/* * Instruction SRAM accessor functions for the Blackfin * * Copyright 2008 Analog Devices Inc. * * Licensed under the GPL-2 or later */ #define pr_fmt(fmt) "isram: " fmt #include <linux/module.h> #include <linux/kernel.h> #include <linux/types.h> #include <linux/slab.h> #include <linux/spinlock.h> #include <linux/sched.h> #include <asm/blackfin.h> #include <asm/dma.h> /* * IMPORTANT WARNING ABOUT THESE FUNCTIONS * * The emulator will not function correctly if a write command is left in * ITEST_COMMAND or DTEST_COMMAND AND access to cache memory is needed by * the emulator. To avoid such problems, ensure that both ITEST_COMMAND * and DTEST_COMMAND are zero when exiting these functions. */ /* * On the Blackfin, L1 instruction sram (which operates at core speeds) can not * be accessed by a normal core load, so we need to go through a few hoops to * read/write it. * To try to make it easier - we export a memcpy interface, where either src or * dest can be in this special L1 memory area. * The low level read/write functions should not be exposed to the rest of the * kernel, since they operate on 64-bit data, and need specific address alignment */ static DEFINE_SPINLOCK(dtest_lock); /* Takes a void pointer */ #define IADDR2DTEST(x) \ ({ unsigned long __addr = (unsigned long)(x); \ ((__addr & (1 << 11)) << (26 - 11)) | /* addr bit 11 (Way0/Way1) */ \ (1 << 24) | /* instruction access = 1 */ \ ((__addr & (1 << 15)) << (23 - 15)) | /* addr bit 15 (Data Bank) */ \ ((__addr & (3 << 12)) << (16 - 12)) | /* addr bits 13:12 (Subbank) */ \ (__addr & 0x47F8) | /* addr bits 14 & 10:3 */ \ (1 << 2); /* data array = 1 */ \ }) /* Takes a pointer, and returns the offset (in bits) which things should be shifted */ #define ADDR2OFFSET(x) ((((unsigned long)(x)) & 0x7) * 8) /* Takes a pointer, determines if it is the last byte in the isram 64-bit data type */ #define ADDR2LAST(x) ((((unsigned long)x) & 0x7) == 0x7) static void isram_write(const void *addr, uint64_t data) { uint32_t cmd; unsigned long flags; if (unlikely(addr >= (void *)(L1_CODE_START + L1_CODE_LENGTH))) return; cmd = IADDR2DTEST(addr) | 2; /* write */ /* * Writes to DTEST_DATA[0:1] need to be atomic with write to DTEST_COMMAND * While in exception context - atomicity is guaranteed or double fault */ spin_lock_irqsave(&dtest_lock, flags); bfin_write_DTEST_DATA0(data & 0xFFFFFFFF); bfin_write_DTEST_DATA1(data >> 32); /* use the builtin, since interrupts are already turned off */ __builtin_bfin_csync(); bfin_write_DTEST_COMMAND(cmd); __builtin_bfin_csync(); bfin_write_DTEST_COMMAND(0); __builtin_bfin_csync(); spin_unlock_irqrestore(&dtest_lock, flags); } static uint64_t isram_read(const void *addr) { uint32_t cmd; unsigned long flags; uint64_t ret; if (unlikely(addr > (void *)(L1_CODE_START + L1_CODE_LENGTH))) return 0; cmd = IADDR2DTEST(addr) | 0; /* read */ /* * Reads of DTEST_DATA[0:1] need to be atomic with write to DTEST_COMMAND * While in exception context - atomicity is guaranteed or double fault */ spin_lock_irqsave(&dtest_lock, flags); /* use the builtin, since interrupts are already turned off */ __builtin_bfin_csync(); bfin_write_DTEST_COMMAND(cmd); __builtin_bfin_csync(); ret = bfin_read_DTEST_DATA0() | ((uint64_t)bfin_read_DTEST_DATA1() << 32); bfin_write_DTEST_COMMAND(0); __builtin_bfin_csync(); spin_unlock_irqrestore(&dtest_lock, flags); return