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C/C++ Source or Header | 2001-04-11 | 31.3 KB | 1,040 lines

//////////////////////////////////////////////////////////////// // File - P9080_LIB.C // // Library for 'WinDriver for PLX 9080' API. // The basic idea is to get a handle for the board // with P9080_Open() and use it in the rest of the program // when calling WD functions. Call P9080_Close() when done. // //////////////////////////////////////////////////////////////// #include "p9080_lib.h" #include "../../../include/windrvr_int_thread.h" #include <stdio.h> // this string is set to an error message, if one occurs CHAR P9080_ErrorString[1024]; // internal data structures and enums enum { P9080_DMA_CHANNEL_SHIFT = 0x14 }; // shift in address between channels 0 and 1 of DMA typedef struct P9080_DMA_STRUCT { WD_DMA dma; WD_DMA dmaList; P9080_DMA_CHANNEL dmaChannel; } P9080_DMA_STRUCT; enum { P9080_MODE_DESC = 0xF9000140 }; enum { P9080_MODE_DESC_BYTE = 0x00000000 }; enum { P9080_MODE_DESC_WORD = 0x00010001 }; enum { P9080_MODE_DESC_DWORD = 0x00030003 }; typedef struct { WD_INTERRUPT Int; HANDLE hThread; WD_TRANSFER Trans[2]; P9080_INT_HANDLER funcIntHandler; } P9080_INTERRUPT; typedef struct { DWORD dwLocalBase; DWORD dwMask; DWORD dwBytes; DWORD dwAddr; DWORD dwAddrDirect; BOOL fIsMemory; } P9080_ADDR_DESC; typedef struct P9080_STRUCT { HANDLE hWD; WD_CARD cardLock; WD_PCI_SLOT pciSlot; WD_CARD_REGISTER cardReg; P9080_ADDR_DESC addrDesc[AD_PCI_BARS]; DWORD addrSpace; BOOL fUseInt; P9080_INTERRUPT Int; BOOL fUseCS46EEPROM; } P9080_STRUCT; // internal function used by P9080_Open() BOOL P9080_DetectCardElements(P9080_HANDLE hPlx); // internal function used by P9080_Read... and P9080_Write... functions void P9080_SetMode (P9080_HANDLE hPlx, P9080_MODE mode, DWORD dwLocalAddr); DWORD P9080_CountCards (DWORD dwVendorID, DWORD dwDeviceID) { WD_VERSION ver; WD_PCI_SCAN_CARDS pciScan; HANDLE hWD = INVALID_HANDLE_VALUE; P9080_ErrorString[0] = '\0'; hWD = WD_Open(); // check if handle valid & version OK if (hWD==INVALID_HANDLE_VALUE) { sprintf( P9080_ErrorString, "Failed opening " WD_PROD_NAME " device\n"); return 0; } BZERO(ver); WD_Version(hWD,&ver); if (ver.dwVer<WD_VER) { sprintf( P9080_ErrorString, "Incorrect " WD_PROD_NAME " version\n"); WD_Close (hWD); return 0; } BZERO(pciScan); pciScan.searchId.dwVendorId = dwVendorID; pciScan.searchId.dwDeviceId = dwDeviceID; WD_PciScanCards (hWD, &pciScan); WD_Close (hWD); if (pciScan.dwCards==0) sprintf( P9080_ErrorString, "no cards found\n"); return pciScan.dwCards; } BOOL P9080_Open (P9080_HANDLE *phPlx, DWORD dwVendorID, DWORD dwDeviceID, DWORD nCardNum, DWORD dwOptions) { P9080_HANDLE hPlx = (P9080_HANDLE) malloc (sizeof (P9080_STRUCT)); DWORD dwIntStatus; WD_VERSION ver; WD_PCI_SCAN_CARDS pciScan; WD_PCI_CARD_INFO pciCardInfo; *phPlx = NULL; P9080_ErrorString[0] = '\0'; BZERO(*hPlx); hPlx->hWD = WD_Open(); // check if handle valid & version OK if (hPlx->hWD==INVALID_HANDLE_VALUE) { sprintf( P9080_ErrorString, "Failed opening " WD_PROD_NAME " device\n"); goto Exit; } BZERO(ver); WD_Version(hPlx->hWD,&ver); if (ver.dwVer<WD_VER) { sprintf( P9080_ErrorString, "Incorrect " WD_PROD_NAME " version\n"); goto Exit; } BZERO(pciScan); pciScan.searchId.dwVendorId = dwVendorID; pciScan.searchId.dwDeviceId = dwDeviceID; WD_PciScanCards (hPlx->hWD, &pciScan); if (pciScan.dwCards==0) // Found at least one card { sprintf( P9080_ErrorString, "Could not find PCI card\n"); goto Exit; } if (pciScan.dwCards<=nCardNum) { sprintf( P9080_ErrorString, "Card out of range of available cards\n"); goto Exit; } BZERO(pciCardInfo); pciCardInfo.pciSlot = pciScan.cardSlot[nCardNum]; WD_PciGetCardInfo (hPlx->hWD, &pciCardInfo); hPlx->pciSlot = pciCardInfo.pciSlot; hPlx->cardReg.Card = pciCardInfo.Card; hPlx->fUseInt = (dwOptions & P9080_OPEN_USE_INT) ? TRUE : FALSE; if (!hPlx->fUseInt) { DWORD i; // Remove interrupt item if not needed for (i=0; i<hPlx->cardReg.Card.dwItems; i++) { WD_ITEMS *pItem = &hPlx->cardReg.Card.Item[i]; if (pItem->item==ITEM_INTERRUPT) pItem->item = ITEM_NONE; } } else { DWORD i; // make interrupt resource sharable for (i=0; i<hPlx->cardReg.Card.dwItems; i++) { WD_ITEMS *pItem = &hPlx->cardReg.Card.Item[i]; if (pItem->item==ITEM_INTERRUPT) pItem->fNotSharable = FALSE; } } hPlx->cardReg.fCheckLockOnly = FALSE; WD_CardRegister (hPlx->hWD, &hPlx->cardReg); if (hPlx->cardReg.hCard==0) { sprintf ( P9080_ErrorString, "Failed locking device\n"); goto Exit; } if (!P9080_DetectCardElements(hPlx)) { sprintf ( P9080_ErrorString, "Card does not have all items expected for PLX 9080\n"); goto Exit; } // this enables target abort so it wont get stuck dwIntStatus = P9080_ReadReg (hPlx, P9080_INTCSR); P9080_WriteReg (hPlx, P9080_INTCSR, dwIntStatus | BIT12); // check for EEPROM type if( dwOptions & P9080_CS46_EEPROM ) { hPlx->fUseCS46EEPROM = TRUE; } // Open finished OK *phPlx = hPlx; return TRUE; Exit: // Error durin Open if (hPlx->cardReg.hCard) WD_CardUnregister(hPlx->hWD, &hPlx->cardReg); if (hPlx->hWD!=INVALID_HANDLE_VALUE) WD_Close(hPlx->hWD); free (hPlx); return FALSE; } void P9080_GetPciSlot(P9080_HANDLE hPlx, WD_PCI_SLOT *pPciSlot) { *pPciSlot = hPlx->pciSlot; } DWORD P9080_ReadPCIReg(P9080_HANDLE hPlx, DWORD dwReg) { WD_PCI_CONFIG_DUMP pciCnf; DWORD dwVal; BZERO (pciCnf); pciCnf.pciSlot = hPlx->pciSlot; pciCnf.pBuffer = &dwVal; pciCnf.dwOffset = dwReg; pciCnf.dwBytes = 4; pciCnf.fIsRead = TRUE; WD_PciConfigDump(hPlx->hWD,&pciCnf); return dwVal; } void P9080_WritePCIReg(P9080_HANDLE hPlx, DWORD dwReg, DWORD dwData) { WD_PCI_CONFIG_DUMP pciCnf; BZERO (pciCnf); pciCnf.pciSlot = hPlx->pciSlot; pciCnf.pBuffer = &dwData; pciCnf.dwOffset = dwReg; pciCnf.dwBytes = 4; pciCnf.fIsRead = FALSE; WD_PciConfigDump(hPlx->hWD,&pciCnf); } BOOL P9080_DetectCardElements(P9080_HANDLE hPlx) { DWORD i; DWORD ad_sp; BZERO(hPlx->Int); BZERO(hPlx->addrDesc); for (i=0; i<hPlx->cardReg.Card.dwItems; i++) { WD_ITEMS *pItem = &hPlx->cardReg.Card.Item[i]; switch (pItem->item) { case ITEM_MEMORY: case ITEM_IO: { DWORD dwBytes; DWORD dwAddr; DWORD dwPhysAddr; DWORD dwAddrDirect = 0; BOOL fIsMemory; if (pItem->item==ITEM_MEMORY) { dwBytes = pItem->I.Mem.dwBytes; dwAddr = pItem->I.Mem.dwTransAddr; dwAddrDirect = pItem->I.Mem.dwUserDirectAddr; dwPhysAddr = pItem->I.Mem.dwPhysicalAddr; fIsMemory = TRUE; } else { dwBytes = pItem->I.IO.dwBytes; dwAddr = pItem->I.IO.dwAddr; dwPhysAddr = dwAddr & 0xffff; fIsMemory = FALSE; } for (ad_sp=P9080_ADDR_REG; ad_sp<=P9080_ADDR_EPROM; ad_sp++) { DWORD dwPCIAddr; DWORD dwPCIReg; if (hPlx->addrDesc[ad_sp].dwAddr) continue; if (ad_sp==P9080_ADDR_REG) dwPCIReg = PCI_BAR0; else if (ad_sp<P9080_ADDR_EPROM) dwPCIReg = PCI_BAR2 + 4*(ad_sp-P9080_ADDR_SPACE0); else dwPCIReg = PCI_ERBAR; dwPCIAddr = P9080_ReadPCIReg(hPlx, dwPCIReg); if (dwPCIAddr & 1) { if (fIsMemory) continue; dwPCIAddr &= ~0x3; } else { if (!fIsMemory) continue; dwPCIAddr &= ~0xf; } if (dwPCIAddr==dwPhysAddr) break; } if (ad_sp<=P9080_ADDR_EPROM) { DWORD j; hPlx->addrDesc[ad_sp].dwBytes = dwBytes; hPlx->addrDesc[ad_sp].dwAddr = dwAddr; hPlx->addrDesc[ad_sp].dwAddrDirect = dwAddrDirect; hPlx->addrDesc[ad_sp].fIsMemory = fIsMemory; hPlx->addrDesc[ad_sp].dwMask = 0; for (j=1; j<hPlx->addrDesc[ad_sp].dwBytes && j!=0x80000000; j *= 2) { hPlx->addrDesc[ad_sp].dwMask = (hPlx->addrDesc[ad_sp].dwMask << 1) | 1; } } } break; case ITEM_INTERRUPT: if (hPlx->Int.Int.hInterrupt) return FALSE; hPlx->Int.Int.hInterrupt = pItem->I.Int.hInterrupt; break; } } // check that all the items needed were found // check if interrupt found if (hPlx->fUseInt && !hPlx->Int.Int.hInterrupt) { return FALSE; } // check that the registers space was found if (!P9080_IsAddrSpaceActive(hPlx, P9080_ADDR_REG)) //|| hPlx->addrDesc[P9080_ADDR_REG].dwBytes!=P9080_RANGE_REG) return FALSE; // use address space 0 for accessing local addresses hPlx->addrSpace = P9080_ADDR_SPACE0; // check that address space 0 was found if (!P9080_IsAddrSpaceActive(hPlx, hPlx->addrSpace)) return FALSE; return TRUE; } void P9080_Close(P9080_HANDLE hPlx) { // disable interrupts if (P9080_IntIsEnabled(hPlx)) P9080_IntDisable(hPlx); // unregister card if (hPlx->cardReg.hCard) WD_CardUnregister(hPlx->hWD, &hPlx->cardReg); // close WinDriver WD_Close(hPlx->hWD); free (hPlx); } BOOL P9080_IsAddrSpaceActive(P9080_HANDLE hPlx, P9080_ADDR addrSpace) { return hPlx->addrDesc[addrSpace].dwAddr!=0; } DWORD P9080_ReadReg (P9080_HANDLE hPlx, DWORD dwReg) { return P9080_ReadDWord(hPlx, P9080_ADDR_REG, dwReg); } void P9080_WriteReg (P9080_HANDLE hPlx, DWORD dwReg, DWORD dwData) { P9080_WriteDWord(hPlx, P9080_ADDR_REG, dwReg, dwData); } BYTE P9080_ReadByte (P9080_HANDLE hPlx, P9080_ADDR addrSpace, DWORD dwOffset) { if (hPlx->addrDesc[addrSpace].fIsMemory) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddrDirect + dwOffset; BYTE *pByte = (BYTE *) dwAddr; return *pByte; } else { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); trans.cmdTrans = RP_BYTE; trans.dwPort = dwAddr; WD_Transfer (hPlx->hWD, &trans); return trans.Data.Byte; } } void P9080_WriteByte (P9080_HANDLE hPlx, P9080_ADDR addrSpace, DWORD dwOffset, BYTE data) { if (hPlx->addrDesc[addrSpace].fIsMemory) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddrDirect + dwOffset; BYTE *pByte = (BYTE *) dwAddr; *pByte = data; } else { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); trans.cmdTrans = WP_BYTE; trans.dwPort = dwAddr; trans.Data.Byte = data; WD_Transfer (hPlx->hWD, &trans); } } WORD P9080_ReadWord (P9080_HANDLE hPlx, P9080_ADDR addrSpace, DWORD dwOffset) { if (hPlx->addrDesc[addrSpace].fIsMemory) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddrDirect + dwOffset; WORD *pWord = (WORD *) dwAddr; return *pWord; } else { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); trans.cmdTrans = RP_WORD; trans.dwPort = dwAddr; WD_Transfer (hPlx->hWD, &trans); return trans.Data.Word; } } void P9080_WriteWord (P9080_HANDLE hPlx, P9080_ADDR addrSpace, DWORD dwOffset, WORD data) { if (hPlx->addrDesc[addrSpace].fIsMemory) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddrDirect + dwOffset; WORD *pWord = (WORD *) dwAddr; *pWord = data; } else { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); trans.cmdTrans = WP_WORD; trans.dwPort = dwAddr; trans.Data.Word = data; WD_Transfer (hPlx->hWD, &trans); } } DWORD P9080_ReadDWord (P9080_HANDLE hPlx, P9080_ADDR addrSpace, DWORD dwOffset) { if (hPlx->addrDesc[addrSpace].fIsMemory) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddrDirect + dwOffset; DWORD *pDword = (DWORD *) dwAddr; return *pDword; } else { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); trans.cmdTrans = RP_DWORD; trans.dwPort = dwAddr; WD_Transfer (hPlx->hWD, &trans); return trans.Data.Dword; } } void P9080_WriteDWord (P9080_HANDLE hPlx, P9080_ADDR addrSpace, DWORD dwOffset, DWORD data) { if (hPlx->addrDesc[addrSpace].fIsMemory) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddrDirect + dwOffset; DWORD *pDword = (DWORD *) dwAddr; *pDword = data; } else { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); trans.cmdTrans = WP_DWORD; trans.dwPort = dwAddr; trans.Data.Dword = data; WD_Transfer (hPlx->hWD, &trans); } } void P9080_ReadWriteBlock (P9080_HANDLE hPlx, DWORD dwOffset, PVOID buf, DWORD dwBytes, BOOL fIsRead, P9080_ADDR addrSpace, P9080_MODE mode) { DWORD dwAddr = hPlx->addrDesc[addrSpace].dwAddr + dwOffset; WD_TRANSFER trans; BZERO(trans); if (hPlx->addrDesc[addrSpace].fIsMemory) { if (fIsRead) { if (mode==P9080_MODE_BYTE) trans.cmdTrans = RM_SBYTE; else if (mode==P9080_MODE_WORD) trans.cmdTrans = RM_SWORD; else trans.cmdTrans = RM_SDWORD; } else { if (mode==P9080_MODE_BYTE) trans.cmdTrans = WM_SBYTE; else if (mode==P9080_MODE_WORD) trans.cmdTrans = WM_SWORD; else trans.cmdTrans = WM_SDWORD; } } else { if (fIsRead) { if (mode==P9080_MODE_BYTE) trans.cmdTrans = RP_SBYTE; else if (mode==P9080_MODE_WORD) trans.cmdTrans = RP_SWORD; else trans.cmdTrans = RP_SDWORD; } else { if (mode==P9080_MODE_BYTE) trans.cmdTrans = WP_SBYTE; else if (mode==P9080_MODE_WORD) trans.cmdTrans = WP_SWORD; else trans.cmdTrans = WP_SDWORD; } } trans.dwPort = dwAddr; trans.fAutoinc = TRUE; trans.dwBytes = dwBytes; trans.dwOptions = 0; trans.Data.pBuffer = buf; WD_Transfer (hPlx->hWD, &trans); } void P9080_ReadBlock (P9080_HANDLE hPlx, DWORD dwOffset, PVOID buf, DWORD dwBytes, P9080_ADDR addrSpace, P9080_MODE mode) { P9080_ReadWriteBlock (hPlx, dwOffset, buf, dwBytes, TRUE, addrSpace, mode); } void P9080_WriteBlock (P9080_HANDLE hPlx, DWORD dwOffset, PVOID buf, DWORD dwBytes, P9080_ADDR addrSpace, P9080_MODE mode) { P9080_ReadWriteBlock (hPlx, dwOffset, buf, dwBytes, FALSE, addrSpace, mode); } void P9080_SetMode (P9080_HANDLE hPlx, P9080_MODE mode, DWORD dwLocalAddr) { hPlx->addrDesc[hPlx->addrSpace].dwLocalBase = dwLocalAddr & ~hPlx->addrDesc[hPlx->addrSpace].dwMask; hPlx->addrDesc[hPlx->addrSpace].dwLocalBase |= BIT0; P9080_WriteReg (hPlx, P9080_LAS0BA, hPlx->addrDesc[hPlx->addrSpace].dwLocalBase); } BYTE P9080_ReadByteLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, P9080_MODE_BYTE, dwLocalAddr); return P9080_ReadByte(hPlx, hPlx->addrSpace, dwOffset); } void P9080_WriteByteLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr, BYTE data) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, P9080_MODE_BYTE, dwLocalAddr); P9080_WriteByte(hPlx, hPlx->addrSpace, dwOffset, data); } WORD P9080_ReadWordLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, P9080_MODE_WORD, dwLocalAddr); return P9080_ReadWord(hPlx, hPlx->addrSpace, dwOffset); } void P9080_WriteWordLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr, WORD data) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, P9080_MODE_WORD, dwLocalAddr); P9080_WriteWord(hPlx, hPlx->addrSpace, dwOffset, data); } DWORD P9080_ReadDWordLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, P9080_MODE_DWORD, dwLocalAddr); return P9080_ReadDWord(hPlx, hPlx->addrSpace, dwOffset); } void P9080_WriteDWordLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr, DWORD data) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, P9080_MODE_DWORD, dwLocalAddr); P9080_WriteDWord(hPlx, hPlx->addrSpace, dwOffset, data); } void P9080_ReadWriteBlockLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr, PVOID buf, DWORD dwBytes, BOOL fIsRead, P9080_MODE mode) { DWORD dwOffset = hPlx->addrDesc[hPlx->addrSpace].dwMask & dwLocalAddr; P9080_SetMode (hPlx, mode, dwLocalAddr); P9080_ReadWriteBlock(hPlx, dwOffset, buf, dwBytes, fIsRead, hPlx->addrSpace, mode); } void P9080_ReadBlockLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr, PVOID buf, DWORD dwBytes, P9080_MODE mode) { P9080_ReadWriteBlockLocal (hPlx, dwLocalAddr, buf, dwBytes, TRUE, mode); } void P9080_WriteBlockLocal (P9080_HANDLE hPlx, DWORD dwLocalAddr, PVOID buf, DWORD dwBytes, P9080_MODE mode) { P9080_ReadWriteBlockLocal (hPlx, dwLocalAddr, buf, dwBytes, FALSE, mode); } BOOL P9080_IntIsEnabled (P9080_HANDLE hPlx) { if (!hPlx->fUseInt) return FALSE; if (!hPlx->Int.hThread) return FALSE; return TRUE; } VOID P9080_IntHandler (PVOID pData) { P9080_HANDLE hPlx = (P9080_HANDLE) pData; P9080_INT_RESULT intResult; intResult.dwCounter = hPlx->Int.Int.dwCounter; intResult.dwLost = hPlx->Int.Int.dwLost; intResult.fStopped = hPlx->Int.Int.fStopped; intResult.dwStatusReg = hPlx->Int.Trans[0].Data.Dword; hPlx->Int.funcIntHandler(hPlx, &intResult); } BOOL P9080_IntEnable (P9080_HANDLE hPlx, P9080_INT_HANDLER funcIntHandler) { DWORD dwIntStatus; DWORD dwAddr; if (!hPlx->fUseInt) return FALSE; // check if interrupt is already enabled if (hPlx->Int.hThread) return FALSE; dwIntStatus = P9080_ReadReg (hPlx, P9080_INTCSR); BZERO(hPlx->Int.Trans); // This is a samlpe of handling interrupts: // Two transfer commands are issued. First the value of the interrrupt control/status // register is read. Then, a value of ZERO is written. // This will cancel interrupts after the first interrupt occurs. // When using interrupts, this section will have to change: // you must put transfer