/* * QTest testcase for the M25P80 Flash (Using the Aspeed SPI * Controller) * * Copyright (C) 2016 IBM Corp. * * 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. */ #include "qemu/osdep.h" #include "qemu/bswap.h" #include "libqtest-single.h" #include "qemu/bitops.h" /* * ASPEED SPI Controller registers */ #define R_CONF 0x00 #define CONF_ENABLE_W0 (1 << 16) #define R_CE_CTRL 0x04 #define CRTL_EXTENDED0 0 /* 32 bit addressing for SPI */ #define R_CTRL0 0x10 #define CTRL_CE_STOP_ACTIVE (1 << 2) #define CTRL_READMODE 0x0 #define CTRL_FREADMODE 0x1 #define CTRL_WRITEMODE 0x2 #define CTRL_USERMODE 0x3 #define SR_WEL BIT(1) #define ASPEED_FMC_BASE 0x1E620000 #define ASPEED_FLASH_BASE 0x20000000 /* * Flash commands */ enum { JEDEC_READ = 0x9f, RDSR = 0x5, WRDI = 0x4, BULK_ERASE = 0xc7, READ = 0x03, PP = 0x02, WRSR = 0x1, WREN = 0x6, SRWD = 0x80, RESET_ENABLE = 0x66, RESET_MEMORY = 0x99, EN_4BYTE_ADDR = 0xB7, ERASE_SECTOR = 0xd8, }; #define FLASH_JEDEC 0x20ba19 /* n25q256a */ #define FLASH_SIZE (32 * 1024 * 1024) #define FLASH_PAGE_SIZE 256 /* * Use an explicit bswap for the values read/wrote to the flash region * as they are BE and the Aspeed CPU is LE. */ static inline uint32_t make_be32(uint32_t data) { return bswap32(data); } static void spi_conf(uint32_t value) { uint32_t conf = readl(ASPEED_FMC_BASE + R_CONF); conf |= value; writel(ASPEED_FMC_BASE + R_CONF, conf); } static void spi_conf_remove(uint32_t value) { uint32_t conf = readl(ASPEED_FMC_BASE + R_CONF); conf &= ~value; writel(ASPEED_FMC_BASE + R_CONF, conf); } static void spi_ce_ctrl(uint32_t value) { uint32_t conf = readl(ASPEED_FMC_BASE + R_CE_CTRL); conf |= value; writel(ASPEED_FMC_BASE + R_CE_CTRL, conf); } static void spi_ctrl_setmode(uint8_t mode, uint8_t cmd) { uint32_t ctrl = readl(ASPEED_FMC_BASE + R_CTRL0); ctrl &= ~(CTRL_USERMODE | 0xff << 16); ctrl |= mode | (cmd << 16); writel(ASPEED_FMC_BASE + R_CTRL0, ctrl); } static void spi_ctrl_start_user(void) { uint32_t ctrl = readl(ASPEED_FMC_BASE + R_CTRL0); ctrl |= CTRL_USERMODE | CTRL_CE_STOP_ACTIVE; writel(ASPEED_FMC_BASE + R_CTRL0, ctrl); ctrl &= ~CTRL_CE_STOP_ACTIVE; writel(ASPEED_FMC_BASE + R_CTRL0, ctrl); } static void spi_ctrl_stop_user(void) { uint32_t ctrl = readl(ASPEED_FMC_BASE + R_CTRL0); ctrl |= CTRL_USERMODE | CTRL_CE_STOP_ACTIVE; writel(ASPEED_FMC_BASE + R_CTRL0, ctrl); } static void flash_reset(void) { spi_conf(CONF_ENABLE_W0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, RESET_ENABLE); writeb(ASPEED_FLASH_BASE, RESET_MEMORY); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, BULK_ERASE); writeb(ASPEED_FLASH_BASE, WRDI); spi_ctrl_stop_user(); spi_conf_remove(CONF_ENABLE_W0); } static void test_read_jedec(void) { uint32_t jedec = 0x0; spi_conf(CONF_ENABLE_W0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, JEDEC_READ); jedec |= readb(ASPEED_FLASH_BASE) << 16; jedec |= readb(ASPEED_FLASH_BASE) << 8; jedec |= readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); flash_reset(); g_assert_cmphex(jedec, ==, FLASH_JEDEC); } static void read_page(uint32_t addr, uint32_t *page) { int i; spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, READ); writel(ASPEED_FLASH_BASE, make_be32(addr)); /* Continuous read are supported */ for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { page[i] = make_be32(readl(ASPEED_FLASH_BASE)); } spi_ctrl_stop_user(); } static void read_page_mem(uint32_t addr, uint32_t *page) { int i; /* move out USER mode to use direct reads from the AHB bus */ spi_ctrl_setmode(CTRL_READMODE, READ); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { page[i] = make_be32(readl(ASPEED_FLASH_BASE + addr + i * 4)); } } static void write_page_mem(uint32_t addr, uint32_t write_value) { spi_ctrl_setmode(CTRL_WRITEMODE, PP); for (int i = 0; i < FLASH_PAGE_SIZE / 4; i++) { writel(ASPEED_FLASH_BASE + addr + i * 4, write_value); } } static void assert_page_mem(uint32_t addr, uint32_t expected_value) { uint32_t page[FLASH_PAGE_SIZE / 4]; read_page_mem(addr, page); for (int i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, expected_value); } } static void test_erase_sector(void) { uint32_t some_page_addr = 0x600 * FLASH_PAGE_SIZE; uint32_t page[FLASH_PAGE_SIZE / 4]; int i; spi_conf(CONF_ENABLE_W0); /* * Previous page should be full of 0xffs after backend is * initialized */ read_page(some_page_addr - FLASH_PAGE_SIZE, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, 0xffffffff); } spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, PP); writel(ASPEED_FLASH_BASE, make_be32(some_page_addr)); /* Fill the page with its own addresses */ for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { writel(ASPEED_FLASH_BASE, make_be32(some_page_addr + i * 4)); } spi_ctrl_stop_user(); /* Check the page is correctly written */ read_page(some_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, some_page_addr + i * 4); } spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, ERASE_SECTOR); writel(ASPEED_FLASH_BASE, make_be32(some_page_addr)); spi_ctrl_stop_user(); /* Check the page is erased */ read_page(some_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, 0xffffffff); } flash_reset(); } static void test_erase_all(void) { uint32_t some_page_addr = 0x15000 * FLASH_PAGE_SIZE; uint32_t page[FLASH_PAGE_SIZE / 4]; int i; spi_conf(CONF_ENABLE_W0); /* * Previous page should be full of 0xffs after backend is * initialized */ read_page(some_page_addr - FLASH_PAGE_SIZE, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, 0xffffffff); } spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, PP); writel(ASPEED_FLASH_BASE, make_be32(some_page_addr)); /* Fill the page with its own addresses */ for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { writel(ASPEED_FLASH_BASE, make_be32(some_page_addr + i * 4)); } spi_ctrl_stop_user(); /* Check the page is correctly written */ read_page(some_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, some_page_addr + i * 4); } spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, BULK_ERASE); spi_ctrl_stop_user(); /* Check the page is erased */ read_page(some_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, 0xffffffff); } flash_reset(); } static void test_write_page(void) { uint32_t my_page_addr = 0x14000 * FLASH_PAGE_SIZE; /* beyond 16MB */ uint32_t some_page_addr = 0x15000 * FLASH_PAGE_SIZE; uint32_t page[FLASH_PAGE_SIZE / 4]; int i; spi_conf(CONF_ENABLE_W0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, PP); writel(ASPEED_FLASH_BASE, make_be32(my_page_addr)); /* Fill the page with its own addresses */ for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { writel(ASPEED_FLASH_BASE, make_be32(my_page_addr + i * 4)); } spi_ctrl_stop_user(); /* Check what was written */ read_page(my_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, my_page_addr + i * 4); } /* Check some other page. It should be full of 0xff */ read_page(some_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, 0xffffffff); } flash_reset(); } static void test_read_page_mem(void) { uint32_t my_page_addr = 0x14000 * FLASH_PAGE_SIZE; /* beyond 16MB */ uint32_t some_page_addr = 0x15000 * FLASH_PAGE_SIZE; uint32_t page[FLASH_PAGE_SIZE / 4]; int i; /* Enable 