// SPDX-License-Identifier: GPL-2.0+ OR BSD-3-Clause /* * Copyright (C) 2019, STMicroelectronics - All Rights Reserved */ #include #include #include #include #include #include #include #include #include "stm32mp1_tests.h" #define ADDR_INVALID 0xFFFFFFFF DECLARE_GLOBAL_DATA_PTR; static int get_bufsize(char *string, int argc, char *argv[], int arg_nb, size_t *bufsize, size_t default_size, size_t min_size) { unsigned long value; if (argc > arg_nb) { if (strict_strtoul(argv[arg_nb], 0, &value) < 0) { sprintf(string, "invalid %d parameter %s", arg_nb, argv[arg_nb]); return -1; } if (value > STM32_DDR_SIZE || value < min_size) { sprintf(string, "invalid size %s (min=%d)", argv[arg_nb], min_size); return -1; } if (value & (min_size - 1)) { sprintf(string, "unaligned size %s (min=%d)", argv[arg_nb], min_size); return -1; } *bufsize = value; } else { if (default_size != STM32_DDR_SIZE) *bufsize = default_size; else *bufsize = get_ram_size((long *)STM32_DDR_BASE, STM32_DDR_SIZE); } return 0; } static int get_nb_loop(char *string, int argc, char *argv[], int arg_nb, u32 *nb_loop, u32 default_nb_loop) { unsigned long value; if (argc > arg_nb) { if (strict_strtoul(argv[arg_nb], 0, &value) < 0) { sprintf(string, "invalid %d parameter %s", arg_nb, argv[arg_nb]); return -1; } if (value == 0) printf("WARNING: infinite loop requested\n"); *nb_loop = value; } else { *nb_loop = default_nb_loop; } return 0; } static int get_addr(char *string, int argc, char *argv[], int arg_nb, u32 *addr) { unsigned long value; if (argc > arg_nb) { if (strict_strtoul(argv[arg_nb], 16, &value) < 0) { sprintf(string, "invalid %d parameter %s", arg_nb, argv[arg_nb]); return -1; } if (value < STM32_DDR_BASE) { sprintf(string, "too low address %s", argv[arg_nb]); return -1; } if (value & 0x3 && value != ADDR_INVALID) { sprintf(string, "unaligned address %s", argv[arg_nb]); return -1; } *addr = value; } else { *addr = STM32_DDR_BASE; } return 0; } static int get_pattern(char *string, int argc, char *argv[], int arg_nb, u32 *pattern, u32 default_pattern) { unsigned long value; if (argc > arg_nb) { if (strict_strtoul(argv[arg_nb], 16, &value) < 0) { sprintf(string, "invalid %d parameter %s", arg_nb, argv[arg_nb]); return -1; } *pattern = value; } else { *pattern = default_pattern; } return 0; } static u32 check_addr(u32 addr, u32 value) { u32 data = readl(addr); if (value != data) { printf("0x%08x: 0x%08x <=> 0x%08x", addr, data, value); data = readl(addr); printf("(2nd read: 0x%08x)", data); if (value == data) printf("- read error"); else printf("- write error"); printf("\n"); return -1; } return 0; } static int progress(u32 offset) { if (!(offset & 0xFFFFFF)) { putc('.'); if (ctrlc()) { printf("\ntest interrupted!\n"); return 1; } } return 0; } static int test_loop_end(u32 *loop, u32 nb_loop, u32 progress) { (*loop)++; if (nb_loop && *loop >= nb_loop) return 1; if ((*loop) % progress) return 0; /* allow to interrupt the test only for progress step */ if (ctrlc()) { printf("test interrupted!\n"); return 1; } printf("loop #%d\n", *loop); WATCHDOG_RESET(); return 0; } /********************************************************************** * * Function: memTestDataBus() * * Description: Test the data bus wiring in a memory region by * performing a walking 1's test at a fixed address * within that region. The address is selected * by the caller. * * Notes: * * Returns: 0 if the test succeeds. * A non-zero result is the first pattern that failed. * **********************************************************************/ static u32 databus(u32 *address) { u32 pattern; u32 read_value; /* Perform a walking 1's test at the given address. */ for (pattern = 1; pattern != 0; pattern <<= 1) { /* Write the test pattern. */ writel(pattern, address); /* Read it back (immediately is okay for this test). */ read_value = readl(address); debug("%x: %x <=> %x\n", (u32)address, read_value, pattern); if (read_value != pattern) return pattern; } return 0; } /********************************************************************** * * Function: memTestAddressBus() * * Description: