIRegister HostConfig;
DWHCIRegister (&HostConfig, DWHCI_HOST_CFG);
DWHCIRegisterRead (&HostConfig);
DWHCIRegisterAnd (&HostConfig, ~DWHCI_HOST_CFG_FSLS_PCLK_SEL__MASK);
TDWHCIRegister HWConfig2;
DWHCIRegister (&HWConfig2, DWHCI_CORE_HW_CFG2);
TDWHCIRegister USBConfig;
DWHCIRegister (&USBConfig, DWHCI_CORE_USB_CFG);
if ( DWHCI_CORE_HW_CFG2_HS_PHY_TYPE (DWHCIRegisterRead (&HWConfig2)) == DWHCI_CORE_HW_CFG2_HS_PHY_TYPE_ULPI
&& DWHCI_CORE_HW_CFG2_FS_PHY_TYPE (DWHCIRegisterGet (&HWConfig2)) == DWHCI_CORE_HW_CFG2_FS_PHY_TYPE_DEDICATED
&& (DWHCIRegisterRead (&USBConfig) & DWHCI_CORE_USB_CFG_ULPI_FSLS))
{
DWHCIRegisterOr (&HostConfig, DWHCI_HOST_CFG_FSLS_PCLK_SEL_48_MHZ);
}
else
{
DWHCIRegisterOr (&HostConfig, DWHCI_HOST_CFG_FSLS_PCLK_SEL_30_60_MHZ);
}
DWHCIRegisterWrite (&HostConfig);
#ifdef DWC_CFG_DYNAMIC_FIFO
TDWHCIRegister RxFIFOSize;
DWHCIRegister2 (&RxFIFOSize, DWHCI_CORE_RX_FIFO_SIZ, DWC_CFG_HOST_RX_FIFO_SIZE);
DWHCIRegisterWrite (&RxFIFOSize);
TDWHCIRegister NonPeriodicTxFIFOSize;
DWHCIRegister2 (&NonPeriodicTxFIFOSize, DWHCI_CORE_NPER_TX_FIFO_SIZ, 0);
DWHCIRegisterOr (&NonPeriodicTxFIFOSize, DWC_CFG_HOST_RX_FIFO_SIZE);
DWHCIRegisterOr (&NonPeriodicTxFIFOSize, DWC_CFG_HOST_NPER_TX_FIFO_SIZE << 16);
DWHCIRegisterWrite (&NonPeriodicTxFIFOSize);
TDWHCIRegister HostPeriodicTxFIFOSize;
DWHCIRegister2 (&HostPeriodicTxFIFOSize, DWHCI_CORE_HOST_PER_TX_FIFO_SIZ, 0);
DWHCIRegisterOr (&HostPeriodicTxFIFOSize, DWC_CFG_HOST_RX_FIFO_SIZE + DWC_CFG_HOST_NPER_TX_FIFO_SIZE);
DWHCIRegisterOr (&HostPeriodicTxFIFOSize, DWC_CFG_HOST_PER_TX_FIFO_SIZE << 16);
DWHCIRegisterWrite (&HostPeriodicTxFIFOSize);
#endif
DWHCIDeviceFlushTxFIFO (pThis, 0x10); // Flush all TX FIFOs
DWHCIDeviceFlushRxFIFO (pThis);
TDWHCIRegister HostPort;
DWHCIRegister (&HostPort, DWHCI_HOST_PORT);
DWHCIRegisterRead (&HostPort);
DWHCIRegisterAnd (&HostPort, ~DWHCI_HOST_PORT_DEFAULT_MASK);
if (!(DWHCIRegisterGet (&HostPort) & DWHCI_HOST_PORT_POWER))
{
DWHCIRegisterOr (&HostPort, DWHCI_HOST_PORT_POWER);
DWHCIRegisterWrite (&HostPort);
}
DWHCIDeviceEnableHostInterrupts (pThis);
_DWHCIRegister (&HostPort);
#ifdef DWC_CFG_DYNAMIC_FIFO
_DWHCIRegister (&HostPeriodicTxFIFOSize);
_DWHCIRegister (&NonPeriodicTxFIFOSize);
_DWHCIRegister (&RxFIFOSize);
#endif
_DWHCIRegister (&USBConfig);
_DWHCIRegister (&HWConfig2);
_DWHCIRegister (&HostConfig);
_DWHCIRegister (&Power);
return TRUE;
}
boolean DWHCIDeviceEnableRootPort (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister HostPort;
DWHCIRegister (&HostPort, DWHCI_HOST_PORT);
if (!DWHCIDeviceWaitForBit (pThis, &HostPort, DWHCI_HOST_PORT_CONNECT, TRUE, 20))
{
_DWHCIRegister (&HostPort);
return FALSE;
}
MsDelay (100); // see USB 2.0 spec
DWHCIRegisterRead (&HostPort);
DWHCIRegisterAnd (&HostPort, ~DWHCI_HOST_PORT_DEFAULT_MASK);
DWHCIRegisterOr (&HostPort, DWHCI_HOST_PORT_RESET);
DWHCIRegisterWrite (&HostPort);
MsDelay (50); // see USB 2.0 spec (tDRSTR)
DWHCIRegisterRead (&HostPort);
DWHCIRegisterAnd (&HostPort, ~DWHCI_HOST_PORT_DEFAULT_MASK);
DWHCIRegisterAnd (&HostPort, ~DWHCI_HOST_PORT_RESET);
DWHCIRegisterWrite (&HostPort);
// normally 10ms, seems to be too short for some devices
MsDelay (20); // see USB 2.0 spec (tRSTRCY)
_DWHCIRegister (&HostPort);
return TRUE;
}
boolean DWHCIDeviceReset (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister Reset;
DWHCIRegister2 (&Reset, DWHCI_CORE_RESET, 0);
// wait for AHB master IDLE state