ret; } static bool isram_check_addr(const void *addr, size_t n) { if ((addr >= (void *)L1_CODE_START) && (addr < (void *)(L1_CODE_START + L1_CODE_LENGTH))) { if (unlikely((addr + n) > (void *)(L1_CODE_START + L1_CODE_LENGTH))) { show_stack(NULL, NULL); pr_err("copy involving %p length (%zu) too long\n", addr, n); } return true; } return false; } /* * The isram_memcpy() function copies n bytes from memory area src to memory area dest. * The isram_memcpy() function returns a pointer to dest. * Either dest or src can be in L1 instruction sram. */ void *isram_memcpy(void *dest, const void *src, size_t n) { uint64_t data_in = 0, data_out = 0; size_t count; bool dest_in_l1, src_in_l1, need_data, put_data; unsigned char byte, *src_byte, *dest_byte; src_byte = (unsigned char *)src; dest_byte = (unsigned char *)dest; dest_in_l1 = isram_check_addr(dest, n); src_in_l1 = isram_check_addr(src, n); need_data = true; put_data = true; for (count = 0; count < n; count++) { if (src_in_l1) { if (need_data) { data_in = isram_read(src + count); need_data = false; } if (ADDR2LAST(src + count)) need_data = true; byte = (unsigned char)((data_in >> ADDR2OFFSET(src + count)) & 0xff); } else { /* src is in L2 or L3 - so just dereference*/ byte = src_byte[count]; } if (dest_in_l1) { if (put_data) { data_out = isram_read(dest + count); put_data = false; } data_out &= ~((uint64_t)0xff << ADDR2OFFSET(dest + count)); data_out |= ((uint64_t)byte << ADDR2OFFSET(dest + count)); if (ADDR2LAST(dest + count)) { put_data = true; isram_write(dest + count, data_out); } } else { /* dest in L2 or L3 - so just dereference */ dest_byte[count] = byte; } } /* make sure we dump the last byte if necessary */ if (dest_in_l1 && !put_data) isram_write(dest + count, data_out); return dest; } EXPORT_SYMBOL(isram_memcpy); #ifdef CONFIG_BFIN_ISRAM_SELF_TEST static int test_len = 0x20000; static __init void hex_dump(unsigned char *buf, int len) { while (len--) pr_cont("%02x", *buf++); } static __init int isram_read_test(char *sdram, void *l1inst) { int i, ret = 0; uint64_t data1, data2; pr_info("INFO: running isram_read tests\n"); /* setup some different data to play with */ for (i = 0; i < test_len; ++i) sdram[i] = i % 255; dma_memcpy(l1inst, sdram, test_len); /* make sure we can read the L1 inst */ for (i = 0; i < test_len; i += sizeof(uint64_t)) { data1 = isram_read(l1inst + i); memcpy(&data2, sdram + i, sizeof(data2)); if (data1 != data2) { pr_err("FAIL: isram_read(%p) returned %#llx but wanted %#llx\n", l1inst + i, data1, data2); ++ret; } } return ret; } static __init int isram_write_test(char *sdram, void *l1inst) { int i, ret = 0; uint64_t data1, data2; pr_info("INFO: running isram_write tests\n"); /* setup some different data to play with */ memset(sdram, 0, test_len * 2); dma_memcpy(l1inst, sdram, test_len); for (i = 0; i < test_len; ++i) sdram[i] = i % 255; /* make sure we can write the L1 inst */ for (i = 0; i < test_len; i += sizeof(uint64_t)) { memcpy(&data1, sdram + i, sizeof(data1)); isram_write(l1inst + i, data1); data2 = isram_read(l1inst + i); if (data1 != data2) { pr_err("FAIL: isram_write(%p, %#llx) != %#llx\n", l1inst + i, data1, data2); ++ret; } } dma_memcpy(sdram + test_len, l1inst, test_len); if (memcmp(sdram, sdram + test_len, test_len)) { pr_err("FAIL: isram_write() did not work properly\n"); ++ret; } return ret; } static __init int _isram_memcpy_test(char pattern, void *sdram, void *l1inst, const char *smemcpy, void *(*fmemcpy)(void *, const void *, size_t)) { memset(sdram, pattern, test_len); fmemcpy(l1inst, sdram, test_len); fmemcpy(sdram + test_len, l1inst, test_len); if (memcmp(sdram, sdram + test_len, test_len)) { pr_err("FAIL: %s(%p <=> %p, %#x) failed (data is %#x)\n", smemcpy, l1inst, sdram, test_len, pattern); return 1; } return 0; } #define _isram_memcpy_test(a, b, c, d) _isram_memcpy_test(a, b, c, #d, d) static __init int isram_memcpy_test(char *sdram, void *l1inst) { int i, j, thisret, ret = 0; /* check broad isram_memcpy() */ pr_info("INFO: running broad isram_memcpy tests\n"); for (i = 0xf; i >= 0; --i) ret += _isram_memcpy_test(i, sdram, l1inst, isram_memcpy); /* check read of small, unaligned, and hardware 64bit limits */ pr_info("INFO: running isram_memcpy (read) tests\n"); /* setup some different data to play with */ for (i = 0; i < test_len; ++i) sdram[i] = i % 255; dma_memcpy(l1inst, sdram, test_len); thisret = 0; for (i = 0; i < test_len - 32; ++i) { unsigned char cmp[32]; for (j = 1; j <= 32; ++j) { memset(cmp, 0, sizeof(cmp)); isram_memcpy(cmp, l1inst + i, j); if (memcmp(cmp, sdram + i, j)) { pr_err("FAIL: %p:", l1inst + 1); hex_dump(cmp, j); pr_cont(" SDRAM:"); hex_dump(sdram + i, j); pr_cont("\n"); if (++thisret > 20) { pr_err("FAIL: skipping remaining series\n"); i = test_len; break; } } } } ret += thisret; /* check write of small, unaligned, and hardware 64bit limits */ pr_info("INFO: running isram_memcpy (write) tests\n"); memset(sdram + test_len, 0, test_len); dma_memcpy(l1inst, sdram + test_len, test_len); thisret = 0; for (i = 0; i < test_len - 32; ++i) { unsigned char cmp[32]; for (j = 1; j <= 32; ++j) { isram_memcpy(l1inst + i, sdram + i, j); dma_memcpy(cmp, l1inst + i, j); if (memcmp(cmp, sdram + i, j)) { pr_err("FAIL: %p:", l1inst + i); hex_dump(cmp, j); pr_cont(" SDRAM:"); hex_dump(sdram + i, j); pr_cont("\n"); if (++thisret > 20) { pr_err("FAIL: skipping remaining series\n"); i = test_len; break; } } } } ret += thisret; return ret; } static __init int isram_test_init(void) { int ret; char *sdram; void *l1inst; /* Try to test as much of L1SRAM as possible */ while (test_len) { test_len >>= 1; l1inst = l1_inst_sram_alloc(test_len); if (l1inst) break; } if (!l1inst) { pr_warning("SKIP: could not allocate L1 inst\n"); return 0; } pr_info("INFO: testing %#x bytes (%p - %p)\n", test_len, l1inst, l1inst + test_len); sdram = kmalloc(test_len * 2, GFP_KERNEL); if (!sdram) { sram_free(l1inst); pr_warning("SKIP: could not allocate sdram\n"); return 0; } /* sanity check initial L1 inst state */ ret = 1; pr_info("INFO: running initial dma_memcpy checks %p\n", sdram); if (_isram_memcpy_test(0xa, sdram, l1inst, dma_memcpy)) goto abort; if (_isram_memcpy_test(0x5, sdram, l1inst, dma_memcpy)) goto abort; ret = 0; ret += isram_read_test(sdram, l1inst); ret += isram_write_test(sdram, l1inst); ret += isram_memcpy_test(sdram, l1inst); abort: sram_free(l1inst); kfree(sdram); if (ret) return -EIO; pr_info("PASS: all tests worked !\n"); return 0; } late_initcall(isram_test_init); static __exit void isram_test_exit(void) { /* stub to allow unloading */ } module_exit(isram_test_exit); #endif