/* IBM_PROLOG_BEGIN_TAG */ /* This is an automatically generated prolog. */ /* */ /* $Source: src/usr/pnor/pnor_sfcdd.C $ */ /* */ /* OpenPOWER HostBoot Project */ /* */ /* Contributors Listed Below - COPYRIGHT 2011,2019 */ /* [+] Google Inc. */ /* [+] International Business Machines Corp. */ /* */ /* */ /* Licensed under the Apache License, Version 2.0 (the "License"); */ /* you may not use this file except in compliance with the License. */ /* You may obtain a copy of the License at */ /* */ /* http://www.apache.org/licenses/LICENSE-2.0 */ /* */ /* Unless required by applicable law or agreed to in writing, software */ /* distributed under the License is distributed on an "AS IS" BASIS, */ /* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or */ /* implied. See the License for the specific language governing */ /* permissions and limitations under the License. */ /* */ /* IBM_PROLOG_END_TAG */ /** * @file pnordd.C * * @brief Implementation of the PNOR Device Driver */ /*****************************************************************************/ // I n c l u d e s /*****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pnor_sfcdd.H" #include "pnor_common.H" #include #include #include #include #include #include #include "sfcdd.H" /*****************************************************************************/ // D e f i n e s /*****************************************************************************/ #define PNORDD_MAX_RETRIES 1 // Initialized in pnorrp.C extern trace_desc_t* g_trac_pnor; namespace PNOR { /** * @brief Performs an PNOR Read Operation * This function performs a PNOR Read operation. It follows a pre-defined * prototype functions in order to be registered with the device-driver * framework. * * @param[in] i_opType Operation type, see DeviceFW::OperationType * in driverif.H * @param[in] i_target PNOR target * @param[in/out] io_buffer Read: Pointer to output data storage * Write: Pointer to input data storage * @param[in/out] io_buflen Input: size of io_buffer (in bytes) * Output: * Read: Size of output data * Write: Size of data written * @param[in] i_accessType DeviceFW::AccessType enum (usrif.H) * @param[in] i_args This is an argument list for DD framework. * In this function, there's only one argument, * containing the PNOR address and chip select * @return errlHndl_t */ errlHndl_t ddRead(DeviceFW::OperationType i_opType, TARGETING::Target* i_target, void* io_buffer, size_t& io_buflen, int64_t i_accessType, va_list i_args) { errlHndl_t l_err = NULL; uint64_t l_addr = va_arg(i_args,uint64_t); do{ //@todo (RTC:36951) - add support for unaligned data // Ensure we are operating on a 32-bit (4-byte) boundary assert( reinterpret_cast(io_buffer) % 4 == 0 ); assert( io_buflen % 4 == 0 ); // The PNOR device driver interface is initialized with the // MASTER_PROCESSOR_CHIP_TARGET_SENTINEL. Other target // access requires a separate PnorSfcDD class created assert( i_target == TARGETING::MASTER_PROCESSOR_CHIP_TARGET_SENTINEL ); // Read the flash l_err = Singleton::instance().readFlash(io_buffer, io_buflen, l_addr); if(l_err) { break; } }while(0); return l_err; } /** * @brief Performs an PNOR Write Operation * This function performs a PNOR Write operation. It follows a