4BYTE mode for controller. This is should be strapped by * HW for CE0 anyhow. */ spi_ce_ctrl(1 << CRTL_EXTENDED0); /* Enable 4BYTE mode for flash. */ spi_conf(CONF_ENABLE_W0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, PP); writel(ASPEED_FLASH_BASE, make_be32(my_page_addr)); /* Fill the page with its own addresses */ for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { writel(ASPEED_FLASH_BASE, make_be32(my_page_addr + i * 4)); } spi_ctrl_stop_user(); spi_conf_remove(CONF_ENABLE_W0); /* Check what was written */ read_page_mem(my_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, my_page_addr + i * 4); } /* Check some other page. It should be full of 0xff */ read_page_mem(some_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, 0xffffffff); } flash_reset(); } static void test_write_page_mem(void) { uint32_t my_page_addr = 0x15000 * FLASH_PAGE_SIZE; uint32_t page[FLASH_PAGE_SIZE / 4]; int i; /* Enable 4BYTE mode for controller. This is should be strapped by * HW for CE0 anyhow. */ spi_ce_ctrl(1 << CRTL_EXTENDED0); /* Enable 4BYTE mode for flash. */ spi_conf(CONF_ENABLE_W0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); spi_ctrl_stop_user(); /* move out USER mode to use direct writes to the AHB bus */ spi_ctrl_setmode(CTRL_WRITEMODE, PP); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { writel(ASPEED_FLASH_BASE + my_page_addr + i * 4, make_be32(my_page_addr + i * 4)); } /* Check what was written */ read_page_mem(my_page_addr, page); for (i = 0; i < FLASH_PAGE_SIZE / 4; i++) { g_assert_cmphex(page[i], ==, my_page_addr + i * 4); } flash_reset(); } static void test_read_status_reg(void) { uint8_t r; spi_conf(CONF_ENABLE_W0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); g_assert_cmphex(r & SR_WEL, ==, 0); g_assert(!qtest_qom_get_bool (global_qtest, "/machine/soc/fmc/ssi.0/child[0]", "write-enable")); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); g_assert_cmphex(r & SR_WEL, ==, SR_WEL); g_assert(qtest_qom_get_bool (global_qtest, "/machine/soc/fmc/ssi.0/child[0]", "write-enable")); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WRDI); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); g_assert_cmphex(r & SR_WEL, ==, 0); g_assert(!qtest_qom_get_bool (global_qtest, "/machine/soc/fmc/ssi.0/child[0]", "write-enable")); flash_reset(); } static void test_status_reg_write_protection(void) { uint8_t r; spi_conf(CONF_ENABLE_W0); /* default case: WP# is high and SRWD is low -> status register writable */ spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); /* test ability to write SRWD */ writeb(ASPEED_FLASH_BASE, WRSR); writeb(ASPEED_FLASH_BASE, SRWD); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); g_assert_cmphex(r & SRWD, ==, SRWD); /* WP# high and SRWD high -> status register writable */ spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); /* test ability to write SRWD */ writeb(ASPEED_FLASH_BASE, WRSR); writeb(ASPEED_FLASH_BASE, 0); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); g_assert_cmphex(r & SRWD, ==, 0); /* WP# low and SRWD low -> status register writable */ qtest_set_irq_in(global_qtest, "/machine/soc/fmc/ssi.0/child[0]", "WP#", 0, 0); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); /* test ability to write SRWD */ writeb(ASPEED_FLASH_BASE, WRSR); writeb(ASPEED_FLASH_BASE, SRWD); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); g_assert_cmphex(r & SRWD, ==, SRWD); /* WP# low and SRWD high -> status register NOT writable */ spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); /* test ability to write SRWD */ writeb(ASPEED_FLASH_BASE, WRSR); writeb(ASPEED_FLASH_BASE, 0); writeb(ASPEED_FLASH_BASE, RDSR); r = readb(ASPEED_FLASH_BASE); spi_ctrl_stop_user(); /* write is not successful */ g_assert_cmphex(r & SRWD, ==, SRWD); qtest_set_irq_in(global_qtest, "/machine/soc/fmc/ssi.0/child[0]", "WP#", 0, 1); flash_reset(); } static void test_write_block_protect(void) { uint32_t sector_size = 65536; uint32_t n_sectors = 512; spi_ce_ctrl(1 << CRTL_EXTENDED0); spi_conf(CONF_ENABLE_W0); uint32_t bp_bits = 0b0; for (int i = 0; i < 16; i++) { bp_bits = ((i & 0b1000) << 3) | ((i & 0b0111) << 2); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, BULK_ERASE); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, WRSR); writeb(ASPEED_FLASH_BASE, bp_bits); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); spi_ctrl_stop_user(); uint32_t num_protected_sectors = i ? MIN(1 << (i - 1), n_sectors) : 0; uint32_t protection_start = n_sectors - num_protected_sectors; uint32_t protection_end = n_sectors; for (int sector = 0; sector < n_sectors; sector++) { uint32_t addr = sector * sector_size; assert_page_mem(addr, 0xffffffff); write_page_mem(addr, make_be32(0xabcdef12)); uint32_t expected_value = protection_start <= sector && sector < protection_end ? 0xffffffff : 0xabcdef12; assert_page_mem(addr, expected_value); } } flash_reset(); } static void test_write_block_protect_bottom_bit(void) { uint32_t sector_size = 65536; uint32_t n_sectors = 512; spi_ce_ctrl(1 << CRTL_EXTENDED0); spi_conf(CONF_ENABLE_W0); /* top bottom bit is enabled */ uint32_t bp_bits = 0b00100 << 3; for (int i = 0; i < 16; i++) { bp_bits = (((i & 0b1000) | 0b0100) << 3) | ((i & 0b0111) << 2); spi_ctrl_start_user(); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, BULK_ERASE); writeb(ASPEED_FLASH_BASE, WREN); writeb(ASPEED_FLASH_BASE, WRSR); writeb(ASPEED_FLASH_BASE, bp_bits); writeb(ASPEED_FLASH_BASE, EN_4BYTE_ADDR); writeb(ASPEED_FLASH_BASE, WREN); spi_ctrl_stop_user(); uint32_t num_protected_sectors = i ? MIN(1 << (i - 1), n_sectors) : 0; uint32_t protection_start = 0; uint32_t protection_end = num_protected_sectors; for (int sector = 0; sector < n_sectors; sector++) { uint32_t addr = sector * sector_size; assert_page_mem(addr, 0xffffffff); write_page_mem(addr, make_be32(0xabcdef12)); uint32_t expected_value = protection_start <= sector && sector < protection_end ? 0xffffffff : 0xabcdef12; assert_page_mem(addr, expected_value); } } flash_reset(); } static char tmp_path[] = "/tmp/qtest.m25p80.XXXXXX"; int main(int argc, char **argv) { int ret; int fd; g_test_init(&argc, &argv, NULL); fd = mkstemp(tmp_path); g_assert(fd >= 0); ret = ftruncate(fd, FLASH_SIZE); g_assert(ret == 0); close(fd); global_qtest = qtest_initf("-m 256 -machine palmetto-bmc " "-drive file=%s,format=raw,if=mtd", tmp_path); qtest_add_func("/ast2400/smc/read_jedec", test_read_jedec); qtest_add_func("/ast2400/smc/erase_sector", test_erase_sector); qtest_add_func("/ast2400/smc/erase_all", test_erase_all); qtest_add_func("/ast2400/smc/write_page", test_write_page); qtest_add_func("/ast2400/smc/read_page_mem", test_read_page_mem); qtest_add_func("/ast2400/smc/write_page_mem", test_write_page_mem); qtest_add_func("/ast2400/smc/read_status_reg", test_read_status_reg); qtest_add_func("/ast2400/smc/status_reg_write_protection", test_status_reg_write_protection); qtest_add_func("/ast2400/smc/write_block_protect", test_write_block_protect); qtest_add_func("/ast2400/smc/write_block_protect_bottom_bit", test_write_block_protect_bottom_bit); flash_reset(); ret = g_test_run(); qtest_quit(global_qtest); unlink(tmp_path); return ret; }