if (!DWHCIDeviceWaitForBit (pThis, &Reset, DWHCI_CORE_RESET_AHB_IDLE, TRUE, 100))
{
_DWHCIRegister (&Reset);
return FALSE;
}
// core soft reset
DWHCIRegisterOr (&Reset, DWHCI_CORE_RESET_SOFT_RESET);
DWHCIRegisterWrite (&Reset);
if (!DWHCIDeviceWaitForBit (pThis, &Reset, DWHCI_CORE_RESET_SOFT_RESET, FALSE, 10))
{
_DWHCIRegister (&Reset);
return FALSE;
}
MsDelay (100);
_DWHCIRegister (&Reset);
return TRUE;
}
void DWHCIDeviceEnableGlobalInterrupts (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister AHBConfig;
DWHCIRegister (&AHBConfig, DWHCI_CORE_AHB_CFG);
DWHCIRegisterRead (&AHBConfig);
DWHCIRegisterOr (&AHBConfig, DWHCI_CORE_AHB_CFG_GLOBALINT_MASK);
DWHCIRegisterWrite (&AHBConfig);
_DWHCIRegister (&AHBConfig);
}
void DWHCIDeviceEnableCommonInterrupts (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister IntStatus;
DWHCIRegister (&IntStatus, DWHCI_CORE_INT_STAT); // Clear any pending interrupts
DWHCIRegisterSetAll (&IntStatus);
DWHCIRegisterWrite (&IntStatus);
#if 0 // not used
TDWHCIRegister IntMask;
DWHCIRegister2 (&IntMask, DWHCI_CORE_INT_MASK, DWHCI_CORE_INT_MASK_MODE_MISMATCH
| DWHCI_CORE_INT_MASK_USB_SUSPEND
| DWHCI_CORE_INT_MASK_CON_ID_STS_CHNG
| DWHCI_CORE_INT_MASK_SESS_REQ_INTR
| DWHCI_CORE_INT_MASK_WKUP_INTR);
DWHCIRegisterWrite (&IntMask);
_DWHCIRegister (&IntMask);
#endif
_DWHCIRegister (&IntStatus);
}
void DWHCIDeviceEnableHostInterrupts (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister IntMask;
DWHCIRegister2 (&IntMask, DWHCI_CORE_INT_MASK, 0);
DWHCIRegisterWrite (&IntMask); // Disable all interrupts
DWHCIDeviceEnableCommonInterrupts (pThis);
DWHCIRegisterRead (&IntMask);
DWHCIRegisterOr (&IntMask, DWHCI_CORE_INT_MASK_HC_INTR
//| DWHCI_CORE_INT_MASK_PORT_INTR
//| DWHCI_CORE_INT_MASK_DISCONNECT
);
DWHCIRegisterWrite (&IntMask);
_DWHCIRegister (&IntMask);
}
void DWHCIDeviceEnableChannelInterrupt (TDWHCIDevice *pThis, unsigned nChannel)
{
assert (pThis != 0);
TDWHCIRegister AllChanInterruptMask;
DWHCIRegister (&AllChanInterruptMask, DWHCI_HOST_ALLCHAN_INT_MASK);
uspi_EnterCritical ();
DWHCIRegisterRead (&AllChanInterruptMask);
DWHCIRegisterOr (&AllChanInterruptMask, 1 << nChannel);
DWHCIRegisterWrite (&AllChanInterruptMask);
uspi_LeaveCritical ();
_DWHCIRegister (&AllChanInterruptMask);
}
void DWHCIDeviceDisableChannelInterrupt (TDWHCIDevice *pThis, unsigned nChannel)
{
assert (pThis != 0);
TDWHCIRegister AllChanInterruptMask;
DWHCIRegister (&AllChanInterruptMask, DWHCI_HOST_ALLCHAN_INT_MASK);
uspi_EnterCritical ();
DWHCIRegisterRead (&AllChanInterruptMask);
DWHCIRegisterAnd (&AllChanInterruptMask, ~(1 << nChannel));
DWHCIRegisterWrite (&AllChanInterruptMask);
uspi_LeaveCritical ();
_DWHCIRegister (&AllChanInterruptMask);
}
void DWHCIDeviceFlushTxFIFO (TDWHCIDevice *pThis, unsigned nFIFO)
{
assert (pThis != 0);
TDWHCIRegister Reset;
DWHCIRegister2 (&Reset, DWHCI_CORE_RESET, 0);
DWHCIRegisterOr (&Reset, DWHCI_CORE_RESET_TX_FIFO_FLUSH);
DWHCIRegisterAnd (&Reset, ~DWHCI_CORE_RESET_TX_FIFO_NUM__MASK);
DWHCIRegisterOr (&Reset, nFIFO << DWHCI_CORE_RESET_TX_FIFO_NUM__SHIFT);
DWHCIRegisterWrite (&Reset);
if (DWHCIDeviceWaitForBit (pThis, &Reset, DWHCI_CORE_RESET_TX_FIFO_FLUSH, FALSE, 10))
{
usDelay (1); // Wait for 3 PHY clocks
}
_DWHCIRegister (&Reset);
}
void DWHCIDeviceFlushRxFIFO (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister Reset;
DWHCIRegister2 (&Reset, DWHCI_CORE_RESET, 0);
DWHCIRegisterOr (&Reset, DWHCI_CORE_RESET_RX_FIFO_FLUSH);
DWHCIRegisterWrite (&Reset);
