/* -*- c++ -*- */ /* * Copyright 2009 Free Software Foundation, Inc. * Copyright 2009-2011 Ettus Research LLC * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "spi_flash_private.h" //#include #include uint32_t spi_flash_rdsr(void) { return spif_transact(SPI_TXRX, SPI_SS_FLASH, RDSR_CMD << 8, 16, FLAGS) & 0xff; } static void spi_flash_write_enable(void) { // spif_transact(SPI_TXONLY, SPI_SS_FLASH, (WRSR_CMD << 8) | 0x00, 16, FLAGS); //disable write protection bits spif_transact(SPI_TXONLY, SPI_SS_FLASH, WREN_CMD, 8, FLAGS); } bool spi_flash_done_p(void) { return (spi_flash_rdsr() & SR_WIP) == 0; } void spi_flash_wait(void) { while (!spi_flash_done_p()) ; } void spi_flash_erase_sector_start(uint32_t flash_addr) { //uprintf(UART_DEBUG, "spi_flash_erase_sector_start: addr = 0x%x\n", flash_addr); if(flash_addr > spi_flash_memory_size()) return; spi_flash_wait(); spi_flash_write_enable(); spif_transact(SPI_TXONLY, SPI_SS_FLASH, (SE_CMD << 24) | (flash_addr & 0x00ffffff), 32, FLAGS); } bool spi_flash_page_program_start(uint32_t flash_addr, size_t nbytes, const void *buf) { if (nbytes == 0 || nbytes > SPI_FLASH_PAGE_SIZE) return false; //please to not be writing past the end of the device if ((flash_addr + nbytes) > spi_flash_memory_size()) return false; uint32_t local_buf[SPI_FLASH_PAGE_SIZE / sizeof(uint32_t)]; memset(local_buf, 0xff, sizeof(local_buf)); // init to 0xff (nops when programming) memcpy(local_buf, buf, nbytes); spi_flash_wait(); spi_flash_write_enable(); /* * We explicitly control the slave select here (/S), so that we can * do the entire write operation as a single transaction from * device's point of view. (The most our SPI peripheral can transfer * in a single shot is 16 bytes.) */ spif_wait(); spif_regs->ss = 0; spif_regs->ctrl = FLAGS; // ASS is now clear and no chip select is enabled. /* write PP_CMD, ADDR2, ADDR1, ADDR0 */ spif_regs->txrx0 = (PP_CMD << 24) | (flash_addr & 0x00ffffff); spif_regs->ss = SPI_SS_FLASH; // assert chip select spif_regs->ctrl = FLAGS | LEN(4 * 8); spif_regs->ctrl = FLAGS | LEN(4 * 8) | SPI_CTRL_GO_BSY; spif_wait(); /* send 256 bytes total, 16 at a time */ for (size_t i = 0; i < 16; i++){ spif_regs->txrx3 = local_buf[i * 4 + 0]; spif_regs->txrx2 = local_buf[i * 4 + 1]; spif_regs->txrx1 = local_buf[i * 4 + 2]; spif_regs->txrx0 = local_buf[i * 4 + 3]; spif_regs->ctrl = FLAGS | LEN(16 * 8); // xfer 16 bytes spif_regs->ctrl = FLAGS | LEN(16 * 8) | SPI_CTRL_GO_BSY; spif_wait(); } spif_regs->ss = 0; // desassert chip select return true; } void spi_flash_erase(uint32_t flash_addr, size_t nbytes) { if (nbytes == 0) return; uint32_t first = round_down(flash_addr, spi_flash_sector_size()); uint32_t last = round_down(flash_addr + nbytes - 1, spi_flash_sector_size()); for (uint32_t s = first; s <= last; s += spi_flash_sector_size()){ spi_flash_erase_sector_start(s); } spi_flash_wait(); } bool spi_flash_program(uint32_t flash_addr, size_t nbytes, const void *buf) { //uprintf(UART_DEBUG, "\nspi_flash_program: addr = 0x%x, nbytes = %d\n", flash_addr, nbytes); const unsigned char *p = (const unsigned char *) buf; size_t n; if ((nbytes + flash_addr) > spi_flash_memory_size()) return false; if (nbytes == 0) return true; uint32_t r = flash_addr % SPI_FLASH_PAGE_SIZE; if (r){ /* do initial non-aligned page */ n = min(SPI_FLASH_PAGE_SIZE - r, nbytes); spi_flash_page_program_start(flash_addr, n, p); flash_addr += n; p += n; nbytes -= n; } while (nbytes > 0){ n = min(SPI_FLASH_PAGE_SIZE, nbytes); spi_flash_page_program_start(flash_addr, n, p); flash_addr += n; p += n; nbytes -= n; } spi_flash_wait(); return true; } void spi_flash_async_erase_start(spi_flash_async_state_t *s, uint32_t flash_addr, size_t nbytes) { if ((nbytes == 0) || ((flash_addr + nbytes) > spi_flash_memory_size())){ s->first = s->last = s->current = 0; return; } uint32_t first = round_down(flash_addr, spi_flash_sector_size()); uint32_t last = round_down(flash_addr + nbytes - 1, spi_flash_sector_size()); s->first = first; s->last = last; s->current = first; spi_flash_erase_sector_start(s->current); } bool spi_flash_async_erase_poll(spi_flash_async_state_t *s) { if (!spi_flash_done_p()) return false; //printf("%d/%d\n", s->current, s->last); // The current sector erase has completed. See if we're finished or // if there's more to do. if (s->current == s->last) // we're done! return true; s->current += spi_flash_sector_size(); spi_flash_erase_sector_start(s->current); return false; }