/* * This file is part of the Serial Flash Universal Driver Library. * * Copyright (c) 2016, Armink, * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * 'Software'), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED 'AS IS', WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * * Function: Analyze the SFDP (Serial Flash Discoverable Parameters) which from JESD216/A/B (V1.X) standard. * JESD216 (V1.0) document: http://www.jedec.org/sites/default/files/docs/JESD216.pdf * JESD216A (V1.5) document: http://www.jedec.org/sites/default/files/docs/JESD216A.pdf * JESD216B (V1.6) document: http://www.jedec.org/sites/default/files/docs/JESD216B.pdf * * Created on: 2016-05-26 */ #include "../inc/sfud.h" /** * JEDEC Standard JESD216 Terms and definitions: * * DWORD: Four consecutive 8-bit bytes used as the basic 32-bit building block for headers and parameter tables. * * Sector: The minimum granularity - size and alignment - of an area that can be erased in the data array * of a flash memory device. Different areas within the address range of the data array may have a different * minimum erase granularity (sector size). */ #ifdef SFUD_USING_SFDP /* support maximum SFDP major revision by driver */ #define SUPPORT_MAX_SFDP_MAJOR_REV 1 /* the JEDEC basic flash parameter table length is 9 DWORDs (288-bit) on JESD216 (V1.0) initial release standard */ #define BASIC_TABLE_LEN 9 /* the smallest eraser in SFDP eraser table */ #define SMALLEST_ERASER_INDEX 0 /** * SFDP parameter header structure */ typedef struct { uint8_t id; /**< Parameter ID LSB */ uint8_t minor_rev; /**< Parameter minor revision */ uint8_t major_rev; /**< Parameter major revision */ uint8_t len; /**< Parameter table length(in double words) */ uint32_t ptp; /**< Parameter table 24bit pointer (byte address) */ } sfdp_para_header; static sfud_err read_sfdp_data(const sfud_flash *flash, uint32_t addr, uint8_t *read_buf, size_t size); static bool read_sfdp_header(sfud_flash *flash); static bool read_basic_header(const sfud_flash *flash, sfdp_para_header *basic_header); static bool read_basic_table(sfud_flash *flash, sfdp_para_header *basic_header); /* ../port/sfup_port.c */ extern void sfud_log_debug(const char *file, const long line, const char *format, ...); extern void sfud_log_info(const char *format, ...); /** * Read SFDP parameter information * * @param flash flash device * * @return true: read OK */ bool sfud_read_sfdp(sfud_flash *flash) { SFUD_ASSERT(flash); /* JEDEC basic flash parameter header */ sfdp_para_header basic_header; if (read_sfdp_header(flash) && read_basic_header(flash, &basic_header)) { return read_basic_table(flash, &basic_header); } else { SFUD_INFO("Warning: Read SFDP parameter header information failed. The %s does not support JEDEC SFDP.", flash->name); return false; } } /** * Read SFDP parameter header * * @param flash flash device * * @return true: read OK */ static bool read_sfdp_header(sfud_flash *flash) { sfud_sfdp *sfdp = &flash->sfdp; /* The SFDP header is located at address 000000h of the SFDP data structure. * It identifies the SFDP Signature, the number of parameter headers, and the SFDP revision numbers. */ /* sfdp parameter header address */ uint32_t header_addr = 0; /* each parameter header being 2 DWORDs (64-bit) */ uint8_t header[2 * 4] = { 0 }; SFUD_ASSERT(flash); sfdp->available = false; /* read SFDP header */ if (read_sfdp_data(flash, header_addr, header, sizeof(header)) != SFUD_SUCCESS) { SFUD_INFO("Error: Can't read SFDP header."); return false; } /* check SFDP header */ if (!(header[0] == 'S' && header[1] == 'F' && header[2] == 'D' && header[3] == 'P')) { SFUD_DEBUG("Error: Check SFDP signature error. It's must be 50444653h('S' 'F' 'D' 'P')."); return false; } sfdp->minor_rev = header[4]; sfdp->major_rev = header[5]; if (sfdp->major_rev > SUPPORT_MAX_SFDP_MAJOR_REV) { SFUD_INFO("Error: This reversion(V%d.%d) of SFDP is not supported.", sfdp->major_rev, sfdp->minor_rev); return false; } SFUD_DEBUG("Check SFDP header is OK. The reversion is V%d.