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[/] [openarty/] [trunk/] [sw/] [host/] [flashdrvr.cpp] - Rev 10
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// // // Filename: flashdrvr.cpp // // Project: FPGA library development (Basys3 development board) // // Purpose: Flash driver. Encapsulate writing to the flash device. // // Creator: Dan Gisselquist // Gisselquist Tecnology, LLC // // Copyright: 2015 // // #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <strings.h> #include <ctype.h> #include <string.h> #include <signal.h> #include <assert.h> #include "port.h" #include "regdefs.h" #include "flashdrvr.h" const bool HIGH_SPEED = false; void FLASHDRVR::flwait(void) { DEVBUS::BUSW v; v = m_fpga->readio(R_QSPI_EREG); if ((v&ERASEFLAG)==0) return; m_fpga->writeio(R_ICONTROL, ISPIF_DIS); m_fpga->clear(); m_fpga->writeio(R_ICONTROL, ISPIF_EN); do { // Start by checking that we are still erasing. The interrupt // may have been generated while we were setting things up and // disabling things, so this just double checks for us. If // the interrupt was tripped, we're done. If not, we can now // wait for an interrupt. v = m_fpga->readio(R_QSPI_EREG); if (v&ERASEFLAG) { m_fpga->usleep(400); if (m_fpga->poll()) { m_fpga->clear(); m_fpga->writeio(R_ICONTROL, ISPIF_EN); } } } while(v & ERASEFLAG); } bool FLASHDRVR::erase_sector(const unsigned sector, const bool verify_erase) { DEVBUS::BUSW page[SZPAGE]; printf("Erasing sector: %08x\n", sector); m_fpga->writeio(R_QSPI_EREG, DISABLEWP); m_fpga->writeio(R_QSPI_EREG, ERASEFLAG + sector); // If we're in high speed mode and we want to verify the erase, then // we can skip waiting for the erase to complete by issueing a read // command immediately. As soon as the erase completes the read will // begin sending commands back. This allows us to recover the lost // time between the interrupt and the next command being received. if ((!HIGH_SPEED)||(!verify_erase)) { flwait(); printf("@%08x -> %08x\n", R_QSPI_EREG, m_fpga->readio(R_QSPI_EREG)); printf("@%08x -> %08x\n", R_QSPI_SREG, m_fpga->readio(R_QSPI_SREG)); printf("@%08x -> %08x\n", sector, m_fpga->readio(sector)); } // Now, let's verify that we erased the sector properly if (verify_erase) { for(int i=0; i<NPAGES; i++) { m_fpga->readi(sector+i*SZPAGE, SZPAGE, page); for(int i=0; i<SZPAGE; i++) if (page[i] != 0xffffffff) return false; } } return true; } bool FLASHDRVR::write_page(const unsigned addr, const unsigned len, const unsigned *data, const bool verify_write) { DEVBUS::BUSW buf[SZPAGE]; assert(len > 0); assert(len <= PGLEN); assert(PAGEOF(addr)==PAGEOF(addr+len-1)); if (len <= 0) return true; // Write the page m_fpga->writeio(R_ICONTROL, ISPIF_DIS); m_fpga->clear(); m_fpga->writeio(R_ICONTROL, ISPIF_EN); printf("Writing page: 0x%08x - 0x%08x\n", addr, addr+len-1); m_fpga->writeio(R_QSPI_EREG, DISABLEWP); m_fpga->writei(addr, len, data); // If we're in high speed mode and we want to verify the write, then // we can skip waiting for the write to complete by issueing a read // command immediately. As soon as the write completes the read will // begin sending commands back. This allows us to recover the lost // time between the interrupt and the next command being received. flwait(); // if ((!HIGH_SPEED)||(!verify_write)) { } if (verify_write) { // printf("Attempting to verify page\n"); // NOW VERIFY THE PAGE m_fpga->readi(addr, len, buf); for(int i=0; i<len; i++) { if (buf[i] != data[i]) { printf("\nVERIFY FAILS[%d]: %08x\n", i, i+addr); printf("\t(Flash[%d]) %08x != %08x (Goal[%08x])\n", i, buf[i], data[i], i+addr); return false; } } // printf("\nVerify success\n"); } return true; } bool FLASHDRVR::write(const unsigned addr, const unsigned len, const unsigned *data, const bool verify) { // Work through this one sector at a time. // If this buffer is equal to the sector value(s), go on // If not, erase the sector /* fprintf(stderr, "FLASH->write(%08x, %d, ..., %s)\n", addr, len, (verify)?"Verify":""); */ // m_fpga->writeio(R_QSPI_CREG, 2); // m_fpga->readio(R_VERSION); // Read something innocuous // Just to make sure the driver knows that these values are ... // m_fpga->readio(R_QSPI_CREG); // m_fpga->readio(R_QSPI_SREG); // Because the status register may invoke protections here, we // void them. // m_fpga->writeio(R_QSPI_SREG, 0); // m_fpga->readio(R_VERSION); // Read something innocuous for(unsigned s=SECTOROF(addr); s<SECTOROF(addr+len+SECTORSZ-1); s+=SECTORSZ) { // printf("IN LOOP, s=%08x\n", s); // Do we need to erase? bool need_erase = false; unsigned newv = 0; // (s<addr)?addr:s; { DEVBUS::BUSW *sbuf = new DEVBUS::BUSW[SECTORSZ]; const DEVBUS::BUSW *dp; unsigned base,ln; base = (addr>s)?addr:s; ln=((addr+len>s+SECTORSZ)?(s+SECTORSZ):(addr+len))-base; m_fpga->readi(base, ln, sbuf); dp = &data[base-addr]; for(unsigned i=0; i<ln; i++) { if ((sbuf[i]&dp[i]) != dp[i]) { printf("\nNEED-ERASE @0x%08x ... %08x != %08x (Goal)\n", i+base-addr, sbuf[i], dp[i]); need_erase = true; newv = i+base; break; } else if ((sbuf[i] != dp[i])&&(newv == 0)) { // if (newv == 0) // printf("MEM[%08x] = %08x (!= %08x (Goal))\n", // i+base, sbuf[i], dp[i]); newv = i+base; } } } if (newv == 0) continue; // This sector already matches // Just erase anyway if (!need_erase) printf("NO ERASE NEEDED\n"); else { printf("ERASING SECTOR: %08x\n", s); if (!erase_sector(s, verify)) { printf("SECTOR ERASE FAILED!\n"); return false; } newv = (s<addr) ? addr : s; } for(unsigned p=newv; (p<s+SECTORSZ)&&(p<addr+len); p=PAGEOF(p+PGLEN)) { unsigned start = p, len = addr+len-start; // BUT! if we cross page boundaries, we need to clip // our results to the page boundary if (PAGEOF(start+len-1)!=PAGEOF(start)) len = PAGEOF(start+PGLEN)-start; if (!write_page(start, len, &data[p-addr], verify)) { printf("WRITE-PAGE FAILED!\n"); return false; } } } m_fpga->writeio(R_QSPI_EREG, 0); // Re-enable write protection return true; }
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