if (DWHCIDeviceWaitForBit (pThis, &Reset, DWHCI_CORE_RESET_RX_FIFO_FLUSH, FALSE, 10))
{
usDelay (1); // Wait for 3 PHY clocks
}
_DWHCIRegister (&Reset);
}
boolean DWHCIDeviceTransferStage (TDWHCIDevice *pThis, TUSBRequest *pURB, boolean bIn, boolean bStatusStage)
{
assert (pThis != 0);
assert (pURB != 0);
USBRequestSetCompletionRoutine (pURB, DWHCIDeviceCompletionRoutine, 0, pThis);
assert (!pThis->m_bWaiting);
pThis->m_bWaiting = TRUE;
if (!DWHCIDeviceTransferStageAsync (pThis, pURB, bIn, bStatusStage))
{
pThis->m_bWaiting = FALSE;
return FALSE;
}
while (pThis->m_bWaiting)
{
// do nothing
}
return USBRequestGetStatus (pURB);
}
void DWHCIDeviceCompletionRoutine (TUSBRequest *pURB, void *pParam, void *pContext)
{
TDWHCIDevice *pThis = (TDWHCIDevice *) pContext;
assert (pThis != 0);
pThis->m_bWaiting = FALSE;
}
boolean DWHCIDeviceTransferStageAsync (TDWHCIDevice *pThis, TUSBRequest *pURB, boolean bIn, boolean bStatusStage)
{
assert (pThis != 0);
assert (pURB != 0);
unsigned nChannel = DWHCIDeviceAllocateChannel (pThis);
if (nChannel >= pThis->m_nChannels)
{
return FALSE;
}
TDWHCITransferStageData *pStageData =
(TDWHCITransferStageData *) malloc (sizeof (TDWHCITransferStageData));
assert (pStageData != 0);
DWHCITransferStageData (pStageData, nChannel, pURB, bIn, bStatusStage);
assert (pThis->m_pStageData[nChannel] == 0);
pThis->m_pStageData[nChannel] = pStageData;
DWHCIDeviceEnableChannelInterrupt (pThis, nChannel);
if (!DWHCITransferStageDataIsSplit (pStageData))
{
DWHCITransferStageDataSetState (pStageData, StageStateNoSplitTransfer);
}
else
{
if (!DWHCITransferStageDataBeginSplitCycle (pStageData))
{
DWHCIDeviceDisableChannelInterrupt (pThis, nChannel);
_DWHCITransferStageData (pStageData);
free (pStageData);
pThis->m_pStageData[nChannel] = 0;
DWHCIDeviceFreeChannel (pThis, nChannel);
return FALSE;
}
DWHCITransferStageDataSetState (pStageData, StageStateStartSplit);
DWHCITransferStageDataSetSplitComplete (pStageData, FALSE);
TDWHCIFrameScheduler *pFrameScheduler =
DWHCITransferStageDataGetFrameScheduler (pStageData);
assert (pFrameScheduler != 0);
pFrameScheduler->StartSplit (pFrameScheduler);
}
DWHCIDeviceStartTransaction (pThis, pStageData);
return TRUE;
}
void DWHCIDeviceStartTransaction (TDWHCIDevice *pThis, TDWHCITransferStageData *pStageData)
{
assert (pThis != 0);
assert (pStageData != 0);
unsigned nChannel = DWHCITransferStageDataGetChannelNumber (pStageData);
assert (nChannel < pThis->m_nChannels);
// channel must be disabled, if not already done but controller
TDWHCIRegister Character;
DWHCIRegister (&Character, DWHCI_HOST_CHAN_CHARACTER (nChannel));
DWHCIRegisterRead (&Character);
if (DWHCIRegisterIsSet (&Character, DWHCI_HOST_CHAN_CHARACTER_ENABLE))
{
DWHCITransferStageDataSetSubState (pStageData, StageSubStateWaitForChannelDisable);
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_ENABLE);
DWHCIRegisterOr (&Character, DWHCI_HOST_CHAN_CHARACTER_DISABLE);
DWHCIRegisterWrite (&Character);
TDWHCIRegister ChanInterruptMask;
DWHCIRegister (&ChanInterruptMask, DWHCI_HOST_CHAN_INT_MASK (nChannel));
DWHCIRegisterSet (&ChanInterruptMask, DWHCI_HOST_CHAN_INT_HALTED);
DWHCIRegisterWrite (&ChanInterruptMask);
_DWHCIRegister (&ChanInterruptMask);
}
else
{
DWHCIDeviceStartChannel (pThis, pStageData);
}
_DWHCIRegister (&Character);
}
void DWHCIDeviceStartChannel (TDWHCIDevice *pThis, TDWHCITransferStageData *pStageData)
{
assert (pThis != 0);
assert (pStageData != 0);