Test the address bus wiring in a memory region by * performing a walking 1's test on the relevant bits * of the address and checking for aliasing. This test * will find single-bit address failures such as stuck * -high, stuck-low, and shorted pins. The base address * and size of the region are selected by the caller. * * Notes: For best results, the selected base address should * have enough LSB 0's to guarantee single address bit * changes. For example, to test a 64-Kbyte region, * select a base address on a 64-Kbyte boundary. Also, * select the region size as a power-of-two--if at all * possible. * * Returns: NULL if the test succeeds. * A non-zero result is the first address at which an * aliasing problem was uncovered. By examining the * contents of memory, it may be possible to gather * additional information about the problem. * **********************************************************************/ static u32 *addressbus(u32 *address, u32 nb_bytes) { u32 mask = (nb_bytes / sizeof(u32) - 1); u32 offset; u32 test_offset; u32 read_value; u32 pattern = 0xAAAAAAAA; u32 antipattern = 0x55555555; /* Write the default pattern at each of the power-of-two offsets. */ for (offset = 1; (offset & mask) != 0; offset <<= 1) writel(pattern, &address[offset]); /* Check for address bits stuck high. */ test_offset = 0; writel(antipattern, &address[test_offset]); for (offset = 1; (offset & mask) != 0; offset <<= 1) { read_value = readl(&address[offset]); debug("%x: %x <=> %x\n", (u32)&address[offset], read_value, pattern); if (read_value != pattern) return &address[offset]; } writel(pattern, &address[test_offset]); /* Check for address bits stuck low or shorted. */ for (test_offset = 1; (test_offset & mask) != 0; test_offset <<= 1) { writel(antipattern, &address[test_offset]); if (readl(&address[0]) != pattern) return &address[test_offset]; for (offset = 1; (offset & mask) != 0; offset <<= 1) { if (readl(&address[offset]) != pattern && offset != test_offset) return &address[test_offset]; } writel(pattern, &address[test_offset]); } return NULL; } /********************************************************************** * * Function: memTestDevice() * * Description: Test the integrity of a physical memory device by * performing an increment/decrement test over the * entire region. In the process every storage bit * in the device is tested as a zero and a one. The * base address and the size of the region are * selected by the caller. * * Notes: * * Returns: NULL if the test succeeds. * * A non-zero result is the first address at which an * incorrect value was read back. By examining the * contents of memory, it may be possible to gather * additional information about the problem. * **********************************************************************/ static u32 *memdevice(u32 *address, u32 nb_bytes) { u32 offset; u32 nb_words = nb_bytes / sizeof(u32); u32 pattern; u32 antipattern; puts("Fill with pattern"); /* Fill memory with a known pattern. */ for (pattern = 1, offset = 0; offset < nb_words; pattern++, offset++) { writel(pattern, &address[offset]); if (progress(offset)) return NULL; } puts("\nCheck and invert pattern"); /* Check each location and invert it for the second pass. */ for (pattern = 1, offset = 0; offset < nb_words; pattern++, offset++) { if (readl(&address[offset]) != pattern) return &address[offset]; antipattern = ~pattern; writel(antipattern, &address[offset]); if (progress(offset)) return NULL; } puts("\nCheck inverted pattern"); /* Check each location for the inverted pattern and zero it. */ for (pattern = 1, offset = 0; offset < nb_words; pattern++, offset++) { antipattern = ~pattern; if (readl(&address[offset]) != antipattern) return &address[offset]; if (progress(offset)) return NULL; } printf("\n"); return NULL; } static enum test_result databuswalk0(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { int i; u32 loop = 0, nb_loop; u32 addr; u32 error = 0; u32 data; if (get_nb_loop(string, argc, argv, 0, &nb_loop, 100)) return TEST_ERROR; if (get_addr(string, argc, argv, 1, &addr)) return