commands to CANCEL the source of the interrupt, otherwise, the // PC will hang when an interrupt occurs! dwAddr = hPlx->addrDesc[P9080_ADDR_REG].dwAddr + P9080_INTCSR; hPlx->Int.Trans[0].cmdTrans = hPlx->addrDesc[P9080_ADDR_REG].fIsMemory ? RM_DWORD : RP_DWORD; hPlx->Int.Trans[0].dwPort = dwAddr; hPlx->Int.Trans[1].cmdTrans = hPlx->addrDesc[P9080_ADDR_REG].fIsMemory ? WM_DWORD : WP_DWORD; hPlx->Int.Trans[1].dwPort = dwAddr; hPlx->Int.Trans[1].Data.Dword = dwIntStatus & ~(BIT8|BIT10); // put here the data to write to the control register hPlx->Int.Int.dwCmds = 2; hPlx->Int.Int.Cmd = hPlx->Int.Trans; hPlx->Int.Int.dwOptions |= INTERRUPT_CMD_COPY; // this calls WD_IntEnable() and creates an interrupt handler thread hPlx->Int.funcIntHandler = funcIntHandler; if (!InterruptThreadEnable(&hPlx->Int.hThread, hPlx->hWD, &hPlx->Int.Int, P9080_IntHandler, (PVOID) hPlx)) return FALSE; // this physically enables interrupts P9080_WriteReg (hPlx, P9080_INTCSR, dwIntStatus | (BIT8|BIT10)); return TRUE; } void P9080_IntDisable (P9080_HANDLE hPlx) { DWORD dwIntStatus; if (!hPlx->fUseInt) return; if (!hPlx->Int.hThread) return; // this disables interrupts dwIntStatus = P9080_ReadReg (hPlx, P9080_INTCSR); P9080_WriteReg (hPlx, P9080_INTCSR, dwIntStatus & ~(BIT8|BIT10)); // this calls WD_IntDisable() InterruptThreadDisable(hPlx->Int.hThread); hPlx->Int.hThread = NULL; } P9080_DMA_HANDLE P9080_DMAOpen (P9080_HANDLE hPlx, DWORD dwLocalAddr, PVOID buf, DWORD dwBytes, BOOL fIsRead, P9080_MODE mode, P9080_DMA_CHANNEL dmaChannel) { DWORD dwDMAMODE, dwDMADPR, dwDMALADR; DWORD dwChannelShift = (dmaChannel==P9080_DMA_CHANNEL_0) ? 0 : P9080_DMA_CHANNEL_SHIFT; BOOL fAutoinc = TRUE; P9080_DMA_HANDLE hDma; hDma = malloc (sizeof(P9080_DMA_STRUCT)); if (hDma==NULL) { sprintf( P9080_ErrorString, "Failed allocating memory for dma handle!\n"); goto Exit; } BZERO (*hDma); hDma->dmaChannel = dmaChannel; hDma->dma.dwBytes = dwBytes; hDma->dma.pUserAddr = buf; hDma->dma.dwOptions = 0; WD_DMALock (hPlx->hWD, &hDma->dma); if (!hDma->dma.hDma) { sprintf( P9080_ErrorString, "Failed locking the buffer!\n"); goto Exit; } if (hDma->dma.dwPages==1) { //dma of one page ==> direct dma dwDMAMODE = (fAutoinc ? 0 : BIT11) | BIT6 | (mode==P9080_MODE_BYTE ? 0 : mode==P9080_MODE_WORD ? BIT0 : (BIT1 | BIT0)); dwDMADPR = BIT0 | (fIsRead ? BIT3 : 0); dwDMALADR = dwLocalAddr; P9080_WriteReg (hPlx, P9080_DMAMODE + dwChannelShift, dwDMAMODE); P9080_WriteReg (hPlx, P9080_DMAPADR + dwChannelShift, (DWORD) hDma->dma.Page[0].pPhysicalAddr); P9080_WriteReg (hPlx, P9080_DMALADR + dwChannelShift, dwDMALADR); P9080_WriteReg (hPlx, P9080_DMASIZ + dwChannelShift, hDma->dma.Page[0].dwBytes); P9080_WriteReg (hPlx, P9080_DMADPR + dwChannelShift, dwDMADPR); } else { DWORD dwAlignShift, dwPageNumber, dwMemoryCopied; typedef struct { DWORD dwPADR; DWORD dwLADR; DWORD dwSIZ; DWORD dwDPR; } DMA_LIST; DMA_LIST *pList; //dma of more then one page ==> chain dma hDma->dmaList.dwBytes = hDma->dma.dwPages * sizeof(DMA_LIST) + 0x10; // includes extra 0x10 bytes for quadword alignment hDma->dmaList.pUserAddr = NULL; hDma->dmaList.dwOptions = DMA_KERNEL_BUFFER_ALLOC; WD_DMALock (hPlx->hWD, &hDma->dmaList); if (!hDma->dmaList.hDma) { sprintf (P9080_ErrorString, "Failed locking the chain buffer!