#include "headers.h" #define DWORD unsigned int static int BcmDoChipSelect(struct bcm_mini_adapter *Adapter, unsigned int offset); static int BcmGetActiveDSD(struct bcm_mini_adapter *Adapter); static int BcmGetActiveISO(struct bcm_mini_adapter *Adapter); static unsigned int BcmGetEEPROMSize(struct bcm_mini_adapter *Adapter); static int BcmGetFlashCSInfo(struct bcm_mini_adapter *Adapter); static unsigned int BcmGetFlashSectorSize(struct bcm_mini_adapter *Adapter, unsigned int FlashSectorSizeSig, unsigned int FlashSectorSize); static VOID BcmValidateNvmType(struct bcm_mini_adapter *Adapter); static int BcmGetNvmSize(struct bcm_mini_adapter *Adapter); static unsigned int BcmGetFlashSize(struct bcm_mini_adapter *Adapter); static enum bcm_nvm_type BcmGetNvmType(struct bcm_mini_adapter *Adapter); static int BcmGetSectionValEndOffset(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal); static B_UINT8 IsOffsetWritable(struct bcm_mini_adapter *Adapter, unsigned int uiOffset); static int IsSectionWritable(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val Section); static int IsSectionExistInVendorInfo(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val section); static int ReadDSDPriority(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val dsd); static int ReadDSDSignature(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val dsd); static int ReadISOPriority(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val iso); static int ReadISOSignature(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val iso); static int CorruptDSDSig(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal); static int CorruptISOSig(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal); static int SaveHeaderIfPresent(struct bcm_mini_adapter *Adapter, PUCHAR pBuff, unsigned int uiSectAlignAddr); static int WriteToFlashWithoutSectorErase(struct bcm_mini_adapter *Adapter, PUINT pBuff, enum bcm_flash2x_section_val eFlash2xSectionVal, unsigned int uiOffset, unsigned int uiNumBytes); static enum bcm_flash2x_section_val getHighestPriDSD(struct bcm_mini_adapter *Adapter); static enum bcm_flash2x_section_val getHighestPriISO(struct bcm_mini_adapter *Adapter); static int BeceemFlashBulkRead( struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes); static int BeceemFlashBulkWrite( struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes, BOOLEAN bVerify); static int GetFlashBaseAddr(struct bcm_mini_adapter *Adapter); static int ReadBeceemEEPROMBulk(struct bcm_mini_adapter *Adapter, unsigned int dwAddress, unsigned int *pdwData, unsigned int dwNumData); /* Procedure: ReadEEPROMStatusRegister * * Description: Reads the standard EEPROM Status Register. * * Arguments: * Adapter - ptr to Adapter object instance * Returns: * OSAL_STATUS_CODE */ static UCHAR ReadEEPROMStatusRegister(struct bcm_mini_adapter *Adapter) { UCHAR uiData = 0; DWORD dwRetries = MAX_EEPROM_RETRIES * RETRIES_PER_DELAY; unsigned int uiStatus = 0; unsigned int value = 0; unsigned int value1 = 0; /* Read the EEPROM status register */ value = EEPROM_READ_STATUS_REGISTER; wrmalt(Adapter, EEPROM_CMDQ_SPI_REG, &value, sizeof(value)); while (dwRetries != 0) { value = 0; uiStatus = 0; rdmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &uiStatus, sizeof(uiStatus)); if (Adapter->device_removed == TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Modem has got removed hence exiting...."); break; } /* Wait for Avail bit to be set. */ if ((uiStatus & EEPROM_READ_DATA_AVAIL) != 0) { /* Clear the Avail/Full bits - which ever is set. */ value = uiStatus & (EEPROM_READ_DATA_AVAIL | EEPROM_READ_DATA_FULL); wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); value = 0; rdmalt(Adapter, EEPROM_READ_DATAQ_REG, &value, sizeof(value)); uiData = (UCHAR)value; break; } dwRetries--; if (dwRetries == 0) { rdmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); rdmalt(Adapter, EEPROM_SPI_Q_STATUS_REG, &value1, sizeof(value1)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "0x3004 = %x 0x3008 = %x, retries = %d failed.\n", value, value1, MAX_EEPROM_RETRIES * RETRIES_PER_DELAY); return uiData; } if (!(dwRetries%RETRIES_PER_DELAY)) udelay(1000); uiStatus = 0 ; } return uiData; } /* ReadEEPROMStatusRegister */ /* * Procedure: ReadBeceemEEPROMBulk * * Description: This routine reads 16Byte data from EEPROM * * Arguments: * Adapter - ptr to Adapter object instance * dwAddress - EEPROM Offset to read the data from. * pdwData - Pointer to double word where data needs to be stored in. // dwNumWords - Number of words. Valid values are 4 ONLY. * * Returns: * OSAL_STATUS_CODE: */ int ReadBeceemEEPROMBulk(struct bcm_mini_adapter *Adapter, DWORD dwAddress, DWORD *pdwData, DWORD dwNumWords) { DWORD dwIndex = 0; DWORD dwRetries = MAX_EEPROM_RETRIES * RETRIES_PER_DELAY; unsigned int uiStatus = 0; unsigned int value = 0; unsigned int value1 = 0; UCHAR *pvalue; /* Flush the read and cmd queue. */ value = (EEPROM_READ_QUEUE_FLUSH | EEPROM_CMD_QUEUE_FLUSH); wrmalt(Adapter, SPI_FLUSH_REG, &value, sizeof(value)); value = 0; wrmalt(Adapter, SPI_FLUSH_REG, &value, sizeof(value)); /* Clear the Avail/Full bits. */ value = (EEPROM_READ_DATA_AVAIL | EEPROM_READ_DATA_FULL); wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); value = dwAddress | ((dwNumWords == 4) ? EEPROM_16_BYTE_PAGE_READ : EEPROM_4_BYTE_PAGE_READ); wrmalt(Adapter, EEPROM_CMDQ_SPI_REG, &value, sizeof(value)); while (dwRetries != 0) { uiStatus = 0; rdmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &uiStatus, sizeof(uiStatus)); if (Adapter->device_removed == TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Modem has got Removed.hence exiting from loop..."); return -ENODEV; } /* If we are reading 16 bytes we want to be sure that the queue * is full before we read. In the other cases we are ok if the * queue has data available */ if (dwNumWords == 4) { if ((uiStatus & EEPROM_READ_DATA_FULL) != 0) { /* Clear the Avail/Full bits - which ever is set. */ value = (uiStatus & (EEPROM_READ_DATA_AVAIL | EEPROM_READ_DATA_FULL)); wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); break; } } else if (dwNumWords == 1) { if ((uiStatus & EEPROM_READ_DATA_AVAIL) != 0) { /* We just got Avail and we have to read 32bits so we * need this sleep for Cardbus kind of devices. */ if (Adapter->chip_id == 0xBECE0210) udelay(800); /* Clear the Avail/Full bits - which ever is set. */ value = (uiStatus & (EEPROM_READ_DATA_AVAIL | EEPROM_READ_DATA_FULL)); wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); break; } } uiStatus = 0; dwRetries--; if (dwRetries == 0) { value = 0; value1 = 0; rdmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); rdmalt(Adapter, EEPROM_SPI_Q_STATUS_REG, &value1, sizeof(value1)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "dwNumWords %d 0x3004 = %x 0x3008 = %x retries = %d failed.\n", dwNumWords, value, value1, MAX_EEPROM_RETRIES * RETRIES_PER_DELAY); return STATUS_FAILURE; } if (!(dwRetries%RETRIES_PER_DELAY)) udelay(1000); } for (dwIndex = 0; dwIndex < dwNumWords; dwIndex++) { /* We get only a byte at a time - from LSB to MSB. We shift it into an integer. */ pvalue = (PUCHAR)(pdwData + dwIndex); value = 0; rdmalt(Adapter, EEPROM_READ_DATAQ_REG, &value, sizeof(value)); pvalue[0] = value; value = 0; rdmalt(Adapter, EEPROM_READ_DATAQ_REG, &value, sizeof(value)); pvalue[1] = value; value = 0; rdmalt(Adapter, EEPROM_READ_DATAQ_REG, &value, sizeof(value)); pvalue[2] = value; value = 0; rdmalt(Adapter, EEPROM_READ_DATAQ_REG, &value, sizeof(value)); pvalue[3] = value; } return STATUS_SUCCESS; } /* ReadBeceemEEPROMBulk() */ /* * Procedure: ReadBeceemEEPROM * * Description: This routine reads 4 data from EEPROM. It uses 1 or 2 page * reads to do this operation. * * Arguments: * Adapter - ptr to Adapter object instance * uiOffset - EEPROM Offset to read the data from. * pBuffer - Pointer to word where data needs to be stored in. * * Returns: * OSAL_STATUS_CODE: */ int ReadBeceemEEPROM(struct bcm_mini_adapter *Adapter, DWORD uiOffset, DWORD *pBuffer) { unsigned int uiData[8] = {0}; unsigned int uiByteOffset = 0; unsigned int uiTempOffset = 0; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, " ====> "); uiTempOffset = uiOffset - (uiOffset % MAX_RW_SIZE); uiByteOffset = uiOffset - uiTempOffset; ReadBeceemEEPROMBulk(Adapter, uiTempOffset, (PUINT)&uiData[0], 4); /* A word can overlap at most over 2 pages. In that case we read the * next page too. */ if (uiByteOffset > 12) ReadBeceemEEPROMBulk(Adapter, uiTempOffset + MAX_RW_SIZE, (PUINT)&uiData[4], 4); memcpy((PUCHAR)pBuffer, (((PUCHAR)&uiData[0]) + uiByteOffset), 4); return STATUS_SUCCESS; } /* ReadBeceemEEPROM() */ int ReadMacAddressFromNVM(struct bcm_mini_adapter *Adapter) { int Status; unsigned char puMacAddr[6]; Status = BeceemNVMRead(Adapter, (PUINT)&puMacAddr[0], INIT_PARAMS_1_MACADDRESS_ADDRESS, MAC_ADDRESS_SIZE); if (Status == STATUS_SUCCESS) memcpy(Adapter->dev->dev_addr, puMacAddr, MAC_ADDRESS_SIZE); return Status; } /* * Procedure: BeceemEEPROMBulkRead * * Description: Reads the EEPROM and returns the Data. * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Buffer to store the data read from EEPROM * uiOffset - Offset of EEPROM from where data should be read * uiNumBytes - Number of bytes to be read from the EEPROM. * * Returns: * OSAL_STATUS_SUCCESS - if EEPROM read is successful. * - if failed. */ int BeceemEEPROMBulkRead(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes) { unsigned int uiData[4] = {0}; /* unsigned int uiAddress = 0; */ unsigned int uiBytesRemaining = uiNumBytes; unsigned int uiIndex = 0; unsigned int uiTempOffset = 0; unsigned int uiExtraBytes = 0; unsigned int uiFailureRetries = 0; PUCHAR pcBuff = (PUCHAR)pBuffer; if (uiOffset % MAX_RW_SIZE && uiBytesRemaining) { uiTempOffset = uiOffset - (uiOffset % MAX_RW_SIZE); uiExtraBytes = uiOffset - uiTempOffset; ReadBeceemEEPROMBulk(Adapter, uiTempOffset, (PUINT)&uiData[0], 4); if (uiBytesRemaining >= (MAX_RW_SIZE - uiExtraBytes)) { memcpy(pBuffer, (((PUCHAR)&uiData[0]) + uiExtraBytes), MAX_RW_SIZE - uiExtraBytes); uiBytesRemaining -= (MAX_RW_SIZE - uiExtraBytes); uiIndex += (MAX_RW_SIZE - uiExtraBytes); uiOffset += (MAX_RW_SIZE - uiExtraBytes); } else { memcpy(pBuffer, (((PUCHAR)&uiData[0]) + uiExtraBytes), uiBytesRemaining); uiIndex += uiBytesRemaining; uiOffset += uiBytesRemaining; uiBytesRemaining = 0; } } while (uiBytesRemaining && uiFailureRetries != 128) { if (Adapter->device_removed) return -1; if (uiBytesRemaining >= MAX_RW_SIZE) { /* For the requests more than or equal to 16 bytes, use bulk * read function to make the access faster. * We read 4 Dwords of data */ if (ReadBeceemEEPROMBulk(Adapter, uiOffset, &uiData[0], 4) == 0) { memcpy(pcBuff + uiIndex, &uiData[0], MAX_RW_SIZE); uiOffset += MAX_RW_SIZE; uiBytesRemaining -= MAX_RW_SIZE; uiIndex += MAX_RW_SIZE; } else { uiFailureRetries++; mdelay(3); /* sleep for a while before retry... */ } } else if (uiBytesRemaining >= 4) { if (ReadBeceemEEPROM(Adapter, uiOffset, &uiData[0]) == 0) { memcpy(pcBuff + uiIndex, &uiData[0], 4); uiOffset += 4; uiBytesRemaining -= 4; uiIndex += 4; } else { uiFailureRetries++; mdelay(3); /* sleep for a while before retry... */ } } else { /* Handle the reads less than 4 bytes... */ PUCHAR pCharBuff = (PUCHAR)pBuffer; pCharBuff += uiIndex; if (ReadBeceemEEPROM(Adapter, uiOffset, &uiData[0]) == 0) { memcpy(pCharBuff, &uiData[0], uiBytesRemaining); /* copy only bytes requested. */ uiBytesRemaining = 0; } else { uiFailureRetries++; mdelay(3); /* sleep for a while before retry... */ } } } return 0; } /* * Procedure: BeceemFlashBulkRead * * Description: Reads the FLASH and returns the Data. * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Buffer to store the data read from FLASH * uiOffset - Offset of FLASH from where data should be read * uiNumBytes - Number of bytes to be read from the FLASH. * * Returns: * OSAL_STATUS_SUCCESS - if FLASH read is successful. * - if failed. */ static int BeceemFlashBulkRead(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes) { unsigned int uiIndex = 0; unsigned int uiBytesToRead = uiNumBytes; int Status = 0; unsigned int uiPartOffset = 0; int bytes; if (Adapter->device_removed) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Device Got Removed"); return -ENODEV; } /* Adding flash Base address * uiOffset = uiOffset + GetFlashBaseAddr(Adapter); */ #if defined(BCM_SHM_INTERFACE) && !defined(FLASH_DIRECT_ACCESS) Status = bcmflash_raw_read((uiOffset/FLASH_PART_SIZE), (uiOffset % FLASH_PART_SIZE), (unsigned char *)pBuffer, uiNumBytes); return Status; #endif Adapter->SelectedChip = RESET_CHIP_SELECT; if (uiOffset % MAX_RW_SIZE) { BcmDoChipSelect(Adapter, uiOffset); uiPartOffset = (uiOffset & (FLASH_PART_SIZE - 1)) + GetFlashBaseAddr(Adapter); uiBytesToRead = MAX_RW_SIZE - (uiOffset % MAX_RW_SIZE); uiBytesToRead = MIN(uiNumBytes, uiBytesToRead); bytes = rdm(Adapter, uiPartOffset, (PCHAR)pBuffer + uiIndex, uiBytesToRead); if (bytes < 0) { Status = bytes; Adapter->SelectedChip = RESET_CHIP_SELECT; return Status; } uiIndex += uiBytesToRead; uiOffset += uiBytesToRead; uiNumBytes -= uiBytesToRead; } while (uiNumBytes) { BcmDoChipSelect(Adapter, uiOffset); uiPartOffset = (uiOffset & (FLASH_PART_SIZE - 1)) + GetFlashBaseAddr(Adapter); uiBytesToRead = MIN(uiNumBytes, MAX_RW_SIZE); bytes = rdm(Adapter, uiPartOffset, (PCHAR)pBuffer + uiIndex, uiBytesToRead); if (bytes < 0) { Status = bytes; break; } uiIndex += uiBytesToRead; uiOffset += uiBytesToRead; uiNumBytes -= uiBytesToRead; } Adapter->SelectedChip = RESET_CHIP_SELECT; return Status; } /* * Procedure: BcmGetFlashSize * * Description: Finds the size of FLASH. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * unsigned int - size of the FLASH Storage. * */ static unsigned int BcmGetFlashSize(struct bcm_mini_adapter *Adapter) { if (IsFlash2x(Adapter)) return Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + sizeof(struct bcm_dsd_header); else return 32 * 1024; } /* * Procedure: BcmGetEEPROMSize * * Description: Finds the size of EEPROM. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * unsigned int - size of the EEPROM Storage. * */ static unsigned int BcmGetEEPROMSize(struct bcm_mini_adapter *Adapter) { unsigned int uiData = 0; unsigned int uiIndex = 0; /* * if EEPROM is present and already Calibrated,it will have * 'BECM' string at 0th offset. * To find the EEPROM size read the possible boundaries of the * EEPROM like 4K,8K etc..accessing the EEPROM beyond its size will * result in wrap around. So when we get the End of the EEPROM we will * get 'BECM' string which is indeed at offset 0. */ BeceemEEPROMBulkRead(Adapter, &uiData, 0x0, 4); if (uiData == BECM) { for (uiIndex = 2; uiIndex <= 256; uiIndex *= 2) { BeceemEEPROMBulkRead(Adapter, &uiData, uiIndex * 1024, 4); if (uiData == BECM) return uiIndex * 1024; } } else { /* * EEPROM may not be present or not programmed */ uiData = 0xBABEFACE; if (BeceemEEPROMBulkWrite(Adapter, (PUCHAR)&uiData, 0, 4, TRUE) == 0) { uiData = 0; for (uiIndex = 2; uiIndex <= 256; uiIndex *= 2) { BeceemEEPROMBulkRead(Adapter, &uiData, uiIndex * 1024, 4); if (uiData == 0xBABEFACE) return uiIndex * 1024; } } } return 0; } /* * Procedure: FlashSectorErase * * Description: Finds the sector size of the FLASH. * * Arguments: * Adapter - ptr to Adapter object instance * addr - sector start address * numOfSectors - number of sectors to be erased. * * Returns: * OSAL_STATUS_CODE * */ static int FlashSectorErase(struct bcm_mini_adapter *Adapter, unsigned int addr, unsigned int numOfSectors) { unsigned int iIndex = 0, iRetries = 0; unsigned int uiStatus = 0; unsigned int value; int bytes; for (iIndex = 0; iIndex < numOfSectors; iIndex++) { value = 0x06000000; wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); value = (0xd8000000 | (addr & 0xFFFFFF)); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); iRetries = 0; do { value = (FLASH_CMD_STATUS_REG_READ << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programing of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } bytes = rdmalt(Adapter, FLASH_SPI_READQ_REG, &uiStatus, sizeof(uiStatus)); if (bytes < 0) { uiStatus = bytes; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Reading status of FLASH_SPI_READQ_REG fails"); return uiStatus; } iRetries++; /* After every try lets make the CPU free for 10 ms. generally time taken by the * the sector erase cycle is 500 ms to 40000 msec. hence sleeping 10 ms * won't hamper performance in any case. */ mdelay(10); } while ((uiStatus & 0x1) && (iRetries < 400)); if (uiStatus & 0x1) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "iRetries crossing the limit of 80000\n"); return STATUS_FAILURE; } addr += Adapter->uiSectorSize; } return 0; } /* * Procedure: flashByteWrite * * Description: Performs Byte by Byte write to flash * * Arguments: * Adapter - ptr to Adapter object instance * uiOffset - Offset of the flash where data needs to be written to. * pData - Address of Data to be written. * Returns: * OSAL_STATUS_CODE * */ static int flashByteWrite(struct bcm_mini_adapter *Adapter, unsigned int uiOffset, PVOID pData) { unsigned int uiStatus = 0; int iRetries = MAX_FLASH_RETRIES * FLASH_PER_RETRIES_DELAY; /* 3 */ unsigned int value; ULONG ulData = *(PUCHAR)pData; int bytes; /* * need not write 0xFF because write requires an erase and erase will * make whole sector 0xFF. */ if (0xFF == ulData) return STATUS_SUCCESS; /* DumpDebug(NVM_RW,("flashWrite ====>\n")); */ value = (FLASH_CMD_WRITE_ENABLE << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write enable in FLASH_SPI_CMDQ_REG register fails"); return STATUS_FAILURE; } if (wrm(Adapter, FLASH_SPI_WRITEQ_REG, (PCHAR)&ulData, 4) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "DATA Write on FLASH_SPI_WRITEQ_REG fails"); return STATUS_FAILURE; } value = (0x02000000 | (uiOffset & 0xFFFFFF)); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programming of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } /* __udelay(950); */ do { value = (FLASH_CMD_STATUS_REG_READ << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programing of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } /* __udelay(1); */ bytes = rdmalt(Adapter, FLASH_SPI_READQ_REG, &uiStatus, sizeof(uiStatus)); if (bytes < 0) { uiStatus = bytes; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Reading status of FLASH_SPI_READQ_REG fails"); return uiStatus; } iRetries--; if (iRetries && ((iRetries % FLASH_PER_RETRIES_DELAY) == 0)) udelay(1000); } while ((uiStatus & 0x1) && (iRetries > 0)); if (uiStatus & 0x1) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Flash Write fails even after checking