unsigned nChannel = DWHCITransferStageDataGetChannelNumber (pStageData);
assert (nChannel < pThis->m_nChannels);
DWHCITransferStageDataSetSubState (pStageData, StageSubStateWaitForTransactionComplete);
// reset all pending channel interrupts
TDWHCIRegister ChanInterrupt;
DWHCIRegister (&ChanInterrupt, DWHCI_HOST_CHAN_INT (nChannel));
DWHCIRegisterSetAll (&ChanInterrupt);
DWHCIRegisterWrite (&ChanInterrupt);
// set transfer size, packet count and pid
TDWHCIRegister TransferSize;
DWHCIRegister2 (&TransferSize, DWHCI_HOST_CHAN_XFER_SIZ (nChannel), 0);
DWHCIRegisterOr (&TransferSize, DWHCITransferStageDataGetBytesToTransfer (pStageData) & DWHCI_HOST_CHAN_XFER_SIZ_BYTES__MASK);
DWHCIRegisterOr (&TransferSize, (DWHCITransferStageDataGetPacketsToTransfer (pStageData) << DWHCI_HOST_CHAN_XFER_SIZ_PACKETS__SHIFT)
& DWHCI_HOST_CHAN_XFER_SIZ_PACKETS__MASK);
DWHCIRegisterOr (&TransferSize, DWHCITransferStageDataGetPID (pStageData) << DWHCI_HOST_CHAN_XFER_SIZ_PID__SHIFT);
DWHCIRegisterWrite (&TransferSize);
// set DMA address
TDWHCIRegister DMAAddress;
DWHCIRegister2 (&DMAAddress, DWHCI_HOST_CHAN_DMA_ADDR (nChannel),
BUS_ADDRESS (DWHCITransferStageDataGetDMAAddress (pStageData)));
DWHCIRegisterWrite (&DMAAddress);
uspi_CleanAndInvalidateDataCacheRange (DWHCITransferStageDataGetDMAAddress (pStageData),
DWHCITransferStageDataGetBytesToTransfer (pStageData));
DataMemBarrier ();
// set split control
TDWHCIRegister SplitControl;
DWHCIRegister2 (&SplitControl, DWHCI_HOST_CHAN_SPLIT_CTRL (nChannel), 0);
if (DWHCITransferStageDataIsSplit (pStageData))
{
DWHCIRegisterOr (&SplitControl, DWHCITransferStageDataGetHubPortAddress (pStageData));
DWHCIRegisterOr (&SplitControl, DWHCITransferStageDataGetHubAddress (pStageData)
<< DWHCI_HOST_CHAN_SPLIT_CTRL_HUB_ADDRESS__SHIFT);
DWHCIRegisterOr (&SplitControl, DWHCITransferStageDataGetSplitPosition (pStageData)
<< DWHCI_HOST_CHAN_SPLIT_CTRL_XACT_POS__SHIFT);
if (DWHCITransferStageDataIsSplitComplete (pStageData))
{
DWHCIRegisterOr (&SplitControl, DWHCI_HOST_CHAN_SPLIT_CTRL_COMPLETE_SPLIT);
}
DWHCIRegisterOr (&SplitControl, DWHCI_HOST_CHAN_SPLIT_CTRL_SPLIT_ENABLE);
}
DWHCIRegisterWrite (&SplitControl);
// set channel parameters
TDWHCIRegister Character;
DWHCIRegister (&Character, DWHCI_HOST_CHAN_CHARACTER (nChannel));
DWHCIRegisterRead (&Character);
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_MAX_PKT_SIZ__MASK);
DWHCIRegisterOr (&Character, DWHCITransferStageDataGetMaxPacketSize (pStageData) & DWHCI_HOST_CHAN_CHARACTER_MAX_PKT_SIZ__MASK);
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_MULTI_CNT__MASK);
DWHCIRegisterOr (&Character, 1 << DWHCI_HOST_CHAN_CHARACTER_MULTI_CNT__SHIFT); // TODO: optimize
if (DWHCITransferStageDataIsDirectionIn (pStageData))
{
DWHCIRegisterOr (&Character, DWHCI_HOST_CHAN_CHARACTER_EP_DIRECTION_IN);
}
else
{
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_EP_DIRECTION_IN);
}
if (DWHCITransferStageDataGetSpeed (pStageData) == USBSpeedLow)
{
DWHCIRegisterOr (&Character, DWHCI_HOST_CHAN_CHARACTER_LOW_SPEED_DEVICE);
}
else
{
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_LOW_SPEED_DEVICE);
}
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_DEVICE_ADDRESS__MASK);
DWHCIRegisterOr (&Character, DWHCITransferStageDataGetDeviceAddress (pStageData) << DWHCI_HOST_CHAN_CHARACTER_DEVICE_ADDRESS__SHIFT);
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_EP_TYPE__MASK);