pre-defined * prototype functions in order to be registered with the device-driver * framework. * * @param[in] i_opType Operation type, see DeviceFW::OperationType * in driverif.H * @param[in] i_target PNOR target * @param[in/out] io_buffer Read: Pointer to output data storage * Write: Pointer to input data storage * @param[in/out] io_buflen Input: size of io_buffer (in bytes) * Output: * Read: Size of output data * Write: Size of data written * @param[in] i_accessType DeviceFW::AccessType enum (usrif.H) * @param[in] i_args This is an argument list for DD framework. * In this function, there's only one argument, * containing the PNOR address and chip select * @return errlHndl_t */ errlHndl_t ddWrite(DeviceFW::OperationType i_opType, TARGETING::Target* i_target, void* io_buffer, size_t& io_buflen, int64_t i_accessType, va_list i_args) { errlHndl_t l_err = NULL; uint64_t l_addr = va_arg(i_args,uint64_t); do{ //@todo (RTC:36951) - add support for unaligned data // Ensure we are operating on a 32-bit (4-byte) boundary assert( reinterpret_cast(io_buffer) % 4 == 0 ); assert( io_buflen % 4 == 0 ); // The PNOR device driver interface is initialized with the // MASTER_PROCESSOR_CHIP_TARGET_SENTINEL. Other target // access requires a separate PnorSfcDD class created assert( i_target == TARGETING::MASTER_PROCESSOR_CHIP_TARGET_SENTINEL ); // Write the flash l_err = Singleton::instance().writeFlash(io_buffer, io_buflen, l_addr); if(l_err) { break; } }while(0); return l_err; } /** * @brief Informs caller if PNORDD is using * L3 Cache for fake PNOR or not. * * @return Indicate state of fake PNOR * true = PNOR DD is using L3 Cache for fake PNOR * false = PNOR DD not using L3 Cache for fake PNOR */ bool usingL3Cache() { return Singleton::instance().usingL3Cache(); } /** * @brief Retrieve some information about the PNOR/SFC hardware */ void getPnorInfo( PnorInfo_t& o_pnorInfo ) { o_pnorInfo.mmioOffset = LPC_SFC_MMIO_OFFSET|LPC_FW_SPACE; o_pnorInfo.norWorkarounds = Singleton::instance().getNorWorkarounds(); o_pnorInfo.flashSize = Singleton::instance().getNorSize(); } // Register PNORDD access functions to DD framework DEVICE_REGISTER_ROUTE(DeviceFW::READ, DeviceFW::PNOR, TARGETING::TYPE_PROC, ddRead); DEVICE_REGISTER_ROUTE(DeviceFW::WRITE, DeviceFW::PNOR, TARGETING::TYPE_PROC, ddWrite); }; //namespace PNOR /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// /** * @brief Performs a PNOR Read Operation */ errlHndl_t PnorSfcDD::readFlash(void* o_buffer, size_t& io_buflen, uint64_t i_address) { //TRACDCOMP(g_trac_pnor, "PnorSfcDD::readFlash(i_address=0x%llx)> ", i_address); //mask off chip select for now, will probably break up fake PNOR into //multiple fake chips eventually uint64_t l_address = i_address & 0x00000000FFFFFFFF; mutex_lock(iv_mutex_ptr); errlHndl_t l_err = _readFlash( l_address, io_buflen, o_buffer ); mutex_unlock(iv_mutex_ptr); return l_err; } /** * @brief Performs a PNOR Write Operation */ errlHndl_t PnorSfcDD::writeFlash(void* i_buffer, size_t& io_buflen, uint64_t i_address) { TRACDCOMP(g_trac_pnor, ENTER_MRK"PnorSfcDD::writeFlash(i_address=0x%llx)> ", i_address); errlHndl_t l_err = NULL; do{ TRACDCOMP(g_trac_pnor,"PNOR write %.8X", i_address); //mask off chip select for now, will probably