TEST_ERROR; printf("running %d loops at 0x%x\n", nb_loop, addr); while (!error) { for (i = 0; i < 32; i++) writel(~(1 << i), addr + 4 * i); for (i = 0; i < 32; i++) { data = readl(addr + 4 * i); if (~(1 << i) != data) { error |= 1 << i; debug("%x: error %x expected %x => error:%x\n", addr + 4 * i, data, ~(1 << i), error); } } if (test_loop_end(&loop, nb_loop, 1000)) break; for (i = 0; i < 32; i++) writel(0, addr + 4 * i); } if (error) { sprintf(string, "loop %d: error for bits 0x%x", loop, error); return TEST_FAILED; } sprintf(string, "no error for %d loops", loop); return TEST_PASSED; } static enum test_result databuswalk1(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { int i; u32 loop = 0, nb_loop; u32 addr; u32 error = 0; u32 data; if (get_nb_loop(string, argc, argv, 0, &nb_loop, 100)) return TEST_ERROR; if (get_addr(string, argc, argv, 1, &addr)) return TEST_ERROR; printf("running %d loops at 0x%x\n", nb_loop, addr); while (!error) { for (i = 0; i < 32; i++) writel(1 << i, addr + 4 * i); for (i = 0; i < 32; i++) { data = readl(addr + 4 * i); if ((1 << i) != data) { error |= 1 << i; debug("%x: error %x expected %x => error:%x\n", addr + 4 * i, data, (1 << i), error); } } if (test_loop_end(&loop, nb_loop, 1000)) break; for (i = 0; i < 32; i++) writel(0, addr + 4 * i); } if (error) { sprintf(string, "loop %d: error for bits 0x%x", loop, error); return TEST_FAILED; } sprintf(string, "no error for %d loops", loop); return TEST_PASSED; } static enum test_result test_databus(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 addr; u32 error; if (get_addr(string, argc, argv, 0, &addr)) return TEST_ERROR; error = databus((u32 *)addr); if (error) { sprintf(string, "0x%x: error for bits 0x%x", addr, error); return TEST_FAILED; } sprintf(string, "address 0x%x", addr); return TEST_PASSED; } static enum test_result test_addressbus(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 addr; u32 bufsize; u32 error; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 4)) return TEST_ERROR; if (!is_power_of_2(bufsize)) { sprintf(string, "size 0x%x is not a power of 2", (u32)bufsize); return TEST_ERROR; } if (get_addr(string, argc, argv, 1, &addr)) return TEST_ERROR; error = (u32)addressbus((u32 *)addr, bufsize); if (error) { sprintf(string, "0x%x: error for address 0x%x", addr, error); return TEST_FAILED; } sprintf(string, "address 0x%x, size 0x%x", addr, bufsize); return TEST_PASSED; } static enum test_result test_memdevice(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 addr; size_t bufsize; u32 error; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 4)) return TEST_ERROR; if (get_addr(string, argc, argv, 1, &addr)) return TEST_ERROR; error = (u32)memdevice((u32 *)addr, (unsigned long)bufsize); if (error) { sprintf(string, "0x%x: error for address 0x%x", addr, error); return TEST_FAILED; } sprintf(string, "address 0x%x, size 0x%x", addr, bufsize); return TEST_PASSED; } /********************************************************************** * * Function: sso * * Description: Test the Simultaneous Switching Output. * Verifies succes sive reads and writes to the same memory word, * holding one bit constant while toggling all other data bits * simultaneously * => stress the data bus over an address range * * The CPU writes to each address in the given range. * For each bit, first the CPU holds the bit at 1 while * toggling the other bits, and then the CPU holds the bit at 0 * while toggling the other bits. * After each write, the CPU reads the address that was written * to verify that it contains the correct data * **********************************************************************/ static enum test_result test_sso(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { int i, j; u32 addr, bufsize, remaining, offset; u32 error = 0; u32 data; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 4)) return TEST_ERROR; if (get_addr(string, argc, argv, 1, &addr)) return TEST_ERROR; printf("running sso at 0x%x length 0x%x", addr, bufsize); offset = addr; remaining = bufsize; while (remaining) { for (i = 0; i < 32; i++) { /* write