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[/] [openrisc/] [trunk/] [orpsocv2/] [sw/] [tests/] [or1200/] [board/] [or1200-mmu.c] - Rev 488
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////////////////////////////////////////////////////////////////////// //// //// //// //// //// OR1200 MMU test //// //// //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2010 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source 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 Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// // Tests most functions of the MMUs. // The tests attempt to keep the areas of instruction and data memory working // as they should, while testing around them, higher in memory. Some linker // variables are relied upon by the interrupt routines for checking if areas // are within the expected text areas of memory, but usually we just keep // above the stack (also set in the linker script) and things go OK. // The tests for translation setup address translation in the MMU from areas // in the 512kB - 1024kB region (64 sets in OR1200, 8kByte per set) to halfway // through RAM. Usually the sets taht would encompass the actual program are // skipped (TLB_TEXT_SET_NB) ie, we say how many sets encompass the program // text for itlb tests and only do tests above it (so, on sets 8-64, meaning // when we enable the iMMU and say have the execution bits disabled to force a // page fault the program gets to continue and is translated 1-1 while // accesses to the areas we are testing will cause a page fault) but it should // still work to test all sets. // In essense, the tests are aware that they could be operating out of the // same memory the tests are being performed in and takes care of this. // The use of the "match_space" variable is for the addresses we'll access // when a non-1-1 translation will occur, otherwise usually the // "translate_space" variable by itself is used (it's first setup to the // desired address, and either data or the return instructions are placed // where we expect the MMU to translate to) #include "cpu-utils.h" #include "spr-defs.h" #include "board.h" #include "uart.h" #include "printf.h" #include "or1200-defines.h" #ifdef OR1200_NO_IMMU # error # error Processor has no instruction MMU. Cannot run this test without it. # error #endif #ifdef OR1200_NO_DMMU # error # error Processor has no data MMU. Cannot run this test without it. # error #endif // Reduce the number of sets tested //#define SHORT_TEST // Set this to 1 to enable the DMMU tests #define DO_DMMU_TESTS 1 // Symbols defined in linker script extern unsigned long _endtext; extern unsigned long _stext; extern unsigned long _edata; extern unsigned long _stack; unsigned long start_text_addr; unsigned long end_text_addr; unsigned long end_data_addr; /* For shorter simulation run */ #define RTL_SIM 1 /* Define RAM physical location and size Bottom half will be used for this program, the rest will be used for testing */ #define RAM_START 0x00000000 // Assume only 2MB memory #define RAM_SIZE 0x00200000 #define VM_BASE 0xc0000000 /* What is the last address in ram that is used by this program */ #define TEXT_START_ADD start_text_addr #define TEXT_END_ADD end_text_addr #define DATA_END_ADD end_data_addr // Pages to start tests at. This should correspond to where the stack is set. // We can set this by hand or figure it out at runtime. // Uncomment the following 3 lines to hard-set the bottom page to test at: //#define TLB_BOTTOM_TEST_PAGE_HARDSET //#define TLB_TEXT_SET_NB 16 //#define TLB_DATA_SET_NB 16 // Uncomment the following to determine the page to test from at run-time unsigned long TLB_TEXT_SET_NB; unsigned long TLB_DATA_SET_NB; /* MMU page size */ #define PAGE_SIZE 8192 /* Number of DTLB sets used (power of 2, max is 256) */ #define DTLB_SETS 64 /* Number of DTLB ways (1, 2, 3 etc., max is 4). */ #define DTLB_WAYS 1 /* Number of ITLB sets used (power of 2, max is 256) */ #define ITLB_SETS 64 /* Number of ITLB ways (1, 2, 3 etc., max is 4). */ #define ITLB_WAYS 1 /* TLB mode codes */ #define TLB_CODE_ONE_TO_ONE 0x00000000 #define TLB_CODE_PLUS_ONE_PAGE 0x10000000 #define TLB_CODE_MINUS_ONE_PAGE 0x20000000 #define TLB_CODE_MASK 0xfffff000 #define TLB_PR_MASK 0x00000fff /* fails if x is false */ #define ASSERT(x) ((x)?1: fail (__FUNCTION__, __LINE__)) // iMMU and dMMU enable functions extern void lo_dmmu_en (void); extern void lo_immu_en (void); /* Local functions prototypes */ void dmmu_disable (void); void immu_disable (void); // Machine code for l.jr r9 and then l.nop #define OR32_L_JR_R9 0x44004800 #define OR32_L_NOP 0x15000000 /* Global variables */ extern unsigned long ram_end; /* DTLB mode status */ volatile unsigned long dtlb_val; /* ITLB mode status */ volatile unsigned long itlb_val; /* DTLB miss counter */ volatile int dtlb_miss_count; /* Data page fault counter */ volatile int dpage_fault_count; /* ITLB miss counter */ volatile int itlb_miss_count; /* Instruction page fault counter */ volatile int ipage_fault_count; /* EA of last DTLB miss exception */ unsigned long dtlb_miss_ea; /* EA of last data page fault