\n"); goto Exit; } //setting chain of dma pages in the memory dwMemoryCopied = 0; dwAlignShift = 0x10 - (DWORD) hDma->dmaList.pUserAddr & 0xf; // verifcation that bits 0-3 are zero (quadword aligned) pList = (DMA_LIST *) ((DWORD) hDma->dmaList.pUserAddr + dwAlignShift); for (dwPageNumber=0; dwPageNumber<hDma->dma.dwPages; dwPageNumber++) { pList[dwPageNumber].dwPADR = (DWORD) hDma->dma.Page[dwPageNumber].pPhysicalAddr; pList[dwPageNumber].dwLADR = dwLocalAddr + (fAutoinc ? dwMemoryCopied : 0); pList[dwPageNumber].dwSIZ = hDma->dma.Page[dwPageNumber].dwBytes; pList[dwPageNumber].dwDPR = ((DWORD) hDma->dmaList.Page[0].pPhysicalAddr + dwAlignShift + sizeof(DMA_LIST)*(dwPageNumber+1)) | BIT0 | (fIsRead ? BIT3 : 0); dwMemoryCopied += hDma->dma.Page[dwPageNumber].dwBytes; } pList[dwPageNumber - 1].dwDPR |= BIT1; // mark end of chain dwDMAMODE = (fAutoinc ? 0 : BIT11) | BIT6 | BIT9 // chain transfer | (mode==P9080_MODE_BYTE ? 0 : mode==P9080_MODE_WORD ? BIT0 : (BIT1 | BIT0)); dwDMADPR = ((DWORD)hDma->dmaList.Page[0].pPhysicalAddr + dwAlignShift) | BIT0; // starting the dma P9080_WriteReg (hPlx, P9080_DMAMODE + dwChannelShift, dwDMAMODE); P9080_WriteReg (hPlx, P9080_DMADPR + dwChannelShift, dwDMADPR); } return hDma; Exit: if (hDma!=NULL) P9080_DMAClose(hPlx,hDma); return NULL; } void P9080_DMAClose (P9080_HANDLE hPlx, P9080_DMA_HANDLE hDma) { if (hDma->dma.hDma) WD_DMAUnlock(hPlx->hWD, &hDma->dma); if (hDma->dmaList.hDma) WD_DMAUnlock(hPlx->hWD, &hDma->dmaList); free (hDma); } BOOL P9080_DMAIsDone (P9080_HANDLE hPlx, P9080_DMA_HANDLE hDma) { return (P9080_ReadByte(hPlx, P9080_ADDR_REG, P9080_DMACSR + hDma->dmaChannel) & BIT4) == BIT4; } void P9080_DMAStart (P9080_HANDLE hPlx, P9080_DMA_HANDLE hDma, BOOL fBlocking) { P9080_WriteByte(hPlx, P9080_ADDR_REG, P9080_DMACSR + hDma->dmaChannel, BIT0 | BIT1); //Busy wait for plx to finish transfer if (fBlocking) while (!P9080_DMAIsDone(hPlx, hDma)); } BOOL P9080_DMAReadWriteBlock (P9080_HANDLE hPlx, DWORD dwLocalAddr, PVOID buf, DWORD dwBytes, BOOL fIsRead, P9080_MODE mode, P9080_DMA_CHANNEL dmaChannel) { P9080_DMA_HANDLE hDma; if (dwBytes==0) return TRUE; hDma = P9080_DMAOpen(hPlx, dwLocalAddr, buf, dwBytes, fIsRead, mode, dmaChannel); if (!hDma) return FALSE; P9080_DMAStart(hPlx, hDma, TRUE); P9080_DMAClose(hPlx, hDma); return TRUE; } void P9080_EEPROMDelay(P9080_HANDLE hPlx) { WD_SLEEP sleep; BZERO (sleep); sleep.dwMicroSeconds = 500; WD_Sleep( hPlx->hWD, &sleep); } void P9080_EEPROMChipSelect(P9080_HANDLE hPlx, BOOL fSelect) { DWORD dwCNTRL = P9080_ReadReg(hPlx, P9080_CNTRL); if (fSelect) dwCNTRL |= BIT25; else dwCNTRL &= ~BIT25; P9080_WriteReg(hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); } BOOL P9080_EEPROMValid(P9080_HANDLE hPlx) { return (P9080_ReadReg(hPlx, P9080_CNTRL) & BIT28)==BIT28; } void P9080_EEPROMWriteBit(P9080_HANDLE hPlx, BOOL fBit) { DWORD dwCNTRL = P9080_ReadReg(hPlx, P9080_CNTRL); dwCNTRL &= ~BIT24; if (fBit) // data dwCNTRL |= BIT26; else dwCNTRL &= ~BIT26; P9080_WriteReg( hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); dwCNTRL |= BIT24; // clock P9080_WriteReg( hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); dwCNTRL &= ~BIT24; P9080_WriteReg( hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); } BOOL P9080_EEPROMReadBit(P9080_HANDLE hPlx) { BOOL fRet; DWORD dwCNTRL = P9080_ReadReg(hPlx, P9080_CNTRL); dwCNTRL &= ~BIT24; P9080_WriteReg( hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); dwCNTRL |= BIT24; // clock P9080_WriteReg( hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); dwCNTRL &= ~BIT24; P9080_WriteReg( hPlx, P9080_CNTRL, dwCNTRL); P9080_EEPROMDelay(hPlx); fRet = (P9080_ReadReg( hPlx, P9080_CNTRL) & BIT27)==BIT27; return fRet; } void P9080_EEPROMWriteEnableDisable(P9080_HANDLE hPlx, BOOL fEnable) { P9080_EEPROMChipSelect(hPlx, TRUE); // send a WEN instruction P9080_EEPROMWriteBit(hPlx, 1); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMWriteBit(hPlx, fEnable ? 1 : 0); P9080_EEPROMWriteBit(hPlx, fEnable ? 1 : 0); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMChipSelect(hPlx, FALSE); } BOOL P9080_EEPROMReadWord(P9080_HANDLE hPlx, DWORD dwOffset, PWORD pwData) { DWORD dwAddr = dwOffset >> 1; DWORD i; *pwData = 0; P9080_EEPROMChipSelect(hPlx, TRUE); P9080_EEPROMWriteBit(hPlx, 1); P9080_EEPROMWriteBit(hPlx, 1); P9080_EEPROMWriteBit(hPlx, 0); // if it's a CS46 EEPROM send only 5 bit address for ( i = hPlx->fUseCS46EEPROM ? BIT5 : BIT7; i; i = i>>1) { P9080_EEPROMWriteBit(hPlx, (dwAddr & i) == i); } for (i=BIT15; i; i = i>>1) { *pwData |= P9080_EEPROMReadBit(hPlx) ? i : 0; } P9080_EEPROMWriteEnableDisable(hPlx, FALSE); return TRUE; } BOOL P9080_EEPROMWriteWord(P9080_HANDLE hPlx, DWORD dwOffset, WORD wData) { DWORD dwAddr = dwOffset >> 1; DWORD i; WORD readback; P9080_EEPROMWriteEnableDisable(hPlx, TRUE); P9080_EEPROMChipSelect(hPlx, TRUE); // send a PRWRITE instruction P9080_EEPROMWriteBit(hPlx, 1); P9080_EEPROMWriteBit(hPlx, 0); P9080_EEPROMWriteBit(hPlx, 1); // if it's a CS46 EEPROM send only a 6 bit address for ( i = hPlx->fUseCS46EEPROM ? BIT5 : BIT7; i; i = i>>1) { P9080_EEPROMWriteBit(hPlx, (dwAddr & i) == i); } for (i=BIT15; i; i = i>>1) { P9080_EEPROMWriteBit(hPlx, (wData & i) == i); } P9080_EEPROMChipSelect(hPlx, FALSE); P9080_EEPROMWriteEnableDisable(hPlx, FALSE); if (P9080_EEPROMReadWord(hPlx, dwOffset, &readback)) { if (wData != readback) { sprintf( P9080_ErrorString, "Write 0x%04x, Read 0x%04x\n", wData, readback); return FALSE; } } else return FALSE; return TRUE; } BOOL P9080_EEPROMReadDWord(P9080_HANDLE hPlx, DWORD dwOffset, PDWORD pdwData) { WORD wData1, wData2; if (dwOffset % 4) { sprintf( P9080_ErrorString, "The offset is not a multiple of 4\n"); return FALSE; } if (!P9080_EEPROMReadWord(hPlx, dwOffset, &wData1)) return FALSE; if (!P9080_EEPROMReadWord(hPlx, dwOffset+2, &wData2)) return FALSE; *pdwData = (DWORD) ((wData1 << 16) + wData2); return TRUE; } BOOL P9080_EEPROMWriteDWord(P9080_HANDLE hPlx, DWORD dwOffset, DWORD dwData) { WORD wData1, wData2; if (dwOffset % 4) { sprintf( P9080_ErrorString, "The offset is not a multiple of 4\n"); return FALSE; } wData1 = (WORD) (dwData >> 16); wData2 = (WORD) (dwData & 0xffff); if (!P9080_EEPROMWriteWord(hPlx, dwOffset, wData1)) return FALSE; if (!P9080_EEPROMWriteWord(hPlx, dwOffset+2, wData2)) return FALSE; return TRUE; }