%d, NPN is %d.", sfdp->major_rev, sfdp->minor_rev, header[6]); return true; } /** * Read JEDEC basic parameter header * * @param flash flash device * * @return true: read OK */ static bool read_basic_header(const sfud_flash *flash, sfdp_para_header *basic_header) { /* The basic parameter header is mandatory, is defined by this standard, and starts at byte offset 08h. */ uint32_t header_addr = 8; /* each parameter header being 2 DWORDs (64-bit) */ uint8_t header[2 * 4] = { 0 }; SFUD_ASSERT(flash); SFUD_ASSERT(basic_header); /* read JEDEC basic flash parameter header */ if (read_sfdp_data(flash, header_addr, header, sizeof(header)) != SFUD_SUCCESS) { SFUD_INFO("Error: Can't read JEDEC basic flash parameter header."); return false; } basic_header->id = header[0]; basic_header->minor_rev = header[1]; basic_header->major_rev = header[2]; basic_header->len = header[3]; basic_header->ptp = (long)header[4] | (long)header[5] << 8 | (long)header[6] << 16; /* check JEDEC basic flash parameter header */ if (basic_header->major_rev > SUPPORT_MAX_SFDP_MAJOR_REV) { SFUD_INFO("Error: This reversion(V%d.%d) of JEDEC basic flash parameter header is not supported.", basic_header->major_rev, basic_header->minor_rev); return false; } if (basic_header->len < BASIC_TABLE_LEN) { SFUD_INFO("Error: The JEDEC basic flash parameter table length (now is %d) error.", basic_header->len); return false; } SFUD_DEBUG("Check JEDEC basic flash parameter header is OK. The table id is %d, reversion is V%d.%d," " length is %d, parameter table pointer is 0x%06lX.", basic_header->id, basic_header->major_rev, basic_header->minor_rev, basic_header->len, basic_header->ptp); return true; } /** * Read JEDEC basic parameter table * * @param flash flash device * * @return true: read OK */ static bool read_basic_table(sfud_flash *flash, sfdp_para_header *basic_header) { sfud_sfdp *sfdp = &flash->sfdp; /* parameter table address */ uint32_t table_addr = basic_header->ptp; /* parameter table */ uint8_t table[BASIC_TABLE_LEN * 4] = { 0 }, i, j; SFUD_ASSERT(flash); SFUD_ASSERT(basic_header); /* read JEDEC basic flash parameter table */ if (read_sfdp_data(flash, table_addr, table, sizeof(table)) != SFUD_SUCCESS) { SFUD_INFO("Warning: Can't read JEDEC basic flash parameter table."); return false; } /* print JEDEC basic flash parameter table info */ SFUD_DEBUG("JEDEC basic flash parameter table info:"); SFUD_DEBUG("MSB-LSB 3 2 1 0"); for (i = 0; i < BASIC_TABLE_LEN; i++) { SFUD_DEBUG("[%04d] 0x%02X 0x%02X 0x%02X 0x%02X", i + 1, table[i * 4 + 3], table[i * 4 + 2], table[i * 4 + 1], table[i * 4]); } /* get block/sector 4 KB erase supported and command */ sfdp->erase_4k_cmd = table[1]; switch (table[0] & 0x03) { case 1: sfdp->erase_4k = true; SFUD_DEBUG("4 KB Erase is supported throughout the device. Command is 0x%02X.", sfdp->erase_4k_cmd); break; case 3: sfdp->erase_4k = false; SFUD_DEBUG("Uniform 4 KB erase is unavailable for this device."); break; default: SFUD_INFO("Error: Uniform 4 KB erase supported information error."); return false; } /* get write granularity */ //TODO 目前为 1.0 所提供的方式,后期支持 V1.5 及以上的方式读取 page size switch ((table[0] & (0x01 << 2)) >> 2) { case 0: sfdp->write_gran = 1; SFUD_DEBUG("Write granularity is 1 byte."); break; case 1: sfdp->write_gran = 256; SFUD_DEBUG("Write granularity is 64 bytes or larger."); break; } /* volatile status register block protect bits */ switch ((table[0] & (0x01 << 3)) >> 3) { case 0: /* Block Protect bits in device's status register are solely non-volatile or may be * programmed either as volatile using the 50h instruction for write enable or non-volatile * using the 06h instruction for write enable. */ sfdp->sr_is_non_vola = true; SFUD_DEBUG("Target flash status register is non-volatile."); break; case 1: /* block protect bits in device's status register are solely volatile. */ sfdp->sr_is_non_vola = false; SFUD_DEBUG("Block Protect bits in device's status register are solely volatile."); /* write enable instruction select for writing to volatile status register */ switch ((table[0] & (0x01 << 4)) >> 4) { case 0: sfdp->vola_sr_we_cmd = SFUD_VOLATILE_SR_WRITE_ENABLE; SFUD_DEBUG("Flash device requires instruction 50h as the write enable prior " "to performing a volatile write to the status register."); break; case 1: sfdp->vola_sr_we_cmd = SFUD_CMD_WRITE_ENABLE; SFUD_DEBUG("Flash device requires instruction 06h as the write enable prior " "to performing a volatile write to the status register."); break; } break; } /* get address bytes, number of bytes used in addressing flash array read, write and erase. */ switch ((table[2] & (0x03 << 1)) >> 1) { case 0: sfdp->addr_3_byte = true; sfdp->addr_4_byte = false; SFUD_DEBUG("3-Byte only addressing."); break; case 1: sfdp->addr_3_byte = true; sfdp->addr_4_byte = true; SFUD_DEBUG("3- or 4-Byte addressing."); break; case 2: sfdp->addr_3_byte = false; sfdp->addr_4_byte = true; SFUD_DEBUG("4-Byte only addressing."); break; default: sfdp->addr_3_byte = false; sfdp->addr_4_byte = false; SFUD_INFO("Error: Read address bytes error!"); return false; } /* get flash memory capacity */ uint32_t table2_temp = ((long)table[7] << 24) | ((long)table[6] << 16) | ((long)table[5] << 8) | (long)table[4]; switch ((table[7] & (0x01 << 7)) >> 7) { case 0: sfdp->capacity = 1 + (table2_temp >> 3); break; case 1: table2_temp &= 0x7FFFFFFF; if (table2_temp > sizeof(sfdp->capacity) * 8 + 3) { sfdp->capacity = 0; SFUD_INFO("Error: The flash capacity is grater than 32 Gb/ 4 GB! Not Supported."); return false; } sfdp->capacity = 1L << (table2_temp - 3); break; } SFUD_DEBUG("Capacity is %ld Bytes.", sfdp->capacity); /* get erase size and erase command */ for (i = 0, j = 0; i < SFUD_SFDP_ERASE_TYPE_MAX_NUM; i++) { if (table[28 + 2 * i] != 0x00) { sfdp->eraser[j].size = 1L << table[28 + 2 * i]; sfdp->eraser[j].cmd = table[28 + 2 * i + 1]; SFUD_DEBUG("Flash device supports %ldKB block erase. Command is 0x%02X.", sfdp->eraser[j].size / 1024, sfdp->eraser[j].cmd); j++; } } /* sort the eraser size from small to large */ for (i = 0, j = 0; i < SFUD_SFDP_ERASE_TYPE_MAX_NUM; i++) { if (sfdp->eraser[i].size) { for (j = i + 1; j < SFUD_SFDP_ERASE_TYPE_MAX_NUM; j++) { if (sfdp->eraser[j].size != 0 && sfdp->eraser[i].size > sfdp->eraser[j].size) { /* swap the small eraser */ uint32_t temp_size = sfdp->eraser[i].size; uint8_t temp_cmd = sfdp->eraser[i].cmd; sfdp->eraser[i].size = sfdp->eraser[j].size; sfdp->eraser[i].cmd = sfdp->eraser[j].cmd; sfdp->eraser[j].size = temp_size; sfdp->eraser[j].cmd = temp_cmd; } } } } sfdp->available = true; return true; } static sfud_err read_sfdp_data(const sfud_flash *flash, uint32_t addr, uint8_t *read_buf, size_t size) { uint8_t cmd[] = { SFUD_CMD_READ_SFDP_REGISTER, (addr >> 16) & 0xFF, (addr >> 8) & 0xFF, (addr >> 0) & 0xFF, SFUD_DUMMY_DATA, }; SFUD_ASSERT(flash); SFUD_ASSERT(addr < 1L << 24); SFUD_ASSERT(read_buf); SFUD_ASSERT(flash->spi.wr); return flash->spi.wr(&flash->spi, cmd, sizeof(cmd), read_buf, size); } /** * get the most suitable eraser for erase process from SFDP parameter * * @param flash flash device * @param addr start address * @param erase_size will be erased size * * @return the eraser index of SFDP eraser table @see sfud_sfdp.eraser[] */ size_t sfud_sfdp_get_suitable_eraser(const sfud_flash *flash, uint32_t addr, size_t erase_size) { size_t index = SMALLEST_ERASER_INDEX, i; /* only used when flash supported SFDP */ SFUD_ASSERT(flash->sfdp.available); /* the address isn't align by smallest eraser's size, then use the smallest eraser */ if (addr % flash->sfdp.eraser[SMALLEST_ERASER_INDEX].size) { return SMALLEST_ERASER_INDEX; } /* Find the suitable eraser. * The largest size eraser is at the end of eraser table. * In order to decrease erase command counts, so the find process is from the end of eraser table. */ for (i = SFUD_SFDP_ERASE_TYPE_MAX_NUM - 1;; i--) { if ((flash->sfdp.eraser[i].size != 0) && (erase_size >= flash->sfdp.eraser[i].size) && (addr % flash->sfdp.eraser[i].size == 0)) { index = i; break; } if (i == SMALLEST_ERASER_INDEX) { break; } } return index; } #endif /* SFUD_USING_SFDP */