break up fake PNOR into //multiple fake chips eventually uint64_t l_address = i_address & 0x00000000FFFFFFFF; // In NOR flash we can clear bits without an erase but we // cannot set them. When we erase we have to erase an entire // block of data at a time. uint32_t cur_writeStart_addr = static_cast(l_address); uint32_t cur_blkStart_addr = findEraseBlock(cur_writeStart_addr); uint32_t cur_blkEnd_addr = cur_blkStart_addr + iv_eraseSizeBytes; uint32_t write_bytes = iv_eraseSizeBytes; uint64_t num_blocks = getNumAffectedBlocks(cur_writeStart_addr,io_buflen); uint64_t bytes_left = io_buflen; // loop through erase blocks until we've gotten through all // affected blocks for( uint64_t block = 0; block < num_blocks; ++block ) { TRACDCOMP(g_trac_pnor,"cur_writeStart_addr=%X, cur_blkStart_addr=%X, cur_blkEnd_addr=%X, bytes_left=%X", cur_writeStart_addr, cur_blkStart_addr, cur_blkEnd_addr, bytes_left ); // writing at a block boundary, just write the whole thing if( cur_writeStart_addr == cur_blkStart_addr ) { if( bytes_left > iv_eraseSizeBytes ) { write_bytes = iv_eraseSizeBytes; } else { write_bytes = bytes_left; } } // writing the end of a block else //cur_writeStart_addr > cur_blkStart_addr { uint32_t bytes_tail = cur_blkEnd_addr - cur_writeStart_addr; if( bytes_left < bytes_tail ) { write_bytes = bytes_left; } else { write_bytes = bytes_tail; } } //note that writestart < blkstart can never happen // write a single block of data out to flash efficiently mutex_lock(iv_mutex_ptr); l_err = compareAndWriteBlock( cur_blkStart_addr, cur_writeStart_addr, write_bytes, (void*)((uint64_t)i_buffer + ((uint64_t)cur_writeStart_addr-l_address))); mutex_unlock(iv_mutex_ptr); if( l_err ) { break; } //move start to end of current erase block cur_blkStart_addr = cur_blkEnd_addr; //increment end by erase block size. cur_blkEnd_addr += iv_eraseSizeBytes; cur_writeStart_addr += write_bytes; bytes_left -= write_bytes; } if( l_err ) { break; } }while(0); // keeping track of every actual byte written is complicated and it can // be misleading in the cases where we end up erasing and writing an // entire block, instead just return zero for any failures if( l_err ) { io_buflen = 0; } TRACDCOMP(g_trac_pnor,EXIT_MRK"PnorSfcDD::writeFlash(i_address=0x%llx)> io_buflen=%.8X", i_address, io_buflen); return l_err; } /******************** Private/Protected Methods ********************/ mutex_t PnorSfcDD::cv_mutex = MUTEX_INITIALIZER; /** * @brief Constructor */ PnorSfcDD::PnorSfcDD( TARGETING::Target* i_target ) : iv_eraseSizeBytes(ERASESIZE_BYTES_DEFAULT) , iv_norChipId(0) , iv_sfc(NULL) { TRACFCOMP(g_trac_pnor, ENTER_MRK "PnorSfcDD::PnorSfcDD()" ); errlHndl_t l_err = NULL; //Zero out erase counter memset(iv_erases, 0xff, sizeof(iv_erases)); // Use i_target if all of these apply // 1) not NULL // 2) not MASTER_PROCESSOR_CHIP_TARGET_SENTINEL // 3) i_target does not correspond to Master processor (ie the // same processor as MASTER_PROCESSOR_CHIP_TARGET_SENTINEL) // otherwise, use MASTER_PROCESSOR_CHIP_TARGET_SENTINEL // NOTE: i_target can only be used when targeting is loaded if ( ( i_target != NULL ) && ( i_target != TARGETING::MASTER_PROCESSOR_CHIP_TARGET_SENTINEL ) ) { iv_target = i_target; // Check if processor is MASTER