status for 200 times."); return STATUS_FAILURE; } return STATUS_SUCCESS; } /* * Procedure: flashWrite * * Description: Performs write to flash * * Arguments: * Adapter - ptr to Adapter object instance * uiOffset - Offset of the flash where data needs to be written to. * pData - Address of Data to be written. * Returns: * OSAL_STATUS_CODE * */ static int flashWrite(struct bcm_mini_adapter *Adapter, unsigned int uiOffset, PVOID pData) { /* unsigned int uiStatus = 0; * int iRetries = 0; * unsigned int uiReadBack = 0; */ unsigned int uiStatus = 0; int iRetries = MAX_FLASH_RETRIES * FLASH_PER_RETRIES_DELAY; /* 3 */ unsigned int value; unsigned int uiErasePattern[4] = {0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF}; int bytes; /* * need not write 0xFFFFFFFF because write requires an erase and erase will * make whole sector 0xFFFFFFFF. */ if (!memcmp(pData, uiErasePattern, MAX_RW_SIZE)) return 0; value = (FLASH_CMD_WRITE_ENABLE << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write Enable of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } if (wrm(Adapter, uiOffset, (PCHAR)pData, MAX_RW_SIZE) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Data write fails..."); return STATUS_FAILURE; } /* __udelay(950); */ do { value = (FLASH_CMD_STATUS_REG_READ << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programing of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } /* __udelay(1); */ bytes = rdmalt(Adapter, FLASH_SPI_READQ_REG, &uiStatus, sizeof(uiStatus)); if (bytes < 0) { uiStatus = bytes; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Reading status of FLASH_SPI_READQ_REG fails"); return uiStatus; } iRetries--; /* this will ensure that in there will be no changes in the current path. * currently one rdm/wrm takes 125 us. * Hence 125 *2 * FLASH_PER_RETRIES_DELAY > 3 ms(worst case delay) * Hence current implementation cycle will intoduce no delay in current path */ if (iRetries && ((iRetries % FLASH_PER_RETRIES_DELAY) == 0)) udelay(1000); } while ((uiStatus & 0x1) && (iRetries > 0)); if (uiStatus & 0x1) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Flash Write fails even after checking status for 200 times."); return STATUS_FAILURE; } return STATUS_SUCCESS; } /*----------------------------------------------------------------------------- * Procedure: flashByteWriteStatus * * Description: Performs byte by byte write to flash with write done status check * * Arguments: * Adapter - ptr to Adapter object instance * uiOffset - Offset of the flash where data needs to be written to. * pData - Address of the Data to be written. * Returns: * OSAL_STATUS_CODE * */ static int flashByteWriteStatus(struct bcm_mini_adapter *Adapter, unsigned int uiOffset, PVOID pData) { unsigned int uiStatus = 0; int iRetries = MAX_FLASH_RETRIES * FLASH_PER_RETRIES_DELAY; /* 3 */ ULONG ulData = *(PUCHAR)pData; unsigned int value; int bytes; /* * need not write 0xFFFFFFFF because write requires an erase and erase will * make whole sector 0xFFFFFFFF. */ if (0xFF == ulData) return STATUS_SUCCESS; /* DumpDebug(NVM_RW,("flashWrite ====>\n")); */ value = (FLASH_CMD_WRITE_ENABLE << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write enable in FLASH_SPI_CMDQ_REG register fails"); return STATUS_SUCCESS; } if (wrm(Adapter, FLASH_SPI_WRITEQ_REG, (PCHAR)&ulData, 4) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "DATA Write on FLASH_SPI_WRITEQ_REG fails"); return STATUS_FAILURE; } value = (0x02000000 | (uiOffset & 0xFFFFFF)); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programming of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } /* msleep(1); */ do { value = (FLASH_CMD_STATUS_REG_READ << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programing of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } /* __udelay(1); */ bytes = rdmalt(Adapter, FLASH_SPI_READQ_REG, &uiStatus, sizeof(uiStatus)); if (bytes < 0) { uiStatus = bytes; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Reading status of FLASH_SPI_READQ_REG fails"); return uiStatus; } iRetries--; if (iRetries && ((iRetries % FLASH_PER_RETRIES_DELAY) == 0)) udelay(1000); } while ((uiStatus & 0x1) && (iRetries > 0)); if (uiStatus & 0x1) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Flash Write fails even after checking status for 200 times."); return STATUS_FAILURE; } return STATUS_SUCCESS; } /* * Procedure: flashWriteStatus * * Description: Performs write to flash with write done status check * * Arguments: * Adapter - ptr to Adapter object instance * uiOffset - Offset of the flash where data needs to be written to. * pData - Address of the Data to be written. * Returns: * OSAL_STATUS_CODE * */ static int flashWriteStatus(struct bcm_mini_adapter *Adapter, unsigned int uiOffset, PVOID pData) { unsigned int uiStatus = 0; int iRetries = MAX_FLASH_RETRIES * FLASH_PER_RETRIES_DELAY; /* 3 */ /* unsigned int uiReadBack = 0; */ unsigned int value; unsigned int uiErasePattern[4] = {0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF}; int bytes; /* * need not write 0xFFFFFFFF because write requires an erase and erase will * make whole sector 0xFFFFFFFF. */ if (!memcmp(pData, uiErasePattern, MAX_RW_SIZE)) return 0; value = (FLASH_CMD_WRITE_ENABLE << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write Enable of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } if (wrm(Adapter, uiOffset, (PCHAR)pData, MAX_RW_SIZE) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Data write fails..."); return STATUS_FAILURE; } /* __udelay(1); */ do { value = (FLASH_CMD_STATUS_REG_READ << 24); if (wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)) < 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Programing of FLASH_SPI_CMDQ_REG fails"); return STATUS_FAILURE; } /* __udelay(1); */ bytes = rdmalt(Adapter, FLASH_SPI_READQ_REG, &uiStatus, sizeof(uiStatus)); if (bytes < 0) { uiStatus = bytes; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Reading status of FLASH_SPI_READQ_REG fails"); return uiStatus; } iRetries--; /* this will ensure that in there will be no changes in the current path. * currently one rdm/wrm takes 125 us. * Hence 125 *2 * FLASH_PER_RETRIES_DELAY >3 ms(worst case delay) * Hence current implementation cycle will intoduce no delay in current path */ if (iRetries && ((iRetries % FLASH_PER_RETRIES_DELAY) == 0)) udelay(1000); } while ((uiStatus & 0x1) && (iRetries > 0)); if (uiStatus & 0x1) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Flash Write fails even after checking status for 200 times."); return STATUS_FAILURE; } return STATUS_SUCCESS; } /* * Procedure: BcmRestoreBlockProtectStatus * * Description: Restores the original block protection status. * * Arguments: * Adapter - ptr to Adapter object instance * ulWriteStatus -Original status * Returns: * * */ static VOID BcmRestoreBlockProtectStatus(struct bcm_mini_adapter *Adapter, ULONG ulWriteStatus) { unsigned int value; value = (FLASH_CMD_WRITE_ENABLE << 24); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); udelay(20); value = (FLASH_CMD_STATUS_REG_WRITE << 24) | (ulWriteStatus << 16); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); udelay(20); } /* * Procedure: BcmFlashUnProtectBlock * * Description: UnProtects appropriate blocks for writing. * * Arguments: * Adapter - ptr to Adapter object instance * uiOffset - Offset of the flash where data needs to be written to. This should be Sector aligned. * Returns: * ULONG - Status value before UnProtect. * */ static ULONG BcmFlashUnProtectBlock(struct bcm_mini_adapter *Adapter, unsigned int uiOffset, unsigned int uiLength) { ULONG ulStatus = 0; ULONG ulWriteStatus = 0; unsigned int value; uiOffset = uiOffset&0x000FFFFF; /* * Implemented only for 1MB Flash parts. */ if (FLASH_PART_SST25VF080B == Adapter->ulFlashID) { /* * Get Current BP status. */ value = (FLASH_CMD_STATUS_REG_READ << 24); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); udelay(10); /* * Read status will be WWXXYYZZ. We have to take only WW. */ rdmalt(Adapter, FLASH_SPI_READQ_REG, (PUINT)&ulStatus, sizeof(ulStatus)); ulStatus >>= 24; ulWriteStatus = ulStatus; /* * Bits [5-2] give current block level protection status. * Bit5: BP3 - DONT CARE * BP2-BP0: 0 - NO PROTECTION, 1 - UPPER 1/16, 2 - UPPER 1/8, 3 - UPPER 1/4 * 4 - UPPER 1/2. 5 to 7 - ALL BLOCKS */ if (ulStatus) { if ((uiOffset+uiLength) <= 0x80000) { /* * Offset comes in lower half of 1MB. Protect the upper half. * Clear BP1 and BP0 and set BP2. */ ulWriteStatus |= (0x4<<2); ulWriteStatus &= ~(0x3<<2); } else if ((uiOffset + uiLength) <= 0xC0000) { /* * Offset comes below Upper 1/4. Upper 1/4 can be protected. * Clear BP2 and set BP1 and BP0. */ ulWriteStatus |= (0x3<<2); ulWriteStatus &= ~(0x1<<4); } else if ((uiOffset + uiLength) <= 0xE0000) { /* * Offset comes below Upper 1/8. Upper 1/8 can be protected. * Clear BP2 and BP0 and set BP1 */ ulWriteStatus |= (0x1<<3); ulWriteStatus &= ~(0x5<<2); } else if ((uiOffset + uiLength) <= 0xF0000) { /* * Offset comes below Upper 1/16. Only upper 1/16 can be protected. * Set BP0 and Clear BP2,BP1. */ ulWriteStatus |= (0x1<<2); ulWriteStatus &= ~(0x3<<3); } else { /* * Unblock all. * Clear BP2,BP1 and BP0. */ ulWriteStatus &= ~(0x7<<2); } value = (FLASH_CMD_WRITE_ENABLE << 24); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); udelay(20); value = (FLASH_CMD_STATUS_REG_WRITE << 24) | (ulWriteStatus << 16); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); udelay(20); } } return ulStatus; } /* * Procedure: BeceemFlashBulkWrite * * Description: Performs write to the flash * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Data to be written. * uiOffset - Offset of the flash where data needs to be written to. * uiNumBytes - Number of bytes to be written. * bVerify - read verify flag. * Returns: * OSAL_STATUS_CODE * */ static int BeceemFlashBulkWrite(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes, BOOLEAN bVerify) { PCHAR pTempBuff = NULL; PUCHAR pcBuffer = (PUCHAR)pBuffer; unsigned int uiIndex = 0; unsigned int uiOffsetFromSectStart = 0; unsigned int uiSectAlignAddr = 0; unsigned int uiCurrSectOffsetAddr = 0; unsigned int uiSectBoundary = 0; unsigned int uiNumSectTobeRead = 0; UCHAR ucReadBk[16] = {0}; ULONG ulStatus = 0; int Status = STATUS_SUCCESS; unsigned int uiTemp = 0; unsigned int index = 0; unsigned int uiPartOffset = 0; #if defined(BCM_SHM_INTERFACE) && !defined(FLASH_DIRECT_ACCESS) Status = bcmflash_raw_write((uiOffset / FLASH_PART_SIZE), (uiOffset % FLASH_PART_SIZE), (unsigned char *)pBuffer, uiNumBytes); return Status; #endif uiOffsetFromSectStart = uiOffset & ~(Adapter->uiSectorSize - 1); /* Adding flash Base address * uiOffset = uiOffset + GetFlashBaseAddr(Adapter); */ uiSectAlignAddr = uiOffset & ~(Adapter->uiSectorSize - 1); uiCurrSectOffsetAddr = uiOffset & (Adapter->uiSectorSize - 1); uiSectBoundary = uiSectAlignAddr + Adapter->uiSectorSize; pTempBuff = kmalloc(Adapter->uiSectorSize, GFP_KERNEL); if (!pTempBuff) goto BeceemFlashBulkWrite_EXIT; /* * check if the data to be written is overlapped across sectors */ if (uiOffset+uiNumBytes < uiSectBoundary) { uiNumSectTobeRead = 1; } else { /* Number of sectors = Last sector start address/First sector start address */ uiNumSectTobeRead = (uiCurrSectOffsetAddr + uiNumBytes) / Adapter->uiSectorSize; if ((uiCurrSectOffsetAddr + uiNumBytes)%Adapter->uiSectorSize) uiNumSectTobeRead++; } /* Check whether Requested sector is writable or not in case of flash2x write. But if write call is * for DSD calibration, allow it without checking of sector permission */ if (IsFlash2x(Adapter) && (Adapter->bAllDSDWriteAllow == FALSE)) { index = 0; uiTemp = uiNumSectTobeRead; while (uiTemp) { if (IsOffsetWritable(Adapter, uiOffsetFromSectStart + index * Adapter->uiSectorSize) == FALSE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Sector Starting at offset <0X%X> is not writable", (uiOffsetFromSectStart + index * Adapter->uiSectorSize)); Status = SECTOR_IS_NOT_WRITABLE; goto BeceemFlashBulkWrite_EXIT; } uiTemp = uiTemp - 1; index = index + 1 ; } } Adapter->SelectedChip = RESET_CHIP_SELECT; while (uiNumSectTobeRead) { /* do_gettimeofday(&tv1); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "\nTime In start of write :%ld ms\n",(tv1.tv_sec *1000 + tv1.tv_usec /1000)); */ uiPartOffset = (uiSectAlignAddr & (FLASH_PART_SIZE - 1)) + GetFlashBaseAddr(Adapter); BcmDoChipSelect(Adapter, uiSectAlignAddr); if (0 != BeceemFlashBulkRead(Adapter, (PUINT)pTempBuff, uiOffsetFromSectStart, Adapter->uiSectorSize)) { Status = -1; goto BeceemFlashBulkWrite_EXIT; } /* do_gettimeofday(&tr); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "Total time taken by Read :%ld ms\n", (tr.tv_sec *1000 + tr.tv_usec/1000) - (tv1.tv_sec *1000 + tv1.tv_usec/1000)); */ ulStatus = BcmFlashUnProtectBlock(Adapter, uiSectAlignAddr, Adapter->uiSectorSize); if (uiNumSectTobeRead > 1) { memcpy(&pTempBuff[uiCurrSectOffsetAddr], pcBuffer, uiSectBoundary - (uiSectAlignAddr + uiCurrSectOffsetAddr)); pcBuffer += ((uiSectBoundary - (uiSectAlignAddr + uiCurrSectOffsetAddr))); uiNumBytes -= (uiSectBoundary - (uiSectAlignAddr + uiCurrSectOffsetAddr)); } else { memcpy(&pTempBuff[uiCurrSectOffsetAddr], pcBuffer, uiNumBytes); } if (IsFlash2x(Adapter)) SaveHeaderIfPresent(Adapter, (PUCHAR)pTempBuff, uiOffsetFromSectStart); FlashSectorErase(Adapter, uiPartOffset, 1); /* do_gettimeofday(&te); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "Total time taken by Erase :%ld ms\n", (te.tv_sec *1000 + te.tv_usec/1000) - (tr.tv_sec *1000 + tr.tv_usec/1000)); */ for (uiIndex = 0; uiIndex < Adapter->uiSectorSize; uiIndex += Adapter->ulFlashWriteSize) { if (Adapter->device_removed) { Status = -1; goto BeceemFlashBulkWrite_EXIT; } if (STATUS_SUCCESS != (*Adapter->fpFlashWrite)(Adapter, uiPartOffset + uiIndex, (&pTempBuff[uiIndex]))) { Status = -1; goto BeceemFlashBulkWrite_EXIT; } } /* do_gettimeofday(&tw); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "Total time taken in Write to Flash :%ld ms\n", (tw.tv_sec *1000 + tw.tv_usec/1000) - (te.tv_sec *1000 + te.tv_usec/1000)); */ for (uiIndex = 0; uiIndex < Adapter->uiSectorSize; uiIndex += MAX_RW_SIZE) { if (STATUS_SUCCESS == BeceemFlashBulkRead(Adapter, (PUINT)ucReadBk, uiOffsetFromSectStart + uiIndex, MAX_RW_SIZE)) { if (Adapter->ulFlashWriteSize == 1) { unsigned int uiReadIndex = 0; for (uiReadIndex = 0; uiReadIndex < 16; uiReadIndex++) { if (ucReadBk[uiReadIndex] != pTempBuff[uiIndex + uiReadIndex]) { if (STATUS_SUCCESS != (*Adapter->fpFlashWriteWithStatusCheck)(Adapter, uiPartOffset + uiIndex + uiReadIndex, &pTempBuff[uiIndex+uiReadIndex])) { Status = STATUS_FAILURE; goto BeceemFlashBulkWrite_EXIT; } } } } else { if (memcmp(ucReadBk, &pTempBuff[uiIndex], MAX_RW_SIZE)) { if (STATUS_SUCCESS != (*Adapter->fpFlashWriteWithStatusCheck)(Adapter, uiPartOffset + uiIndex, &pTempBuff[uiIndex])) { Status = STATUS_FAILURE; goto BeceemFlashBulkWrite_EXIT; } } } } } /* do_gettimeofday(&twv); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "Total time taken in Write to Flash verification :%ld ms\n", (twv.tv_sec *1000 + twv.tv_usec/1000) - (tw.tv_sec *1000 + tw.tv_usec/1000)); */ if (ulStatus) { BcmRestoreBlockProtectStatus(Adapter, ulStatus); ulStatus = 0; } uiCurrSectOffsetAddr = 0; uiSectAlignAddr = uiSectBoundary; uiSectBoundary += Adapter->uiSectorSize; uiOffsetFromSectStart += Adapter->uiSectorSize; uiNumSectTobeRead--; } /* do_gettimeofday(&tv2); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "Time after Write :%ld ms\n",(tv2.tv_sec *1000 + tv2.tv_usec/1000)); * BCM_DEBUG_PRINT(Adapter,DBG_TYPE_PRINTK, 0, 0, "Total time taken by in Write is :%ld ms\n", (tv2.tv_sec *1000 + tv2.tv_usec/1000) - (tv1.tv_sec *1000 + tv1.tv_usec/1000)); * * Cleanup. */ BeceemFlashBulkWrite_EXIT: if (ulStatus) BcmRestoreBlockProtectStatus(Adapter, ulStatus); kfree(pTempBuff); Adapter->SelectedChip = RESET_CHIP_SELECT; return Status; } /* * Procedure: BeceemFlashBulkWriteStatus * * Description: Writes to Flash. Checks the SPI status after each write. * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Data to be written. * uiOffset - Offset of the flash where data needs to be written to. * uiNumBytes - Number of bytes to be written. * bVerify - read verify flag. * Returns: * OSAL_STATUS_CODE * */ static int BeceemFlashBulkWriteStatus(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes, BOOLEAN bVerify) { PCHAR pTempBuff = NULL; PUCHAR pcBuffer = (PUCHAR)pBuffer; unsigned int uiIndex = 0; unsigned int uiOffsetFromSectStart = 0; unsigned int uiSectAlignAddr = 0; unsigned int uiCurrSectOffsetAddr = 0; unsigned int uiSectBoundary = 0; unsigned int uiNumSectTobeRead = 0; UCHAR ucReadBk[16] = {0}; ULONG ulStatus = 0; unsigned int Status = STATUS_SUCCESS; unsigned int uiTemp = 0; unsigned int index = 0; unsigned int uiPartOffset = 0; uiOffsetFromSectStart = uiOffset & ~(Adapter->uiSectorSize - 1); /* uiOffset += Adapter->ulFlashCalStart; * Adding flash Base address * uiOffset = uiOffset + GetFlashBaseAddr(Adapter); */ uiSectAlignAddr = uiOffset & ~(Adapter->uiSectorSize - 1); uiCurrSectOffsetAddr = uiOffset & (Adapter->uiSectorSize - 1); uiSectBoundary = uiSectAlignAddr + Adapter->uiSectorSize; pTempBuff = kmalloc(Adapter->uiSectorSize, GFP_KERNEL); if (!pTempBuff) goto BeceemFlashBulkWriteStatus_EXIT; /* * check if the data to be written is overlapped across sectors */ if (uiOffset+uiNumBytes < uiSectBoundary) { uiNumSectTobeRead = 1; } else { /* Number of sectors = Last sector start address/First sector start address */ uiNumSectTobeRead = (uiCurrSectOffsetAddr + uiNumBytes) / Adapter->uiSectorSize; if ((uiCurrSectOffsetAddr + uiNumBytes)%Adapter->uiSectorSize) uiNumSectTobeRead++; } if (IsFlash2x(Adapter) && (Adapter->bAllDSDWriteAllow == FALSE)) { index = 0; uiTemp = uiNumSectTobeRead; while (uiTemp) { if (IsOffsetWritable(Adapter, uiOffsetFromSectStart + index * Adapter->uiSectorSize) == FALSE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Sector Starting at offset <0X%x> is not writable", (uiOffsetFromSectStart + index * Adapter->uiSectorSize)); Status = SECTOR_IS_NOT_WRITABLE; goto BeceemFlashBulkWriteStatus_EXIT; } uiTemp = uiTemp - 1; index = index + 1 ; } } Adapter->SelectedChip = RESET_CHIP_SELECT; while (uiNumSectTobeRead) { uiPartOffset = (uiSectAlignAddr & (FLASH_PART_SIZE - 1)) + GetFlashBaseAddr(Adapter); BcmDoChipSelect(Adapter, uiSectAlignAddr); if (0 != BeceemFlashBulkRead(Adapter, (PUINT)pTempBuff, uiOffsetFromSectStart, Adapter->uiSectorSize)) { Status = -1; goto BeceemFlashBulkWriteStatus_EXIT; } ulStatus = BcmFlashUnProtectBlock(Adapter, uiOffsetFromSectStart, Adapter->uiSectorSize); if (uiNumSectTobeRead > 