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[/] [openrisc/] [trunk/] [or1ksim/] [testsuite/] [test-code-or1k/] [cache/] [cache.c] - Rev 589
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/* cache.c. Cache test of Or1ksim Copyright (C) 1999-2006 OpenCores Copyright (C) 2010 Embecosm Limited Contributors various OpenCores participants Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> This file is part of OpenRISC 1000 Architectural Simulator. 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 <http: www.gnu.org/licenses/>. */ /* ---------------------------------------------------------------------------- This code is commented throughout for use with Doxygen. --------------------------------------------------------------------------*/ #include "support.h" #include "spr-defs.h" #define MEM_RAM 0x00100000 /* Linker script symbols */ extern unsigned int _ram_end; unsigned int program_ram_end; unsigned int ic_present; unsigned int dc_present; /* Number of IC sets (power of 2) */ unsigned int ic_sets; #define IC_SETS ic_sets unsigned int dc_sets; #define DC_SETS dc_sets /* Block size in bytes (1, 2, 4, 8, 16, 32 etc.) */ unsigned int ic_bs; #define IC_BLOCK_SIZE ic_bs unsigned int dc_bs; #define DC_BLOCK_SIZE dc_bs /* Number of IC ways (1, 2, 3 etc.). */ unsigned int ic_ways; #define IC_WAYS ic_ways unsigned int dc_ways; #define DC_WAYS dc_ways /* Cache size */ #define IC_SIZE (IC_WAYS*IC_SETS*IC_BLOCK_SIZE) #define DC_SIZE (DC_WAYS*DC_SETS*DC_BLOCK_SIZE) extern void ic_enable(void); extern void ic_disable(void); extern void dc_enable(void); extern void dc_disable(void); extern void dc_inv(void); extern unsigned long ic_inv_test(void); extern unsigned long dc_inv_test(unsigned long); extern void (*jalr)(void); extern void (*jr)(void); /* Index on jump table */ unsigned long jump_indx; /* Jump address table */ #define MAX_IC_WAYS 32 unsigned long jump_addr[15*MAX_IC_WAYS]; void dummy(); void jump_and_link(void) { asm("jalr:"); asm("l.jr\tr9"); asm("l.nop"); } void jump(void) { asm("jr:"); /* Read and increment index */ asm("l.lwz\t\tr3,0(r11)"); asm("l.addi\t\tr3,r3,4"); asm("l.sw\t\t0(r11),r3"); /* Load next executin address from table */ asm("l.lwz\t\tr3,0(r3)"); /* Jump to that address */ asm("l.jr\t\tr3") ; /* Report that we succeeded */ asm("l.nop\t0"); } void copy_jr(unsigned long add) { memcpy((void *)add, (void *)&jr, 24); } void call(unsigned long add) { asm("l.movhi\tr11,hi(jump_indx)" : :); asm("l.ori\tr11,r11,lo(jump_indx)" : :); asm("l.jalr\t\t%0" : : "r" (add) : "r11", "r9"); asm("l.nop" : :); } /* Determine cache configuration from cache configuration registers */ void init_cache_config(void) { unsigned long iccfgr, dccfgr; unsigned long upr; ic_present = dc_present = 0; upr = mfspr (SPR_UPR); if (!(upr & SPR_UPR_ICP)) { printf("No instruction cache present. Skipping tests.\n"); } else { iccfgr = mfspr (SPR_ICCFGR); /* Number of ways */ ic_ways = (1 << (iccfgr & SPR_ICCFGR_NCW)); /* Number of sets */ ic_sets = 1 << ((iccfgr & SPR_ICCFGR_NCS) >> SPR_ICCFGR_NCS_OFF); /* Block size */ ic_bs = 16 << ((iccfgr & SPR_ICCFGR_CBS) >> SPR_ICCFGR_CBS_OFF); ic_present = 1; } if (!