TARGETING::ATTR_PROC_MASTER_TYPE_type type_enum = iv_target->getAttr(); // Master target could collide and cause deadlocks with PnorSfcDD singleton // used for ddRead/ddWrite with MASTER_PROCESSOR_CHIP_TARGET_SENTINEL assert( type_enum != TARGETING::PROC_MASTER_TYPE_ACTING_MASTER ); // Initialize and use class-specific mutex iv_mutex_ptr = &iv_mutex; mutex_init(iv_mutex_ptr); TRACFCOMP(g_trac_pnor, "PnorSfcDD::PnorSfcDD()> Using i_target=0x%X (non-master) and iv_mutex_ptr", TARGETING::get_huid(i_target)); } else { iv_target = TARGETING::MASTER_PROCESSOR_CHIP_TARGET_SENTINEL; iv_mutex_ptr = &(cv_mutex); } do { //Instantiate the appropriate SFC object l_err = PNOR::create_SfcDD( iv_sfc, iv_target ); if( l_err ) { break; } //Initialize the SFC hardware if needed #ifndef BMC_DOES_SFC_INIT l_err = iv_sfc->hwInit(); if( l_err ) { break; } #endif //Figure out what kind of flash chip we have l_err = iv_sfc->getNORChipId(iv_norChipId); if( l_err ) { break; } //Keep track of the size of the erase block iv_eraseSizeBytes = iv_sfc->eraseSizeBytes(); //We only support 4K erase blocks for now assert(iv_eraseSizeBytes == ERASESIZE_BYTES_DEFAULT); } while(0); if( l_err ) { TRACFCOMP( g_trac_pnor, "Failure to initialize the PNOR logic :: RC=%.4X", ERRL_GETRC_SAFE(l_err) ); l_err->collectTrace(PNOR_COMP_NAME); ERRORLOG::errlCommit(l_err,PNOR_COMP_ID); //Only shutdown if this error occurs on the master proc if (TARGETING::MASTER_PROCESSOR_CHIP_TARGET_SENTINEL == iv_target) { TRACFCOMP( g_trac_pnor, "PNOR Error on Master Proc, shutting down"); INITSERVICE::doShutdown( PNOR::RC_PNOR_INIT_FAILURE ); } } TRACFCOMP(g_trac_pnor, EXIT_MRK "PnorSfcDD::PnorSfcDD()" ); } /** * @brief Destructor */ PnorSfcDD::~PnorSfcDD() { if( iv_sfc ) { delete iv_sfc; } } /** * @brief Informs caller if PNORDD is using * L3 Cache for fake PNOR or not. */ bool PnorSfcDD::usingL3Cache( void ) { return iv_sfc->usingL3Cache(); } /** * @brief Compare the existing data in 1 erase block of the flash with * the incoming data and write or erase as needed */ errlHndl_t PnorSfcDD::compareAndWriteBlock(uint32_t i_blockStart, uint32_t i_writeStart, size_t i_bytesToWrite, void* i_data) { TRACDCOMP(g_trac_pnor,">>compareAndWriteBlock(0x%.8X,0x%.8X,0x%.8X)", i_blockStart, i_writeStart, i_bytesToWrite); errlHndl_t l_err = NULL; uint8_t* read_data = NULL; do { // remember any data we read so we don't have to reread it later read_data = new uint8_t[iv_eraseSizeBytes]; // remember if we need to erase the block or not bool need_erase = false; bool need_write = false; //STEP 1: Read data in PNOR for compares (only read section we // want to write) //read_start needs to be uint32* for bitwise word compares later uint32_t* read_start = (uint32_t*)(read_data + i_writeStart-i_blockStart); l_err = _readFlash( i_writeStart, i_bytesToWrite, (void*) read_start ); if( l_err ) { break; } //STEP 2: walk through the write data to see if we need to do an erase const uint32_t wordsToWrite = i_bytesToWrite/4; uint32_t* i_dataWord = (uint32_t*) i_data; for(uint32_t cword = 0; cword < wordsToWrite; cword++) { // look for any bits being changed (using XOR) if(read_start[cword] ^ i_dataWord[cword] ) { need_write = true; //Can only write zeros to NOR, see if any bits changed