pattern. */ for (j = 0; j < 6; j++) { switch (j) { case 0: case 2: data = 1 << i; break; case 3: case 5: data = ~(1 << i); break; case 1: data = ~0x0; break; case 4: data = 0x0; break; } writel(data, offset); error = check_addr(offset, data); if (error) goto end; } } offset += 4; remaining -= 4; if (progress(offset << 7)) goto end; } puts("\n"); end: if (error) { sprintf(string, "error for pattern 0x%x @0x%x", data, offset); return TEST_FAILED; } sprintf(string, "no error for sso at 0x%x length 0x%x", addr, bufsize); return TEST_PASSED; } /********************************************************************** * * Function: Random * * Description: Verifies r/w with pseudo-ramdom value on one region * + write the region (individual access) * + memcopy to the 2nd region (try to use burst) * + verify the 2 regions * **********************************************************************/ static enum test_result test_random(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 addr, offset, value = 0; size_t bufsize; u32 loop = 0, nb_loop; u32 error = 0; unsigned int seed; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 8)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; bufsize /= 2; printf("running %d loops copy from 0x%x to 0x%x (buffer size=0x%x)\n", nb_loop, addr, addr + bufsize, bufsize); while (!error) { seed = rand(); for (offset = 0; offset < bufsize; offset += 4) writel(rand(), addr + offset); memcpy((void *)addr + bufsize, (void *)addr, bufsize); srand(seed); for (offset = 0; offset < 2 * bufsize; offset += 4) { if (offset == bufsize) srand(seed); value = rand(); error = check_addr(addr + offset, value); if (error) break; if (progress(offset)) return TEST_FAILED; } if (test_loop_end(&loop, nb_loop, 100)) break; } putc('\n'); if (error) { sprintf(string, "loop %d: error for address 0x%x: 0x%x expected 0x%x", loop, offset, readl(offset), value); return TEST_FAILED; } sprintf(string, "no error for %d loops, size 0x%x", loop, bufsize); return TEST_PASSED; } /********************************************************************** * * Function: noise * * Description: Verifies r/w while forcing switching of all data bus lines. * optimised 4 iteration write/read/write/read cycles... * for pattern and inversed pattern * **********************************************************************/ void do_noise(u32 addr, u32 pattern, u32 *result) { __asm__("push {R0-R11}"); __asm__("mov r0, %0" : : "r" (addr)); __asm__("mov r1, %0" : : "r" (pattern)); __asm__("mov r11, %0" : : "r" (result)); __asm__("mvn r2, r1"); __asm__("str r1, [r0]"); __asm__("ldr r3, [r0]"); __asm__("str r2, [r0]"); __asm__("ldr r4, [r0]"); __asm__("str r1, [r0]"); __asm__("ldr r5, [r0]"); __asm__("str r2, [r0]"); __asm__("ldr r6, [r0]"); __asm__("str r1, [r0]"); __asm__("ldr r7, [r0]"); __asm__("str r2, [r0]"); __asm__("ldr r8, [r0]"); __asm__("str r1, [r0]"); __asm__("ldr r9, [r0]"); __asm__("str r2, [r0]"); __asm__("ldr r10, [r0]"); __asm__("stmia R11!, {R3-R10}"); __asm__("pop {R0-R11}"); } static enum test_result test_noise(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 addr, pattern; u32 result[8]; int i; enum test_result res = TEST_PASSED; if (get_pattern(string, argc, argv, 0, &pattern, 0xFFFFFFFF)) return TEST_ERROR; if (get_addr(string, argc, argv, 1, &addr)) return TEST_ERROR; printf("running noise for 0x%x at 0x%x\n", pattern, addr); do_noise(addr, pattern, result); for (i = 0; i < 0x8;) { if (check_addr((u32)&result[i++], pattern)) res = TEST_FAILED; if (check_addr((u32)&result[i++], ~pattern)) res = TEST_FAILED; } return res; } /********************************************************************** * * Function: noise_burst * * Description: Verifies r/w while forcing switching of all data bus lines. * optimised write loop witrh store multiple to use burst * for pattern and inversed pattern * **********************************************************************/ void do_noise_burst(u32 addr, u32 pattern, size_t bufsize) { __asm__("push {R0-R9}"); __asm__("mov r0, %0" : : "r" (addr)); __asm__("mov