(upr & SPR_UPR_DCP)) { printf("No data cache present. Skipping tests.\n"); } else { dccfgr = mfspr (SPR_DCCFGR); /* Number of ways */ dc_ways = (1 << (dccfgr & SPR_DCCFGR_NCW)); /* Number of sets */ dc_sets = 1 << ((dccfgr & SPR_DCCFGR_NCS) >> SPR_DCCFGR_NCS_OFF); /* Block size */ dc_bs = 16 << ((dccfgr & SPR_DCCFGR_CBS) >> SPR_DCCFGR_CBS_OFF); dc_present = 1; } } int dc_test(void) { int i; unsigned long base, add, ul; base = (((unsigned long)MEM_RAM / (IC_SETS*IC_BLOCK_SIZE)) * IC_SETS*IC_BLOCK_SIZE) + IC_SETS*IC_BLOCK_SIZE; dc_enable(); /* Cache miss r */ add = base; for(i = 0; i < DC_WAYS; i++) { ul = REG32(add); ul = REG32(add + DC_BLOCK_SIZE + 4); ul = REG32(add + 2*DC_BLOCK_SIZE + 8); ul = REG32(add + 3*DC_BLOCK_SIZE + 12); add += DC_SETS*DC_BLOCK_SIZE; } /* Cache hit w */ add = base; for(i = 0; i < DC_WAYS; i++) { REG32(add + 0) = 0x00000001; REG32(add + 4) = 0x00000000; REG32(add + 8) = 0x00000000; REG32(add + 12) = 0x00000000; REG32(add + DC_BLOCK_SIZE + 0) = 0x00000000; REG32(add + DC_BLOCK_SIZE + 4) = 0x00000002; REG32(add + DC_BLOCK_SIZE + 8) = 0x00000000; REG32(add + DC_BLOCK_SIZE + 12) = 0x00000000; REG32(add + 2*DC_BLOCK_SIZE + 0) = 0x00000000; REG32(add + 2*DC_BLOCK_SIZE + 4) = 0x00000000; REG32(add + 2*DC_BLOCK_SIZE + 8) = 0x00000003; REG32(add + 2*DC_BLOCK_SIZE + 12) = 0x00000000; REG32(add + 3*DC_BLOCK_SIZE + 0) = 0x00000000; REG32(add + 3*DC_BLOCK_SIZE + 4) = 0x00000000; REG32(add + 3*DC_BLOCK_SIZE + 8) = 0x00000000; REG32(add + 3*DC_BLOCK_SIZE + 12) = 0x00000004; add += DC_SETS*DC_BLOCK_SIZE; } /* Cache hit r/w */ add = base; for(i = 0; i < DC_WAYS; i++) { REG8(add + DC_BLOCK_SIZE - 4) = REG8(add + 3); REG8(add + 2*DC_BLOCK_SIZE - 8) = REG8(add + DC_BLOCK_SIZE + 7); REG8(add + 3*DC_BLOCK_SIZE - 12) = REG8(add + 2*DC_BLOCK_SIZE + 11); REG8(add + 4*DC_BLOCK_SIZE - 16) = REG8(add + 3*DC_BLOCK_SIZE + 15); add += DC_SETS*DC_BLOCK_SIZE; } /* Cache hit/miss r/w */ add = base; for(i = 0; i < DC_WAYS; i++) { REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE) = REG16(add + DC_BLOCK_SIZE - 4) + REG16(add + 2); REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE + 2) = REG16(add + DC_BLOCK_SIZE - 8) + REG16(add + DC_BLOCK_SIZE + 6); REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE + 4) = REG16(add + DC_BLOCK_SIZE - 12) + REG16(add + 2*DC_BLOCK_SIZE + 10); REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE + 6) = REG16(add+ DC_BLOCK_SIZE - 16) + REG16(add + 2*DC_BLOCK_SIZE + 14); add += DC_SETS*DC_BLOCK_SIZE; } /* Fill cache with unused data */ add = base + DC_WAYS*DC_SETS*DC_BLOCK_SIZE; for(i = 0; i < DC_WAYS; i++) { ul = REG32(add); ul = REG32(add + DC_BLOCK_SIZE); ul = REG32(add + 2*DC_BLOCK_SIZE); ul = REG32(add + 3*DC_BLOCK_SIZE); add += DC_SETS*DC_BLOCK_SIZE; } /* Cache hit/miss r */ ul = 0; add = base; for(i = 0; i < DC_WAYS; i++) { ul += REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE) + REG16(add + DC_BLOCK_SIZE - 4) + REG16(add + 2); ul += REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE + 2) + REG16(add + DC_BLOCK_SIZE - 8) + REG16(add + DC_BLOCK_SIZE + 6); ul += REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE + 4) + REG16(add + DC_BLOCK_SIZE - 12) + REG16(add + 2*DC_BLOCK_SIZE + 10); ul += REG16(add + (IC_SETS - 1)*IC_BLOCK_SIZE + 6) + REG16(add+ DC_BLOCK_SIZE - 16) + REG16(add + 2*DC_BLOCK_SIZE + 14); add += DC_SETS*DC_BLOCK_SIZE; } dc_disable(); return ul; } int ic_test(void) { int i; unsigned long base, addr; base = (((unsigned int)program_ram_end / (IC_SETS*IC_BLOCK_SIZE)) * IC_SETS*IC_BLOCK_SIZE) + IC_SETS*IC_BLOCK_SIZE; //printf("ic_test\n"); //printf("Test program from base at 0x%08x\n",(unsigned int)base); /* Copy jr to various location */ addr = base; for(i = 0; i < IC_WAYS; i++) { copy_jr(addr); copy_jr(addr + 2*IC_BLOCK_SIZE + 4); copy_jr(addr + 4*IC_BLOCK_SIZE + 8); copy_jr(addr + 6*IC_BLOCK_SIZE + 12); copy_jr(addr + (IC_SETS - 2)*IC_BLOCK_SIZE + 0); copy_jr(addr + (IC_SETS - 4)*IC_BLOCK_SIZE + 4); copy_jr(addr + (IC_SETS - 6)*IC_BLOCK_SIZE + 8); copy_jr(addr + (IC_SETS - 8)*IC_BLOCK_SIZE + 12); addr += IC_SETS*IC_BLOCK_SIZE; } /* Load execution table which starts at address 4 (at address 0 is table index) */ addr = base; for(i = 0; i < IC_WAYS; i++) { /* Cache miss */ jump_addr[15*i + 0] = addr + 2*IC_BLOCK_SIZE + 4; jump_addr[15*i + 1] = addr + 4*IC_BLOCK_SIZE + 8; jump_addr[15*i + 2] = addr + 6*IC_BLOCK_SIZE + 12; /* Cache hit/miss */ jump_addr[15*i + 3] = addr; jump_addr[15*i + 4] = addr + (IC_SETS - 2)*IC_BLOCK_SIZE + 0; jump_addr[15*i + 5] = addr + 2*IC_BLOCK_SIZE + 4; jump_addr[15*i + 6] = addr + (IC_SETS - 4)*IC_BLOCK_SIZE + 4; jump_addr[15*i + 7] = addr + 4*IC_BLOCK_SIZE + 8; jump_addr[15*i + 8] = addr + (IC_SETS - 6)*IC_BLOCK_SIZE + 8; jump_addr[15*i + 9] = addr + 6*IC_BLOCK_SIZE + 12; jump_addr[15*i + 10] = addr + (IC_SETS - 8)*IC_BLOCK_SIZE + 12; /* Cache hit */ jump_addr[15*i + 11] = addr + (IC_SETS - 2)*IC_BLOCK_SIZE + 0; jump_addr[15*i + 12] = addr + (IC_SETS - 4)*IC_BLOCK_SIZE + 4; jump_addr[15*i + 13] = addr + (IC_SETS - 6)*IC_BLOCK_SIZE + 8; jump_addr[15*i + 14] = addr + (IC_SETS - 8)*IC_BLOCK_SIZE + 12; addr += IC_SETS*IC_BLOCK_SIZE; } /* Go home */ /* Warning - if using all 32 sets, the SET_MAX define above will need to be incremented*/ jump_addr[15*i] = (unsigned long)&jalr; /* Initilalize table index */ jump_indx = (unsigned long)&jump_addr[0]; ic_enable(); /* Go */ call(base); ic_disable(); return 0; } /* Each of the 5 reports should be 0xdeaddead if the code is working correctly. */ int main(void) { unsigned long rc, ret = 0; program_ram_end = (unsigned int)&_ram_end; program_ram_end += 4; /* Read UPR and configuration registers, extract cache settings */ init_cache_config(); if (dc_present) { report(0); rc = dc_test(); ret += rc; report(rc + 0xdeaddca1); report(1); rc = dc_inv_test(MEM_RAM); ret += rc; report(rc + 0x9e8daa91); } if (ic_present) { report(2); rc = ic_test(); ret += rc; report(rc + 0xdeaddead); report(3); ic_enable(); report(4); rc = ic_inv_test(); ret += rc; report(rc + 0xdeadde8f); report(ret + 0x9e8da867); } exit(0); return 0; } /* just for size calculation */ void dummy() { }
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