from 0->1 if( (~(read_start[cword])) & (i_dataWord[cword]) ) { need_erase = true; // skip comparing the rest of the block, // just start writing it break; } } } if(need_write == false) { //No write actually needed, break out here TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> NO Write Needed! Exiting Function"); break; } //STEP 3: If the need to erase was detected, read out the // rest of the Erase block if(need_erase) { TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> Need to perform Erase"); //Get data before write section if(i_writeStart > i_blockStart) { TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> Reading beginning data i_blockStart=0x%.8x, readLen=0x%.8x", i_blockStart, i_writeStart-i_blockStart); l_err = _readFlash( i_blockStart, i_writeStart-i_blockStart, read_data ); if( l_err ) { break; } } //Get data after write section if( (i_writeStart+i_bytesToWrite) < (i_blockStart + iv_eraseSizeBytes) ) { uint32_t tail_length = i_blockStart + iv_eraseSizeBytes - (i_writeStart+i_bytesToWrite); uint8_t* tail_buffer = read_data + i_writeStart-i_blockStart + i_bytesToWrite; TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> Reading tail data. addr=0x%.8x, tail_length=0x%.8x", i_writeStart+i_bytesToWrite, tail_length); l_err = _readFlash( i_writeStart+i_bytesToWrite, tail_length, tail_buffer ); if( l_err ) { break; } } // erase the flash TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> Calling eraseFlash:. i_blockStart=0x%.8x", i_blockStart); l_err = _eraseFlash( i_blockStart ); if( l_err ) { break; } //STEP 4: Write the data back out - need to write everything // since we erased the block //re-write data before new data to write if(i_writeStart > i_blockStart) { TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> Writing beginning data i_blockStart=0x%.8x, readLen=0x%.8x", i_blockStart, i_writeStart-i_blockStart); l_err = _writeFlash(i_blockStart, i_writeStart-i_blockStart, read_data); if( l_err ) { break; } } //Write data after new data to write if( (i_writeStart+i_bytesToWrite) < (i_blockStart + iv_eraseSizeBytes) ) { uint32_t tail_length = i_blockStart + iv_eraseSizeBytes - (i_writeStart+i_bytesToWrite); uint8_t* tail_buffer = read_data + i_writeStart-i_blockStart + i_bytesToWrite; TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> Writing tail data. addr=0x%.8x, tail_length=0x%.8x", i_writeStart+i_bytesToWrite, tail_length); l_err = _writeFlash(i_writeStart+i_bytesToWrite, tail_length, tail_buffer); if( l_err ) { break; } } //Write the new data - always do this l_err = _writeFlash(i_writeStart, i_bytesToWrite, i_data); if( l_err ) { break; } } else // { //STEP 4 ALT: No erase needed, only write the parts that changed. TRACDCOMP(g_trac_pnor,"compareAndWriteBlock> No erase, just writing"); for(uint32_t cword = 0; cword < wordsToWrite; cword++) { // look for any bits being changed (using XOR) if(read_start[cword] ^ i_dataWord[cword] ) { //Write the new data - always do this l_err = _writeFlash(i_writeStart + (cword*4), 4, &i_dataWord[cword]); if( l_err ) { break; } } if( l_err ) { break; } } } } while(0); if( read_data ) { delete[] read_data; } TRACDCOMP(g_trac_pnor,"<>PnorSfcDD::eraseFlash> Block 0x%.8X", i_address ); do { if( findEraseBlock(i_address) != i_address ) { /*@ * @errortype * @moduleid PNOR::MOD_PNORDD_ERASEFLASH * @reasoncode PNOR::RC_INVALID_ADDRESS * @userdata1 Flash Address * @userdata2 Nearest Erase Boundary * @devdesc PnorSfcDD::eraseFlash> Address not on erase boundary * @custdesc Firmware error accessing flash during IPL */ l_err = new ERRORLOG::ErrlEntry(ERRORLOG::ERRL_SEV_UNRECOVERABLE, PNOR::MOD_PNORDD_ERASEFLASH, PNOR::RC_INVALID_ADDRESS, TWO_UINT32_TO_UINT64(0,i_address), findEraseBlock(i_address), true /*Add HB SW Callout*/ ); l_err->collectTrace(PNOR_COMP_NAME); break; } for(uint32_t idx = 0; idx < ERASE_COUNT_MAX; idx++ ) { if(iv_erases[idx].addr == i_address) { iv_erases[idx].count++; TRACFCOMP(g_trac_pnor, "PnorSfcDD::eraseFlash> Block 0x%.8X has %d erasures", i_address, iv_erases[idx].count ); break; } //iv_erases is init to all 0xff, // so can use ~0 to check for an unused position else if(iv_erases[idx].addr == ~0u) { iv_erases[idx].addr = i_address; iv_erases[idx].count = 1; TRACFCOMP(g_trac_pnor, "PnorSfcDD::eraseFlash> Block 0x%.8X has %d erasures", i_address, iv_erases[idx].count ); break; } else if( idx == (ERASE_COUNT_MAX - 1)) { TRACFCOMP(g_trac_pnor, "PnorSfcDD::eraseFlash> Erase counter full! Block 0x%.8X Erased", i_address ); break; } } // actually do the erase l_err = _eraseFlash(i_address); if(l_err) { break; } } while(0); return l_err; } /** * @brief Returns if an operation should be retried and handles * the error logs */ bool PnorSfcDD::shouldRetry( RetryOp i_op, errlHndl_t& io_err, errlHndl_t& io_original_err, uint8_t& io_retry_count ) { TRACDCOMP(g_trac_pnor, ENTER_MRK"PnorSfcDD::shouldRetry(%d)", i_op); bool should_retry = false; if ( io_err == NULL ) { // Operation was successful so don't retry should_retry = false; // Error logs handled below } else { // Operation failed // If op will be attempted again: save log and continue if ( io_retry_count < PNORDD_MAX_RETRIES ) { // Save original error - and only original error if ( io_original_err == NULL ) { io_original_err = io_err; io_err = NULL; TRACFCOMP(g_trac_pnor, ERR_MRK"PnorSfcDD::shouldRetry(%d)> Error rc=0x%X, eid=0x%X, retry/MAX=%d/%d. Save error and retry", i_op, io_original_err->reasonCode(), io_original_err->eid(), io_retry_count, PNORDD_MAX_RETRIES); io_original_err->collectTrace(PNOR_COMP_NAME); } else { // Add data to original error TRACFCOMP(g_trac_pnor, ERR_MRK"PnorSfcDD::shouldRetry(%d)> Another Error rc=0x%X, eid=0x%X, plid=%d, retry/MAX=%d/%d. Delete error and retry", i_op, io_err->reasonCode(), io_err->eid(), io_err->plid(), io_retry_count, PNORDD_MAX_RETRIES); char err_str[80]; snprintf(err_str, sizeof(err_str), "Another fail: Deleted " "Retried Error Log rc=0x%.8X eid=0x%.8X", io_err->reasonCode(), io_err->eid()); ERRORLOG::ErrlUserDetailsString(err_str) .addToLog(io_original_err); // Delete this new error delete io_err; io_err = NULL; } should_retry = true; io_retry_count++; } else // no more retries: trace and break { should_retry = false; TRACFCOMP(g_trac_pnor, ERR_MRK"PnorSfcDD::shouldRetry(%d)> Another Error rc=0x%X, eid=0x%X, No More Retries (retry/MAX=%d/%d). Returning Original Error (rc=0x%X, eid=0x%X)", i_op, io_err->reasonCode(), io_err->eid(), io_retry_count, PNORDD_MAX_RETRIES, io_original_err->reasonCode(), io_original_err->eid()); // error