DWHCIRegisterOr (&Character, DWHCITransferStageDataGetEndpointType (pStageData) << DWHCI_HOST_CHAN_CHARACTER_EP_TYPE__SHIFT);
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_EP_NUMBER__MASK);
DWHCIRegisterOr (&Character, DWHCITransferStageDataGetEndpointNumber (pStageData) << DWHCI_HOST_CHAN_CHARACTER_EP_NUMBER__SHIFT);
TDWHCIFrameScheduler *pFrameScheduler = DWHCITransferStageDataGetFrameScheduler (pStageData);
if (pFrameScheduler != 0)
{
pFrameScheduler->WaitForFrame (pFrameScheduler);
if (pFrameScheduler->IsOddFrame (pFrameScheduler))
{
DWHCIRegisterOr (&Character, DWHCI_HOST_CHAN_CHARACTER_PER_ODD_FRAME);
}
else
{
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_PER_ODD_FRAME);
}
}
TDWHCIRegister ChanInterruptMask;
DWHCIRegister (&ChanInterruptMask, DWHCI_HOST_CHAN_INT_MASK (nChannel));
DWHCIRegisterSet (&ChanInterruptMask, DWHCITransferStageDataGetStatusMask (pStageData));
DWHCIRegisterWrite (&ChanInterruptMask);
DWHCIRegisterOr (&Character, DWHCI_HOST_CHAN_CHARACTER_ENABLE);
DWHCIRegisterAnd (&Character, ~DWHCI_HOST_CHAN_CHARACTER_DISABLE);
DWHCIRegisterWrite (&Character);
_DWHCIRegister (&ChanInterruptMask);
_DWHCIRegister (&Character);
_DWHCIRegister (&SplitControl);
_DWHCIRegister (&DMAAddress);
_DWHCIRegister (&TransferSize);
_DWHCIRegister (&ChanInterrupt);
}
void DWHCIDeviceChannelInterruptHandler (TDWHCIDevice *pThis, unsigned nChannel)
{
assert (pThis != 0);
TDWHCITransferStageData *pStageData = pThis->m_pStageData[nChannel];
assert (pStageData != 0);
TDWHCIFrameScheduler *pFrameScheduler = DWHCITransferStageDataGetFrameScheduler (pStageData);
TUSBRequest *pURB = DWHCITransferStageDataGetURB (pStageData);
assert (pURB != 0);
switch (DWHCITransferStageDataGetSubState (pStageData))
{
case StageSubStateWaitForChannelDisable:
DWHCIDeviceStartChannel (pThis, pStageData);
return;
case StageSubStateWaitForTransactionComplete: {
uspi_CleanAndInvalidateDataCacheRange (DWHCITransferStageDataGetDMAAddress (pStageData),
DWHCITransferStageDataGetBytesToTransfer (pStageData));
DataMemBarrier ();
TDWHCIRegister TransferSize;
DWHCIRegister (&TransferSize, DWHCI_HOST_CHAN_XFER_SIZ (nChannel));
DWHCIRegisterRead (&TransferSize);
TDWHCIRegister ChanInterrupt;
DWHCIRegister (&ChanInterrupt, DWHCI_HOST_CHAN_INT (nChannel));
// restart halted transaction
if (DWHCIRegisterRead (&ChanInterrupt) == DWHCI_HOST_CHAN_INT_HALTED)
{
DWHCIDeviceStartTransaction (pThis, pStageData);
return;
}
assert ( !DWHCITransferStageDataIsPeriodic (pStageData)
|| DWHCI_HOST_CHAN_XFER_SIZ_PID (DWHCIRegisterGet (&TransferSize))
!= DWHCI_HOST_CHAN_XFER_SIZ_PID_MDATA);
DWHCITransferStageDataTransactionComplete (pStageData, DWHCIRegisterRead (&ChanInterrupt),
DWHCI_HOST_CHAN_XFER_SIZ_PACKETS (DWHCIRegisterGet (&TransferSize)),
DWHCIRegisterGet (&TransferSize) & DWHCI_HOST_CHAN_XFER_SIZ_BYTES__MASK);
_DWHCIRegister (&ChanInterrupt);
_DWHCIRegister (&TransferSize);
} break;
default:
assert (0);
break;
}
unsigned nStatus;
switch (DWHCITransferStageDataGetState (pStageData))
{
case StageStateNoSplitTransfer:
nStatus = DWHCITransferStageDataGetTransactionStatus (pStageData);
if (nStatus & DWHCI_HOST_CHAN_INT_ERROR_MASK)
{
LogWrite (FromDWHCI, LOG_ERROR, "Transaction failed (status 0x%X)", nStatus);
USBRequestSetStatus (pURB, 0);
}
else if ( (nStatus & (DWHCI_HOST_CHAN_INT_NAK | DWHCI_HOST_CHAN_INT_NYET))
&& DWHCITransferStageDataIsPeriodic (pStageData))
{
DWHCITransferStageDataSetState (pStageData, StageStatePeriodicDelay);