r1, %0" : : "r" (pattern)); __asm__("mov r9, %0" : : "r" (bufsize)); __asm__("mvn r2, r1"); __asm__("mov r3, r1"); __asm__("mov r4, r2"); __asm__("mov r5, r1"); __asm__("mov r6, r2"); __asm__("mov r7, r1"); __asm__("mov r8, r2"); __asm__("loop1:"); __asm__("stmia R0!, {R1-R8}"); __asm__("stmia R0!, {R1-R8}"); __asm__("stmia R0!, {R1-R8}"); __asm__("stmia R0!, {R1-R8}"); __asm__("subs r9, r9, #128"); __asm__("bge loop1"); __asm__("pop {R0-R9}"); } /* chunk size enough to allow interruption with Ctrl-C*/ #define CHUNK_SIZE 0x8000000 static enum test_result test_noise_burst(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 addr, offset, pattern; size_t bufsize, remaining, size; int i; enum test_result res = TEST_PASSED; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 128)) return TEST_ERROR; if (get_pattern(string, argc, argv, 1, &pattern, 0xFFFFFFFF)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running noise burst for 0x%x at 0x%x + 0x%x", pattern, addr, bufsize); offset = addr; remaining = bufsize; size = CHUNK_SIZE; while (remaining) { if (remaining < size) size = remaining; do_noise_burst(offset, pattern, size); remaining -= size; offset += size; if (progress(offset)) { res = TEST_FAILED; goto end; } } puts("\ncheck buffer"); for (i = 0; i < bufsize;) { if (check_addr(addr + i, pattern)) res = TEST_FAILED; i += 4; if (check_addr(addr + i, ~pattern)) res = TEST_FAILED; i += 4; if (progress(i)) { res = TEST_FAILED; goto end; } } end: puts("\n"); return res; } /********************************************************************** * * Function: pattern test * * Description: optimized loop for read/write pattern (array of 8 u32) * **********************************************************************/ #define PATTERN_SIZE 8 static enum test_result test_loop(const u32 *pattern, u32 *address, const u32 bufsize) { int i; int j; enum test_result res = TEST_PASSED; u32 offset, testsize, remaining; offset = (u32)address; remaining = bufsize; while (remaining) { testsize = bufsize > 0x1000000 ? 0x1000000 : bufsize; __asm__("push {R0-R10}"); __asm__("mov r0, %0" : : "r" (pattern)); __asm__("mov r1, %0" : : "r" (offset)); __asm__("mov r2, %0" : : "r" (testsize)); __asm__("ldmia r0!, {R3-R10}"); __asm__("loop2:"); __asm__("stmia r1!, {R3-R10}"); __asm__("stmia r1!, {R3-R10}"); __asm__("stmia r1!, {R3-R10}"); __asm__("stmia r1!, {R3-R10}"); __asm__("subs r2, r2, #128"); __asm__("bge loop2"); __asm__("pop {R0-R10}"); offset += testsize; remaining -= testsize; if (progress((u32)offset)) { res = TEST_FAILED; goto end; } } puts("\ncheck buffer"); for (i = 0; i < bufsize; i += PATTERN_SIZE * 4) { for (j = 0; j < PATTERN_SIZE; j++, address++) if (check_addr((u32)address, pattern[j])) { res = TEST_FAILED; goto end; } if (progress(i)) { res = TEST_FAILED; goto end; } } end: puts("\n"); return res; } const u32 pattern_div1_x16[PATTERN_SIZE] = { 0x0000FFFF, 0x0000FFFF, 0x0000FFFF, 0x0000FFFF, 0x0000FFFF, 0x0000FFFF, 0x0000FFFF, 0x0000FFFF }; const u32 pattern_div2_x16[PATTERN_SIZE] = { 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0x00000000 }; const u32 pattern_div4_x16[PATTERN_SIZE] = { 0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000, 0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000 }; const u32 pattern_div4_x32[PATTERN_SIZE] = { 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000, 0x00000000, 0x00000000 }; const u32 pattern_mostly_zero_x16[PATTERN_SIZE] = { 0x00000000, 0x00000000, 0x00000000, 0x0000FFFF, 0x00000000, 0x00000000, 0x00000000, 0x00000000 }; const u32 pattern_mostly_zero_x32[PATTERN_SIZE] = { 0x00000000, 0x00000000, 0x00000000, 0xFFFFFFFF, 0x00000000, 0x00000000, 0x00000000, 0x00000000 }; const u32 pattern_mostly_one_x16[PATTERN_SIZE] = { 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0x0000FFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF }; const u32 pattern_mostly_one_x32[PATTERN_SIZE] = { 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF }; #define NB_PATTERN 5 static enum test_result test_freq_pattern(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { const u32 * const patterns_x16[NB_PATTERN] = { pattern_div1_x16, pattern_div2_x16, pattern_div4_x16, pattern_mostly_zero_x16, pattern_mostly_one_x16, }; const u32 * const patterns_x32[NB_PATTERN] = { pattern_div2_x16, pattern_div4_x16, pattern_div4_x32, pattern_mostly_zero_x32, pattern_mostly_one_x32 }; const char *patterns_comments[NB_PATTERN] = { "switching at frequency F/1", "switching at frequency F/2", "switching at frequency F/4", "mostly zero", "mostly one" }; enum test_result res = TEST_PASSED, pattern_res; int i, bus_width; const u32 **patterns; u32 bufsize; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 128)) return TEST_ERROR; switch (readl(&ctl->mstr) & DDRCTRL_MSTR_DATA_BUS_WIDTH_MASK) { case DDRCTRL_MSTR_DATA_BUS_WIDTH_HALF: case DDRCTRL_MSTR_DATA_BUS_WIDTH_QUARTER: bus_width = 16; break; default: bus_width = 32; break; } printf("running test pattern at 0x%08x length 0x%x width = %d\n", STM32_DDR_BASE, bufsize, bus_width); patterns = (const u32 **)(bus_width == 16 ? patterns_x16 : patterns_x32); for (i = 0; i < NB_PATTERN; i++) { printf("test data pattern %s:", patterns_comments[i]); pattern_res = test_loop(patterns[i], (u32 *)STM32_DDR_BASE, bufsize); if (pattern_res != TEST_PASSED) { printf("Failed\n"); return pattern_res; } printf("Passed\n"); } return res; } /********************************************************************** * * Function: pattern test with size * * Description: loop for write pattern * **********************************************************************/ static enum test_result test_loop_size(const u32 *pattern, u32 size, u32 *address, const u32 bufsize) { int i, j; enum test_result res = TEST_PASSED; u32 *p = address; for (i = 0; i < bufsize; i += size * 4) { for (j = 0; j < size ; j++, p++) *p = pattern[j]; if (progress(i)) { res = TEST_FAILED; goto end; } } puts("\ncheck buffer"); p = address; for (i = 0; i < bufsize; i += size * 4) { for (j = 0; j < size; j++, p++) if (check_addr((u32)p, pattern[j])) { res = TEST_FAILED; goto end; } if (progress(i)) { res = TEST_FAILED; goto end; } } end: puts("\n"); return res; } static enum test_result test_checkboard(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED; u32 bufsize, nb_loop, loop = 0, addr; int i; u32 checkboard[2] = {0x55555555, 0xAAAAAAAA}; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 8)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running %d loops at 0x%08x length 0x%x\n", nb_loop, addr, bufsize); while (1) { for (i = 0; i < 2; i++) { res = test_loop_size(checkboard, 2, (u32 *)addr, bufsize); if (res) return res; checkboard[0] = ~checkboard[0]; checkboard[1] = ~checkboard[1]; } if (test_loop_end(&loop, nb_loop, 1)) break; } sprintf(string, "no error for %d loops at 0x%08x length 0x%x", loop, addr, bufsize); return res; } static enum test_result test_blockseq(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED; u32 bufsize, nb_loop, loop = 0, addr, value; int i; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 4)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running %d loops at 0x%08x length 0x%x\n", nb_loop, addr, bufsize); while (1) { for (i = 0; i < 256; i++) { value = i | i << 8 | i << 16 | i << 24; printf("pattern = %08x", value); res = test_loop_size(&value, 1, (u32 *)addr, bufsize); if (res != TEST_PASSED) return res; } if (test_loop_end(&loop, nb_loop, 1)) break; } sprintf(string, "no error for %d loops at 0x%08x length 0x%x", loop, addr, bufsize); return res; } static enum test_result test_walkbit0(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED; u32 bufsize, nb_loop, loop = 0, addr, value; int i; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 4)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running %d loops at 0x%08x length 0x%x\n", nb_loop, addr, bufsize); while (1) { for (i = 0; i < 64; i++) { if (i < 32) value = 1 << i; else value = 1 << (63 - i); printf("pattern = %08x", value); res = test_loop_size(&value, 1, (u32 *)addr, bufsize); if (res != TEST_PASSED) return res; } if (test_loop_end(&loop, nb_loop, 1)) break; } sprintf(string, "no error for %d