1) { memcpy(&pTempBuff[uiCurrSectOffsetAddr], pcBuffer, uiSectBoundary - (uiSectAlignAddr + uiCurrSectOffsetAddr)); pcBuffer += ((uiSectBoundary - (uiSectAlignAddr + uiCurrSectOffsetAddr))); uiNumBytes -= (uiSectBoundary - (uiSectAlignAddr + uiCurrSectOffsetAddr)); } else { memcpy(&pTempBuff[uiCurrSectOffsetAddr], pcBuffer, uiNumBytes); } if (IsFlash2x(Adapter)) SaveHeaderIfPresent(Adapter, (PUCHAR)pTempBuff, uiOffsetFromSectStart); FlashSectorErase(Adapter, uiPartOffset, 1); for (uiIndex = 0; uiIndex < Adapter->uiSectorSize; uiIndex += Adapter->ulFlashWriteSize) { if (Adapter->device_removed) { Status = -1; goto BeceemFlashBulkWriteStatus_EXIT; } if (STATUS_SUCCESS != (*Adapter->fpFlashWriteWithStatusCheck)(Adapter, uiPartOffset+uiIndex, &pTempBuff[uiIndex])) { Status = -1; goto BeceemFlashBulkWriteStatus_EXIT; } } if (bVerify) { for (uiIndex = 0; uiIndex < Adapter->uiSectorSize; uiIndex += MAX_RW_SIZE) { if (STATUS_SUCCESS == BeceemFlashBulkRead(Adapter, (PUINT)ucReadBk, uiOffsetFromSectStart + uiIndex, MAX_RW_SIZE)) { if (memcmp(ucReadBk, &pTempBuff[uiIndex], MAX_RW_SIZE)) { Status = STATUS_FAILURE; goto BeceemFlashBulkWriteStatus_EXIT; } } } } if (ulStatus) { BcmRestoreBlockProtectStatus(Adapter, ulStatus); ulStatus = 0; } uiCurrSectOffsetAddr = 0; uiSectAlignAddr = uiSectBoundary; uiSectBoundary += Adapter->uiSectorSize; uiOffsetFromSectStart += Adapter->uiSectorSize; uiNumSectTobeRead--; } /* * Cleanup. */ BeceemFlashBulkWriteStatus_EXIT: if (ulStatus) BcmRestoreBlockProtectStatus(Adapter, ulStatus); kfree(pTempBuff); Adapter->SelectedChip = RESET_CHIP_SELECT; return Status; } /* * Procedure: PropagateCalParamsFromEEPROMToMemory * * Description: Dumps the calibration section of EEPROM to DDR. * * Arguments: * Adapter - ptr to Adapter object instance * Returns: * OSAL_STATUS_CODE * */ int PropagateCalParamsFromEEPROMToMemory(struct bcm_mini_adapter *Adapter) { PCHAR pBuff = kmalloc(BUFFER_4K, GFP_KERNEL); unsigned int uiEepromSize = 0; unsigned int uiIndex = 0; unsigned int uiBytesToCopy = 0; unsigned int uiCalStartAddr = EEPROM_CALPARAM_START; unsigned int uiMemoryLoc = EEPROM_CAL_DATA_INTERNAL_LOC; unsigned int value; int Status = 0; if (!pBuff) return -ENOMEM; if (0 != BeceemEEPROMBulkRead(Adapter, &uiEepromSize, EEPROM_SIZE_OFFSET, 4)) { kfree(pBuff); return -1; } uiEepromSize >>= 16; if (uiEepromSize > 1024 * 1024) { kfree(pBuff); return -1; } uiBytesToCopy = MIN(BUFFER_4K, uiEepromSize); while (uiBytesToCopy) { if (0 != BeceemEEPROMBulkRead(Adapter, (PUINT)pBuff, uiCalStartAddr, uiBytesToCopy)) { Status = -1; break; } wrm(Adapter, uiMemoryLoc, (PCHAR)(((PULONG)pBuff) + uiIndex), uiBytesToCopy); uiMemoryLoc += uiBytesToCopy; uiEepromSize -= uiBytesToCopy; uiCalStartAddr += uiBytesToCopy; uiIndex += uiBytesToCopy / 4; uiBytesToCopy = MIN(BUFFER_4K, uiEepromSize); } value = 0xbeadbead; wrmalt(Adapter, EEPROM_CAL_DATA_INTERNAL_LOC - 4, &value, sizeof(value)); value = 0xbeadbead; wrmalt(Adapter, EEPROM_CAL_DATA_INTERNAL_LOC - 8, &value, sizeof(value)); kfree(pBuff); return Status; } /* * Procedure: PropagateCalParamsFromFlashToMemory * * Description: Dumps the calibration section of EEPROM to DDR. * * Arguments: * Adapter - ptr to Adapter object instance * Returns: * OSAL_STATUS_CODE * */ int PropagateCalParamsFromFlashToMemory(struct bcm_mini_adapter *Adapter) { PCHAR pBuff, pPtr; unsigned int uiEepromSize = 0; unsigned int uiBytesToCopy = 0; /* unsigned int uiIndex = 0; */ unsigned int uiCalStartAddr = EEPROM_CALPARAM_START; unsigned int uiMemoryLoc = EEPROM_CAL_DATA_INTERNAL_LOC; unsigned int value; int Status = 0; /* * Write the signature first. This will ensure firmware does not access EEPROM. */ value = 0xbeadbead; wrmalt(Adapter, EEPROM_CAL_DATA_INTERNAL_LOC - 4, &value, sizeof(value)); value = 0xbeadbead; wrmalt(Adapter, EEPROM_CAL_DATA_INTERNAL_LOC - 8, &value, sizeof(value)); if (0 != BeceemNVMRead(Adapter, &uiEepromSize, EEPROM_SIZE_OFFSET, 4)) return -1; uiEepromSize = ntohl(uiEepromSize); uiEepromSize >>= 16; /* * subtract the auto init section size */ uiEepromSize -= EEPROM_CALPARAM_START; if (uiEepromSize > 1024 * 1024) return -1; pBuff = kmalloc(uiEepromSize, GFP_KERNEL); if (pBuff == NULL) return -ENOMEM; if (0 != BeceemNVMRead(Adapter, (PUINT)pBuff, uiCalStartAddr, uiEepromSize)) { kfree(pBuff); return -1; } pPtr = pBuff; uiBytesToCopy = MIN(BUFFER_4K, uiEepromSize); while (uiBytesToCopy) { Status = wrm(Adapter, uiMemoryLoc, (PCHAR)pPtr, uiBytesToCopy); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "wrm failed with status :%d", Status); break; } pPtr += uiBytesToCopy; uiEepromSize -= uiBytesToCopy; uiMemoryLoc += uiBytesToCopy; uiBytesToCopy = MIN(BUFFER_4K, uiEepromSize); } kfree(pBuff); return Status; } /* * Procedure: BeceemEEPROMReadBackandVerify * * Description: Read back the data written and verifies. * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Data to be written. * uiOffset - Offset of the flash where data needs to be written to. * uiNumBytes - Number of bytes to be written. * Returns: * OSAL_STATUS_CODE * */ static int BeceemEEPROMReadBackandVerify(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes) { unsigned int uiRdbk = 0; unsigned int uiIndex = 0; unsigned int uiData = 0; unsigned int auiData[4] = {0}; while (uiNumBytes) { if (Adapter->device_removed) return -1; if (uiNumBytes >= MAX_RW_SIZE) { /* for the requests more than or equal to MAX_RW_SIZE bytes, use bulk read function to make the access faster. */ BeceemEEPROMBulkRead(Adapter, &auiData[0], uiOffset, MAX_RW_SIZE); if (memcmp(&pBuffer[uiIndex], &auiData[0], MAX_RW_SIZE)) { /* re-write */ BeceemEEPROMBulkWrite(Adapter, (PUCHAR)(pBuffer + uiIndex), uiOffset, MAX_RW_SIZE, FALSE); mdelay(3); BeceemEEPROMBulkRead(Adapter, &auiData[0], uiOffset, MAX_RW_SIZE); if (memcmp(&pBuffer[uiIndex], &auiData[0], MAX_RW_SIZE)) return -1; } uiOffset += MAX_RW_SIZE; uiNumBytes -= MAX_RW_SIZE; uiIndex += 4; } else if (uiNumBytes >= 4) { BeceemEEPROMBulkRead(Adapter, &uiData, uiOffset, 4); if (uiData != pBuffer[uiIndex]) { /* re-write */ BeceemEEPROMBulkWrite(Adapter, (PUCHAR)(pBuffer + uiIndex), uiOffset, 4, FALSE); mdelay(3); BeceemEEPROMBulkRead(Adapter, &uiData, uiOffset, 4); if (uiData != pBuffer[uiIndex]) return -1; } uiOffset += 4; uiNumBytes -= 4; uiIndex++; } else { /* Handle the reads less than 4 bytes... */ uiData = 0; memcpy(&uiData, ((PUCHAR)pBuffer) + (uiIndex * sizeof(unsigned int)), uiNumBytes); BeceemEEPROMBulkRead(Adapter, &uiRdbk, uiOffset, 4); if (memcmp(&uiData, &uiRdbk, uiNumBytes)) return -1; uiNumBytes = 0; } } return 0; } static VOID BcmSwapWord(unsigned int *ptr1) { unsigned int tempval = (unsigned int)*ptr1; char *ptr2 = (char *)&tempval; char *ptr = (char *)ptr1; ptr[0] = ptr2[3]; ptr[1] = ptr2[2]; ptr[2] = ptr2[1]; ptr[3] = ptr2[0]; } /* * Procedure: BeceemEEPROMWritePage * * Description: Performs page write (16bytes) to the EEPROM * * Arguments: * Adapter - ptr to Adapter object instance * uiData - Data to be written. * uiOffset - Offset of the EEPROM where data needs to be written to. * Returns: * OSAL_STATUS_CODE * */ static int BeceemEEPROMWritePage(struct bcm_mini_adapter *Adapter, unsigned int uiData[], unsigned int uiOffset) { unsigned int uiRetries = MAX_EEPROM_RETRIES * RETRIES_PER_DELAY; unsigned int uiStatus = 0; UCHAR uiEpromStatus = 0; unsigned int value = 0; /* Flush the Write/Read/Cmd queues. */ value = (EEPROM_WRITE_QUEUE_FLUSH | EEPROM_CMD_QUEUE_FLUSH | EEPROM_READ_QUEUE_FLUSH); wrmalt(Adapter, SPI_FLUSH_REG, &value, sizeof(value)); value = 0; wrmalt(Adapter, SPI_FLUSH_REG, &value, sizeof(value)); /* Clear the Empty/Avail/Full bits. After this it has been confirmed * that the bit was cleared by reading back the register. See NOTE below. * We also clear the Read queues as we do a EEPROM status register read * later. */ value = (EEPROM_WRITE_QUEUE_EMPTY | EEPROM_WRITE_QUEUE_AVAIL | EEPROM_WRITE_QUEUE_FULL | EEPROM_READ_DATA_AVAIL | EEPROM_READ_DATA_FULL); wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); /* Enable write */ value = EEPROM_WRITE_ENABLE; wrmalt(Adapter, EEPROM_CMDQ_SPI_REG, &value, sizeof(value)); /* We can write back to back 8bits * 16 into the queue and as we have * checked for the queue to be empty we can write in a burst. */ value = uiData[0]; BcmSwapWord(&value); wrm(Adapter, EEPROM_WRITE_DATAQ_REG, (PUCHAR)&value, 4); value = uiData[1]; BcmSwapWord(&value); wrm(Adapter, EEPROM_WRITE_DATAQ_REG, (PUCHAR)&value, 4); value = uiData[2]; BcmSwapWord(&value); wrm(Adapter, EEPROM_WRITE_DATAQ_REG, (PUCHAR)&value, 4); value = uiData[3]; BcmSwapWord(&value); wrm(Adapter, EEPROM_WRITE_DATAQ_REG, (PUCHAR)&value, 4); /* NOTE : After this write, on readback of EEPROM_SPI_Q_STATUS1_REG * shows that we see 7 for the EEPROM data write. Which means that * queue got full, also space is available as well as the queue is empty. * This may happen in sequence. */ value = EEPROM_16_BYTE_PAGE_WRITE | uiOffset; wrmalt(Adapter, EEPROM_CMDQ_SPI_REG, &value, sizeof(value)); /* Ideally we should loop here without tries and eventually succeed. * What we are checking if the previous write has completed, and this * may take time. We should wait till the Empty bit is set. */ uiStatus = 0; rdmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &uiStatus, sizeof(uiStatus)); while ((uiStatus & EEPROM_WRITE_QUEUE_EMPTY) == 0) { uiRetries--; if (uiRetries == 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "0x0f003004 = %x, %d retries failed.\n", uiStatus, MAX_EEPROM_RETRIES * RETRIES_PER_DELAY); return STATUS_FAILURE; } if (!(uiRetries%RETRIES_PER_DELAY)) udelay(1000); uiStatus = 0; rdmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &uiStatus, sizeof(uiStatus)); if (Adapter->device_removed == TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Modem got removed hence exiting from loop...."); return -ENODEV; } } if (uiRetries != 0) { /* Clear the ones that are set - either, Empty/Full/Avail bits */ value = (uiStatus & (EEPROM_WRITE_QUEUE_EMPTY | EEPROM_WRITE_QUEUE_AVAIL | EEPROM_WRITE_QUEUE_FULL)); wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); } /* Here we should check if the EEPROM status register is correct before * proceeding. Bit 0 in the EEPROM Status register should be 0 before * we proceed further. A 1 at Bit 0 indicates that the EEPROM is busy * with the previous write. Note also that issuing this read finally * means the previous write to the EEPROM has completed. */ uiRetries = MAX_EEPROM_RETRIES * RETRIES_PER_DELAY; uiEpromStatus = 0; while (uiRetries != 0) { uiEpromStatus = ReadEEPROMStatusRegister(Adapter); if (Adapter->device_removed == TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Modem has got removed hence exiting from loop..."); return -ENODEV; } if ((EEPROM_STATUS_REG_WRITE_BUSY & uiEpromStatus) == 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "EEPROM status register = %x tries = %d\n", uiEpromStatus, (MAX_EEPROM_RETRIES * RETRIES_PER_DELAY - uiRetries)); return STATUS_SUCCESS; } uiRetries--; if (uiRetries == 0) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "0x0f003004 = %x, for EEPROM status read %d retries failed.\n", uiEpromStatus, MAX_EEPROM_RETRIES * RETRIES_PER_DELAY); return STATUS_FAILURE; } uiEpromStatus = 0; if (!(uiRetries%RETRIES_PER_DELAY)) udelay(1000); } return STATUS_SUCCESS; } /* BeceemEEPROMWritePage */ /* * Procedure: BeceemEEPROMBulkWrite * * Description: Performs write to the EEPROM * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Data to be written. * uiOffset - Offset of the EEPROM where data needs to be written to. * uiNumBytes - Number of bytes to be written. * bVerify - read verify flag. * Returns: * OSAL_STATUS_CODE * */ int BeceemEEPROMBulkWrite(struct bcm_mini_adapter *Adapter, PUCHAR pBuffer, unsigned int uiOffset, unsigned int uiNumBytes, BOOLEAN bVerify) { unsigned int uiBytesToCopy = uiNumBytes; /* unsigned int uiRdbk = 0; */ unsigned int uiData[4] = {0}; unsigned int uiIndex = 0; unsigned int uiTempOffset = 0; unsigned int uiExtraBytes = 0; /* PUINT puiBuffer = (PUINT)pBuffer; * int value; */ if (uiOffset % MAX_RW_SIZE && uiBytesToCopy) { uiTempOffset = uiOffset - (uiOffset % MAX_RW_SIZE); uiExtraBytes = uiOffset - uiTempOffset; BeceemEEPROMBulkRead(Adapter, &uiData[0], uiTempOffset, MAX_RW_SIZE); if (uiBytesToCopy >= (16 - uiExtraBytes)) { memcpy((((PUCHAR)&uiData[0]) + uiExtraBytes), pBuffer, MAX_RW_SIZE - uiExtraBytes); if (STATUS_FAILURE == BeceemEEPROMWritePage(Adapter, uiData, uiTempOffset)) return STATUS_FAILURE; uiBytesToCopy -= (MAX_RW_SIZE - uiExtraBytes); uiIndex += (MAX_RW_SIZE - uiExtraBytes); uiOffset += (MAX_RW_SIZE - uiExtraBytes); } else { memcpy((((PUCHAR)&uiData[0]) + uiExtraBytes), pBuffer, uiBytesToCopy); if (STATUS_FAILURE == BeceemEEPROMWritePage(Adapter, uiData, uiTempOffset)) return STATUS_FAILURE; uiIndex += uiBytesToCopy; uiOffset += uiBytesToCopy; uiBytesToCopy = 0; } } while (uiBytesToCopy) { if (Adapter->device_removed) return -1; if (uiBytesToCopy >= MAX_RW_SIZE) { if (STATUS_FAILURE == BeceemEEPROMWritePage(Adapter, (PUINT) &pBuffer[uiIndex], uiOffset)) return STATUS_FAILURE; uiIndex += MAX_RW_SIZE; uiOffset += MAX_RW_SIZE; uiBytesToCopy -= MAX_RW_SIZE; } else { /* * To program non 16byte aligned data, read 16byte and then update. */ BeceemEEPROMBulkRead(Adapter, &uiData[0], uiOffset, 16); memcpy(&uiData[0], pBuffer + uiIndex, uiBytesToCopy); if (STATUS_FAILURE == BeceemEEPROMWritePage(Adapter, uiData, uiOffset)) return STATUS_FAILURE; uiBytesToCopy = 0; } } return 0; } /* * Procedure: BeceemNVMRead * * Description: Reads n number of bytes from NVM. * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Buffer to store the data read from NVM * uiOffset - Offset of NVM from where data should be read * uiNumBytes - Number of bytes to be read from the NVM. * * Returns: * OSAL_STATUS_SUCCESS - if NVM read is successful. * - if failed. */ int BeceemNVMRead(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes) { int Status = 0; #if !defined(BCM_SHM_INTERFACE) || defined(FLASH_DIRECT_ACCESS) unsigned int uiTemp = 0, value; #endif if (Adapter->eNVMType == NVM_FLASH) { if (Adapter->bFlashRawRead == FALSE) { if (IsSectionExistInVendorInfo(Adapter, Adapter->eActiveDSD)) return vendorextnReadSection(Adapter, (PUCHAR)pBuffer, Adapter->eActiveDSD, uiOffset, uiNumBytes); uiOffset = uiOffset + Adapter->ulFlashCalStart; } #if defined(BCM_SHM_INTERFACE) && !defined(FLASH_DIRECT_ACCESS) Status = bcmflash_raw_read((uiOffset / FLASH_PART_SIZE), (uiOffset % FLASH_PART_SIZE), (unsigned char *)pBuffer, uiNumBytes); #else rdmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); value = 0; wrmalt(Adapter, 0x0f000C80, &value, sizeof(value)); Status = BeceemFlashBulkRead(Adapter, pBuffer, uiOffset, uiNumBytes); wrmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); #endif } else if (Adapter->eNVMType == NVM_EEPROM) { Status = BeceemEEPROMBulkRead(Adapter, pBuffer, uiOffset, uiNumBytes); } else { Status = -1; } return Status; } /* * Procedure: BeceemNVMWrite * * Description: Writes n number of bytes to NVM. * * Arguments: * Adapter - ptr to Adapter object instance * pBuffer - Buffer contains the data to be written. * uiOffset - Offset of NVM where data to be written to. * uiNumBytes - Number of bytes to be written.. * * Returns: * OSAL_STATUS_SUCCESS - if NVM write is successful. * - if failed. */ int BeceemNVMWrite(struct bcm_mini_adapter *Adapter, PUINT pBuffer, unsigned int uiOffset, unsigned int uiNumBytes, BOOLEAN bVerify) { int Status = 0; unsigned int uiTemp = 0; unsigned int uiMemoryLoc = EEPROM_CAL_DATA_INTERNAL_LOC; unsigned int uiIndex = 0; #if !defined(BCM_SHM_INTERFACE) || defined(FLASH_DIRECT_ACCESS) unsigned int value; #endif unsigned int uiFlashOffset = 0; if (Adapter->eNVMType == NVM_FLASH) { if (IsSectionExistInVendorInfo(Adapter, Adapter->eActiveDSD)) Status = vendorextnWriteSection(Adapter, (PUCHAR)pBuffer, Adapter->eActiveDSD, uiOffset, uiNumBytes, bVerify); else { uiFlashOffset = uiOffset + Adapter->ulFlashCalStart; #if defined(BCM_SHM_INTERFACE) && !defined(FLASH_DIRECT_ACCESS) Status = bcmflash_raw_write((uiFlashOffset / FLASH_PART_SIZE), (uiFlashOffset % FLASH_PART_SIZE), (unsigned char *)pBuffer, uiNumBytes); #else rdmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); value = 0; wrmalt(Adapter, 0x0f000C80, &value, sizeof(value)); if (Adapter->bStatusWrite == TRUE) Status = BeceemFlashBulkWriteStatus(Adapter, pBuffer, uiFlashOffset, uiNumBytes , bVerify); else Status = BeceemFlashBulkWrite(Adapter, pBuffer, uiFlashOffset, uiNumBytes, bVerify); #endif } if (uiOffset >= EEPROM_CALPARAM_START) { uiMemoryLoc += (uiOffset - EEPROM_CALPARAM_START); while (uiNumBytes) { if (uiNumBytes > BUFFER_4K) { wrm(Adapter, (uiMemoryLoc+uiIndex), (PCHAR)(pBuffer + (uiIndex / 4)), BUFFER_4K); uiNumBytes -= BUFFER_4K; uiIndex += BUFFER_4K; } else { wrm(Adapter, uiMemoryLoc+uiIndex, (PCHAR)(pBuffer + (uiIndex / 4)), uiNumBytes); uiNumBytes = 0; break; } } } else { if ((uiOffset + uiNumBytes) > EEPROM_CALPARAM_START) { ULONG ulBytesTobeSkipped = 0; PUCHAR pcBuffer = (PUCHAR)pBuffer; /* char pointer to take care of odd byte cases. */ uiNumBytes -= (EEPROM_CALPARAM_START - uiOffset); ulBytesTobeSkipped += (EEPROM_CALPARAM_START - uiOffset); uiOffset += (EEPROM_CALPARAM_START - uiOffset); while (uiNumBytes) { if (uiNumBytes > BUFFER_4K) { wrm(Adapter, uiMemoryLoc + uiIndex, (PCHAR)&pcBuffer[ulBytesTobeSkipped + uiIndex], BUFFER_4K); uiNumBytes -= BUFFER_4K; uiIndex += BUFFER_4K; } else { wrm(Adapter, uiMemoryLoc + uiIndex, (PCHAR)&pcBuffer[ulBytesTobeSkipped + uiIndex], uiNumBytes); uiNumBytes = 0; break; } } } } /* restore the values. */ wrmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); } else if (Adapter->eNVMType == NVM_EEPROM) { Status = BeceemEEPROMBulkWrite(Adapter, (PUCHAR)pBuffer, uiOffset, uiNumBytes, bVerify); if (bVerify) Status = BeceemEEPROMReadBackandVerify(Adapter, (PUINT)pBuffer, uiOffset, uiNumBytes); } else { Status = -1; } return Status; } /* * Procedure: BcmUpdateSectorSize * * Description: Updates the sector size to FLASH. * * Arguments: * Adapter - ptr to Adapter object instance * uiSectorSize - sector size * * Returns: * OSAL_STATUS_SUCCESS - if NVM write is successful. * - if failed. */ int BcmUpdateSectorSize(struct bcm_mini_adapter *Adapter, unsigned int uiSectorSize) { int Status = -1; struct bcm_flash_cs_info sFlashCsInfo = {0}; unsigned int uiTemp = 0; unsigned int uiSectorSig = 0; unsigned int uiCurrentSectorSize = 0; unsigned int value; rdmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); value = 0; wrmalt(Adapter, 0x0f000C80, &value, sizeof(value)); /* * Before updating the sector size in the reserved area, check if already present. */ BeceemFlashBulkRead(Adapter, (PUINT)&sFlashCsInfo, Adapter->ulFlashControlSectionStart, sizeof(sFlashCsInfo)); uiSectorSig = ntohl(sFlashCsInfo.FlashSectorSizeSig); uiCurrentSectorSize = ntohl(sFlashCsInfo.FlashSectorSize); if (uiSectorSig == FLASH_SECTOR_SIZE_SIG) { if ((uiCurrentSectorSize <= MAX_SECTOR_SIZE) && (uiCurrentSectorSize >= MIN_SECTOR_SIZE)) { if (uiSectorSize == uiCurrentSectorSize) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Provided sector size is same as programmed in Flash"); Status = STATUS_SUCCESS; goto Restore; } } } if ((uiSectorSize <= MAX_SECTOR_SIZE) && (uiSectorSize >= MIN_SECTOR_SIZE)) { sFlashCsInfo.FlashSectorSize = htonl(uiSectorSize); sFlashCsInfo.FlashSectorSizeSig = htonl(FLASH_SECTOR_SIZE_SIG); Status = BeceemFlashBulkWrite(Adapter, (PUINT)&sFlashCsInfo, Adapter->ulFlashControlSectionStart, sizeof(sFlashCsInfo), TRUE); } Restore: /* restore the values. */ wrmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); return Status; } /* * Procedure: BcmGetFlashSectorSize * * Description: Finds the sector size of the FLASH. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * unsigned int - sector size. * */ static unsigned int BcmGetFlashSectorSize(struct bcm_mini_adapter *Adapter, unsigned int FlashSectorSizeSig, unsigned int FlashSectorSize) { unsigned int uiSectorSize = 0; unsigned int uiSectorSig = 0; if (Adapter->bSectorSizeOverride && (Adapter->uiSectorSizeInCFG <= MAX_SECTOR_SIZE && Adapter->uiSectorSizeInCFG >= MIN_SECTOR_SIZE)) { Adapter->uiSectorSize = Adapter->uiSectorSizeInCFG; } else { uiSectorSig = FlashSectorSizeSig; if (uiSectorSig == FLASH_SECTOR_SIZE_SIG) { uiSectorSize = FlashSectorSize; /* * If the sector size stored in the FLASH makes sense then use it. */ if (uiSectorSize <= MAX_SECTOR_SIZE && uiSectorSize >= MIN_SECTOR_SIZE) { Adapter->uiSectorSize = uiSectorSize; } else if (Adapter->uiSectorSizeInCFG <= MAX_SECTOR_SIZE && Adapter->uiSectorSizeInCFG >= MIN_SECTOR_SIZE) { /* No valid size in FLASH, check if Config file has it. */ Adapter->uiSectorSize = Adapter->uiSectorSizeInCFG; } else { /* Init to Default, if none of the above works. */ Adapter->uiSectorSize = DEFAULT_SECTOR_SIZE; } } else { if (Adapter->uiSectorSizeInCFG <= MAX_SECTOR_SIZE && Adapter->uiSectorSizeInCFG >= MIN_SECTOR_SIZE) Adapter->uiSectorSize = Adapter->uiSectorSizeInCFG; else Adapter->uiSectorSize = DEFAULT_SECTOR_SIZE; } } BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Sector size :%x\n", Adapter->uiSectorSize); return Adapter->uiSectorSize; } /* * Procedure: BcmInitEEPROMQueues * * Description: Initialization of EEPROM queues. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * */ static int BcmInitEEPROMQueues(struct bcm_mini_adapter *Adapter) { unsigned int value = 0; /* CHIP Bug : Clear the Avail bits on the Read queue. The default * value on this register is supposed to be 0x00001102. * But we get 0x00001122. */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Fixing reset value on 0x0f003004 register\n"); value = EEPROM_READ_DATA_AVAIL; wrmalt(Adapter, EEPROM_SPI_Q_STATUS1_REG, &value, sizeof(value)); /* Flush the all the EEPROM queues. */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, " Flushing the queues\n"); value = EEPROM_ALL_QUEUE_FLUSH; wrmalt(Adapter, SPI_FLUSH_REG, &value, sizeof(value)); value = 0; wrmalt(Adapter, SPI_FLUSH_REG, &value, sizeof(value)); /* Read the EEPROM Status Register. Just to see, no real purpose. */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "EEPROM Status register value = %x\n", ReadEEPROMStatusRegister(Adapter)); return STATUS_SUCCESS; } /* BcmInitEEPROMQueues() */ /* * Procedure: BcmInitNVM * * Description: Initialization of NVM, EEPROM size,FLASH size, sector size etc. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * */ int BcmInitNVM(struct bcm_mini_adapter *ps_adapter) { BcmValidateNvmType(ps_adapter); BcmInitEEPROMQueues(ps_adapter); if (ps_adapter->eNVMType == NVM_AUTODETECT) { ps_adapter->eNVMType = BcmGetNvmType(ps_adapter); if (ps_adapter->eNVMType == NVM_UNKNOWN) BCM_DEBUG_PRINT(ps_adapter, DBG_TYPE_PRINTK, 0, 0, "NVM Type is unknown!!\n"); } else if (ps_adapter->eNVMType == NVM_FLASH) { BcmGetFlashCSInfo(ps_adapter); } BcmGetNvmSize(ps_adapter); return STATUS_SUCCESS; } /* BcmGetNvmSize : set the EEPROM or flash size in Adapter. * * Input Parameter: * Adapter data structure * Return Value : * 0. means success; */ static int BcmGetNvmSize(struct bcm_mini_adapter *Adapter) { if (Adapter->eNVMType == NVM_EEPROM) Adapter->uiNVMDSDSize = BcmGetEEPROMSize(Adapter); else if (Adapter->eNVMType == NVM_FLASH) Adapter->uiNVMDSDSize = BcmGetFlashSize(Adapter); return 0; } /* * Procedure: BcmValidateNvm * * Description: Validates the NVM Type option selected against the device * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * */ static VOID BcmValidateNvmType(struct bcm_mini_adapter *Adapter) { /* * if forcing the FLASH through CFG file, we should ensure device really has a FLASH. * Accessing the FLASH address without the FLASH being present can cause hang/freeze etc. * So if NVM_FLASH is selected for older chipsets, change it to AUTODETECT where EEPROM is 1st choice. */ if (Adapter->eNVMType == NVM_FLASH && Adapter->chip_id < 0xBECE3300) Adapter->eNVMType = NVM_AUTODETECT; } /* * Procedure: BcmReadFlashRDID * * Description: Reads ID from Serial Flash * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * Flash ID */ static ULONG BcmReadFlashRDID(struct bcm_mini_adapter *Adapter) { ULONG ulRDID = 0; unsigned int value; /* * Read ID Instruction. */ value = (FLASH_CMD_READ_ID << 24); wrmalt(Adapter, FLASH_SPI_CMDQ_REG, &value, sizeof(value)); /* Delay */ udelay(10); /* * Read SPI READQ REG. The output will be WWXXYYZZ. * The ID is 3Bytes long and is WWXXYY. ZZ needs to be Ignored. */ rdmalt(Adapter, FLASH_SPI_READQ_REG, (PUINT)&ulRDID, sizeof(ulRDID)); return ulRDID >> 8; } int BcmAllocFlashCSStructure(struct bcm_mini_adapter *psAdapter) { if (!psAdapter) { BCM_DEBUG_PRINT(psAdapter, DBG_TYPE_PRINTK, 0, 0, "Adapter structure point is NULL"); return -EINVAL; } psAdapter->psFlashCSInfo = kzalloc(sizeof(struct bcm_flash_cs_info), GFP_KERNEL); if (psAdapter->psFlashCSInfo == NULL) { BCM_DEBUG_PRINT(psAdapter, DBG_TYPE_PRINTK, 0, 0, "Can't Allocate memory for Flash 1.x"); return -ENOMEM; } psAdapter->psFlash2xCSInfo = kzalloc(sizeof(struct bcm_flash2x_cs_info), GFP_KERNEL); if (!psAdapter->psFlash2xCSInfo) { BCM_DEBUG_PRINT(psAdapter, DBG_TYPE_PRINTK, 0, 0, "Can't Allocate memory for Flash 2.x"); kfree(psAdapter->psFlashCSInfo); return -ENOMEM; } psAdapter->psFlash2xVendorInfo = kzalloc(sizeof(struct bcm_flash2x_vendor_info), GFP_KERNEL); if (!psAdapter->psFlash2xVendorInfo) { BCM_DEBUG_PRINT(psAdapter, DBG_TYPE_PRINTK, 0, 0, "Can't Allocate Vendor Info Memory for Flash 2.x"); kfree(psAdapter->psFlashCSInfo); kfree(psAdapter->psFlash2xCSInfo); return -ENOMEM; } return STATUS_SUCCESS; } int BcmDeAllocFlashCSStructure(struct bcm_mini_adapter *psAdapter) { if (!psAdapter) { BCM_DEBUG_PRINT(psAdapter, DBG_TYPE_PRINTK, 0, 0, "Adapter structure point is NULL"); return -EINVAL; } kfree(psAdapter->psFlashCSInfo); kfree(psAdapter->psFlash2xCSInfo); kfree(psAdapter->psFlash2xVendorInfo); return STATUS_SUCCESS; } static int BcmDumpFlash2XCSStructure(struct bcm_flash2x_cs_info *psFlash2xCSInfo, struct bcm_mini_adapter *Adapter) { unsigned int Index = 0; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "**********************FLASH2X CS Structure *******************"); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Signature is :%x", (psFlash2xCSInfo->MagicNumber)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Flash Major Version :%d", MAJOR_VERSION(psFlash2xCSInfo->FlashLayoutVersion)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Flash Minor Version :%d", MINOR_VERSION(psFlash2xCSInfo->FlashLayoutVersion)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, " ISOImageMajorVersion:0x%x", (psFlash2xCSInfo->ISOImageVersion)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "SCSIFirmwareMajorVersion :0x%x", (psFlash2xCSInfo->SCSIFirmwareVersion)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForPart1ISOImage :0x%x", (psFlash2xCSInfo->OffsetFromZeroForPart1ISOImage)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForScsiFirmware :0x%x", (psFlash2xCSInfo->OffsetFromZeroForScsiFirmware)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "SizeOfScsiFirmware :0x%x", (psFlash2xCSInfo->SizeOfScsiFirmware)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForPart2ISOImage :0x%x", (psFlash2xCSInfo->OffsetFromZeroForPart2ISOImage)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForDSDStart :0x%x", (psFlash2xCSInfo->OffsetFromZeroForDSDStart)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForDSDEnd :0x%x", (psFlash2xCSInfo->OffsetFromZeroForDSDEnd)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForVSAStart :0x%x", (psFlash2xCSInfo->OffsetFromZeroForVSAStart)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForVSAEnd :0x%x", (psFlash2xCSInfo->OffsetFromZeroForVSAEnd)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForControlSectionStart :0x%x", (psFlash2xCSInfo->OffsetFromZeroForControlSectionStart)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForControlSectionData :0x%x", (psFlash2xCSInfo->OffsetFromZeroForControlSectionData)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "CDLessInactivityTimeout :0x%x", (psFlash2xCSInfo->CDLessInactivityTimeout)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "NewImageSignature :0x%x", (psFlash2xCSInfo->NewImageSignature)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "FlashSectorSizeSig :0x%x", (psFlash2xCSInfo->FlashSectorSizeSig)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "FlashSectorSize :0x%x", (psFlash2xCSInfo->FlashSectorSize)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "FlashWriteSupportSize :0x%x", (psFlash2xCSInfo->FlashWriteSupportSize)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "TotalFlashSize :0x%X", (psFlash2xCSInfo->TotalFlashSize)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "FlashBaseAddr :0x%x", (psFlash2xCSInfo->FlashBaseAddr)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "FlashPartMaxSize :0x%x", (psFlash2xCSInfo->FlashPartMaxSize)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "IsCDLessDeviceBootSig :0x%x", (psFlash2xCSInfo->IsCDLessDeviceBootSig)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "MassStorageTimeout :0x%x", (psFlash2xCSInfo->MassStorageTimeout)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage1Part1Start :0x%x", (psFlash2xCSInfo->OffsetISOImage1Part1Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage1Part1End :0x%x", (psFlash2xCSInfo->OffsetISOImage1Part1End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage1Part2Start :0x%x", (psFlash2xCSInfo->OffsetISOImage1Part2Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage1Part2End :0x%x", (psFlash2xCSInfo->OffsetISOImage1Part2End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage1Part3Start :0x%x", (psFlash2xCSInfo->OffsetISOImage1Part3Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage1Part3End :0x%x", (psFlash2xCSInfo->OffsetISOImage1Part3End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage2Part1Start :0x%x", (psFlash2xCSInfo->OffsetISOImage2Part1Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage2Part1End :0x%x", (psFlash2xCSInfo->OffsetISOImage2Part1End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage2Part2Start :0x%x", (psFlash2xCSInfo->OffsetISOImage2Part2Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage2Part2End :0x%x", (psFlash2xCSInfo->OffsetISOImage2Part2End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage2Part3Start :0x%x", (psFlash2xCSInfo->OffsetISOImage2Part3Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetISOImage2Part3End :0x%x", (psFlash2xCSInfo->OffsetISOImage2Part3End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromDSDStartForDSDHeader :0x%x", (psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForDSD1Start :0x%x", (psFlash2xCSInfo->OffsetFromZeroForDSD1Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForDSD1End :0x%x", (psFlash2xCSInfo->OffsetFromZeroForDSD1End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForDSD2Start :0x%x", (psFlash2xCSInfo->OffsetFromZeroForDSD2Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForDSD2End :0x%x", (psFlash2xCSInfo->OffsetFromZeroForDSD2End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForVSA1Start :0x%x", (psFlash2xCSInfo->OffsetFromZeroForVSA1Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForVSA1End :0x%x", (psFlash2xCSInfo->OffsetFromZeroForVSA1End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForVSA2Start :0x%x", (psFlash2xCSInfo->OffsetFromZeroForVSA2Start)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "OffsetFromZeroForVSA2End :0x%x", (psFlash2xCSInfo->OffsetFromZeroForVSA2End)); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Sector Access Bit Map is Defined as :"); for (Index = 0; Index < (FLASH2X_TOTAL_SIZE / (DEFAULT_SECTOR_SIZE * 16)); Index++) BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "SectorAccessBitMap[%d] :0x%x", Index, (psFlash2xCSInfo->SectorAccessBitMap[Index])); return STATUS_SUCCESS; } static int ConvertEndianOf2XCSStructure(struct bcm_flash2x_cs_info *psFlash2xCSInfo) { unsigned int Index = 0; psFlash2xCSInfo->MagicNumber = ntohl(psFlash2xCSInfo->MagicNumber); psFlash2xCSInfo->FlashLayoutVersion = ntohl(psFlash2xCSInfo->FlashLayoutVersion); /* psFlash2xCSInfo->FlashLayoutMinorVersion = ntohs(psFlash2xCSInfo->FlashLayoutMinorVersion); */ psFlash2xCSInfo->ISOImageVersion = ntohl(psFlash2xCSInfo->ISOImageVersion); psFlash2xCSInfo->SCSIFirmwareVersion = ntohl(psFlash2xCSInfo->SCSIFirmwareVersion); psFlash2xCSInfo->OffsetFromZeroForPart1ISOImage = ntohl(psFlash2xCSInfo->OffsetFromZeroForPart1ISOImage); psFlash2xCSInfo->OffsetFromZeroForScsiFirmware = ntohl(psFlash2xCSInfo->OffsetFromZeroForScsiFirmware); psFlash2xCSInfo->SizeOfScsiFirmware = ntohl(psFlash2xCSInfo->SizeOfScsiFirmware); psFlash2xCSInfo->OffsetFromZeroForPart2ISOImage = ntohl(psFlash2xCSInfo->OffsetFromZeroForPart2ISOImage); psFlash2xCSInfo->OffsetFromZeroForDSDStart = ntohl(psFlash2xCSInfo->OffsetFromZeroForDSDStart); psFlash2xCSInfo->OffsetFromZeroForDSDEnd = ntohl(psFlash2xCSInfo->OffsetFromZeroForDSDEnd); psFlash2xCSInfo->OffsetFromZeroForVSAStart = ntohl(psFlash2xCSInfo->OffsetFromZeroForVSAStart); psFlash2xCSInfo->OffsetFromZeroForVSAEnd = ntohl(psFlash2xCSInfo->OffsetFromZeroForVSAEnd); psFlash2xCSInfo->OffsetFromZeroForControlSectionStart = ntohl(psFlash2xCSInfo->OffsetFromZeroForControlSectionStart); psFlash2xCSInfo->OffsetFromZeroForControlSectionData = ntohl(psFlash2xCSInfo->OffsetFromZeroForControlSectionData); psFlash2xCSInfo->CDLessInactivityTimeout = ntohl(psFlash2xCSInfo->CDLessInactivityTimeout); psFlash2xCSInfo->NewImageSignature = ntohl(psFlash2xCSInfo->NewImageSignature); psFlash2xCSInfo->FlashSectorSizeSig = ntohl(psFlash2xCSInfo->FlashSectorSizeSig); psFlash2xCSInfo->FlashSectorSize = ntohl(psFlash2xCSInfo->FlashSectorSize); psFlash2xCSInfo->FlashWriteSupportSize = ntohl(psFlash2xCSInfo->FlashWriteSupportSize); psFlash2xCSInfo->TotalFlashSize = ntohl(psFlash2xCSInfo->TotalFlashSize); psFlash2xCSInfo->FlashBaseAddr = ntohl(psFlash2xCSInfo->FlashBaseAddr); psFlash2xCSInfo->FlashPartMaxSize = ntohl(psFlash2xCSInfo->FlashPartMaxSize); psFlash2xCSInfo->IsCDLessDeviceBootSig = ntohl(psFlash2xCSInfo->IsCDLessDeviceBootSig); psFlash2xCSInfo->MassStorageTimeout = ntohl(psFlash2xCSInfo->MassStorageTimeout); psFlash2xCSInfo->OffsetISOImage1Part1Start = ntohl(psFlash2xCSInfo->OffsetISOImage1Part1Start); psFlash2xCSInfo->OffsetISOImage1Part1End = ntohl(psFlash2xCSInfo->OffsetISOImage1Part1End); psFlash2xCSInfo->OffsetISOImage1Part2Start = ntohl(psFlash2xCSInfo->OffsetISOImage1Part2Start); psFlash2xCSInfo->OffsetISOImage1Part2End = ntohl(psFlash2xCSInfo->OffsetISOImage1Part2End); psFlash2xCSInfo->OffsetISOImage1Part3Start = ntohl(psFlash2xCSInfo->OffsetISOImage1Part3Start); psFlash2xCSInfo->OffsetISOImage1Part3End = ntohl(psFlash2xCSInfo->OffsetISOImage1Part3End); psFlash2xCSInfo->OffsetISOImage2Part1Start = ntohl(psFlash2xCSInfo->OffsetISOImage2Part1Start); psFlash2xCSInfo->OffsetISOImage2Part1End = ntohl(psFlash2xCSInfo->OffsetISOImage2Part1End); psFlash2xCSInfo->OffsetISOImage2Part2Start = ntohl(psFlash2xCSInfo->OffsetISOImage2Part2Start); psFlash2xCSInfo->OffsetISOImage2Part2End = ntohl(psFlash2xCSInfo->OffsetISOImage2Part2End); psFlash2xCSInfo->OffsetISOImage2Part3Start = ntohl(psFlash2xCSInfo->OffsetISOImage2Part3Start); psFlash2xCSInfo->OffsetISOImage2Part3End = ntohl(psFlash2xCSInfo->OffsetISOImage2Part3End); psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader = ntohl(psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader); psFlash2xCSInfo->OffsetFromZeroForDSD1Start = ntohl(psFlash2xCSInfo->OffsetFromZeroForDSD1Start); psFlash2xCSInfo->OffsetFromZeroForDSD1End = ntohl(psFlash2xCSInfo->OffsetFromZeroForDSD1End); psFlash2xCSInfo->OffsetFromZeroForDSD2Start = ntohl(psFlash2xCSInfo->OffsetFromZeroForDSD2Start); psFlash2xCSInfo->OffsetFromZeroForDSD2End = ntohl(psFlash2xCSInfo->OffsetFromZeroForDSD2End); psFlash2xCSInfo->OffsetFromZeroForVSA1Start = ntohl(psFlash2xCSInfo->OffsetFromZeroForVSA1Start); psFlash2xCSInfo->OffsetFromZeroForVSA1End = ntohl(psFlash2xCSInfo->OffsetFromZeroForVSA1End); psFlash2xCSInfo->OffsetFromZeroForVSA2Start = ntohl(psFlash2xCSInfo->OffsetFromZeroForVSA2Start); psFlash2xCSInfo->OffsetFromZeroForVSA2End = ntohl(psFlash2xCSInfo->OffsetFromZeroForVSA2End); for (Index = 0; Index < (FLASH2X_TOTAL_SIZE / (DEFAULT_SECTOR_SIZE * 16)); Index++) psFlash2xCSInfo->SectorAccessBitMap[Index] = ntohl(psFlash2xCSInfo->SectorAccessBitMap[Index]); return STATUS_SUCCESS; } static int ConvertEndianOfCSStructure(struct bcm_flash_cs_info *psFlashCSInfo) { /* unsigned int Index = 0; */ psFlashCSInfo->MagicNumber = ntohl(psFlashCSInfo->MagicNumber); psFlashCSInfo->FlashLayoutVersion = ntohl(psFlashCSInfo->FlashLayoutVersion); psFlashCSInfo->ISOImageVersion = ntohl(psFlashCSInfo->ISOImageVersion); /* won't convert according to old assumption */ psFlashCSInfo->SCSIFirmwareVersion = (psFlashCSInfo->SCSIFirmwareVersion); psFlashCSInfo->OffsetFromZeroForPart1ISOImage = ntohl(psFlashCSInfo->OffsetFromZeroForPart1ISOImage); psFlashCSInfo->OffsetFromZeroForScsiFirmware = ntohl(psFlashCSInfo->OffsetFromZeroForScsiFirmware); psFlashCSInfo->SizeOfScsiFirmware = ntohl(psFlashCSInfo->SizeOfScsiFirmware); psFlashCSInfo->OffsetFromZeroForPart2ISOImage = ntohl(psFlashCSInfo->OffsetFromZeroForPart2ISOImage); psFlashCSInfo->OffsetFromZeroForCalibrationStart = ntohl(psFlashCSInfo->OffsetFromZeroForCalibrationStart); psFlashCSInfo->OffsetFromZeroForCalibrationEnd = ntohl(psFlashCSInfo->OffsetFromZeroForCalibrationEnd); psFlashCSInfo->OffsetFromZeroForVSAStart = ntohl(psFlashCSInfo->OffsetFromZeroForVSAStart); psFlashCSInfo->OffsetFromZeroForVSAEnd = ntohl(psFlashCSInfo->OffsetFromZeroForVSAEnd); psFlashCSInfo->OffsetFromZeroForControlSectionStart = ntohl(psFlashCSInfo->OffsetFromZeroForControlSectionStart); psFlashCSInfo->OffsetFromZeroForControlSectionData = ntohl(psFlashCSInfo->OffsetFromZeroForControlSectionData); psFlashCSInfo->CDLessInactivityTimeout = ntohl(psFlashCSInfo->CDLessInactivityTimeout); psFlashCSInfo->NewImageSignature = ntohl(psFlashCSInfo->NewImageSignature); psFlashCSInfo->FlashSectorSizeSig = ntohl(psFlashCSInfo->FlashSectorSizeSig); psFlashCSInfo->FlashSectorSize = ntohl(psFlashCSInfo->FlashSectorSize); psFlashCSInfo->FlashWriteSupportSize = ntohl(psFlashCSInfo->FlashWriteSupportSize); psFlashCSInfo->TotalFlashSize = ntohl(psFlashCSInfo->TotalFlashSize); psFlashCSInfo->FlashBaseAddr = ntohl(psFlashCSInfo->FlashBaseAddr); psFlashCSInfo->FlashPartMaxSize = ntohl(psFlashCSInfo->FlashPartMaxSize); psFlashCSInfo->IsCDLessDeviceBootSig = ntohl(psFlashCSInfo->IsCDLessDeviceBootSig); psFlashCSInfo->MassStorageTimeout = ntohl(psFlashCSInfo->MassStorageTimeout); return STATUS_SUCCESS; } static int IsSectionExistInVendorInfo(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val section) { return (Adapter->uiVendorExtnFlag && (Adapter->psFlash2xVendorInfo->VendorSection[section].AccessFlags & FLASH2X_SECTION_PRESENT) && (Adapter->psFlash2xVendorInfo->VendorSection[section].OffsetFromZeroForSectionStart != UNINIT_PTR_IN_CS)); } static VOID UpdateVendorInfo(struct bcm_mini_adapter *Adapter) { B_UINT32 i = 0; unsigned int uiSizeSection = 0; Adapter->uiVendorExtnFlag = FALSE; for (i = 0; i < TOTAL_SECTIONS; i++) Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart = UNINIT_PTR_IN_CS; if (STATUS_SUCCESS != vendorextnGetSectionInfo(Adapter, Adapter->psFlash2xVendorInfo)) return; i = 0; while (i < TOTAL_SECTIONS) { if (!