unsigned nInterval = USBEndpointGetInterval (USBRequestGetEndpoint (pURB));
StartKernelTimer (MSEC2HZ (nInterval), DWHCIDeviceTimerHandler, pStageData, pThis);
break;
}
else
{
if (!DWHCITransferStageDataIsStatusStage (pStageData))
{
USBRequestSetResultLen (pURB, DWHCITransferStageDataGetResultLen (pStageData));
}
USBRequestSetStatus (pURB, 1);
}
DWHCIDeviceDisableChannelInterrupt (pThis, nChannel);
_DWHCITransferStageData (pStageData);
free (pStageData);
pThis->m_pStageData[nChannel] = 0;
DWHCIDeviceFreeChannel (pThis, nChannel);
USBRequestCallCompletionRoutine (pURB);
break;
case StageStateStartSplit:
nStatus = DWHCITransferStageDataGetTransactionStatus (pStageData);
if ( (nStatus & DWHCI_HOST_CHAN_INT_ERROR_MASK)
|| (nStatus & DWHCI_HOST_CHAN_INT_NAK)
|| (nStatus & DWHCI_HOST_CHAN_INT_NYET))
{
LogWrite (FromDWHCI, LOG_ERROR, "Transaction failed (status 0x%X)", nStatus);
USBRequestSetStatus (pURB, 0);
DWHCIDeviceDisableChannelInterrupt (pThis, nChannel);
_DWHCITransferStageData (pStageData);
free (pStageData);
pThis->m_pStageData[nChannel] = 0;
DWHCIDeviceFreeChannel (pThis, nChannel);
USBRequestCallCompletionRoutine (pURB);
break;
}
pFrameScheduler->TransactionComplete (pFrameScheduler, nStatus);
DWHCITransferStageDataSetState (pStageData, StageStateCompleteSplit);
DWHCITransferStageDataSetSplitComplete (pStageData, TRUE);
if (!pFrameScheduler->CompleteSplit (pFrameScheduler))
{
goto LeaveCompleteSplit;
}
DWHCIDeviceStartTransaction (pThis, pStageData);
break;
case StageStateCompleteSplit:
nStatus = DWHCITransferStageDataGetTransactionStatus (pStageData);
if (nStatus & DWHCI_HOST_CHAN_INT_ERROR_MASK)
{
LogWrite (FromDWHCI, LOG_ERROR, "Transaction failed (status 0x%X)", nStatus);
USBRequestSetStatus (pURB, 0);
DWHCIDeviceDisableChannelInterrupt (pThis, nChannel);
_DWHCITransferStageData (pStageData);
free (pStageData);
pThis->m_pStageData[nChannel] = 0;
DWHCIDeviceFreeChannel (pThis, nChannel);
USBRequestCallCompletionRoutine (pURB);
break;
}
pFrameScheduler->TransactionComplete (pFrameScheduler, nStatus);
if (pFrameScheduler->CompleteSplit (pFrameScheduler))
{
DWHCIDeviceStartTransaction (pThis, pStageData);
break;
}
LeaveCompleteSplit:
if (!DWHCITransferStageDataIsStageComplete (pStageData))
{
if (!DWHCITransferStageDataBeginSplitCycle (pStageData))
{
USBRequestSetStatus (pURB, 0);
DWHCIDeviceDisableChannelInterrupt (pThis, nChannel);
_DWHCITransferStageData (pStageData);
free (pStageData);
pThis->m_pStageData[nChannel] = 0;
DWHCIDeviceFreeChannel (pThis, nChannel);
USBRequestCallCompletionRoutine (pURB);
break;
}
if (!DWHCITransferStageDataIsPeriodic (pStageData))
{
DWHCITransferStageDataSetState (pStageData, StageStateStartSplit);
DWHCITransferStageDataSetSplitComplete (pStageData, FALSE);
pFrameScheduler->StartSplit (pFrameScheduler);
DWHCIDeviceStartTransaction (pThis, pStageData);
}
else
{
DWHCITransferStageDataSetState (pStageData, StageStatePeriodicDelay);
unsigned nInterval = USBEndpointGetInterval (USBRequestGetEndpoint (pURB));
StartKernelTimer (MSEC2HZ (nInterval), DWHCIDeviceTimerHandler, pStageData, pThis);
}
break;
}
DWHCIDeviceDisableChannelInterrupt (pThis, nChannel);
if (!DWHCITransferStageDataIsStatusStage (pStageData))
{
USBRequestSetResultLen (pURB, DWHCITransferStageDataGetResultLen (pStageData));
}
USBRequestSetStatus (pURB, 1);
_DWHCITransferStageData (pStageData);
free (pStageData);
pThis->m_pStageData[nChannel] = 0;