loops at 0x%08x length 0x%x", loop, addr, bufsize); return res; } static enum test_result test_walkbit1(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED; u32 bufsize, nb_loop, loop = 0, addr, value; int i; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 4)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running %d loops at 0x%08x length 0x%x\n", nb_loop, addr, bufsize); while (1) { for (i = 0; i < 64; i++) { if (i < 32) value = ~(1 << i); else value = ~(1 << (63 - i)); printf("pattern = %08x", value); res = test_loop_size(&value, 1, (u32 *)addr, bufsize); if (res != TEST_PASSED) return res; } if (test_loop_end(&loop, nb_loop, 1)) break; } sprintf(string, "no error for %d loops at 0x%08x length 0x%x", loop, addr, bufsize); return res; } /* * try to catch bad bits which are dependent on the current values of * surrounding bits in either the same word32 */ static enum test_result test_bitspread(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED; u32 bufsize, nb_loop, loop = 0, addr, bitspread[4]; int i, j; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 32)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running %d loops at 0x%08x length 0x%x\n", nb_loop, addr, bufsize); while (1) { for (i = 1; i < 32; i++) { for (j = 0; j < i; j++) { if (i < 32) bitspread[0] = (1 << i) | (1 << j); else bitspread[0] = (1 << (63 - i)) | (1 << (63 - j)); bitspread[1] = bitspread[0]; bitspread[2] = ~bitspread[0]; bitspread[3] = ~bitspread[0]; printf("pattern = %08x", bitspread[0]); res = test_loop_size(bitspread, 4, (u32 *)addr, bufsize); if (res != TEST_PASSED) return res; } } if (test_loop_end(&loop, nb_loop, 1)) break; } sprintf(string, "no error for %d loops at 0x%08x length 0x%x", loop, addr, bufsize); return res; } static enum test_result test_bitflip(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED; u32 bufsize, nb_loop, loop = 0, addr; int i; u32 bitflip[4]; if (get_bufsize(string, argc, argv, 0, &bufsize, 4 * 1024, 32)) return TEST_ERROR; if (get_nb_loop(string, argc, argv, 1, &nb_loop, 1)) return TEST_ERROR; if (get_addr(string, argc, argv, 2, &addr)) return TEST_ERROR; printf("running %d loops at 0x%08x length 0x%x\n", nb_loop, addr, bufsize); while (1) { for (i = 0; i < 32; i++) { bitflip[0] = 1 << i; bitflip[1] = bitflip[0]; bitflip[2] = ~bitflip[0]; bitflip[3] = bitflip[2]; printf("pattern = %08x", bitflip[0]); res = test_loop_size(bitflip, 4, (u32 *)addr, bufsize); if (res != TEST_PASSED) return res; } if (test_loop_end(&loop, nb_loop, 1)) break; } sprintf(string, "no error for %d loops at 0x%08x length 0x%x", loop, addr, bufsize); return res; } /********************************************************************** * * Function: infinite read access to DDR * * Description: continuous read the same pattern at the same address * **********************************************************************/ static enum test_result test_read(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 *addr; u32 data; u32 loop = 0; int i, size = 1024 * 1024; bool random = false; if (get_addr(string, argc, argv, 0, (u32 *)&addr)) return TEST_ERROR; if (get_pattern(string, argc, argv, 1, &data, 0xA5A5AA55)) return TEST_ERROR; if ((u32)addr == ADDR_INVALID) { printf("running random\n"); random = true; } else { printf("running at 0x%08x with pattern=0x%08x\n", (u32)addr, data); writel(data, addr); } while (1) { for (i = 0; i < size; i++) { if (random) addr = (u32 *)(STM32_DDR_BASE + (rand() & (STM32_DDR_SIZE - 1) & ~0x3)); data = readl(addr); } if (test_loop_end(&loop, 0, 1)) break; } if (random) sprintf(string, "%d loops random", loop); else sprintf(string, "%d loops at 0x%x: %x", loop, (u32)addr, data); return TEST_PASSED; } /********************************************************************** * * Function: infinite write access to DDR * * Description: continuous write the same pattern at the same address * **********************************************************************/ static enum test_result test_write(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { u32 *addr; u32 data; u32 loop = 