(Adapter->psFlash2xVendorInfo->VendorSection[i].AccessFlags & FLASH2X_SECTION_PRESENT)) { i++; continue; } Adapter->uiVendorExtnFlag = TRUE; uiSizeSection = (Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionEnd - Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart); switch (i) { case DSD0: if ((uiSizeSection >= (Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + sizeof(struct bcm_dsd_header))) && (UNINIT_PTR_IN_CS != Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart)) Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDEnd = VENDOR_PTR_IN_CS; else Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDEnd = UNINIT_PTR_IN_CS; break; case DSD1: if ((uiSizeSection >= (Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + sizeof(struct bcm_dsd_header))) && (UNINIT_PTR_IN_CS != Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart)) Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1End = VENDOR_PTR_IN_CS; else Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1End = UNINIT_PTR_IN_CS; break; case DSD2: if ((uiSizeSection >= (Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + sizeof(struct bcm_dsd_header))) && (UNINIT_PTR_IN_CS != Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart)) Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2End = VENDOR_PTR_IN_CS; else Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2End = UNINIT_PTR_IN_CS; break; case VSA0: if (UNINIT_PTR_IN_CS != Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart) Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAEnd = VENDOR_PTR_IN_CS; else Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAEnd = UNINIT_PTR_IN_CS; break; case VSA1: if (UNINIT_PTR_IN_CS != Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart) Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1End = VENDOR_PTR_IN_CS; else Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1End = UNINIT_PTR_IN_CS; break; case VSA2: if (UNINIT_PTR_IN_CS != Adapter->psFlash2xVendorInfo->VendorSection[i].OffsetFromZeroForSectionStart) Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2End = VENDOR_PTR_IN_CS; else Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2Start = Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2End = UNINIT_PTR_IN_CS; break; default: break; } i++; } } /* * Procedure: BcmGetFlashCSInfo * * Description: Reads control structure and gets Cal section addresses. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * */ static int BcmGetFlashCSInfo(struct bcm_mini_adapter *Adapter) { /* struct bcm_flash_cs_info sFlashCsInfo = {0}; */ #if !defined(BCM_SHM_INTERFACE) || defined(FLASH_DIRECT_ACCESS) unsigned int value; #endif unsigned int uiFlashLayoutMajorVersion; Adapter->uiFlashLayoutMinorVersion = 0; Adapter->uiFlashLayoutMajorVersion = 0; Adapter->ulFlashControlSectionStart = FLASH_CS_INFO_START_ADDR; Adapter->uiFlashBaseAdd = 0; Adapter->ulFlashCalStart = 0; memset(Adapter->psFlashCSInfo, 0 , sizeof(struct bcm_flash_cs_info)); memset(Adapter->psFlash2xCSInfo, 0 , sizeof(struct bcm_flash2x_cs_info)); if (!Adapter->bDDRInitDone) { value = FLASH_CONTIGIOUS_START_ADDR_BEFORE_INIT; wrmalt(Adapter, 0xAF00A080, &value, sizeof(value)); } /* Reading first 8 Bytes to get the Flash Layout * MagicNumber(4 bytes) +FlashLayoutMinorVersion(2 Bytes) +FlashLayoutMajorVersion(2 Bytes) */ BeceemFlashBulkRead(Adapter, (PUINT)Adapter->psFlashCSInfo, Adapter->ulFlashControlSectionStart, 8); Adapter->psFlashCSInfo->FlashLayoutVersion = ntohl(Adapter->psFlashCSInfo->FlashLayoutVersion); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Flash Layout Version :%X", (Adapter->psFlashCSInfo->FlashLayoutVersion)); /* BCM_DEBUG_PRINT(Adapter,DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Flash Layout Minor Version :%d\n", ntohs(sFlashCsInfo.FlashLayoutMinorVersion)); */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Signature is :%x\n", ntohl(Adapter->psFlashCSInfo->MagicNumber)); if (FLASH_CONTROL_STRUCT_SIGNATURE == ntohl(Adapter->psFlashCSInfo->MagicNumber)) { uiFlashLayoutMajorVersion = MAJOR_VERSION((Adapter->psFlashCSInfo->FlashLayoutVersion)); Adapter->uiFlashLayoutMinorVersion = MINOR_VERSION((Adapter->psFlashCSInfo->FlashLayoutVersion)); } else { Adapter->uiFlashLayoutMinorVersion = 0; uiFlashLayoutMajorVersion = 0; } BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "FLASH LAYOUT MAJOR VERSION :%X", uiFlashLayoutMajorVersion); if (uiFlashLayoutMajorVersion < FLASH_2X_MAJOR_NUMBER) { BeceemFlashBulkRead(Adapter, (PUINT)Adapter->psFlashCSInfo, Adapter->ulFlashControlSectionStart, sizeof(struct bcm_flash_cs_info)); ConvertEndianOfCSStructure(Adapter->psFlashCSInfo); Adapter->ulFlashCalStart = (Adapter->psFlashCSInfo->OffsetFromZeroForCalibrationStart); if (!((Adapter->uiFlashLayoutMajorVersion == 1) && (Adapter->uiFlashLayoutMinorVersion == 1))) Adapter->ulFlashControlSectionStart = Adapter->psFlashCSInfo->OffsetFromZeroForControlSectionStart; if ((FLASH_CONTROL_STRUCT_SIGNATURE == (Adapter->psFlashCSInfo->MagicNumber)) && (SCSI_FIRMWARE_MINOR_VERSION <= MINOR_VERSION(Adapter->psFlashCSInfo->SCSIFirmwareVersion)) && (FLASH_SECTOR_SIZE_SIG == (Adapter->psFlashCSInfo->FlashSectorSizeSig)) && (BYTE_WRITE_SUPPORT == (Adapter->psFlashCSInfo->FlashWriteSupportSize))) { Adapter->ulFlashWriteSize = (Adapter->psFlashCSInfo->FlashWriteSupportSize); Adapter->fpFlashWrite = flashByteWrite; Adapter->fpFlashWriteWithStatusCheck = flashByteWriteStatus; } else { Adapter->ulFlashWriteSize = MAX_RW_SIZE; Adapter->fpFlashWrite = flashWrite; Adapter->fpFlashWriteWithStatusCheck = flashWriteStatus; } BcmGetFlashSectorSize(Adapter, (Adapter->psFlashCSInfo->FlashSectorSizeSig), (Adapter->psFlashCSInfo->FlashSectorSize)); Adapter->uiFlashBaseAdd = Adapter->psFlashCSInfo->FlashBaseAddr & 0xFCFFFFFF; } else { if (BcmFlash2xBulkRead(Adapter, (PUINT)Adapter->psFlash2xCSInfo, NO_SECTION_VAL, Adapter->ulFlashControlSectionStart, sizeof(struct bcm_flash2x_cs_info))) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Unable to read CS structure\n"); return STATUS_FAILURE; } ConvertEndianOf2XCSStructure(Adapter->psFlash2xCSInfo); BcmDumpFlash2XCSStructure(Adapter->psFlash2xCSInfo, Adapter); if ((FLASH_CONTROL_STRUCT_SIGNATURE == Adapter->psFlash2xCSInfo->MagicNumber) && (SCSI_FIRMWARE_MINOR_VERSION <= MINOR_VERSION(Adapter->psFlash2xCSInfo->SCSIFirmwareVersion)) && (FLASH_SECTOR_SIZE_SIG == Adapter->psFlash2xCSInfo->FlashSectorSizeSig) && (BYTE_WRITE_SUPPORT == Adapter->psFlash2xCSInfo->FlashWriteSupportSize)) { Adapter->ulFlashWriteSize = Adapter->psFlash2xCSInfo->FlashWriteSupportSize; Adapter->fpFlashWrite = flashByteWrite; Adapter->fpFlashWriteWithStatusCheck = flashByteWriteStatus; } else { Adapter->ulFlashWriteSize = MAX_RW_SIZE; Adapter->fpFlashWrite = flashWrite; Adapter->fpFlashWriteWithStatusCheck = flashWriteStatus; } BcmGetFlashSectorSize(Adapter, Adapter->psFlash2xCSInfo->FlashSectorSizeSig, Adapter->psFlash2xCSInfo->FlashSectorSize); UpdateVendorInfo(Adapter); BcmGetActiveDSD(Adapter); BcmGetActiveISO(Adapter); Adapter->uiFlashBaseAdd = Adapter->psFlash2xCSInfo->FlashBaseAddr & 0xFCFFFFFF; Adapter->ulFlashControlSectionStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForControlSectionStart; } /* * Concerns: what if CS sector size does not match with this sector size ??? * what is the indication of AccessBitMap in CS in flash 2.x ???? */ Adapter->ulFlashID = BcmReadFlashRDID(Adapter); Adapter->uiFlashLayoutMajorVersion = uiFlashLayoutMajorVersion; return STATUS_SUCCESS; } /* * Procedure: BcmGetNvmType * * Description: Finds the type of NVM used. * * Arguments: * Adapter - ptr to Adapter object instance * * Returns: * NVM_TYPE * */ static enum bcm_nvm_type BcmGetNvmType(struct bcm_mini_adapter *Adapter) { unsigned int uiData = 0; BeceemEEPROMBulkRead(Adapter, &uiData, 0x0, 4); if (uiData == BECM) return NVM_EEPROM; /* * Read control struct and get cal addresses before accessing the flash */ BcmGetFlashCSInfo(Adapter); BeceemFlashBulkRead(Adapter, &uiData, 0x0 + Adapter->ulFlashCalStart, 4); if (uiData == BECM) return NVM_FLASH; /* * even if there is no valid signature on EEPROM/FLASH find out if they really exist. * if exist select it. */ if (BcmGetEEPROMSize(Adapter)) return NVM_EEPROM; /* TBD for Flash. */ return NVM_UNKNOWN; } /* * BcmGetSectionValStartOffset - this will calculate the section's starting offset if section val is given * @Adapter : Drivers Private Data structure * @eFlashSectionVal : Flash secion value defined in enum bcm_flash2x_section_val * * Return value:- * On success it return the start offset of the provided section val * On Failure -returns STATUS_FAILURE */ int BcmGetSectionValStartOffset(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlashSectionVal) { /* * Considering all the section for which end offset can be calculated or directly given * in CS Structure. if matching case does not exist, return STATUS_FAILURE indicating section * endoffset can't be calculated or given in CS Structure. */ int SectStartOffset = 0; SectStartOffset = INVALID_OFFSET; if (IsSectionExistInVendorInfo(Adapter, eFlashSectionVal)) return Adapter->psFlash2xVendorInfo->VendorSection[eFlashSectionVal].OffsetFromZeroForSectionStart; switch (eFlashSectionVal) { case ISO_IMAGE1: if ((Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start != UNINIT_PTR_IN_CS) && (IsNonCDLessDevice(Adapter) == FALSE)) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start); break; case ISO_IMAGE2: if ((Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start != UNINIT_PTR_IN_CS) && (IsNonCDLessDevice(Adapter) == FALSE)) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start); break; case DSD0: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart); break; case DSD1: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start); break; case DSD2: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start); break; case VSA0: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAStart != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAStart); break; case VSA1: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1Start); break; case VSA2: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2Start); break; case SCSI: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForScsiFirmware != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForScsiFirmware); break; case CONTROL_SECTION: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForControlSectionStart != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForControlSectionStart); break; case ISO_IMAGE1_PART2: if (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2Start); break; case ISO_IMAGE1_PART3: if (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3Start); break; case ISO_IMAGE2_PART2: if (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2Start); break; case ISO_IMAGE2_PART3: if (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3Start != UNINIT_PTR_IN_CS) SectStartOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3Start); break; default: BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section Does not exist in Flash 2.x"); SectStartOffset = INVALID_OFFSET; } return SectStartOffset; } /* * BcmGetSectionValEndOffset - this will calculate the section's Ending offset if section val is given * @Adapter : Drivers Private Data structure * @eFlashSectionVal : Flash secion value defined in enum bcm_flash2x_section_val * * Return value:- * On success it return the end offset of the provided section val * On Failure -returns STATUS_FAILURE */ int BcmGetSectionValEndOffset(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal) { int SectEndOffset = 0; SectEndOffset = INVALID_OFFSET; if (IsSectionExistInVendorInfo(Adapter, eFlash2xSectionVal)) return Adapter->psFlash2xVendorInfo->VendorSection[eFlash2xSectionVal].OffsetFromZeroForSectionEnd; switch (eFlash2xSectionVal) { case ISO_IMAGE1: if ((Adapter->psFlash2xCSInfo->OffsetISOImage1Part1End != UNINIT_PTR_IN_CS) && (IsNonCDLessDevice(Adapter) == FALSE)) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1End); break; case ISO_IMAGE2: if ((Adapter->psFlash2xCSInfo->OffsetISOImage2Part1End != UNINIT_PTR_IN_CS) && (IsNonCDLessDevice(Adapter) == FALSE)) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1End); break; case DSD0: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDEnd != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDEnd); break; case DSD1: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1End); break; case DSD2: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2End); break; case VSA0: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAEnd != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAEnd); break; case VSA1: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1End); break; case VSA2: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2End); break; case SCSI: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForScsiFirmware != UNINIT_PTR_IN_CS) SectEndOffset = ((Adapter->psFlash2xCSInfo->OffsetFromZeroForScsiFirmware) + (Adapter->psFlash2xCSInfo->SizeOfScsiFirmware)); break; case CONTROL_SECTION: /* Not Clear So Putting failure. confirm and fix it. */ SectEndOffset = STATUS_FAILURE; break; case ISO_IMAGE1_PART2: if (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2End); break; case ISO_IMAGE1_PART3: if (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3End); break; case ISO_IMAGE2_PART2: if (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2End); break; case ISO_IMAGE2_PART3: if (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3End != UNINIT_PTR_IN_CS) SectEndOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3End); break; default: SectEndOffset = INVALID_OFFSET; } return SectEndOffset ; } /* * BcmFlash2xBulkRead:- Read API for Flash Map 2.x . * @Adapter :Driver Private Data Structure * @pBuffer : Buffer where data has to be put after reading * @eFlashSectionVal :Flash Section Val defined in enum bcm_flash2x_section_val * @uiOffsetWithinSectionVal :- Offset with in provided section * @uiNumBytes : Number of Bytes for Read * * Return value:- * return true on success and STATUS_FAILURE on fail. */ int BcmFlash2xBulkRead(struct bcm_mini_adapter *Adapter, PUINT pBuffer, enum bcm_flash2x_section_val eFlash2xSectionVal, unsigned int uiOffsetWithinSectionVal, unsigned int uiNumBytes) { int Status = STATUS_SUCCESS; int SectionStartOffset = 0; unsigned int uiAbsoluteOffset = 0; unsigned int uiTemp = 0, value = 0; if (!Adapter) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Adapter structure is NULL"); return -EINVAL; } if (Adapter->device_removed) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Device has been removed"); return -ENODEV; } /* NO_SECTION_VAL means absolute offset is given. */ if (eFlash2xSectionVal == NO_SECTION_VAL) SectionStartOffset = 0; else SectionStartOffset = BcmGetSectionValStartOffset(Adapter, eFlash2xSectionVal); if (SectionStartOffset == STATUS_FAILURE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "This Section<%d> does not exixt in Flash 2.x Map ", eFlash2xSectionVal); return -EINVAL; } if (IsSectionExistInVendorInfo(Adapter, eFlash2xSectionVal)) return vendorextnReadSection(Adapter, (PUCHAR)pBuffer, eFlash2xSectionVal, uiOffsetWithinSectionVal, uiNumBytes); /* calculating the absolute offset from FLASH; */ uiAbsoluteOffset = uiOffsetWithinSectionVal + SectionStartOffset; rdmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); value = 0; wrmalt(Adapter, 0x0f000C80, &value, sizeof(value)); Status = BeceemFlashBulkRead(Adapter, pBuffer, uiAbsoluteOffset, uiNumBytes); wrmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Flash Read Failed with Status :%d", Status); return Status; } return Status; } /* * BcmFlash2xBulkWrite :-API for Writing on the Flash Map 2.x. * @Adapter :Driver Private Data Structure * @pBuffer : Buffer From where data has to taken for writing * @eFlashSectionVal :Flash Section Val defined in enum bcm_flash2x_section_val * @uiOffsetWithinSectionVal :- Offset with in provided section * @uiNumBytes : Number of Bytes for Write * * Return value:- * return true on success and STATUS_FAILURE on fail. * */ int BcmFlash2xBulkWrite(struct bcm_mini_adapter *Adapter, PUINT pBuffer, enum bcm_flash2x_section_val eFlash2xSectVal, unsigned int uiOffset, unsigned int uiNumBytes, unsigned int bVerify) { int Status = STATUS_SUCCESS; unsigned int FlashSectValStartOffset = 0; unsigned int uiTemp = 0, value = 0; if (!Adapter) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Adapter structure is NULL"); return -EINVAL; } if (Adapter->device_removed) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Device has been removed"); return -ENODEV; } /* NO_SECTION_VAL means absolute offset is given. */ if (eFlash2xSectVal == NO_SECTION_VAL) FlashSectValStartOffset = 0; else FlashSectValStartOffset = BcmGetSectionValStartOffset(Adapter, eFlash2xSectVal); if (FlashSectValStartOffset == STATUS_FAILURE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "This Section<%d> does not exixt in Flash Map 2.x", eFlash2xSectVal); return -EINVAL; } if (IsSectionExistInVendorInfo(Adapter, eFlash2xSectVal)) return vendorextnWriteSection(Adapter, (PUCHAR)pBuffer, eFlash2xSectVal, uiOffset, uiNumBytes, bVerify); /* calculating the absolute offset from FLASH; */ uiOffset = uiOffset + FlashSectValStartOffset; rdmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); value = 0; wrmalt(Adapter, 0x0f000C80, &value, sizeof(value)); Status = BeceemFlashBulkWrite(Adapter, pBuffer, uiOffset, uiNumBytes, bVerify); wrmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Flash Write failed with Status :%d", Status); return Status; } return Status; } /* * BcmGetActiveDSD : Set the Active DSD in Adapter Structure which has to be dumped in DDR * @Adapter :-Drivers private Data Structure * * Return Value:- * Return STATUS_SUCESS if get success in setting the right DSD else negaive error code * */ static int BcmGetActiveDSD(struct bcm_mini_adapter *Adapter) { enum bcm_flash2x_section_val uiHighestPriDSD = 0; uiHighestPriDSD = getHighestPriDSD(Adapter); Adapter->eActiveDSD = uiHighestPriDSD; if (DSD0 == uiHighestPriDSD) Adapter->ulFlashCalStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart; if (DSD1 == uiHighestPriDSD) Adapter->ulFlashCalStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start; if (DSD2 == uiHighestPriDSD) Adapter->ulFlashCalStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start; if (Adapter->eActiveDSD) BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Active DSD :%d", Adapter->eActiveDSD); if (Adapter->eActiveDSD == 0) { /* if No DSD gets Active, Make Active the DSD with WR permission */ if (IsSectionWritable(Adapter, DSD2)) { Adapter->eActiveDSD = DSD2; Adapter->ulFlashCalStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start; } else if (IsSectionWritable(Adapter, DSD1)) { Adapter->eActiveDSD = DSD1; Adapter->ulFlashCalStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start; } else if (IsSectionWritable(Adapter, DSD0)) { Adapter->eActiveDSD = DSD0; Adapter->ulFlashCalStart = Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart; } } return STATUS_SUCCESS; } /* * BcmGetActiveISO :- Set the Active ISO in Adapter Data Structue * @Adapter : Driver private Data Structure * * Return Value:- * Sucsess:- STATUS_SUCESS * Failure- : negative erro code * */ static int BcmGetActiveISO(struct bcm_mini_adapter *Adapter) { int HighestPriISO = 0; HighestPriISO = getHighestPriISO(Adapter); Adapter->eActiveISO = HighestPriISO; if (Adapter->eActiveISO == ISO_IMAGE2) Adapter->uiActiveISOOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start); else if (Adapter->eActiveISO == ISO_IMAGE1) Adapter->uiActiveISOOffset = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start); if (Adapter->eActiveISO) BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Active ISO :%x", Adapter->eActiveISO); return STATUS_SUCCESS; } /* * IsOffsetWritable :- it will tell the access permission of the sector having passed offset * @Adapter : Drivers Private Data Structure * @uiOffset : Offset provided in the Flash * * Return Value:- * Success:-TRUE , offset is writable * Failure:-FALSE, offset is RO * */ B_UINT8 IsOffsetWritable(struct bcm_mini_adapter *Adapter, unsigned int uiOffset) { unsigned int uiSectorNum = 0; unsigned int uiWordOfSectorPermission = 0; unsigned int uiBitofSectorePermission = 0; B_UINT32 permissionBits = 0; uiSectorNum = uiOffset/Adapter->uiSectorSize; /* calculating the word having this Sector Access permission from SectorAccessBitMap Array */ uiWordOfSectorPermission = Adapter->psFlash2xCSInfo->SectorAccessBitMap[uiSectorNum / 16]; /* calculating the bit index inside the word for this sector */ uiBitofSectorePermission = 2 * (15 - uiSectorNum % 16); /* Setting Access permission */ permissionBits = uiWordOfSectorPermission & (0x3 << uiBitofSectorePermission); permissionBits = (permissionBits >> uiBitofSectorePermission) & 0x3; if (permissionBits == SECTOR_READWRITE_PERMISSION) return TRUE; else return FALSE; } static int BcmDumpFlash2xSectionBitMap(struct bcm_flash2x_bitmap *psFlash2xBitMap) { struct bcm_mini_adapter *Adapter = GET_BCM_ADAPTER(gblpnetdev); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "***************Flash 2.x Section Bitmap***************"); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "ISO_IMAGE1 :0X%x", psFlash2xBitMap->ISO_IMAGE1); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "ISO_IMAGE2 :0X%x", psFlash2xBitMap->ISO_IMAGE2); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "DSD0 :0X%x", psFlash2xBitMap->DSD0); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "DSD1 :0X%x", psFlash2xBitMap->DSD1); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "DSD2 :0X%x", psFlash2xBitMap->DSD2); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "VSA0 :0X%x", psFlash2xBitMap->VSA0); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "VSA1 :0X%x", psFlash2xBitMap->VSA1); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "VSA2 :0X%x", psFlash2xBitMap->VSA2); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "SCSI :0X%x", psFlash2xBitMap->SCSI); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "CONTROL_SECTION :0X%x", psFlash2xBitMap->CONTROL_SECTION); return STATUS_SUCCESS; } /* * BcmGetFlash2xSectionalBitMap :- It will provide the bit map of all the section present in Flash * 8bit has been assigned to every section. * bit[0] :Section present or not * bit[1] :section is valid or not * bit[2] : Secton is read only or has write permission too. * bit[3] : Active Section - * bit[7...4] = Reserved . * * @Adapter:-Driver private Data Structure * * Return value:- * Success:- STATUS_SUCESS * Failure:- negative error code */ int BcmGetFlash2xSectionalBitMap(struct bcm_mini_adapter *Adapter, struct bcm_flash2x_bitmap *psFlash2xBitMap) { struct bcm_flash2x_cs_info *psFlash2xCSInfo = Adapter->psFlash2xCSInfo; enum bcm_flash2x_section_val uiHighestPriDSD = 0; enum bcm_flash2x_section_val uiHighestPriISO = 0; BOOLEAN SetActiveDSDDone = FALSE; BOOLEAN SetActiveISODone = FALSE; /* For 1.x map all the section except DSD0 will be shown as not present * This part will be used by calibration tool to detect the number of DSD present in Flash. */ if (IsFlash2x(Adapter) == FALSE) { psFlash2xBitMap->ISO_IMAGE2 = 0; psFlash2xBitMap->ISO_IMAGE1 = 0; psFlash2xBitMap->DSD0 = FLASH2X_SECTION_VALID | FLASH2X_SECTION_ACT | FLASH2X_SECTION_PRESENT; /* 0xF; 0000(Reseved)1(Active)0(RW)1(valid)1(present) */ psFlash2xBitMap->DSD1 = 0; psFlash2xBitMap->DSD2 = 0; psFlash2xBitMap->VSA0 = 0; psFlash2xBitMap->VSA1 = 0; psFlash2xBitMap->VSA2 = 0; psFlash2xBitMap->CONTROL_SECTION = 0; psFlash2xBitMap->SCSI = 0; psFlash2xBitMap->Reserved0 = 0; psFlash2xBitMap->Reserved1 = 0; psFlash2xBitMap->Reserved2 = 0; return STATUS_SUCCESS; } uiHighestPriDSD = getHighestPriDSD(Adapter); uiHighestPriISO = getHighestPriISO(Adapter); /* * IS0 IMAGE 2 */ if ((psFlash2xCSInfo->OffsetISOImage2Part1Start) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->ISO_IMAGE2 = psFlash2xBitMap->ISO_IMAGE2 | FLASH2X_SECTION_PRESENT; if (ReadISOSignature(Adapter, ISO_IMAGE2) == ISO_IMAGE_MAGIC_NUMBER) psFlash2xBitMap->ISO_IMAGE2 |= FLASH2X_SECTION_VALID; /* Calculation for extrating the Access permission */ if (IsSectionWritable(Adapter, ISO_IMAGE2) == FALSE) psFlash2xBitMap->ISO_IMAGE2 |= FLASH2X_SECTION_RO; if (SetActiveISODone == FALSE && uiHighestPriISO == ISO_IMAGE2) { psFlash2xBitMap->ISO_IMAGE2 |= FLASH2X_SECTION_ACT; SetActiveISODone = TRUE; } } /* * IS0 IMAGE 1 */ if ((psFlash2xCSInfo->OffsetISOImage1Part1Start) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->ISO_IMAGE1 = psFlash2xBitMap->ISO_IMAGE1 | FLASH2X_SECTION_PRESENT; if (ReadISOSignature(Adapter, ISO_IMAGE1) == ISO_IMAGE_MAGIC_NUMBER) psFlash2xBitMap->ISO_IMAGE1 |= FLASH2X_SECTION_VALID; /* Calculation for extrating the Access permission */ if (IsSectionWritable(Adapter, ISO_IMAGE1) == FALSE) psFlash2xBitMap->ISO_IMAGE1 |= FLASH2X_SECTION_RO; if (SetActiveISODone == FALSE && uiHighestPriISO == ISO_IMAGE1) { psFlash2xBitMap->ISO_IMAGE1 |= FLASH2X_SECTION_ACT; SetActiveISODone = TRUE; } } /* * DSD2 */ if ((psFlash2xCSInfo->OffsetFromZeroForDSD2Start) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->DSD2 = psFlash2xBitMap->DSD2 | FLASH2X_SECTION_PRESENT; if (ReadDSDSignature(Adapter, DSD2) == DSD_IMAGE_MAGIC_NUMBER) psFlash2xBitMap->DSD2 |= FLASH2X_SECTION_VALID; /* Calculation for extrating the Access permission */ if (IsSectionWritable(Adapter, DSD2) == FALSE) { psFlash2xBitMap->DSD2 |= FLASH2X_SECTION_RO; } else { /* Means section is writable */ if ((SetActiveDSDDone == FALSE) && (uiHighestPriDSD == DSD2)) { psFlash2xBitMap->DSD2 |= FLASH2X_SECTION_ACT; SetActiveDSDDone = TRUE; } } } /* * DSD 1 */ if ((psFlash2xCSInfo->OffsetFromZeroForDSD1Start) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->DSD1 = psFlash2xBitMap->DSD1 | FLASH2X_SECTION_PRESENT; if (ReadDSDSignature(Adapter, DSD1) == DSD_IMAGE_MAGIC_NUMBER) psFlash2xBitMap->DSD1 |= FLASH2X_SECTION_VALID; /* Calculation for extrating the Access permission */ if (IsSectionWritable(Adapter, DSD1) == FALSE) { psFlash2xBitMap->DSD1 |= FLASH2X_SECTION_RO; } else { /* Means section is writable */ if ((SetActiveDSDDone == FALSE) && (uiHighestPriDSD == DSD1)) { psFlash2xBitMap->DSD1 |= FLASH2X_SECTION_ACT; SetActiveDSDDone = TRUE; } } } /* * For DSD 0 */ if ((psFlash2xCSInfo->OffsetFromZeroForDSDStart) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->DSD0 = psFlash2xBitMap->DSD0 | FLASH2X_SECTION_PRESENT; if (ReadDSDSignature(Adapter, DSD0) == DSD_IMAGE_MAGIC_NUMBER) psFlash2xBitMap->DSD0 |= FLASH2X_SECTION_VALID; /* Setting Access permission */ if (IsSectionWritable(Adapter, DSD0) == FALSE) { psFlash2xBitMap->DSD0 |= FLASH2X_SECTION_RO; } else { /* Means section is writable */ if ((SetActiveDSDDone == FALSE) && (uiHighestPriDSD == DSD0)) { psFlash2xBitMap->DSD0 |= FLASH2X_SECTION_ACT; SetActiveDSDDone = TRUE; } } } /* * VSA 0 */ if ((psFlash2xCSInfo->OffsetFromZeroForVSAStart) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->VSA0 = psFlash2xBitMap->VSA0 | FLASH2X_SECTION_PRESENT; /* Setting the Access Bit. Map is not defined hece setting it always valid */ psFlash2xBitMap->VSA0 |= FLASH2X_SECTION_VALID; /* Calculation for extrating the Access permission */ if (IsSectionWritable(Adapter, VSA0) == FALSE) psFlash2xBitMap->VSA0 |= FLASH2X_SECTION_RO; /* By Default section is Active */ psFlash2xBitMap->VSA0 |= FLASH2X_SECTION_ACT; } /* * VSA 1 */ if ((psFlash2xCSInfo->OffsetFromZeroForVSA1Start) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->VSA1 = psFlash2xBitMap->VSA1 | FLASH2X_SECTION_PRESENT; /* Setting the Access Bit. Map is not defined hece setting it always valid */ psFlash2xBitMap->VSA1 |= FLASH2X_SECTION_VALID; /* Checking For Access permission */ if (IsSectionWritable(Adapter, VSA1) == FALSE) psFlash2xBitMap->VSA1 |= FLASH2X_SECTION_RO; /* By Default section is Active */ psFlash2xBitMap->VSA1 |= FLASH2X_SECTION_ACT; } /* * VSA 2 */ if ((psFlash2xCSInfo->OffsetFromZeroForVSA2Start) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->VSA2 = psFlash2xBitMap->VSA2 | FLASH2X_SECTION_PRESENT; /* Setting the Access Bit. Map is not defined hece setting it always valid */ psFlash2xBitMap->VSA2 |= FLASH2X_SECTION_VALID; /* Checking For Access permission */ if (IsSectionWritable(Adapter, VSA2) == FALSE) psFlash2xBitMap->VSA2 |= FLASH2X_SECTION_RO; /* By Default section is Active */ psFlash2xBitMap->VSA2 |= FLASH2X_SECTION_ACT; } /* * SCSI Section */ if ((psFlash2xCSInfo->OffsetFromZeroForScsiFirmware) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->SCSI = psFlash2xBitMap->SCSI | FLASH2X_SECTION_PRESENT; /* Setting the Access Bit. Map is not defined hece setting it always valid */ psFlash2xBitMap->SCSI |= FLASH2X_SECTION_VALID; /* Checking For Access permission */ if (IsSectionWritable(Adapter, SCSI) == FALSE) psFlash2xBitMap->SCSI |= FLASH2X_SECTION_RO; /* By Default section is Active */ psFlash2xBitMap->SCSI |= FLASH2X_SECTION_ACT; } /* * Control Section */ if ((psFlash2xCSInfo->OffsetFromZeroForControlSectionStart) != UNINIT_PTR_IN_CS) { /* Setting the 0th Bit representing the Section is present or not. */ psFlash2xBitMap->CONTROL_SECTION = psFlash2xBitMap->CONTROL_SECTION | (FLASH2X_SECTION_PRESENT); /* Setting the Access Bit. Map is not defined hece setting it always valid */ psFlash2xBitMap->CONTROL_SECTION |= FLASH2X_SECTION_VALID; /* Checking For Access permission */ if (IsSectionWritable(Adapter, CONTROL_SECTION) == FALSE) psFlash2xBitMap->CONTROL_SECTION |= FLASH2X_SECTION_RO; /* By Default section is Active */ psFlash2xBitMap->CONTROL_SECTION |= FLASH2X_SECTION_ACT; } /* * For Reserved Sections */ psFlash2xBitMap->Reserved0 = 0; psFlash2xBitMap->Reserved0 = 0; psFlash2xBitMap->Reserved0 = 0; BcmDumpFlash2xSectionBitMap(psFlash2xBitMap); return STATUS_SUCCESS; } /* * BcmSetActiveSection :- Set Active section is used to make priority field highest over other * section of same type. * * @Adapater :- Bcm Driver Private Data Structure * @eFlash2xSectionVal :- Flash section val whose priority has to be made highest. * * Return Value:- Make the priorit highest else return erorr code * */ int BcmSetActiveSection(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectVal) { unsigned int SectImagePriority = 0; int Status = STATUS_SUCCESS; /* struct bcm_dsd_header sDSD = {0}; * struct bcm_iso_header sISO = {0}; */ int HighestPriDSD = 0 ; int HighestPriISO = 0; Status = IsSectionWritable(Adapter, eFlash2xSectVal); if (Status != TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Provided Section <%d> is not writable", eFlash2xSectVal); return STATUS_FAILURE; } Adapter->bHeaderChangeAllowed = TRUE; switch (eFlash2xSectVal) { case ISO_IMAGE1: case ISO_IMAGE2: if (ReadISOSignature(Adapter, eFlash2xSectVal) == ISO_IMAGE_MAGIC_NUMBER) { HighestPriISO = getHighestPriISO(Adapter); if (HighestPriISO == eFlash2xSectVal) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Given ISO<%x> already has highest priority", eFlash2xSectVal); Status = STATUS_SUCCESS; break; } SectImagePriority = ReadISOPriority(Adapter, HighestPriISO) + 1; if ((SectImagePriority <= 0) && IsSectionWritable(Adapter, HighestPriISO)) { /* This is a SPECIAL Case which will only happen if the current highest priority ISO has priority value = 0x7FFFFFFF. * We will write 1 to the current Highest priority ISO And then shall increase the priority of the requested ISO * by user */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "SectImagePriority wraparound happened, eFlash2xSectVal: 0x%x\n", eFlash2xSectVal); SectImagePriority = htonl(0x1); Status = BcmFlash2xBulkWrite(Adapter, &SectImagePriority, HighestPriISO, 0 + FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImagePriority), SIGNATURE_SIZE, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Priority has not been written properly"); Status = STATUS_FAILURE; break; } HighestPriISO = getHighestPriISO(Adapter); if (HighestPriISO == eFlash2xSectVal) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Given ISO<%x> already has highest priority", eFlash2xSectVal); Status = STATUS_SUCCESS; break; } SectImagePriority = 2; } SectImagePriority = htonl(SectImagePriority); Status = BcmFlash2xBulkWrite(Adapter, &SectImagePriority, eFlash2xSectVal, 0 + FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImagePriority), SIGNATURE_SIZE, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Priority has not been written properly"); break; } } else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Signature is currupted. Hence can't increase the priority"); Status = STATUS_FAILURE; break; } break; case DSD0: case DSD1: case DSD2: if (ReadDSDSignature(Adapter, eFlash2xSectVal) == DSD_IMAGE_MAGIC_NUMBER) { HighestPriDSD = getHighestPriDSD(Adapter); if ((HighestPriDSD == eFlash2xSectVal)) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Given DSD<%x> already has highest priority", eFlash2xSectVal); Status = STATUS_SUCCESS; break; } SectImagePriority = ReadDSDPriority(Adapter, HighestPriDSD) + 1; if (SectImagePriority <= 0) { /* This is a SPECIAL Case which will only happen if the current highest priority DSD has priority value = 0x7FFFFFFF. * We will write 1 to the current Highest priority DSD And then shall increase the priority of the requested DSD * by user */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, NVM_RW, DBG_LVL_ALL, "SectImagePriority wraparound happened, eFlash2xSectVal: 0x%x\n", eFlash2xSectVal); SectImagePriority = htonl(0x1); Status = BcmFlash2xBulkWrite(Adapter, &SectImagePriority, HighestPriDSD, Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImagePriority), SIGNATURE_SIZE, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Priority has not been written properly"); break; } HighestPriDSD = getHighestPriDSD(Adapter); if ((HighestPriDSD == eFlash2xSectVal)) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Made the DSD: %x highest by reducing priority of other\n", eFlash2xSectVal); Status = STATUS_SUCCESS; break; } SectImagePriority = htonl(0x2); Status = BcmFlash2xBulkWrite(Adapter, &SectImagePriority, HighestPriDSD, Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImagePriority), SIGNATURE_SIZE, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Priority has not been written properly"); break; } HighestPriDSD = getHighestPriDSD(Adapter); if ((HighestPriDSD == eFlash2xSectVal)) { Status = STATUS_SUCCESS; break; } SectImagePriority = 3; } SectImagePriority = htonl(SectImagePriority); Status = BcmFlash2xBulkWrite(Adapter, &SectImagePriority, eFlash2xSectVal, Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImagePriority), SIGNATURE_SIZE, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Priority has not been written properly"); Status = STATUS_FAILURE; break; } } else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Signature is currupted. Hence can't increase the priority"); Status = STATUS_FAILURE; break; } break; case VSA0: case VSA1: case VSA2: /* Has to be decided */ break; default: Status = STATUS_FAILURE; break; } Adapter->bHeaderChangeAllowed = FALSE; return Status; } /* * BcmCopyISO - Used only for copying the ISO section * @Adapater :- Bcm Driver Private Data Structure * @sCopySectStrut :- Section copy structure * * Return value:- SUCCESS if copies successfully else negative error code * */ int BcmCopyISO(struct bcm_mini_adapter *Adapter, struct bcm_flash2x_copy_section sCopySectStrut) { PCHAR Buff = NULL; enum bcm_flash2x_section_val eISOReadPart = 0, eISOWritePart = 0; unsigned int uiReadOffsetWithinPart = 0, uiWriteOffsetWithinPart = 0; unsigned int uiTotalDataToCopy = 0; BOOLEAN IsThisHeaderSector = FALSE; unsigned int sigOffset = 0; unsigned int ISOLength = 0; unsigned int Status = STATUS_SUCCESS; unsigned int SigBuff[MAX_RW_SIZE]; unsigned int i = 0; if (ReadISOSignature(Adapter, sCopySectStrut.SrcSection) != ISO_IMAGE_MAGIC_NUMBER) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "error as Source ISO Section does not have valid signature"); return STATUS_FAILURE; } Status = BcmFlash2xBulkRead(Adapter, &ISOLength, sCopySectStrut.SrcSection, 0 + FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImageSize), 4); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Read failed while copying ISO\n"); return Status; } ISOLength = htonl(ISOLength); if (ISOLength % Adapter->uiSectorSize) ISOLength = Adapter->uiSectorSize * (1 + ISOLength/Adapter->uiSectorSize); sigOffset = FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImageMagicNumber); Buff = kzalloc(Adapter->uiSectorSize, GFP_KERNEL); if (!Buff) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Memory allocation failed for section size"); return -ENOMEM; } if (sCopySectStrut.SrcSection == ISO_IMAGE1 && sCopySectStrut.DstSection == ISO_IMAGE2) { eISOReadPart = ISO_IMAGE1; eISOWritePart = ISO_IMAGE2; uiReadOffsetWithinPart = 0; uiWriteOffsetWithinPart = 0; uiTotalDataToCopy = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1End) - (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2End) - (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3End) - (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3Start); if (uiTotalDataToCopy < ISOLength) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "error as Source ISO Section does not have valid signature"); Status = STATUS_FAILURE; goto out; } uiTotalDataToCopy = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1End) - (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2End) - (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3End) - (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3Start); if (uiTotalDataToCopy < ISOLength) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "error as Dest ISO Section does not have enough section size"); Status = STATUS_FAILURE; goto out; } uiTotalDataToCopy = ISOLength; CorruptISOSig(Adapter, ISO_IMAGE2); while (uiTotalDataToCopy) { if (uiTotalDataToCopy == Adapter->uiSectorSize) { /* Setting for write of first sector. First sector is assumed to be written in last */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Writing the signature sector"); eISOReadPart = ISO_IMAGE1; uiReadOffsetWithinPart = 0; eISOWritePart = ISO_IMAGE2; uiWriteOffsetWithinPart = 0; IsThisHeaderSector = TRUE; } else { uiReadOffsetWithinPart = uiReadOffsetWithinPart + Adapter->uiSectorSize; uiWriteOffsetWithinPart = uiWriteOffsetWithinPart + Adapter->uiSectorSize; if ((eISOReadPart == ISO_IMAGE1) && (uiReadOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1End - Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start))) { eISOReadPart = ISO_IMAGE1_PART2; uiReadOffsetWithinPart = 0; } if ((eISOReadPart == ISO_IMAGE1_PART2) && (uiReadOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2End - Adapter->psFlash2xCSInfo->OffsetISOImage1Part2Start))) { eISOReadPart = ISO_IMAGE1_PART3; uiReadOffsetWithinPart = 0; } if ((eISOWritePart == ISO_IMAGE2) && (uiWriteOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1End - Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start))) { eISOWritePart = ISO_IMAGE2_PART2; uiWriteOffsetWithinPart = 0; } if ((eISOWritePart == ISO_IMAGE2_PART2) && (uiWriteOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2End - Adapter->psFlash2xCSInfo->OffsetISOImage2Part2Start))) { eISOWritePart = ISO_IMAGE2_PART3; uiWriteOffsetWithinPart = 0; } } Status = BcmFlash2xBulkRead(Adapter, (PUINT)Buff, eISOReadPart, uiReadOffsetWithinPart, Adapter->uiSectorSize); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Read failed while copying ISO: Part: %x, OffsetWithinPart: %x\n", eISOReadPart, uiReadOffsetWithinPart); break; } if (IsThisHeaderSector == TRUE) { /* If this is header sector write 0xFFFFFFFF at the sig time and in last write sig */ memcpy(SigBuff, Buff + sigOffset, MAX_RW_SIZE); for (i = 0; i < MAX_RW_SIZE; i++) *(Buff + sigOffset + i) = 0xFF; } Adapter->bHeaderChangeAllowed = TRUE; Status = BcmFlash2xBulkWrite(Adapter, (PUINT)Buff, eISOWritePart, uiWriteOffsetWithinPart, Adapter->uiSectorSize, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write failed while copying ISO: Part: %x, OffsetWithinPart: %x\n", eISOWritePart, uiWriteOffsetWithinPart); break; } Adapter->bHeaderChangeAllowed = FALSE; if (IsThisHeaderSector == TRUE) { WriteToFlashWithoutSectorErase(Adapter, SigBuff, eISOWritePart, sigOffset, MAX_RW_SIZE); IsThisHeaderSector = FALSE; } /* subtracting the written Data */ uiTotalDataToCopy = uiTotalDataToCopy - Adapter->uiSectorSize; } } if (sCopySectStrut.SrcSection == ISO_IMAGE2 && sCopySectStrut.DstSection == ISO_IMAGE1) { eISOReadPart = ISO_IMAGE2; eISOWritePart = ISO_IMAGE1; uiReadOffsetWithinPart = 0; uiWriteOffsetWithinPart = 0; uiTotalDataToCopy = (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1End) - (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2End) - (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3End) - (Adapter->psFlash2xCSInfo->OffsetISOImage2Part3Start); if (uiTotalDataToCopy < ISOLength) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "error as Source ISO Section does not have valid signature"); Status = STATUS_FAILURE; goto out; } uiTotalDataToCopy = (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1End) - (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2End) - (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2Start) + (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3End) - (Adapter->psFlash2xCSInfo->OffsetISOImage1Part3Start); if (uiTotalDataToCopy < ISOLength) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "error as Dest ISO Section does not have enough section size"); Status = STATUS_FAILURE; goto out; } uiTotalDataToCopy = ISOLength; CorruptISOSig(Adapter, ISO_IMAGE1); while (uiTotalDataToCopy) { if (uiTotalDataToCopy == Adapter->uiSectorSize) { /* Setting for write of first sector. First sector is assumed to be written in last */ BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Writing the signature sector"); eISOReadPart = ISO_IMAGE2; uiReadOffsetWithinPart = 0; eISOWritePart = ISO_IMAGE1; uiWriteOffsetWithinPart = 0; IsThisHeaderSector = TRUE; } else { uiReadOffsetWithinPart = uiReadOffsetWithinPart + Adapter->uiSectorSize; uiWriteOffsetWithinPart = uiWriteOffsetWithinPart + Adapter->uiSectorSize; if ((eISOReadPart == ISO_IMAGE2) && (uiReadOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage2Part1End - Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start))) { eISOReadPart = ISO_IMAGE2_PART2; uiReadOffsetWithinPart = 0; } if ((eISOReadPart == ISO_IMAGE2_PART2) && (uiReadOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage2Part2End - Adapter->psFlash2xCSInfo->OffsetISOImage2Part2Start))) { eISOReadPart = ISO_IMAGE2_PART3; uiReadOffsetWithinPart = 0; } if ((eISOWritePart == ISO_IMAGE1) && (uiWriteOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage1Part1End - Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start))) { eISOWritePart = ISO_IMAGE1_PART2; uiWriteOffsetWithinPart = 0; } if ((eISOWritePart == ISO_IMAGE1_PART2) && (uiWriteOffsetWithinPart == (Adapter->psFlash2xCSInfo->OffsetISOImage1Part2End - Adapter->psFlash2xCSInfo->OffsetISOImage1Part2Start))) { eISOWritePart = ISO_IMAGE1_PART3; uiWriteOffsetWithinPart = 0; } } Status = BcmFlash2xBulkRead(Adapter, (PUINT)Buff, eISOReadPart, uiReadOffsetWithinPart, Adapter->uiSectorSize); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Read failed while copying ISO: Part: %x, OffsetWithinPart: %x\n", eISOReadPart, uiReadOffsetWithinPart); break; } if (IsThisHeaderSector == TRUE) { /* If this is header sector write 0xFFFFFFFF at the sig time and in last write sig */ memcpy(SigBuff, Buff + sigOffset, MAX_RW_SIZE); for (i = 0; i < MAX_RW_SIZE; i++) *(Buff + sigOffset + i) = 0xFF; } Adapter->bHeaderChangeAllowed = TRUE; Status = BcmFlash2xBulkWrite(Adapter, (PUINT)Buff, eISOWritePart, uiWriteOffsetWithinPart, Adapter->uiSectorSize, TRUE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write failed while copying ISO: Part: %x, OffsetWithinPart: %x\n", eISOWritePart, uiWriteOffsetWithinPart); break; } Adapter->bHeaderChangeAllowed = FALSE; if (IsThisHeaderSector == TRUE) { WriteToFlashWithoutSectorErase(Adapter, SigBuff, eISOWritePart, sigOffset, MAX_RW_SIZE); IsThisHeaderSector = FALSE; } /* subtracting the written Data */ uiTotalDataToCopy = uiTotalDataToCopy - Adapter->uiSectorSize; } } out: kfree(Buff); return Status; } /* * BcmFlash2xCorruptSig : this API is used to corrupt the written sig in Bcm Header present in flash section. * It will corrupt the sig, if Section is writable, by making first bytes as zero. * @Adapater :- Bcm Driver Private Data Structure * @eFlash2xSectionVal :- Flash section val which has header * * Return Value :- * Success :- If Section is present and writable, corrupt the sig and return STATUS_SUCCESS * Failure :-Return negative error code */ int BcmFlash2xCorruptSig(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal) { int Status = STATUS_SUCCESS; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section Value :%x\n", eFlash2xSectionVal); if ((eFlash2xSectionVal == DSD0) || (eFlash2xSectionVal == DSD1) || (eFlash2xSectionVal == DSD2)) { Status = CorruptDSDSig(Adapter, eFlash2xSectionVal); } else if (eFlash2xSectionVal == ISO_IMAGE1 || eFlash2xSectionVal == ISO_IMAGE2) { Status = CorruptISOSig(Adapter, eFlash2xSectionVal); } else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Given Section <%d>does not have Header", eFlash2xSectionVal); return STATUS_SUCCESS; } return Status; } /* *BcmFlash2xWriteSig :-this API is used to Write the sig if requested Section has * header and Write Permission. * @Adapater :- Bcm Driver Private Data Structure * @eFlashSectionVal :- Flash section val which has header * * Return Value :- * Success :- If Section is present and writable write the sig and return STATUS_SUCCESS * Failure :-Return negative error code */ int BcmFlash2xWriteSig(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlashSectionVal) { unsigned int uiSignature = 0; unsigned int uiOffset = 0; /* struct bcm_dsd_header dsdHeader = {0}; */ if (Adapter->bSigCorrupted == FALSE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Signature is not corrupted by driver, hence not restoring\n"); return STATUS_SUCCESS; } if (Adapter->bAllDSDWriteAllow == FALSE) { if (IsSectionWritable(Adapter, eFlashSectionVal) == FALSE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section is not Writable...Hence can't Write signature"); return SECTOR_IS_NOT_WRITABLE; } } if ((eFlashSectionVal == DSD0) || (eFlashSectionVal == DSD1) || (eFlashSectionVal == DSD2)) { uiSignature = htonl(DSD_IMAGE_MAGIC_NUMBER); uiOffset = Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader; uiOffset += FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImageMagicNumber); if ((ReadDSDSignature(Adapter, eFlashSectionVal) & 0xFF000000) != CORRUPTED_PATTERN) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Corrupted Pattern is not there. Hence won't write sig"); return STATUS_FAILURE; } } else if ((eFlashSectionVal == ISO_IMAGE1) || (eFlashSectionVal == ISO_IMAGE2)) { uiSignature = htonl(ISO_IMAGE_MAGIC_NUMBER); /* uiOffset = 0; */ uiOffset = FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImageMagicNumber); if ((ReadISOSignature(Adapter, eFlashSectionVal) & 0xFF000000) != CORRUPTED_PATTERN) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Currupted Pattern is not there. Hence won't write sig"); return STATUS_FAILURE; } } else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "GIVEN SECTION< %d > IS NOT VALID FOR SIG WRITE...", eFlashSectionVal); return STATUS_FAILURE; } BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Restoring the signature"); Adapter->bHeaderChangeAllowed = TRUE; Adapter->bSigCorrupted = FALSE; BcmFlash2xBulkWrite(Adapter, &uiSignature, eFlashSectionVal, uiOffset, SIGNATURE_SIZE, TRUE); Adapter->bHeaderChangeAllowed = FALSE; return STATUS_SUCCESS; } /* * validateFlash2xReadWrite :- This API is used to validate the user request for Read/Write. * if requested Bytes goes beyond the Requested section, it reports error. * @Adapater :- Bcm Driver Private Data Structure * @psFlash2xReadWrite :-Flash2x Read/write structure pointer * * Return values:-Return TRUE is request is valid else FALSE. */ int validateFlash2xReadWrite(struct bcm_mini_adapter *Adapter, struct bcm_flash2x_readwrite *psFlash2xReadWrite) { unsigned int uiNumOfBytes = 0; unsigned int uiSectStartOffset = 0; unsigned int uiSectEndOffset = 0; uiNumOfBytes = psFlash2xReadWrite->numOfBytes; if (IsSectionExistInFlash(Adapter, psFlash2xReadWrite->Section) != TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section<%x> does not exixt in Flash", psFlash2xReadWrite->Section); return FALSE; } uiSectStartOffset = BcmGetSectionValStartOffset(Adapter, psFlash2xReadWrite->Section); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Start offset :%x ,section :%d\n", uiSectStartOffset, psFlash2xReadWrite->Section); if ((psFlash2xReadWrite->Section == ISO_IMAGE1) || (psFlash2xReadWrite->Section == ISO_IMAGE2)) { if (psFlash2xReadWrite->Section == ISO_IMAGE1) { uiSectEndOffset = BcmGetSectionValEndOffset(Adapter, ISO_IMAGE1) - BcmGetSectionValStartOffset(Adapter, ISO_IMAGE1) + BcmGetSectionValEndOffset(Adapter, ISO_IMAGE1_PART2) - BcmGetSectionValStartOffset(Adapter, ISO_IMAGE1_PART2) + BcmGetSectionValEndOffset(Adapter, ISO_IMAGE1_PART3) - BcmGetSectionValStartOffset(Adapter, ISO_IMAGE1_PART3); } else if (psFlash2xReadWrite->Section == ISO_IMAGE2) { uiSectEndOffset = BcmGetSectionValEndOffset(Adapter, ISO_IMAGE2) - BcmGetSectionValStartOffset(Adapter, ISO_IMAGE2) + BcmGetSectionValEndOffset(Adapter, ISO_IMAGE2_PART2) - BcmGetSectionValStartOffset(Adapter, ISO_IMAGE2_PART2) + BcmGetSectionValEndOffset(Adapter, ISO_IMAGE2_PART3) - BcmGetSectionValStartOffset(Adapter, ISO_IMAGE2_PART3); } /* since this uiSectEndoffset is the size of iso Image. hence for calculating the virtual endoffset * it should be added in startoffset. so that check done in last of this function can be valued. */ uiSectEndOffset = uiSectStartOffset + uiSectEndOffset; BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Total size of the ISO Image :%x", uiSectEndOffset); } else uiSectEndOffset = BcmGetSectionValEndOffset(Adapter, psFlash2xReadWrite->Section); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "End offset :%x\n", uiSectEndOffset); /* Checking the boundary condition */ if ((uiSectStartOffset + psFlash2xReadWrite->offset + uiNumOfBytes) <= uiSectEndOffset) return TRUE; else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Invalid Request...."); return FALSE; } } /* * IsFlash2x :- check for Flash 2.x * Adapater :- Bcm Driver Private Data Structure * * Return value:- * return TRUE if flah2.x of hgher version else return false. */ int IsFlash2x(struct bcm_mini_adapter *Adapter) { if (Adapter->uiFlashLayoutMajorVersion >= FLASH_2X_MAJOR_NUMBER) return TRUE; else return FALSE; } /* * GetFlashBaseAddr :- Calculate the Flash Base address * @Adapater :- Bcm Driver Private Data Structure * * Return Value:- * Success :- Base Address of the Flash */ static int GetFlashBaseAddr(struct bcm_mini_adapter *Adapter) { unsigned int uiBaseAddr = 0; if (Adapter->bDDRInitDone) { /* * For All Valid Flash Versions... except 1.1, take the value from FlashBaseAddr * In case of Raw Read... use the default value */ if (Adapter->uiFlashLayoutMajorVersion && (Adapter->bFlashRawRead == FALSE) && !((Adapter->uiFlashLayoutMajorVersion == 1) && (Adapter->uiFlashLayoutMinorVersion == 1))) uiBaseAddr = Adapter->uiFlashBaseAdd; else uiBaseAddr = FLASH_CONTIGIOUS_START_ADDR_AFTER_INIT; } else { /* * For All Valid Flash Versions... except 1.1, take the value from FlashBaseAddr * In case of Raw Read... use the default value */ if (Adapter->uiFlashLayoutMajorVersion && (Adapter->bFlashRawRead == FALSE) && !