DWHCIDeviceFreeChannel (pThis, nChannel);
USBRequestCallCompletionRoutine (pURB);
break;
default:
assert (0);
break;
}
}
void DWHCIDeviceInterruptHandler (void *pParam)
{
TDWHCIDevice *pThis = (TDWHCIDevice *) pParam;
assert (pThis != 0);
DataMemBarrier ();
TDWHCIRegister IntStatus;
DWHCIRegister (&IntStatus, DWHCI_CORE_INT_STAT);
DWHCIRegisterRead (&IntStatus);
if (DWHCIRegisterGet (&IntStatus) & DWHCI_CORE_INT_STAT_HC_INTR)
{
TDWHCIRegister AllChanInterrupt;
DWHCIRegister (&AllChanInterrupt, DWHCI_HOST_ALLCHAN_INT);
DWHCIRegisterRead (&AllChanInterrupt);
DWHCIRegisterWrite (&AllChanInterrupt);
unsigned nChannelMask = 1;
for (unsigned nChannel = 0; nChannel < pThis->m_nChannels; nChannel++)
{
if (DWHCIRegisterGet (&AllChanInterrupt) & nChannelMask)
{
TDWHCIRegister ChanInterruptMask;
DWHCIRegister2 (&ChanInterruptMask, DWHCI_HOST_CHAN_INT_MASK(nChannel), 0);
DWHCIRegisterWrite (&ChanInterruptMask);
DWHCIDeviceChannelInterruptHandler (pThis, nChannel);
_DWHCIRegister (&ChanInterruptMask);
}
nChannelMask <<= 1;
}
_DWHCIRegister (&AllChanInterrupt);
}
#if 0
if (IntStatus.Get () & DWHCI_CORE_INT_STAT_PORT_INTR)
{
CDWHCIRegister HostPort (DWHCI_HOST_PORT);
HostPort.Read ();
CLogger::Get ()->Write (FromDWHCI, LOG_DEBUG, "Port interrupt (status 0x%08X)", HostPort.Get ());
HostPort.And (~DWHCI_HOST_PORT_ENABLE);
HostPort.Or ( DWHCI_HOST_PORT_CONNECT_CHANGED
| DWHCI_HOST_PORT_ENABLE_CHANGED
| DWHCI_HOST_PORT_OVERCURRENT_CHANGED);
HostPort.Write ();
IntStatus.Or (DWHCI_CORE_INT_STAT_PORT_INTR);
}
#endif
DWHCIRegisterWrite (&IntStatus);
DataMemBarrier ();
_DWHCIRegister (&IntStatus);
}
void DWHCIDeviceTimerHandler (unsigned hTimer, void *pParam, void *pContext)
{
TDWHCIDevice *pThis = (TDWHCIDevice *) pContext;
assert (pThis != 0);
TDWHCITransferStageData *pStageData = (TDWHCITransferStageData *) pParam;
assert (pStageData != 0);
DataMemBarrier ();
assert (pStageData != 0);
assert (DWHCITransferStageDataGetState (pStageData) == StageStatePeriodicDelay);
if (DWHCITransferStageDataIsSplit (pStageData))
{
DWHCITransferStageDataSetState (pStageData, StageStateStartSplit);
DWHCITransferStageDataSetSplitComplete (pStageData, FALSE);
TDWHCIFrameScheduler *pFrameScheduler =
DWHCITransferStageDataGetFrameScheduler (pStageData);
assert (pFrameScheduler != 0);
pFrameScheduler->StartSplit (pFrameScheduler);
}
else
{
DWHCITransferStageDataSetState (pStageData, StageStateNoSplitTransfer);
}
DWHCIDeviceStartTransaction (pThis, pStageData);
DataMemBarrier ();
}
unsigned DWHCIDeviceAllocateChannel (TDWHCIDevice *pThis)
{
assert (pThis != 0);
uspi_EnterCritical ();
unsigned nChannelMask = 1;
for (unsigned nChannel = 0; nChannel < pThis->m_nChannels; nChannel++)
{
if (!(pThis->m_nChannelAllocated & nChannelMask))
{
pThis->m_nChannelAllocated |= nChannelMask;
uspi_LeaveCritical ();
return nChannel;
}
nChannelMask <<= 1;
}
uspi_LeaveCritical ();
return DWHCI_MAX_CHANNELS;
}
void DWHCIDeviceFreeChannel (TDWHCIDevice *pThis, unsigned nChannel)
{
assert (pThis != 0);
assert (nChannel < pThis->m_nChannels);
unsigned nChannelMask = 1 << nChannel;
uspi_EnterCritical ();
assert (pThis->m_nChannelAllocated & nChannelMask);
pThis->m_nChannelAllocated &= ~nChannelMask;
uspi_LeaveCritical ();
}
boolean DWHCIDeviceWaitForBit (TDWHCIDevice *pThis, TDWHCIRegister *pRegister, u32 nMask, boolean bWaitUntilSet, unsigned nMsTimeout)
{
assert (pThis != 0);
assert (pRegister != 0);
assert (nMask != 0);
assert (nMsTimeout > 0);