exception */ unsigned long dpage_fault_ea; /* EA of last ITLB miss exception */ unsigned long itlb_miss_ea; /* EA of last insn page fault exception */ unsigned long ipage_fault_ea; #define sys_call() __asm__ __volatile__("l.sys\t0"); /* void sys_call (void) { asm("l.sys\t0"); } */ void fail (char *func, int line) { #ifndef __FUNCTION__ #define __FUNCTION__ "?" #endif /* Trigger sys call exception to enable supervisor mode again */ sys_call (); immu_disable (); dmmu_disable (); report(line); report (0xeeeeeeee); exit (1); } void call(unsigned long add) { asm("l.jalr\t\t%0" : : "r" (add) : "r9", "r11"); asm("l.nop" : :); } void jump(void) { return; /*asm("_jr:"); asm("l.jr\t\tr9") ; asm("l.nop" : :);*/ } void copy_jump(unsigned long phy_add) { memcpy((void *)phy_add, (void *)&jump, (8*4)); } /* Bus error exception handler */ void bus_err_handler (void) { /* This shouldn't happend */ printf("Test failed: Bus error\n"); report (0xeeeeeeee); exit (1); } /* Illegal insn exception handler */ void ill_insn_handler (void) { /* This shouldn't happend */ printf("Test failed: Illegal insn\n"); report (0xeeeeeeee); exit (1); } /* Sys call exception handler */ void sys_call_handler (void) { /* Set supervisor mode */ mtspr (SPR_ESR_BASE, mfspr (SPR_ESR_BASE) | SPR_SR_SM); } /* DTLB miss exception handler */ void dtlb_miss_handler (void) { unsigned long ea, ta, tlbtr; int set, way = 0; int i; /* Get EA that cause the exception */ ea = mfspr (SPR_EEAR_BASE); /* Find TLB set and LRU way */ set = (ea / PAGE_SIZE) % DTLB_SETS; for (i = 0; i < DTLB_WAYS; i++) { if ((mfspr (SPR_DTLBMR_BASE(i) + set) & SPR_DTLBMR_LRU) == 0) { way = i; break; } } printf("dtlb miss ea = %.8lx set = %d way = %d\n", ea, set, way); // Anything under the stack belongs to the program, direct tranlsate it if (ea < (unsigned long)&_stack){ /* If this is acces to data of this program set one to one translation */ mtspr (SPR_DTLBMR_BASE(way) + set, (ea & SPR_DTLBMR_VPN) | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(way) + set, (ea & SPR_DTLBTR_PPN) | DTLB_PR_NOLIMIT); return; } /* Update DTLB miss counter and EA */ dtlb_miss_count++; dtlb_miss_ea = ea; // Everything gets translated back to the space halfway through RAM ta = (set*PAGE_SIZE) + RAM_START + (RAM_SIZE/2); tlbtr = (ta & SPR_DTLBTR_PPN) | (dtlb_val & TLB_PR_MASK); printf("ta = %.8lx tlbtr = %.8lx dtlb_val = %.8lx\n",ta, tlbtr, dtlb_val); /* Set DTLB entry */ mtspr (SPR_DTLBMR_BASE(way) + set, (ea & SPR_DTLBMR_VPN) | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(way) + set, tlbtr); } /* Data page fault exception handler */ void dpage_fault_handler (void) { unsigned long ea; int set, way = 0; int i; /* Get EA that cause the exception */ ea = mfspr (SPR_EEAR_BASE); /* Find TLB set and way */ set = (ea / PAGE_SIZE) % DTLB_SETS; for (i = 0; i < DTLB_WAYS; i++) { if ((mfspr (SPR_DTLBMR_BASE(i) + set) & SPR_DTLBMR_VPN) == (ea & SPR_DTLBMR_VPN)) { way = i; break; } } printf("ea = %.8lx set = %d way = %d\n", ea, set, way); if (((RAM_START <= ea) & (ea < DATA_END_ADD) ) | ((TEXT_START_ADD <= ea) & (ea < TEXT_END_ADD))) { /* If this is acces to data of this program set one to one translation */ mtspr (SPR_DTLBTR_BASE(way) + set, (ea & SPR_DTLBTR_PPN) | DTLB_PR_NOLIMIT); return; } /* Update data page fault counter and EA */ dpage_fault_count++; dpage_fault_ea = ea; /* Give permission */ mtspr (SPR_DTLBTR_BASE(way) + set, (mfspr (SPR_DTLBTR_BASE(way) + set) & ~DTLB_PR_NOLIMIT) | dtlb_val); } /* ITLB miss exception handler */ void itlb_miss_handler (void) { unsigned long ea, ta, tlbtr; int set, way = 0; int i; /* Get EA that cause the exception */ ea = mfspr (SPR_EEAR_BASE); /* Find TLB set and LRU way */ set = (ea / PAGE_SIZE) % ITLB_SETS; for (i = 0; i < ITLB_WAYS; i++) { if ((mfspr (SPR_ITLBMR_BASE(i) + set) & SPR_ITLBMR_LRU) == 0) { way = i; break; } } printf("itlb miss ea = %.8lx set = %d way = %d\n", ea, set, way); if ((TEXT_START_ADD <= ea) && (ea < TEXT_END_ADD)) { /* If this is acces to data of this program set one to one translation */ mtspr (SPR_ITLBMR_BASE(way) + set, (ea & SPR_ITLBMR_VPN) | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(way) + set, (ea & SPR_ITLBTR_PPN) | ITLB_PR_NOLIMIT); return; } /* Update ITLB miss counter and EA */ itlb_miss_count++; itlb_miss_ea = ea; /* Whatever access is in progress, translated address have to point to physical RAM */ ta = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); tlbtr = (ta & SPR_ITLBTR_PPN) | (itlb_val & TLB_PR_MASK); printf("ta = %.8lx\n", ta); /* Set ITLB entry */ mtspr (SPR_ITLBMR_BASE(way) + set, (ea & SPR_ITLBMR_VPN) | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(way) + set, tlbtr); } /* Intstruction page fault exception handler */ void ipage_fault_handler (void) { unsigned long ea; int set, way = 0; int i; /* Get EA that cause the exception */ ea = mfspr (SPR_EEAR_BASE); /* Find TLB set and way */ set = (ea / PAGE_SIZE) % ITLB_SETS; for (i = 0; i < ITLB_WAYS; i++) { if ((mfspr (SPR_ITLBMR_BASE(i) + set) & SPR_ITLBMR_VPN) == (ea & SPR_ITLBMR_VPN)) { way = i; break; } } printf("ipage fault: ea = %.8lx set = %d way = %d\n", ea, set, way); if ((TEXT_START_ADD <= ea) && (ea < TEXT_END_ADD)) { /* If this is acces to data of this program set one to one translation */ mtspr (SPR_DTLBTR_BASE(way) + set, (ea & SPR_DTLBTR_PPN) | ITLB_PR_NOLIMIT); return; } printf("ipage fault was outside of code area\n", ea, set, way); /* Update instruction page fault counter and EA */ ipage_fault_count++; ipage_fault_ea = ea; /* Give permission */ mtspr (SPR_ITLBTR_BASE(way) + set, (mfspr (SPR_ITLBTR_BASE(way) + set) & ~ITLB_PR_NOLIMIT) | itlb_val); } /* Invalidate all entries in DTLB and enable DMMU */ void dmmu_enable (void) { /* Register DTLB miss handler */ add_handler(0x9, dtlb_miss_handler); //excpt_dtlbmiss = (unsigned long)dtlb_miss_handler; /* Register data page fault handler */ add_handler(0x3, dpage_fault_handler); //excpt_dpfault = (unsigned long)dpage_fault_handler; /* Enable DMMU */ lo_dmmu_en (); } /* Disable DMMU */ void dmmu_disable (void) { mtspr (SPR_SR, mfspr (SPR_SR) & ~SPR_SR_DME); } /* Invalidate all entries in ITLB and enable IMMU */ void immu_enable (void) { /* Register ITLB miss handler */ add_handler(0xa, itlb_miss_handler); //excpt_itlbmiss = (unsigned long)itlb_miss_handler; /* Register instruction page fault handler */ add_handler(0x4, ipage_fault_handler); //excpt_ipfault = (unsigned long)ipage_fault_handler; /* Enable IMMU */ lo_immu_en (); } /* Disable IMMU */ void immu_disable (void) { mtspr (SPR_SR, mfspr (SPR_SR) & ~SPR_SR_IME); } void write_pattern(unsigned long start, unsigned long end) { unsigned long add; add = start; while (add < end) { REG32(add) = add; add += PAGE_SIZE; } } /* Translation address register test Set various translation and check the pattern */ int dtlb_translation_test (void) { int i, j; unsigned long ea, ta; /* Disable DMMU */ dmmu_disable(); printf("dtlb translation test set\n"); /* Invalidate all entries in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { for (j = 0; j < DTLB_SETS; j++) { mtspr (SPR_DTLBMR_BASE(i) + j, 0); mtspr (SPR_DTLBTR_BASE(i) + j, 0); } } /* Set one to one translation for program's data space */ for (i = 0; i < TLB_DATA_SET_NB; i++) { ea = RAM_START + (i*PAGE_SIZE); ta = RAM_START + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(0) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(0) + i, ta | (DTLB_PR_NOLIMIT)); } /* Set dtlb permisions */ dtlb_val = DTLB_PR_NOLIMIT; /* Write test pattern */ for (i = 0; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); REG32(ea) = i; ea = RAM_START + (RAM_SIZE/2) + ((i + 1)*PAGE_SIZE) - 4; REG32(ea) = 0xffffffff - i; } /* Set one to one translation */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); ta = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(DTLB_WAYS - 1) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + i, ta | DTLB_PR_NOLIMIT); } /* Enable DMMU */ dmmu_enable(); /* Check the pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); ASSERT(REG32(ea) == i); ea = RAM_START + (RAM_SIZE/2) + ((i + 1)*PAGE_SIZE) - 4; ASSERT(REG32(ea) == (0xffffffff - i)); } /* Write new pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); REG32(ea) = 0xffffffff - i; ea = RAM_START + (RAM_SIZE/2) + ((i + 1)*PAGE_SIZE) - 4; REG32(ea) = i; } /* Set 0 -> RAM_START + (RAM_SIZE/2) translation */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = i*PAGE_SIZE; ta = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(DTLB_WAYS - 1) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + i, ta | DTLB_PR_NOLIMIT); } /* Check the pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = i*PAGE_SIZE; ASSERT(REG32(ea) == (0xffffffff - i)); ea = ((i + 1)*PAGE_SIZE) - 4; ASSERT(REG32(ea) == i); } /* Write new pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { REG32(i*PAGE_SIZE) = i; REG32(((i + 1)*PAGE_SIZE) - 4) = 0xffffffff - i; } /* Set hi -> lo, lo -> hi translation */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); ta = RAM_START + (RAM_SIZE/2) + ((DTLB_SETS - i - 1 + TLB_DATA_SET_NB)* PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(DTLB_WAYS - 1) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + i, ta | DTLB_PR_NOLIMIT); } /* Check the pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); ASSERT(REG32(ea) == (DTLB_SETS - i - 1 + TLB_DATA_SET_NB)); ea = RAM_START + (RAM_SIZE/2) + ((i + 1)*PAGE_SIZE) - 4; ASSERT(REG32(ea) == (0xffffffff - DTLB_SETS + i + 1 - TLB_DATA_SET_NB)); } /* Write new pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { REG32(RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE)) = 0xffffffff - i; REG32(RAM_START + (RAM_SIZE/2) + ((i + 1)*PAGE_SIZE) - 4) = i; } /* Disable DMMU */ dmmu_disable(); /* Check the pattern */ for (i = TLB_DATA_SET_NB; i < DTLB_SETS; i++) { ea = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); ASSERT(REG32(ea) == (0xffffffff - DTLB_SETS + i + 1 - TLB_DATA_SET_NB)); ea = RAM_START + (RAM_SIZE/2) + ((i + 1)*PAGE_SIZE) - 4; ASSERT(REG32(ea) == (DTLB_SETS - i - 1 + TLB_DATA_SET_NB)); } printf("-------------------------------------------\n"); return 0; } /* EA match register test Shifting one in DTLBMR and performing accesses to boundaries of the page, checking the triggering of exceptions */ int dtlb_match_test (int way, int set) { int i, j, tmp; unsigned long add, t_add; unsigned long ea, ta; /* Disable DMMU */ dmmu_disable(); printf("dtlb_match_test - way %d set %d\n",way, set); /* Invalidate all entries in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { for (j = 0; j < DTLB_SETS; j++) { mtspr (SPR_DTLBMR_BASE(i) + j, 0); mtspr (SPR_DTLBTR_BASE(i) + j, 0); } } // Program text/data pages should be 1-1 translation for (i = 0; i < TLB_DATA_SET_NB; i++) { ea = RAM_START + (i*PAGE_SIZE); ta = RAM_START + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(0) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(0) + i, ta | DTLB_PR_NOLIMIT); } /* Set dtlb permisions */ dtlb_val = DTLB_PR_NOLIMIT; // Setup match area address - based at halfway through RAM, // and then offset by the area encompassed by the set we wish to test. unsigned long translate_space = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); /* Set pattern */ // Last word of page before the one covered by this set REG32(translate_space - 4) = 0x00112233; //printf("pattern0 @ 0x%.8lx = 0x%.8lx\n", translate_space-4, REG32(translate_space - 4) ); // First word of page covered by this set REG32(translate_space) = 0x44556677; // Last word of page covered by this set REG32(translate_space + PAGE_SIZE - 4) = 0x8899aabb; // First word of page covered by next set REG32(translate_space + PAGE_SIZE) = 0xccddeeff; /* Enable DMMU */ dmmu_enable(); /* Shifting one in DTLBMR */ i = 0; // Setup match space - place we will do accesses to, and have them // tranlsated into the translate space addresses unsigned long match_space = (PAGE_SIZE*DTLB_SETS) + (set*PAGE_SIZE); // //add = (PAGE_SIZE*DTLB_SETS); // 8kB * 64, 512KB //t_add = add + (set*PAGE_SIZE); // while (add != 0x00000000) { // Set MATCH register for the areas we will access explicitly, and validate it mtspr (SPR_DTLBMR_BASE(way) + set, match_space | SPR_DTLBMR_V); // Set TRANSLATE register to the areas where we have set our data mtspr (SPR_DTLBTR_BASE(way) + set, translate_space | DTLB_PR_NOLIMIT); /* Reset DTLB miss counter and EA */ dtlb_miss_count = 0; dtlb_miss_ea = 0; //if (((match_space < RAM_START) || (t_add >= DATA_END_ADD)) && // ((t_add < TEXT_START_ADD) || (t_add >= TEXT_END_ADD))) { if (match_space > DATA_END_ADD){ /* Read last address of previous page */ tmp = REG32(match_space - 4); ASSERT(tmp == 0x00112233); ASSERT(dtlb_miss_count == 1); /* Read first address of the page */ tmp = REG32(match_space); ASSERT(tmp == 0x44556677); ASSERT(dtlb_miss_count == 1); /* Read last address of the page */ tmp = REG32(match_space + PAGE_SIZE - 4); ASSERT(tmp == 0x8899aabb); ASSERT(dtlb_miss_count == 1); /* Read first address of next page */ tmp = REG32(match_space + PAGE_SIZE); ASSERT(tmp == 0xccddeeff); ASSERT(dtlb_miss_count == 2); } i++; add = (PAGE_SIZE*DTLB_SETS) << i; match_space = add + (set*PAGE_SIZE); for (j = 0; j < DTLB_WAYS; j++) { mtspr (SPR_DTLBMR_BASE(j) + ((set - 1) & (DTLB_SETS - 1)), 0); mtspr (SPR_DTLBMR_BASE(j) + ((set + 1) & (DTLB_SETS - 1)), 0); } } /* Disable DMMU */ dmmu_disable(); printf("-------------------------------------------\n"); return 0; } /* Valid bit test Set all ways of one set to be invalid, perform access so miss handler will set them to valid, try access again - there should be no miss exceptions */ int dtlb_valid_bit_test (int set) { int i, j; unsigned long ea, ta; /* Disable DMMU */ dmmu_disable(); printf("dtlb_valid_bit_test, set %d\n", set); /* Invalidate all entries in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { for (j = 0; j < DTLB_SETS; j++) { mtspr (SPR_DTLBMR_BASE(i) + j, 0); mtspr (SPR_DTLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_DATA_SET_NB; i++) { ea = RAM_START + (i*PAGE_SIZE); ta = RAM_START + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(0) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(0) + i, ta | DTLB_PR_NOLIMIT); } /* Reset DTLB miss counter and EA */ dtlb_miss_count = 0; dtlb_miss_ea = 0; /* Set dtlb permisions */ dtlb_val = DTLB_PR_NOLIMIT; /* Resetv DTLBMR for every way */ for (i = 0; i < DTLB_WAYS; i++) { mtspr (SPR_DTLBMR_BASE(i) + set, 0); } /* Enable DMMU */ dmmu_enable(); /* Perform writes to address, that is not in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { REG32(RAM_START + RAM_SIZE + (i*DTLB_SETS*PAGE_SIZE) + (set*PAGE_SIZE)) = i; /* Check if there was DTLB miss */ ASSERT(dtlb_miss_count == (i + 1)); ASSERT(dtlb_miss_ea == (RAM_START + RAM_SIZE + (i*DTLB_SETS*PAGE_SIZE) + (set*PAGE_SIZE))); } /* Reset DTLB miss counter and EA */ dtlb_miss_count = 0; dtlb_miss_ea = 0; /* Perform reads to address, that is now in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { ASSERT(REG32(RAM_START + RAM_SIZE + (i*DTLB_SETS*PAGE_SIZE) + (set*PAGE_SIZE)) == i); /* Check if there was DTLB miss */ ASSERT(dtlb_miss_count == 0); } /* Reset valid bits */ for (i = 0; i < DTLB_WAYS; i++) { mtspr (SPR_DTLBMR_BASE(i) + set, mfspr (SPR_DTLBMR_BASE(i) + set) & ~SPR_DTLBMR_V); } /* Perform reads to address, that is now in DTLB but is invalid */ for (i = 0; i < DTLB_WAYS; i++) { ASSERT(REG32(RAM_START + RAM_SIZE + (i*DTLB_SETS*PAGE_SIZE) + (set*PAGE_SIZE)) == i); /* Check if there was DTLB miss */ ASSERT(dtlb_miss_count == (i + 1)); ASSERT(dtlb_miss_ea == (RAM_START + RAM_SIZE + (i*DTLB_SETS*PAGE_SIZE) + (set*PAGE_SIZE))); } /* Disable DMMU */ dmmu_disable(); printf("-------------------------------------------\n"); return 0; } /* Permission test Set various permissions, perform r/w access in user and supervisor mode and chack triggering of page fault exceptions */ int dtlb_permission_test (int set) { int i, j; unsigned long ea, ta, tmp; printf("dtlb_permission_test, set %d\n", set); /* Disable DMMU */ dmmu_disable(); /* Invalidate all entries in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { for (j = 0; j < DTLB_SETS; j++) { mtspr (SPR_DTLBMR_BASE(i) + j, 0); mtspr (SPR_DTLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_DATA_SET_NB; i++) { ea = RAM_START + (i*PAGE_SIZE); ta = RAM_START + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(0) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(0) + i, ta | DTLB_PR_NOLIMIT); } /* Testing page */ ea = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); /* Set match register */ mtspr (SPR_DTLBMR_BASE(DTLB_WAYS - 1) + set, ea | SPR_DTLBMR_V); /* Reset page fault counter and EA */ dpage_fault_count = 0; dpage_fault_ea = 0; /* Enable DMMU */ dmmu_enable(); /* Write supervisor */ dtlb_val = DTLB_PR_NOLIMIT | SPR_DTLBTR_SWE; mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + set, ea | (DTLB_PR_NOLIMIT & ~SPR_DTLBTR_SWE)); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 0) = 0x00112233; ASSERT(dpage_fault_count == 1); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 4) = 0x44556677; ASSERT(dpage_fault_count == 1); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 8) = 0x8899aabb; ASSERT(dpage_fault_count == 1); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 12) = 0xccddeeff; ASSERT(dpage_fault_count == 1); /* Read supervisor */ dtlb_val = DTLB_PR_NOLIMIT | SPR_DTLBTR_SRE; mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + set, ea | (DTLB_PR_NOLIMIT & ~SPR_DTLBTR_SRE)); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 0); ASSERT(dpage_fault_count == 2); ASSERT(tmp == 0x00112233); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 4); ASSERT(dpage_fault_count == 2); ASSERT(tmp == 0x44556677); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 8); ASSERT(dpage_fault_count == 2); ASSERT(tmp == 0x8899aabb); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 12); ASSERT(dpage_fault_count == 2); ASSERT(tmp == 0xccddeeff); /* Write user */ dtlb_val = DTLB_PR_NOLIMIT | SPR_DTLBTR_UWE; mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + set, ea | (DTLB_PR_NOLIMIT & ~SPR_DTLBTR_UWE)); /* Set user mode */ mtspr (SPR_SR, mfspr (SPR_SR) & ~SPR_SR_SM); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 0) = 0xffeeddcc; ASSERT(dpage_fault_count == 3); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 4) = 0xbbaa9988; ASSERT(dpage_fault_count == 3); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 8) = 0x77665544; ASSERT(dpage_fault_count == 3); REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 12) = 0x33221100; ASSERT(dpage_fault_count == 3); /* Trigger sys call exception to enable supervisor mode again */ sys_call (); /* Read user mode */ dtlb_val = DTLB_PR_NOLIMIT | SPR_DTLBTR_URE; mtspr (SPR_DTLBTR_BASE(DTLB_WAYS - 1) + set, ea | (DTLB_PR_NOLIMIT & ~SPR_DTLBTR_URE)); /* Set user mode */ mtspr (SPR_SR, mfspr (SPR_SR) & ~SPR_SR_SM); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 0); ASSERT(dpage_fault_count == 4); ASSERT(tmp == 0xffeeddcc); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 4); ASSERT(dpage_fault_count == 4); ASSERT(tmp == 0xbbaa9988); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 8); ASSERT(dpage_fault_count == 4); ASSERT(tmp == 0x77665544); tmp = REG32(RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) + 12); ASSERT(dpage_fault_count == 4); ASSERT(tmp == 0x33221100); /* Trigger sys call exception to enable supervisor mode again */ sys_call (); /* Disable DMMU */ dmmu_disable(); printf("-------------------------------------------\n"); return 0; } /* Dcache test - check inhibit Write data with cache inhibit on and off, check for coherency */ int dtlb_dcache_test (int set) { int i, j; unsigned long ea, ta, vmea; // Check data cache is present and enabled if (!(mfspr(SPR_UPR)& SPR_UPR_DCP)) return 0; if (!