logs handled below } } // Handle saved error if we're not retrying if ( ( io_original_err != NULL) && ( should_retry == false ) ) { if (io_err) { // commit l_err with original error PLID as informational io_err->plid(io_original_err->plid()); io_err->setSev(ERRORLOG::ERRL_SEV_INFORMATIONAL); TRACFCOMP(g_trac_pnor, ERR_MRK"PnorSfcDD::shouldRetry(%d)> Committing latest io_err eid=0x%X with plid of original err (eid=0x%X): plid=0x%X", i_op, io_err->eid(), io_original_err->plid(), io_err->plid()); io_err->collectTrace(PNOR_COMP_NAME); errlCommit(io_err, PNOR_COMP_ID); // return original error io_err = io_original_err; // set io_original_err to NULL to avoid dual references io_original_err = NULL; } else { // Since we eventually succeeded, delete original error TRACFCOMP(g_trac_pnor, "PnorSfcDD::shouldRetry(%d)> Op successful, deleting saved err eid=0x%X, plid=0x%X", i_op, io_original_err->eid(), io_original_err->plid()); delete io_original_err; io_original_err = NULL; } } TRACDCOMP(g_trac_pnor, EXIT_MRK"PnorSfcDD::shouldRetry(%d)> return %d (io_retry_count=%d)", i_op, should_retry, io_retry_count); return should_retry; } /** * @brief Calls the SFC to perform a PNOR Write Operation */ errlHndl_t PnorSfcDD::_writeFlash( uint32_t i_addr, size_t i_size, void* i_data ) { TRACDCOMP(g_trac_pnor, ENTER_MRK"PnorSfcDD::_writeFlash(i_addr=0x%.8X)> ", i_addr); errlHndl_t l_err = NULL; errlHndl_t original_err = NULL; uint8_t retry = 0; do { // Call over to the SFC code to do the actual write l_err = iv_sfc->writeFlash( i_addr, i_size, i_data ); // end of operation - check for retry } while( shouldRetry(RETRY_writeFlash, l_err, original_err, retry) ); if( l_err ) { l_err->collectTrace(PNOR_COMP_NAME); } return l_err; } /** * @brief Calls the SFC to perform a PNOR Read Operation */ errlHndl_t PnorSfcDD::_readFlash( uint32_t i_addr, size_t i_size, void* o_data ) { //TRACDCOMP(g_trac_pnor, "PnorSfcDD::_readFlash(i_address=0x%.8X)> ", i_addr); errlHndl_t l_err = NULL; errlHndl_t original_err = NULL; uint8_t retry = 0; do{ //Send command over to the flash controller to do the work l_err = iv_sfc->readFlash(i_addr, i_size, o_data); // end of operation - check for retry } while( shouldRetry(RETRY_readFlash, l_err, original_err, retry) ); if( l_err ) { l_err->collectTrace(PNOR_COMP_NAME); } return l_err; } /** * @brief Calls the SFC to perform a PNOR Read Operation */ errlHndl_t PnorSfcDD::_eraseFlash( uint32_t i_addr ) { TRACDCOMP(g_trac_pnor, "PnorSfcDD::_eraseFlash(i_address=0x%.8X)> ", i_addr); errlHndl_t l_err = NULL; errlHndl_t original_err = NULL; uint8_t retry = 0; do{ //Send command over to the flash controller to do the work l_err = iv_sfc->eraseFlash(i_addr); // end of operation - check for retry } while( shouldRetry(RETRY_eraseFlash, l_err, original_err, retry) ); if( l_err ) { l_err->collectTrace(PNOR_COMP_NAME); } return l_err; } /** * @brief Retrieve bitstring of NOR workarounds */ uint32_t PnorSfcDD::getNorWorkarounds( void ) { return iv_sfc->getNorWorkarounds(); } /** * @brief Retrieve size of NOR flash */ uint32_t PnorSfcDD::getNorSize( void ) { #ifdef CONFIG_PNOR_IS_32MB return (32*MEGABYTE); #else //default to 64MB return (64*MEGABYTE); #endif }