0; int i, size = 1024 * 1024; bool random = false; if (get_addr(string, argc, argv, 0, (u32 *)&addr)) return TEST_ERROR; if (get_pattern(string, argc, argv, 1, &data, 0xA5A5AA55)) return TEST_ERROR; if ((u32)addr == ADDR_INVALID) { printf("running random\n"); random = true; } else { printf("running at 0x%08x with pattern 0x%08x\n", (u32)addr, data); } while (1) { for (i = 0; i < size; i++) { if (random) { addr = (u32 *)(STM32_DDR_BASE + (rand() & (STM32_DDR_SIZE - 1) & ~0x3)); data = rand(); } writel(data, addr); } if (test_loop_end(&loop, 0, 1)) break; } if (random) sprintf(string, "%d loops random", loop); else sprintf(string, "%d loops at 0x%x: %x", loop, (u32)addr, data); return TEST_PASSED; } #define NB_TEST_INFINITE 2 static enum test_result test_all(struct stm32mp1_ddrctl *ctl, struct stm32mp1_ddrphy *phy, char *string, int argc, char *argv[]) { enum test_result res = TEST_PASSED, result; int i, nb_error = 0; u32 loop = 0, nb_loop; if (get_nb_loop(string, argc, argv, 0, &nb_loop, 1)) return TEST_ERROR; while (!nb_error) { /* execute all the test except the lasts which are infinite */ for (i = 1; i < test_nb - NB_TEST_INFINITE; i++) { printf("execute %d:%s\n", (int)i, test[i].name); result = test[i].fct(ctl, phy, string, 0, NULL); printf("result %d:%s = ", (int)i, test[i].name); if (result != TEST_PASSED) { nb_error++; res = TEST_FAILED; puts("Failed"); } else { puts("Passed"); } puts("\n\n"); } printf("loop %d: %d/%d test failed\n\n\n", loop + 1, nb_error, test_nb - NB_TEST_INFINITE); if (test_loop_end(&loop, nb_loop, 1)) break; } if (res != TEST_PASSED) { sprintf(string, "loop %d: %d/%d test failed", loop, nb_error, test_nb - NB_TEST_INFINITE); } else { sprintf(string, "loop %d: %d tests passed", loop, test_nb - NB_TEST_INFINITE); } return res; } /**************************************************************** * TEST Description ****************************************************************/ const struct test_desc test[] = { {test_all, "All", "[loop]", "Execute all tests", 1 }, {test_databus, "Simple DataBus", "[addr]", "Verifies each data line by walking 1 on fixed address", 1 }, {databuswalk0, "DataBusWalking0", "[loop] [addr]", "Verifies each data bus signal can be driven low (32 word burst)", 2 }, {databuswalk1, "DataBusWalking1", "[loop] [addr]", "Verifies each data bus signal can be driven high (32 word burst)", 2 }, {test_addressbus, "AddressBus", "[size] [addr]", "Verifies each relevant bits of the address and checking for aliasing", 2 }, {test_memdevice, "MemDevice", "[size] [addr]", "Test the integrity of a physical memory (test every storage bit in the region)", 2 }, {test_sso, "SimultaneousSwitchingOutput", "[size] [addr] ", "Stress the data bus over an address range", 2 }, {test_noise, "Noise", "[pattern] [addr]", "Verifies r/w while forcing switching of all data bus lines.", 3 }, {test_noise_burst, "NoiseBurst", "[size] [pattern] [addr]", "burst transfers while forcing switching of the data bus lines", 3 }, {test_random, "Random", "[size] [loop] [addr]", "Verifies r/w and memcopy(burst for pseudo random value.", 3 }, {test_freq_pattern, "FrequencySelectivePattern", "[size]", "write & test patterns: Mostly Zero, Mostly One and F/n", 1 }, {test_blockseq, "BlockSequential", "[size] [loop] [addr]", "test incremental pattern", 3 }, {test_checkboard, "Checkerboard", "[size] [loop] [addr]", "test checker pattern", 3 }, {test_bitspread, "BitSpread", "[size] [loop] [addr]", "test Bit Spread pattern", 3 }, {test_bitflip, "BitFlip", "[size] [loop] [addr]", "test Bit Flip pattern", 3 }, {test_walkbit0, "WalkingOnes", "[size] [loop] [addr]", "test Walking Ones pattern", 3 }, {test_walkbit1, "WalkingZeroes", "[size] [loop] [addr]", "test Walking Zeroes pattern", 3 }, /* need to the the 2 last one (infinite) : skipped for test all */ {test_read, "infinite read", "[addr] [pattern]", "basic test : infinite read access (random: addr=0xFFFFFFFF)", 2}, {test_write, "infinite write", "[addr] [pattern]", "basic test : infinite write access (random: addr=0xFFFFFFFF)", 2}, }; const int test_nb = ARRAY_SIZE(test);