(mfspr(SPR_SR) & SPR_SR_DCE)) return 0; printf("dtlb_dcache_test, set %d\n", set); /* Disable DMMU */ dmmu_disable(); /* Invalidate all entries in DTLB */ for (i = 0; i < DTLB_WAYS; i++) { for (j = 0; j < DTLB_SETS; j++) { mtspr (SPR_DTLBMR_BASE(i) + j, 0); mtspr (SPR_DTLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_DATA_SET_NB; i++) { ea = RAM_START + (i*PAGE_SIZE); ta = RAM_START + (i*PAGE_SIZE); mtspr (SPR_DTLBMR_BASE(0) + i, ea | SPR_DTLBMR_V); mtspr (SPR_DTLBTR_BASE(0) + i, ta | DTLB_PR_NOLIMIT); } /* Testing page */ ea = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); ta = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); vmea = VM_BASE + RAM_START + (RAM_SIZE/2) + ((DTLB_SETS-1)*PAGE_SIZE); // Set a 1-1 translation for this page without cache inhibited /* Set match register */ mtspr (SPR_DTLBMR_BASE(0) + set, ea | SPR_DTLBMR_V); /* Set translate register */ mtspr (SPR_DTLBTR_BASE(0) + set, ta | DTLB_PR_NOLIMIT); // Now set a far-off translation, VM_BASE, for this page with cache inhibited // Use the last set /* Set match register */ mtspr (SPR_DTLBMR_BASE(0) + (DTLB_SETS-1), vmea | SPR_DTLBMR_V); /* Set translate register */ mtspr (SPR_DTLBTR_BASE(0) + (DTLB_SETS-1), ta | DTLB_PR_NOLIMIT | SPR_DTLBTR_CI); /* Enable DMMU */ dmmu_enable(); // First do a write with the cache inhibited mapping unsigned long int testwrite_to_be_cached = 0xfeca1d0d ^ set; REG32((vmea)) = testwrite_to_be_cached; // Read it back to check that it's the same, this read should get cached ASSERT(REG32(ea) == testwrite_to_be_cached); // Now write again to the cache inhibited location unsigned long int testwrite_not_to_be_cached = 0xbaadbeef ^ set; REG32((vmea)) = testwrite_not_to_be_cached; // Now check that the cached mapping doesn't read this value back ASSERT(REG32(ea) == testwrite_to_be_cached); // Now disable cache inhibition on the 1-1 mapping /* Set translate register */ mtspr (SPR_DTLBTR_BASE(0) + set, ea | DTLB_PR_NOLIMIT | SPR_DTLBTR_CI); // Check that we now get the second value we wrote testwrite_to_be_cached = testwrite_not_to_be_cached; ASSERT(REG32(ea) == testwrite_to_be_cached); /* Disable DMMU */ dmmu_disable(); printf("-------------------------------------------\n"); return 0; } /* Translation address register test Set various translation and check the pattern */ int itlb_translation_test (void) { int i, j; //unsigned long ea, ta; unsigned long translate_space; unsigned long match_space; printf("itlb_translation_test\n"); /* Disable IMMU */ immu_disable(); /* Invalidate all entries in DTLB */ for (i = 0; i < ITLB_WAYS; i++) { for (j = 0; j < ITLB_SETS; j++) { mtspr (SPR_ITLBMR_BASE(i) + j, 0); mtspr (SPR_ITLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_TEXT_SET_NB; i++) { match_space = TEXT_START_ADD + (i*PAGE_SIZE); translate_space = TEXT_START_ADD + (i*PAGE_SIZE); mtspr (SPR_ITLBMR_BASE(0) + i, match_space | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(0) + i, translate_space | ITLB_PR_NOLIMIT); } /* Set itlb permisions */ itlb_val = ITLB_PR_NOLIMIT; /* Write test program */ for (i = TLB_TEXT_SET_NB; i < ITLB_SETS; i++) { translate_space = (RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE) + (i*0x10)); //printf("writing app to 0x%.8lx to be translated in set %d\n",translate_space, i); REG32(translate_space) = OR32_L_JR_R9; REG32(translate_space + 4) = OR32_L_NOP; // Now flush this in case DC isn't on write-through mtspr(SPR_DCBFR, translate_space); mtspr(SPR_DCBFR, translate_space+4); } /* Set one to one translation of the last way of ITLB */ for (i = TLB_TEXT_SET_NB; i < ITLB_SETS; i++) { translate_space = (RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE) + (i*0x10)); mtspr (SPR_ITLBMR_BASE(ITLB_WAYS - 1) + i, translate_space | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(ITLB_WAYS - 1) + i, translate_space | ITLB_PR_NOLIMIT); } /* Enable IMMU */ immu_enable(); /* Check the tranlsation works by jumping there */ for (i = TLB_TEXT_SET_NB; i < ITLB_SETS; i++) { translate_space = (RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE) + (i*0x10)); //printf("calling 0x%.8lx - should use set %d\n",translate_space, i); call (translate_space); } /* Set hi -> lo, lo -> hi translation */ for (i = TLB_TEXT_SET_NB; i < ITLB_SETS; i++) { match_space = RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE); translate_space = RAM_START + (RAM_SIZE/2) + (((ITLB_SETS-1)+TLB_TEXT_SET_NB - i)*PAGE_SIZE); printf("setting itlb set %d match -> trans = 0x%.8lx -> 0x%.8lx\n", i, match_space, translate_space); mtspr (SPR_ITLBMR_BASE(ITLB_WAYS - 1) + i, match_space | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(ITLB_WAYS - 1) + i, translate_space|ITLB_PR_NOLIMIT); } /* Check the pattern */ for (i = TLB_TEXT_SET_NB; i < ITLB_SETS; i++) { match_space = RAM_START + (RAM_SIZE/2) + (((ITLB_SETS-1)+TLB_TEXT_SET_NB - i)*PAGE_SIZE) + (i*0x10); printf("immu hi->lo check - calling 0x%.8lx\n",match_space); call(match_space); } /* Disable IMMU */ immu_disable (); /* Check the pattern */ for (i = TLB_TEXT_SET_NB; i < ITLB_SETS; i++) { translate_space = (RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE) + (i*0x10)); //call (RAM_START + (RAM_SIZE/2) + (i*PAGE_SIZE) + (i*0x10)); //printf("immu disabled check of set %d - calling 0x%.8lx\n",i, translate_space); call (translate_space); } printf("-------------------------------------------\n"); return 0; } /* EA match register test Shifting one in ITLBMR and performing accesses to boundaries of the page, checking the triggering of exceptions */ int itlb_match_test (int way, int set) { int i, j; unsigned long add, t_add; unsigned long ea, ta; printf("itlb_match_test\n"); /* Disable IMMU */ immu_disable(); /* Invalidate all entries in ITLB */ for (i = 0; i < ITLB_WAYS; i++) { for (j = 0; j < ITLB_SETS; j++) { mtspr (SPR_ITLBMR_BASE(i) + j, 0); mtspr (SPR_ITLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_TEXT_SET_NB; i++) { ea = TEXT_START_ADD + (i*PAGE_SIZE); ta = TEXT_START_ADD + (i*PAGE_SIZE); mtspr (SPR_ITLBMR_BASE(0) + i, ea | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(0) + i, ta | ITLB_PR_NOLIMIT); } /* Set dtlb permisions */ itlb_val = ITLB_PR_NOLIMIT; // Write program which will just return into these places unsigned long translate_space = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); //copy_jump (RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE) - 8); REG32(translate_space-8) = OR32_L_JR_R9; REG32(translate_space-4) = OR32_L_NOP; //copy_jump (RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE)); REG32(translate_space) = OR32_L_JR_R9; REG32(translate_space+4) = OR32_L_NOP; //copy_jump (RAM_START + (RAM_SIZE/2) + (set + 1)*PAGE_SIZE - 8); REG32(translate_space + PAGE_SIZE - 8) = OR32_L_JR_R9; REG32(translate_space + PAGE_SIZE - 4) = OR32_L_NOP; //copy_jump (RAM_START + (RAM_SIZE/2) + (set + 1)*PAGE_SIZE); REG32(translate_space + PAGE_SIZE) = OR32_L_JR_R9; REG32(translate_space + PAGE_SIZE + 4) = OR32_L_NOP; // Flush these areas incase cache doesn't write them through immediately mtspr(SPR_DCBFR, translate_space-8); mtspr(SPR_DCBFR, translate_space); mtspr(SPR_DCBFR, translate_space+4); mtspr(SPR_DCBFR, translate_space + PAGE_SIZE - 8); mtspr(SPR_DCBFR, translate_space + PAGE_SIZE - 4); mtspr(SPR_DCBFR, translate_space + PAGE_SIZE); mtspr(SPR_DCBFR, translate_space + PAGE_SIZE + 4); /* Enable IMMU */ immu_enable(); /* Shifting one in ITLBMR */ i = 0; //add = (PAGE_SIZE*ITLB_SETS); //t_add = add + (set*PAGE_SIZE); // Space we'll access and expect the MMU to translate our requests unsigned long match_space = (PAGE_SIZE*DTLB_SETS) + (set*PAGE_SIZE); while (add != 0x00000000) { mtspr (SPR_ITLBMR_BASE(way) + set, match_space | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(way) + set, translate_space | ITLB_PR_NOLIMIT); /* Reset ITLB miss counter and EA */ itlb_miss_count = 0; itlb_miss_ea = 0; //if (((t_add < RAM_START) || (t_add >= DATA_END_ADD)) && ((t_add < TEXT_START_ADD) || (t_add >= TEXT_END_ADD))) { /* Jump on last address of previous page */ call (match_space - 8); ASSERT(itlb_miss_count == 1); /* Jump on first address of the page */ call (match_space); ASSERT(itlb_miss_count == 1); /* Jump on last address of the page */ call (match_space + PAGE_SIZE - 8); ASSERT(itlb_miss_count == 1); /* Jump on first address of next page */ call (match_space + PAGE_SIZE); ASSERT(itlb_miss_count == 2); //} i++; add = (PAGE_SIZE*ITLB_SETS) << i; match_space = add + (set*PAGE_SIZE); for (j = 0; j < ITLB_WAYS; j++) { mtspr (SPR_ITLBMR_BASE(j) + ((set - 1) & (ITLB_SETS - 1)), 0); mtspr (SPR_ITLBMR_BASE(j) + ((set + 1) & (ITLB_SETS - 1)), 0); } } printf("-------------------------------------------\n"); /* Disable IMMU */ immu_disable(); return 0; } /* Valid bit test Set all ways of one set to be invalid, perform access so miss handler will set them to valid, try access again - there should be no miss exceptions */ int itlb_valid_bit_test (int set) { int i, j; unsigned long ea, ta; printf("itlb_valid_bit_test set = %d\n", set); /* Disable IMMU */ immu_disable(); /* Invalidate all entries in ITLB */ for (i = 0; i < ITLB_WAYS; i++) { for (j = 0; j < ITLB_SETS; j++) { mtspr (SPR_ITLBMR_BASE(i) + j, 0); mtspr (SPR_ITLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_TEXT_SET_NB; i++) { ea = TEXT_START_ADD + (i*PAGE_SIZE); ta = TEXT_START_ADD + (i*PAGE_SIZE); mtspr (SPR_ITLBMR_BASE(0) + i, ea | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(0) + i, ta | ITLB_PR_NOLIMIT); } /* Reset ITLB miss counter and EA */ itlb_miss_count = 0; itlb_miss_ea = 0; /* Set itlb permisions */ itlb_val = ITLB_PR_NOLIMIT; /* Resetv ITLBMR for every way after the program code */ for (i = TLB_TEXT_SET_NB; i < ITLB_WAYS; i++) { mtspr (SPR_ITLBMR_BASE(i) + set, 0); } /* Enable IMMU */ immu_enable(); // Address we'll jump to and expect it to be translated unsigned long match_space = (PAGE_SIZE*ITLB_SETS) + (set*PAGE_SIZE); // Address that we will actually access unsigned long translate_space = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); /* Perform jumps to address, that is not in ITLB */ printf("writing program to 0x%.8lx\n", translate_space); REG32(translate_space) = OR32_L_JR_R9; REG32(translate_space+4) = OR32_L_NOP; mtspr(SPR_DCBFR, translate_space); mtspr(SPR_DCBFR, translate_space+4); printf("jumping to 0x%.8lx, should be itlb miss\n",match_space); call (match_space); /* Check if there was ITLB miss */ ASSERT(itlb_miss_count == 1); ASSERT(itlb_miss_ea == match_space); /* Reset ITLB miss counter and EA */ itlb_miss_count = 0; itlb_miss_ea = 0; printf("jumping to 0x%.8lx again - should not be a miss\n", match_space); /* Perform jumps to address, that is now in ITLB */ call (match_space); /* Check if there was ITLB miss */ ASSERT(itlb_miss_count == 0); /* Reset valid bits */ for (i = 0; i < ITLB_WAYS; i++) { mtspr (SPR_ITLBMR_BASE(i) + set, mfspr (SPR_ITLBMR_BASE(i) + set) & ~SPR_ITLBMR_V); } printf("jumping to 0x%.8lx again - mmu entries invalidated, so should be a miss\n", match_space); /* Perform