((Adapter->uiFlashLayoutMajorVersion == 1) && (Adapter->uiFlashLayoutMinorVersion == 1))) uiBaseAddr = Adapter->uiFlashBaseAdd | FLASH_CONTIGIOUS_START_ADDR_BEFORE_INIT; else uiBaseAddr = FLASH_CONTIGIOUS_START_ADDR_BEFORE_INIT; } return uiBaseAddr; } /* * BcmCopySection :- This API is used to copy the One section in another. Both section should * be contiuous and of same size. Hence this Will not be applicabe to copy ISO. * * @Adapater :- Bcm Driver Private Data Structure * @SrcSection :- Source section From where data has to be copied * @DstSection :- Destination section to which data has to be copied * @offset :- Offset from/to where data has to be copied from one section to another. * @numOfBytes :- number of byes that has to be copyed from one section to another at given offset. * in case of numofBytes equal zero complete section will be copied. * Return Values- * Success : Return STATUS_SUCCESS * Faillure :- return negative error code */ int BcmCopySection(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val SrcSection, enum bcm_flash2x_section_val DstSection, unsigned int offset, unsigned int numOfBytes) { unsigned int BuffSize = 0; unsigned int BytesToBeCopied = 0; PUCHAR pBuff = NULL; int Status = STATUS_SUCCESS; if (SrcSection == DstSection) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Source and Destination should be different ...try again"); return -EINVAL; } if ((SrcSection != DSD0) && (SrcSection != DSD1) && (SrcSection != DSD2)) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Source should be DSD subsection"); return -EINVAL; } if ((DstSection != DSD0) && (DstSection != DSD1) && (DstSection != DSD2)) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Destination should be DSD subsection"); return -EINVAL; } /* if offset zero means have to copy complete secton */ if (numOfBytes == 0) { numOfBytes = BcmGetSectionValEndOffset(Adapter, SrcSection) - BcmGetSectionValStartOffset(Adapter, SrcSection); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Section Size :0x%x", numOfBytes); } if ((offset + numOfBytes) > BcmGetSectionValEndOffset(Adapter, SrcSection) - BcmGetSectionValStartOffset(Adapter, SrcSection)) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, " Input parameters going beyond the section offS: %x numB: %x of Source Section\n", offset, numOfBytes); return -EINVAL; } if ((offset + numOfBytes) > BcmGetSectionValEndOffset(Adapter, DstSection) - BcmGetSectionValStartOffset(Adapter, DstSection)) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Input parameters going beyond the section offS: %x numB: %x of Destination Section\n", offset, numOfBytes); return -EINVAL; } if (numOfBytes > Adapter->uiSectorSize) BuffSize = Adapter->uiSectorSize; else BuffSize = numOfBytes; pBuff = kzalloc(BuffSize, GFP_KERNEL); if (!pBuff) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Memory allocation failed.. "); return -ENOMEM; } BytesToBeCopied = Adapter->uiSectorSize; if (offset % Adapter->uiSectorSize) BytesToBeCopied = Adapter->uiSectorSize - (offset % Adapter->uiSectorSize); if (BytesToBeCopied > numOfBytes) BytesToBeCopied = numOfBytes; Adapter->bHeaderChangeAllowed = TRUE; do { Status = BcmFlash2xBulkRead(Adapter, (PUINT)pBuff, SrcSection , offset, BytesToBeCopied); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Read failed at offset :%d for NOB :%d", SrcSection, BytesToBeCopied); break; } Status = BcmFlash2xBulkWrite(Adapter, (PUINT)pBuff, DstSection, offset, BytesToBeCopied, FALSE); if (Status) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Write failed at offset :%d for NOB :%d", DstSection, BytesToBeCopied); break; } offset = offset + BytesToBeCopied; numOfBytes = numOfBytes - BytesToBeCopied; if (numOfBytes) { if (numOfBytes > Adapter->uiSectorSize) BytesToBeCopied = Adapter->uiSectorSize; else BytesToBeCopied = numOfBytes; } } while (numOfBytes > 0); kfree(pBuff); Adapter->bHeaderChangeAllowed = FALSE; return Status; } /* * SaveHeaderIfPresent :- This API is use to Protect the Header in case of Header Sector write * @Adapater :- Bcm Driver Private Data Structure * @pBuff :- Data buffer that has to be written in sector having the header map. * @uiOffset :- Flash offset that has to be written. * * Return value :- * Success :- On success return STATUS_SUCCESS * Faillure :- Return negative error code */ int SaveHeaderIfPresent(struct bcm_mini_adapter *Adapter, PUCHAR pBuff, unsigned int uiOffset) { unsigned int offsetToProtect = 0, HeaderSizeToProtect = 0; BOOLEAN bHasHeader = FALSE; PUCHAR pTempBuff = NULL; unsigned int uiSectAlignAddr = 0; unsigned int sig = 0; /* making the offset sector aligned */ uiSectAlignAddr = uiOffset & ~(Adapter->uiSectorSize - 1); if ((uiSectAlignAddr == BcmGetSectionValEndOffset(Adapter, DSD2) - Adapter->uiSectorSize) || (uiSectAlignAddr == BcmGetSectionValEndOffset(Adapter, DSD1) - Adapter->uiSectorSize) || (uiSectAlignAddr == BcmGetSectionValEndOffset(Adapter, DSD0) - Adapter->uiSectorSize)) { /* offset from the sector boundary having the header map */ offsetToProtect = Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader % Adapter->uiSectorSize; HeaderSizeToProtect = sizeof(struct bcm_dsd_header); bHasHeader = TRUE; } if (uiSectAlignAddr == BcmGetSectionValStartOffset(Adapter, ISO_IMAGE1) || uiSectAlignAddr == BcmGetSectionValStartOffset(Adapter, ISO_IMAGE2)) { offsetToProtect = 0; HeaderSizeToProtect = sizeof(struct bcm_iso_header); bHasHeader = TRUE; } /* If Header is present overwrite passed buffer with this */ if (bHasHeader && (Adapter->bHeaderChangeAllowed == FALSE)) { pTempBuff = kzalloc(HeaderSizeToProtect, GFP_KERNEL); if (!pTempBuff) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Memory allocation failed"); return -ENOMEM; } /* Read header */ BeceemFlashBulkRead(Adapter, (PUINT)pTempBuff, (uiSectAlignAddr + offsetToProtect), HeaderSizeToProtect); BCM_DEBUG_PRINT_BUFFER(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, pTempBuff, HeaderSizeToProtect); /* Replace Buffer content with Header */ memcpy(pBuff + offsetToProtect, pTempBuff, HeaderSizeToProtect); kfree(pTempBuff); } if (bHasHeader && Adapter->bSigCorrupted) { sig = *((PUINT)(pBuff + offsetToProtect + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImageMagicNumber))); sig = ntohl(sig); if ((sig & 0xFF000000) != CORRUPTED_PATTERN) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Desired pattern is not at sig offset. Hence won't restore"); Adapter->bSigCorrupted = FALSE; return STATUS_SUCCESS; } BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, " Corrupted sig is :%X", sig); *((PUINT)(pBuff + offsetToProtect + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImageMagicNumber))) = htonl(DSD_IMAGE_MAGIC_NUMBER); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Restoring the signature in Header Write only"); Adapter->bSigCorrupted = FALSE; } return STATUS_SUCCESS; } /* * BcmDoChipSelect : This will selcet the appropriate chip for writing. * @Adapater :- Bcm Driver Private Data Structure * * OutPut:- * Select the Appropriate chip and retrn status Success */ static int BcmDoChipSelect(struct bcm_mini_adapter *Adapter, unsigned int offset) { unsigned int FlashConfig = 0; int ChipNum = 0; unsigned int GPIOConfig = 0; unsigned int PartNum = 0; ChipNum = offset / FLASH_PART_SIZE; /* * Chip Select mapping to enable flash0. * To select flash 0, we have to OR with (0<<12). * ORing 0 will have no impact so not doing that part. * In future if Chip select value changes from 0 to non zero, * That needs be taken care with backward comaptibility. No worries for now. */ /* * SelectedChip Variable is the selection that the host is 100% Sure the same as what the register will hold. This can be ONLY ensured * if the Chip doesn't goes to low power mode while the flash operation is in progress (NVMRdmWrmLock is taken) * Before every new Flash Write operation, we reset the variable. This is to ensure that after any wake-up from * power down modes (Idle mode/shutdown mode), the values in the register will be different. */ if (Adapter->SelectedChip == ChipNum) return STATUS_SUCCESS; /* BCM_DEBUG_PRINT(Adapter,DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Selected Chip :%x", ChipNum); */ Adapter->SelectedChip = ChipNum; /* bit[13..12] will select the appropriate chip */ rdmalt(Adapter, FLASH_CONFIG_REG, &FlashConfig, 4); rdmalt(Adapter, FLASH_GPIO_CONFIG_REG, &GPIOConfig, 4); { switch (ChipNum) { case 0: PartNum = 0; break; case 1: PartNum = 3; GPIOConfig |= (0x4 << CHIP_SELECT_BIT12); break; case 2: PartNum = 1; GPIOConfig |= (0x1 << CHIP_SELECT_BIT12); break; case 3: PartNum = 2; GPIOConfig |= (0x2 << CHIP_SELECT_BIT12); break; } } /* In case the bits already written in the FLASH_CONFIG_REG is same as what the user desired, * nothing to do... can return immediately. * ASSUMPTION: FLASH_GPIO_CONFIG_REG will be in sync with FLASH_CONFIG_REG. * Even if the chip goes to low power mode, it should wake with values in each register in sync with each other. * These values are not written by host other than during CHIP_SELECT. */ if (PartNum == ((FlashConfig >> CHIP_SELECT_BIT12) & 0x3)) return STATUS_SUCCESS; /* clearing the bit[13..12] */ FlashConfig &= 0xFFFFCFFF; FlashConfig = (FlashConfig | (PartNum<psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImageMagicNumber), SIGNATURE_SIZE); uiDSDsig = ntohl(uiDSDsig); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "DSD SIG :%x", uiDSDsig); return uiDSDsig; } int ReadDSDPriority(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val dsd) { /* unsigned int priOffsetInMap = 0 ; */ unsigned int uiDSDPri = STATUS_FAILURE; /* struct bcm_dsd_header dsdHeader = {0}; * priOffsetInMap = (PUCHAR)&(dsdHeader.DSDImagePriority) -(PUCHAR)&dsdHeader; */ if (IsSectionWritable(Adapter, dsd)) { if (ReadDSDSignature(Adapter, dsd) == DSD_IMAGE_MAGIC_NUMBER) { BcmFlash2xBulkRead(Adapter, &uiDSDPri, dsd, Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + FIELD_OFFSET_IN_HEADER(struct bcm_dsd_header *, DSDImagePriority), 4); uiDSDPri = ntohl(uiDSDPri); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "DSD<%x> Priority :%x", dsd, uiDSDPri); } } return uiDSDPri; } enum bcm_flash2x_section_val getHighestPriDSD(struct bcm_mini_adapter *Adapter) { int DSDHighestPri = STATUS_FAILURE; int DsdPri = 0; enum bcm_flash2x_section_val HighestPriDSD = 0; if (IsSectionWritable(Adapter, DSD2)) { DSDHighestPri = ReadDSDPriority(Adapter, DSD2); HighestPriDSD = DSD2; } if (IsSectionWritable(Adapter, DSD1)) { DsdPri = ReadDSDPriority(Adapter, DSD1); if (DSDHighestPri < DsdPri) { DSDHighestPri = DsdPri; HighestPriDSD = DSD1; } } if (IsSectionWritable(Adapter, DSD0)) { DsdPri = ReadDSDPriority(Adapter, DSD0); if (DSDHighestPri < DsdPri) { DSDHighestPri = DsdPri; HighestPriDSD = DSD0; } } if (HighestPriDSD) BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Highest DSD :%x , and its Pri :%x", HighestPriDSD, DSDHighestPri); return HighestPriDSD; } int ReadISOSignature(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val iso) { unsigned int uiISOsig = 0; /* unsigned int sigoffsetInMap = 0; * struct bcm_iso_header ISOHeader = {0}; * sigoffsetInMap =(PUCHAR)&(ISOHeader.ISOImageMagicNumber) -(PUCHAR)&ISOHeader; */ if (iso != ISO_IMAGE1 && iso != ISO_IMAGE2) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "passed section value is not for ISOs"); return STATUS_FAILURE; } BcmFlash2xBulkRead(Adapter, &uiISOsig, iso, 0 + FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImageMagicNumber), SIGNATURE_SIZE); uiISOsig = ntohl(uiISOsig); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "ISO SIG :%x", uiISOsig); return uiISOsig; } int ReadISOPriority(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val iso) { unsigned int ISOPri = STATUS_FAILURE; if (IsSectionWritable(Adapter, iso)) { if (ReadISOSignature(Adapter, iso) == ISO_IMAGE_MAGIC_NUMBER) { BcmFlash2xBulkRead(Adapter, &ISOPri, iso, 0 + FIELD_OFFSET_IN_HEADER(struct bcm_iso_header *, ISOImagePriority), 4); ISOPri = ntohl(ISOPri); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "ISO<%x> Priority :%x", iso, ISOPri); } } return ISOPri; } enum bcm_flash2x_section_val getHighestPriISO(struct bcm_mini_adapter *Adapter) { int ISOHighestPri = STATUS_FAILURE; int ISOPri = 0; enum bcm_flash2x_section_val HighestPriISO = NO_SECTION_VAL; if (IsSectionWritable(Adapter, ISO_IMAGE2)) { ISOHighestPri = ReadISOPriority(Adapter, ISO_IMAGE2); HighestPriISO = ISO_IMAGE2; } if (IsSectionWritable(Adapter, ISO_IMAGE1)) { ISOPri = ReadISOPriority(Adapter, ISO_IMAGE1); if (ISOHighestPri < ISOPri) { ISOHighestPri = ISOPri; HighestPriISO = ISO_IMAGE1; } } if (HighestPriISO) BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Highest ISO :%x and its Pri :%x", HighestPriISO, ISOHighestPri); return HighestPriISO; } int WriteToFlashWithoutSectorErase(struct bcm_mini_adapter *Adapter, PUINT pBuff, enum bcm_flash2x_section_val eFlash2xSectionVal, unsigned int uiOffset, unsigned int uiNumBytes) { #if !defined(BCM_SHM_INTERFACE) || defined(FLASH_DIRECT_ACCESS) unsigned int uiTemp = 0, value = 0; unsigned int i = 0; unsigned int uiPartOffset = 0; #endif unsigned int uiStartOffset = 0; /* Adding section start address */ int Status = STATUS_SUCCESS; PUCHAR pcBuff = (PUCHAR)pBuff; if (uiNumBytes % Adapter->ulFlashWriteSize) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Writing without Sector Erase for non-FlashWriteSize number of bytes 0x%x\n", uiNumBytes); return STATUS_FAILURE; } uiStartOffset = BcmGetSectionValStartOffset(Adapter, eFlash2xSectionVal); if (IsSectionExistInVendorInfo(Adapter, eFlash2xSectionVal)) return vendorextnWriteSectionWithoutErase(Adapter, pcBuff, eFlash2xSectionVal, uiOffset, uiNumBytes); uiOffset = uiOffset + uiStartOffset; #if defined(BCM_SHM_INTERFACE) && !defined(FLASH_DIRECT_ACCESS) Status = bcmflash_raw_writenoerase((uiOffset / FLASH_PART_SIZE), (uiOffset % FLASH_PART_SIZE), pcBuff, uiNumBytes); #else rdmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); value = 0; wrmalt(Adapter, 0x0f000C80, &value, sizeof(value)); Adapter->SelectedChip = RESET_CHIP_SELECT; BcmDoChipSelect(Adapter, uiOffset); uiPartOffset = (uiOffset & (FLASH_PART_SIZE - 1)) + GetFlashBaseAddr(Adapter); for (i = 0 ; i < uiNumBytes; i += Adapter->ulFlashWriteSize) { if (Adapter->ulFlashWriteSize == BYTE_WRITE_SUPPORT) Status = flashByteWrite(Adapter, uiPartOffset, pcBuff); else Status = flashWrite(Adapter, uiPartOffset, pcBuff); if (Status != STATUS_SUCCESS) break; pcBuff = pcBuff + Adapter->ulFlashWriteSize; uiPartOffset = uiPartOffset + Adapter->ulFlashWriteSize; } wrmalt(Adapter, 0x0f000C80, &uiTemp, sizeof(uiTemp)); Adapter->SelectedChip = RESET_CHIP_SELECT; #endif return Status; } BOOLEAN IsSectionExistInFlash(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val section) { BOOLEAN SectionPresent = FALSE; switch (section) { case ISO_IMAGE1: if ((Adapter->psFlash2xCSInfo->OffsetISOImage1Part1Start != UNINIT_PTR_IN_CS) && (IsNonCDLessDevice(Adapter) == FALSE)) SectionPresent = TRUE; break; case ISO_IMAGE2: if ((Adapter->psFlash2xCSInfo->OffsetISOImage2Part1Start != UNINIT_PTR_IN_CS) && (IsNonCDLessDevice(Adapter) == FALSE)) SectionPresent = TRUE; break; case DSD0: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSDStart != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case DSD1: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD1Start != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case DSD2: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForDSD2Start != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case VSA0: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSAStart != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case VSA1: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA1Start != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case VSA2: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForVSA2Start != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case SCSI: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForScsiFirmware != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; case CONTROL_SECTION: if (Adapter->psFlash2xCSInfo->OffsetFromZeroForControlSectionStart != UNINIT_PTR_IN_CS) SectionPresent = TRUE; break; default: BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section Does not exist in Flash 2.x"); SectionPresent = FALSE; } return SectionPresent; } int IsSectionWritable(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val Section) { int offset = STATUS_FAILURE; int Status = FALSE; if (IsSectionExistInFlash(Adapter, Section) == FALSE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section <%d> does not exixt", Section); return FALSE; } offset = BcmGetSectionValStartOffset(Adapter, Section); if (offset == INVALID_OFFSET) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section<%d> does not exixt", Section); return FALSE; } if (IsSectionExistInVendorInfo(Adapter, Section)) return !(Adapter->psFlash2xVendorInfo->VendorSection[Section].AccessFlags & FLASH2X_SECTION_RO); Status = IsOffsetWritable(Adapter, offset); return Status; } static int CorruptDSDSig(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal) { PUCHAR pBuff = NULL; unsigned int sig = 0; unsigned int uiOffset = 0; unsigned int BlockStatus = 0; unsigned int uiSectAlignAddr = 0; Adapter->bSigCorrupted = FALSE; if (Adapter->bAllDSDWriteAllow == FALSE) { if (IsSectionWritable(Adapter, eFlash2xSectionVal) != TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section is not Writable...Hence can't Corrupt signature"); return SECTOR_IS_NOT_WRITABLE; } } pBuff = kzalloc(MAX_RW_SIZE, GFP_KERNEL); if (!pBuff) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Can't allocate memorey"); return -ENOMEM; } uiOffset = Adapter->psFlash2xCSInfo->OffsetFromDSDStartForDSDHeader + sizeof(struct bcm_dsd_header); uiOffset -= MAX_RW_SIZE; BcmFlash2xBulkRead(Adapter, (PUINT)pBuff, eFlash2xSectionVal, uiOffset, MAX_RW_SIZE); sig = *((PUINT)(pBuff + 12)); sig = ntohl(sig); BCM_DEBUG_PRINT_BUFFER(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, pBuff, MAX_RW_SIZE); /* Now corrupting the sig by corrupting 4th last Byte. */ *(pBuff + 12) = 0; if (sig == DSD_IMAGE_MAGIC_NUMBER) { Adapter->bSigCorrupted = TRUE; if (Adapter->ulFlashWriteSize == BYTE_WRITE_SUPPORT) { uiSectAlignAddr = uiOffset & ~(Adapter->uiSectorSize - 1); BlockStatus = BcmFlashUnProtectBlock(Adapter, uiSectAlignAddr, Adapter->uiSectorSize); WriteToFlashWithoutSectorErase(Adapter, (PUINT)(pBuff + 12), eFlash2xSectionVal, (uiOffset + 12), BYTE_WRITE_SUPPORT); if (BlockStatus) { BcmRestoreBlockProtectStatus(Adapter, BlockStatus); BlockStatus = 0; } } else { WriteToFlashWithoutSectorErase(Adapter, (PUINT)pBuff, eFlash2xSectionVal, uiOffset, MAX_RW_SIZE); } } else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "BCM Signature is not present in header"); kfree(pBuff); return STATUS_FAILURE; } kfree(pBuff); BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Corrupted the signature"); return STATUS_SUCCESS; } static int CorruptISOSig(struct bcm_mini_adapter *Adapter, enum bcm_flash2x_section_val eFlash2xSectionVal) { PUCHAR pBuff = NULL; unsigned int sig = 0; unsigned int uiOffset = 0; Adapter->bSigCorrupted = FALSE; if (IsSectionWritable(Adapter, eFlash2xSectionVal) != TRUE) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Section is not Writable...Hence can't Corrupt signature"); return SECTOR_IS_NOT_WRITABLE; } pBuff = kzalloc(MAX_RW_SIZE, GFP_KERNEL); if (!pBuff) { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "Can't allocate memorey"); return -ENOMEM; } uiOffset = 0; BcmFlash2xBulkRead(Adapter, (PUINT)pBuff, eFlash2xSectionVal, uiOffset, MAX_RW_SIZE); sig = *((PUINT)pBuff); sig = ntohl(sig); /* corrupt signature */ *pBuff = 0; if (sig == ISO_IMAGE_MAGIC_NUMBER) { Adapter->bSigCorrupted = TRUE; WriteToFlashWithoutSectorErase(Adapter, (PUINT)pBuff, eFlash2xSectionVal, uiOffset, Adapter->ulFlashWriteSize); } else { BCM_DEBUG_PRINT(Adapter, DBG_TYPE_PRINTK, 0, 0, "BCM Signature is not present in header"); kfree(pBuff); return STATUS_FAILURE; } BCM_DEBUG_PRINT(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, "Corrupted the signature"); BCM_DEBUG_PRINT_BUFFER(Adapter, DBG_TYPE_OTHERS, NVM_RW, DBG_LVL_ALL, pBuff, MAX_RW_SIZE); kfree(pBuff); return STATUS_SUCCESS; } BOOLEAN IsNonCDLessDevice(struct bcm_mini_adapter *Adapter) { if (Adapter->psFlash2xCSInfo->IsCDLessDeviceBootSig == NON_CDLESS_DEVICE_BOOT_SIG) return TRUE; else return FALSE; }