while ((DWHCIRegisterRead (pRegister) & nMask) ? !bWaitUntilSet : bWaitUntilSet)
{
MsDelay (1);
if (--nMsTimeout == 0)
{
//LogWrite (FromDWHCI, LOG_WARNING, "Timeout");
#ifndef NDEBUG
//DWHCIRegisterDump (pRegister);
#endif
return FALSE;
}
}
return TRUE;
}
TUSBSpeed DWHCIDeviceGetPortSpeed (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TUSBSpeed Result = USBSpeedUnknown;
TDWHCIRegister HostPort;
DWHCIRegister (&HostPort, DWHCI_HOST_PORT);
switch (DWHCI_HOST_PORT_SPEED (DWHCIRegisterRead (&HostPort)))
{
case DWHCI_HOST_PORT_SPEED_HIGH:
Result = USBSpeedHigh;
break;
case DWHCI_HOST_PORT_SPEED_FULL:
Result = USBSpeedFull;
break;
case DWHCI_HOST_PORT_SPEED_LOW:
Result = USBSpeedLow;
break;
default:
break;
}
_DWHCIRegister (&HostPort);
return Result;
}
boolean DWHCIDeviceOvercurrentDetected (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister HostPort;
DWHCIRegister (&HostPort, DWHCI_HOST_PORT);
if (DWHCIRegisterRead (&HostPort) & DWHCI_HOST_PORT_OVERCURRENT)
{
_DWHCIRegister (&HostPort);
return TRUE;
}
_DWHCIRegister (&HostPort);
return FALSE;
}
void DWHCIDeviceDisableRootPort (TDWHCIDevice *pThis)
{
assert (pThis != 0);
TDWHCIRegister HostPort;
DWHCIRegister (&HostPort, DWHCI_HOST_PORT);
DWHCIRegisterRead (&HostPort);
DWHCIRegisterAnd (&HostPort, ~DWHCI_HOST_PORT_POWER);
DWHCIRegisterWrite (&HostPort);
_DWHCIRegister (&HostPort);
}
#ifndef NDEBUG
void DWHCIDeviceDumpRegister (TDWHCIDevice *pThis, const char *pName, u32 nAddress)
{
assert (pThis != 0);
TDWHCIRegister Register;
DWHCIRegister (&Register, nAddress);
DataMemBarrier ();
LogWrite (FromDWHCI, LOG_DEBUG, "0x%08X %s", DWHCIRegisterRead (&Register), pName);
_DWHCIRegister (&Register);
}
void DWHCIDeviceDumpStatus (TDWHCIDevice *pThis, unsigned nChannel)
{
assert (pThis != 0);
DWHCIDeviceDumpRegister (pThis, "OTG_CTRL", DWHCI_CORE_OTG_CTRL);
DWHCIDeviceDumpRegister (pThis, "AHB_CFG", DWHCI_CORE_AHB_CFG);
DWHCIDeviceDumpRegister (pThis, "USB_CFG", DWHCI_CORE_USB_CFG);
DWHCIDeviceDumpRegister (pThis, "RESET", DWHCI_CORE_RESET);
DWHCIDeviceDumpRegister (pThis, "INT_STAT", DWHCI_CORE_INT_STAT);
DWHCIDeviceDumpRegister (pThis, "INT_MASK", DWHCI_CORE_INT_MASK);
DWHCIDeviceDumpRegister (pThis, "RX_FIFO_SIZ", DWHCI_CORE_RX_FIFO_SIZ);
DWHCIDeviceDumpRegister (pThis, "NPER_TX_FIFO_SIZ", DWHCI_CORE_NPER_TX_FIFO_SIZ);
DWHCIDeviceDumpRegister (pThis, "NPER_TX_STAT", DWHCI_CORE_NPER_TX_STAT);
DWHCIDeviceDumpRegister (pThis, "HOST_PER_TX_FIFO_SIZ", DWHCI_CORE_HOST_PER_TX_FIFO_SIZ);
DWHCIDeviceDumpRegister (pThis, "HOST_CFG", DWHCI_HOST_CFG);
DWHCIDeviceDumpRegister (pThis, "HOST_PER_TX_FIFO_STAT", DWHCI_HOST_PER_TX_FIFO_STAT);
DWHCIDeviceDumpRegister (pThis, "HOST_ALLCHAN_INT", DWHCI_HOST_ALLCHAN_INT);
DWHCIDeviceDumpRegister (pThis, "HOST_ALLCHAN_INT_MASK", DWHCI_HOST_ALLCHAN_INT_MASK);
DWHCIDeviceDumpRegister (pThis, "HOST_PORT", DWHCI_HOST_PORT);
DWHCIDeviceDumpRegister (pThis, "HOST_CHAN_CHARACTER(n)", DWHCI_HOST_CHAN_CHARACTER (nChannel));
DWHCIDeviceDumpRegister (pThis, "HOST_CHAN_SPLIT_CTRL(n)", DWHCI_HOST_CHAN_SPLIT_CTRL (nChannel));
DWHCIDeviceDumpRegister (pThis, "HOST_CHAN_INT(n)", DWHCI_HOST_CHAN_INT (nChannel));
DWHCIDeviceDumpRegister (pThis, "HOST_CHAN_INT_MASK(n)", DWHCI_HOST_CHAN_INT_MASK (nChannel));
DWHCIDeviceDumpRegister (pThis, "HOST_CHAN_XFER_SIZ(n)", DWHCI_HOST_CHAN_XFER_SIZ (nChannel));
DWHCIDeviceDumpRegister (pThis, "HOST_CHAN_DMA_ADDR(n)", DWHCI_HOST_CHAN_DMA_ADDR (nChannel));
}
#endif