jumps to address, that is now in ITLB but is invalid */ call (match_space); /* Check if there was ITLB miss */ ASSERT(itlb_miss_count == 1); ASSERT(itlb_miss_ea == match_space); /* Disable IMMU */ immu_disable (); printf("-------------------------------------------\n"); return 0; } /* Permission test Set various permissions, perform r/w access in user and supervisor mode and chack triggering of page fault exceptions */ int itlb_permission_test (int set) { int i, j; unsigned long ea, ta; printf("itlb_permission_test set = %d\n", set); /* Disable IMMU */ immu_disable(); /* Invalidate all entries in ITLB */ for (i = 0; i < ITLB_WAYS; i++) { for (j = 0; j < ITLB_SETS; j++) { mtspr (SPR_ITLBMR_BASE(i) + j, 0); mtspr (SPR_ITLBTR_BASE(i) + j, 0); } } /* Set one to one translation for the use of this program */ for (i = 0; i < TLB_TEXT_SET_NB; i++) { ea = TEXT_START_ADD + (i*PAGE_SIZE); ta = TEXT_START_ADD + (i*PAGE_SIZE); mtspr (SPR_ITLBMR_BASE(0) + i, ea | SPR_ITLBMR_V); mtspr (SPR_ITLBTR_BASE(0) + i, ta | ITLB_PR_NOLIMIT); } // Address that we will actually access unsigned long match_space = RAM_START + (RAM_SIZE/2) + (set*PAGE_SIZE); /* Set match register */ mtspr (SPR_ITLBMR_BASE(ITLB_WAYS - 1) + set, match_space | SPR_ITLBMR_V); /* Reset page fault counter and EA */ ipage_fault_count = 0; ipage_fault_ea = 0; /* Copy the code */ REG32(match_space+0x0) = OR32_L_JR_R9; REG32(match_space+0x4) = OR32_L_NOP; REG32(match_space+0x8) = OR32_L_JR_R9; REG32(match_space+0xc) = OR32_L_NOP; mtspr(SPR_DCBFR, match_space); mtspr(SPR_DCBFR, match_space+4); mtspr(SPR_DCBFR, match_space+8); mtspr(SPR_DCBFR, match_space+12); /* Enable IMMU */ immu_enable (); /* Execute supervisor */ printf("execute disable for supervisor - should cause ipage fault\n"); itlb_val = SPR_ITLBTR_CI | SPR_ITLBTR_SXE; mtspr (SPR_ITLBTR_BASE(ITLB_WAYS - 1) + set, match_space | (ITLB_PR_NOLIMIT & ~SPR_ITLBTR_SXE)); printf("calling address 0x%.8lx\n", match_space); call (match_space); ASSERT(ipage_fault_count == 1); call (match_space + 8); ASSERT(ipage_fault_count == 1); /* Execute user */ printf("execute disable for user - should cause ipage fault\n"); itlb_val = SPR_ITLBTR_CI | SPR_ITLBTR_UXE; mtspr (SPR_ITLBTR_BASE(ITLB_WAYS - 1) + set, match_space | (ITLB_PR_NOLIMIT & ~SPR_ITLBTR_UXE)); /* Set user mode */ printf("disabling supervisor mode\n"); mtspr (SPR_SR, mfspr (SPR_SR) & ~SPR_SR_SM); printf("calling address 0x%.8lx\n", match_space); printf("instruction at jump space: 0x%.8lx\n",REG32(match_space)); call (match_space); ASSERT(ipage_fault_count == 2); call (match_space + 8); ASSERT(ipage_fault_count == 2); /* Trigger sys call exception to enable supervisor mode again */ sys_call (); /* Disable IMMU */ immu_disable (); printf("-------------------------------------------\n"); return 0; } int main (void) { int i, j; start_text_addr = (unsigned long*)&_stext; end_text_addr = (unsigned long*)&_endtext; end_data_addr = (unsigned long*)&_stack; end_data_addr += 4; #ifndef TLB_BOTTOM_TEST_PAGE_HARDSET TLB_TEXT_SET_NB = TLB_DATA_SET_NB = (end_data_addr+PAGE_SIZE) / PAGE_SIZE; #endif #ifdef _UART_H_ uart_init(DEFAULT_UART); #endif i = j = 0; /* Get rid of warnings */ /* Register bus error handler */ add_handler(0x2, bus_err_handler); /* Register illegal insn handler */ add_handler(0x7, ill_insn_handler); /* Register sys call handler */ add_handler(0xc, sys_call_handler); #if DO_DMMU_TESTS==1 /* Translation test */ dtlb_translation_test (); /* Virtual address match test */ for (j = 0; j < DTLB_WAYS; j++) { #ifdef SHORT_TEST for (i = TLB_DATA_SET_NB; i < (TLB_DATA_SET_NB+4 - 1); i++) #else for (i = TLB_DATA_SET_NB; i < (DTLB_SETS - 1); i++) #endif dtlb_match_test (j, i); } /* Valid bit testing */ #ifdef SHORT_TEST for (i = TLB_DATA_SET_NB; i < (TLB_DATA_SET_NB+4 - 1); i++) #else for (i = TLB_DATA_SET_NB; i < (DTLB_SETS - 1); i++) #endif dtlb_valid_bit_test (i); /* Permission test */ #ifdef SHORT_TEST for (i = TLB_DATA_SET_NB; i < (TLB_DATA_SET_NB+4 - 1); i++) #else for (i = TLB_DATA_SET_NB; i < (DTLB_SETS - 1); i++) #endif dtlb_permission_test (i); /* Data cache test */ #ifndef OR1200_NO_DC #ifdef SHORT_TEST for (i = TLB_DATA_SET_NB; i < (TLB_DATA_SET_NB+4 - 1); i++) #else for (i = TLB_DATA_SET_NB; i < (DTLB_SETS - 2); i++) #endif dtlb_dcache_test (i); #endif // ifndef OR1200_NO_DC #endif /* Translation test */ itlb_translation_test (); /* Virtual address match test */ for (j = 0; j < DTLB_WAYS; j++) { #ifdef SHORT_TEST for (i = TLB_DATA_SET_NB + 1; i < (TLB_DATA_SET_NB+4 - 1); i++) #else for (i = TLB_DATA_SET_NB + 1; i < (ITLB_SETS - 1); i++) #endif itlb_match_test (j, i); } /* Valid bit testing */ #ifdef SHORT_TEST for (i = TLB_DATA_SET_NB; i < (TLB_DATA_SET_NB+4 - 1); i++) #else for (i = TLB_DATA_SET_NB; i < (ITLB_SETS - 1); i++) #endif itlb_valid_bit_test (i); /* Permission test */ #ifdef SHORT_TEST for (i = TLB_TEXT_SET_NB; i < (TLB_TEXT_SET_NB + 4); i++) #else for (i = TLB_TEXT_SET_NB; i < (ITLB_SETS - 1); i++) #endif itlb_permission_test (i); printf("Tests completed\n"); report (0xdeaddead); report (0x8000000d); exit (0); }
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