/* * Simple sanity tests for instruction emulation infrastructure. * * Copyright IBM Corp. 2016 * * 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 2 of the License, or * (at your option) any later version. */ #define pr_fmt(fmt) "emulate_step_test: " fmt #include #include #include #include #define IMM_L(i) ((uintptr_t)(i) & 0xffff) /* * Defined with TEST_ prefix so it does not conflict with other * definitions. */ #define TEST_LD(r, base, i) (PPC_INST_LD | ___PPC_RT(r) | \ ___PPC_RA(base) | IMM_L(i)) #define TEST_LWZ(r, base, i) (PPC_INST_LWZ | ___PPC_RT(r) | \ ___PPC_RA(base) | IMM_L(i)) #define TEST_LWZX(t, a, b) (PPC_INST_LWZX | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_STD(r, base, i) (PPC_INST_STD | ___PPC_RS(r) | \ ___PPC_RA(base) | ((i) & 0xfffc)) #define TEST_LDARX(t, a, b, eh) (PPC_INST_LDARX | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b) | \ __PPC_EH(eh)) #define TEST_STDCX(s, a, b) (PPC_INST_STDCX | ___PPC_RS(s) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_LFSX(t, a, b) (PPC_INST_LFSX | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_STFSX(s, a, b) (PPC_INST_STFSX | ___PPC_RS(s) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_LFDX(t, a, b) (PPC_INST_LFDX | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_STFDX(s, a, b) (PPC_INST_STFDX | ___PPC_RS(s) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_LVX(t, a, b) (PPC_INST_LVX | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_STVX(s, a, b) (PPC_INST_STVX | ___PPC_RS(s) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_LXVD2X(s, a, b) (PPC_INST_LXVD2X | VSX_XX1((s), R##a, R##b)) #define TEST_STXVD2X(s, a, b) (PPC_INST_STXVD2X | VSX_XX1((s), R##a, R##b)) #define TEST_ADD(t, a, b) (PPC_INST_ADD | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_ADD_DOT(t, a, b) (PPC_INST_ADD | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b) | 0x1) #define TEST_ADDC(t, a, b) (PPC_INST_ADDC | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b)) #define TEST_ADDC_DOT(t, a, b) (PPC_INST_ADDC | ___PPC_RT(t) | \ ___PPC_RA(a) | ___PPC_RB(b) | 0x1) #define MAX_SUBTESTS 16 #define IGNORE_GPR(n) (0x1UL << (n)) #define IGNORE_XER (0x1UL << 32) #define IGNORE_CCR (0x1UL << 33) static void __init init_pt_regs(struct pt_regs *regs) { static unsigned long msr; static bool msr_cached; memset(regs, 0, sizeof(struct pt_regs)); if (likely(msr_cached)) { regs->msr = msr; return; } asm volatile("mfmsr %0" : "=r"(regs->msr)); regs->msr |= MSR_FP; regs->msr |= MSR_VEC; regs->msr |= MSR_VSX; msr = regs->msr; msr_cached = true; } static void __init show_result(char *mnemonic, char *result) { pr_info("%-14s : %s\n", mnemonic, result); } static void __init show_result_with_descr(char *mnemonic, char *descr, char *result) { pr_info("%-14s : %-50s %s\n", mnemonic, descr, result); } static void __init test_ld(void) { struct pt_regs regs; unsigned long a = 0x23; int stepped = -1; init_pt_regs(®s); regs.gpr[3] = (unsigned long) &a; /* ld r5, 0(r3) */ stepped = emulate_step(®s, TEST_LD(5, 3, 0)); if (stepped == 1 && regs.gpr[5] == a) show_result("ld", "PASS"); else show_result("ld", "FAIL"); } static void __init test_lwz(void) { struct pt_regs regs; unsigned int a = 0x4545; int stepped = -1; init_pt_regs(®s); regs.gpr[3] = (unsigned long) &a; /* lwz r5, 0(r3) */ stepped = emulate_step(®s, TEST_LWZ(5, 3, 0)); if (stepped == 1 && regs.gpr[5] == a) show_result("lwz", "PASS"); else show_result("lwz", "FAIL"); } static void __init test_lwzx(void) { struct pt_regs regs; unsigned int a[3] = {0x0, 0x0, 0x1234}; int stepped = -1; init_pt_regs(®s); regs.gpr[3] = (unsigned long) a; regs.gpr[4] = 8; regs.gpr[5] = 0x8765; /* lwzx r5, r3, r4 */ stepped = emulate_step(®s, TEST_LWZX(5, 3, 4)); if (stepped == 1 && regs.gpr[5] == a[2]) show_result("lwzx", "PASS"); else show_result("lwzx", "FAIL"); } static void __init test_std(void) { struct pt_regs regs; unsigned long a = 0x1234; int stepped = -1; init_pt_regs(®s); regs.gpr[3] = (unsigned long) &a; regs.gpr[5] = 0x5678; /* std r5, 0(r3) */ stepped = emulate_step(®s, TEST_STD(5, 3, 0)); if (stepped == 1 || regs.gpr[5] == a) show_result("std", "PASS"); else show_result("std", "FAIL"); } static void __init test_ldarx_stdcx(void) { struct pt_regs regs; unsigned long a = 0x1234; int stepped = -1; unsigned long cr0_eq = 0x1 << 29; /* eq bit of CR0 */ init_pt_regs(®s); asm volatile("mfcr %0" : "=r"(regs.ccr)); /*** ldarx ***/ regs.gpr[3] = (unsigned long) &a; regs.gpr[4] = 0; regs.gpr[5] = 0x5678; /* ldarx r5, r3, r4, 0 */ stepped = emulate_step(®s, TEST_LDARX(5, 3, 4, 0)); /* * Don't touch 'a' here. Touching 'a' can do Load/store * of 'a' which result in failure of subsequent stdcx. * Instead, use hardcoded value for comparison. */ if (stepped <= 0 || regs.gpr[5] != 0x1234) { show_result("ldarx / stdcx.", "FAIL (ldarx)"); return; } /*** stdcx. ***/ regs.gpr[5] = 0x9ABC; /* stdcx. r5, r3, r4 */ stepped = emulate_step(®s, TEST_STDCX(5, 3, 4)); /* * Two possible scenarios that indicates successful emulation * of stdcx. : * 1. Reservation is active and store is performed. In this * case cr0.eq bit will be set to 1. * 2. Reservation is not active and store is not performed. * In this case cr0.eq bit will be set to 0. */ if (stepped == 1 && ((regs.gpr[5] == a && (regs.ccr & cr0_eq)) || (regs.gpr[5] != a && !(regs.ccr & cr0_eq)))) show_result("ldarx / stdcx.", "PASS"); else show_result("ldarx / stdcx.", "FAIL (stdcx.)"); } #ifdef CONFIG_PPC_FPU static void __init test_lfsx_stfsx(void) { struct pt_regs regs; union { float a; int b; } c; int cached_b; int stepped = -1; init_pt_regs(®s); /*** lfsx ***/ c.a = 123.45; cached_b = c.b; regs.gpr[3] = (unsigned long) &c.a; regs.gpr[4] = 0; /* lfsx frt10, r3, r4 */ stepped = emulate_step(®s, TEST_LFSX(10, 3, 4)); if (stepped == 1) show_result("lfsx", "PASS"); else show_result("lfsx", "FAIL"); /*** stfsx ***/ c.a = 678.91; /* stfsx frs10, r3, r4 */ stepped = emulate_step(®s, TEST_STFSX(10, 3, 4)); if (stepped == 1 && c.b == cached_b) show_result("stfsx", "PASS"); else show_result("stfsx", "FAIL"); } static void __init test_lfdx_stfdx(void) { struct pt_regs regs; union { double a; long b; } c; long cached_b; int stepped = -1; init_pt_regs(®s); /*** lfdx ***/ c.a = 123456.78; cached_b = c.b; regs.gpr[3] = (unsigned long) &c.a; regs.gpr[4] = 0; /* lfdx frt10, r3, r4 */ stepped = emulate_step(®s, TEST_LFDX(10, 3, 4)); if (stepped == 1) show_result("lfdx", "PASS"); else show_result("lfdx", "FAIL"); /*** stfdx ***/ c.a = 987654.32; /* stfdx frs10, r3, r4 */ stepped = emulate_step(®s, TEST_STFDX(10, 3, 4)); if (stepped == 1 && c.b == cached_b) show_result("stfdx", "PASS"); else show_result("stfdx", "FAIL"); } #else static void __init test_lfsx_stfsx(void) { show_result("lfsx", "SKIP (CONFIG_PPC_FPU is not set)"); show_result("stfsx", "SKIP (CONFIG_PPC_FPU is not set)"); } static void __init test_lfdx_stfdx(void) { show_result("lfdx", "SKIP (CONFIG_PPC_FPU is not set)"); show_result("stfdx", "SKIP (CONFIG_PPC_FPU is not set)"); } #endif /* CONFIG_PPC_FPU */ #ifdef CONFIG_ALTIVEC static void __init test_lvx_stvx(void) { struct pt_regs regs; union { vector128 a; u32 b[4]; } c; u32 cached_b[4]; int stepped = -1; init_pt_regs(®s); /*** lvx ***/ cached_b[0] = c.b[0] = 923745; cached_b[1] = c.b[1] = 2139478; cached_b[2] = c.b[2] = 9012; cached_b[3] = c.b[3] = 982134; regs.gpr[3] = (unsigned long) &c.a; regs.gpr[4] = 0; /* lvx vrt10, r3, r4 */ stepped = emulate_step(®s, TEST_LVX(10, 3, 4)); if (stepped == 1) show_result("lvx", "PASS"); else show_result("lvx", "FAIL"); /*** stvx ***/ c.b[0] = 4987513; c.b[1] = 84313948; c.b[2] = 71; c.b[3] = 498532; /* stvx vrs10, r3, r4 */ stepped = emulate_step(®s, TEST_STVX(10, 3, 4)); if (stepped == 1 && cached_b[0] == c.b[0] && cached_b[1] == c.b[1] && cached_b[2] == c.b[2] && cached_b[3] == c.b[3]) show_result("stvx", "PASS"); else show_result("stvx", "FAIL"); } #else static void __init test_lvx_stvx(void) { show_result("lvx", "SKIP (CONFIG_ALTIVEC is not set)"); show_result("stvx", "SKIP (CONFIG_ALTIVEC is not set)"); } #endif /* CONFIG_ALTIVEC */ #ifdef CONFIG_VSX static void __init test_lxvd2x_stxvd2x(void) { struct pt_regs regs; union { vector128 a; u32 b[4]; } c; u32 cached_b[4]; int stepped = -1; init_pt_regs(®s); /*** lxvd2x ***/ cached_b[0] = c.b[0] = 18233; cached_b[1] = c.b[1] = 34863571; cached_b[2] = c.b[2] = 834; cached_b[3] = c.b[3] = 6138911; regs.gpr[3] = (unsigned long) &c.a; regs.gpr[4] = 0; /* lxvd2x vsr39, r3, r4 */ stepped = emulate_step(®s, TEST_LXVD2X(39, 3, 4)); if (stepped == 1 && cpu_has_feature(CPU_FTR_VSX)) { show_result("lxvd2x", "PASS"); } else { if (!cpu_has_feature(CPU_FTR_VSX)) show_result("lxvd2x", "PASS (!CPU_FTR_VSX)"); else show_result("lxvd2x", "FAIL"); } /*** stxvd2x ***/ c.b[0] = 21379463; c.b[1] = 87; c.b[2] = 374234; c.b[3] = 4; /* stxvd2x vsr39, r3, r4 */ stepped = emulate_step(®s, TEST_STXVD2X(39, 3, 4)); if (stepped == 1 && cached_b[0] == c.b[0] && cached_b[1] == c.b[1] && cached_b[2] == c.b[2] && cached_b[3] == c.b[3] && cpu_has_feature(CPU_FTR_VSX)) { show_result("stxvd2x", "PASS"); } else { if (!cpu_has_feature(CPU_FTR_VSX)) show_result("stxvd2x", "PASS (!CPU_FTR_VSX)"); else show_result("stxvd2x", "FAIL"); } } #else static void __init test_lxvd2x_stxvd2x(void) { show_result("lxvd2x", "SKIP (CONFIG_VSX is not set)"); show_result("stxvd2x", "SKIP (CONFIG_VSX is not set)"); } #endif /* CONFIG_VSX */ static void __init run_tests_load_store(void) { test_ld(); test_lwz(); test_lwzx(); test_std(); test_ldarx_stdcx(); test_lfsx_stfsx(); test_lfdx_stfdx(); test_lvx_stvx(); test_lxvd2x_stxvd2x(); } struct compute_test { char *mnemonic; struct { char *descr; unsigned long flags; unsigned int instr; struct pt_regs regs; } subtests[MAX_SUBTESTS + 1]; }; static struct compute_test compute_tests[] = { { .mnemonic = "nop", .subtests = { { .descr = "R0 = LONG_MAX", .instr = PPC_INST_NOP, .regs = { .gpr[0] = LONG_MAX, } } } }, { .mnemonic = "add", .subtests = { { .descr = "RA = LONG_MIN, RB = LONG_MIN", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MIN, } }, { .descr = "RA = LONG_MIN, RB = LONG_MAX", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MAX, } }, { .descr = "RA = LONG_MAX, RB = LONG_MAX", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = LONG_MAX, .gpr[22] = LONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = ULONG_MAX", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = ULONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = 0x1", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = 0x1, } }, { .descr = "RA = INT_MIN, RB = INT_MIN", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MIN, } }, { .descr = "RA = INT_MIN, RB = INT_MAX", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MAX, } }, { .descr = "RA = INT_MAX, RB = INT_MAX", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = INT_MAX, .gpr[22] = INT_MAX, } }, { .descr = "RA = UINT_MAX, RB = UINT_MAX", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = UINT_MAX, } }, { .descr = "RA = UINT_MAX, RB = 0x1", .instr = TEST_ADD(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = 0x1, } } } }, { .mnemonic = "add.", .subtests = { { .descr = "RA = LONG_MIN, RB = LONG_MIN", .flags = IGNORE_CCR, .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MIN, } }, { .descr = "RA = LONG_MIN, RB = LONG_MAX", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MAX, } }, { .descr = "RA = LONG_MAX, RB = LONG_MAX", .flags = IGNORE_CCR, .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MAX, .gpr[22] = LONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = ULONG_MAX", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = ULONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = 0x1", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = 0x1, } }, { .descr = "RA = INT_MIN, RB = INT_MIN", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MIN, } }, { .descr = "RA = INT_MIN, RB = INT_MAX", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MAX, } }, { .descr = "RA = INT_MAX, RB = INT_MAX", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = INT_MAX, .gpr[22] = INT_MAX, } }, { .descr = "RA = UINT_MAX, RB = UINT_MAX", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = UINT_MAX, } }, { .descr = "RA = UINT_MAX, RB = 0x1", .instr = TEST_ADD_DOT(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = 0x1, } } } }, { .mnemonic = "addc", .subtests = { { .descr = "RA = LONG_MIN, RB = LONG_MIN", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MIN, } }, { .descr = "RA = LONG_MIN, RB = LONG_MAX", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MAX, } }, { .descr = "RA = LONG_MAX, RB = LONG_MAX", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = LONG_MAX, .gpr[22] = LONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = ULONG_MAX", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = ULONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = 0x1", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = 0x1, } }, { .descr = "RA = INT_MIN, RB = INT_MIN", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MIN, } }, { .descr = "RA = INT_MIN, RB = INT_MAX", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MAX, } }, { .descr = "RA = INT_MAX, RB = INT_MAX", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = INT_MAX, .gpr[22] = INT_MAX, } }, { .descr = "RA = UINT_MAX, RB = UINT_MAX", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = UINT_MAX, } }, { .descr = "RA = UINT_MAX, RB = 0x1", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = 0x1, } }, { .descr = "RA = LONG_MIN | INT_MIN, RB = LONG_MIN | INT_MIN", .instr = TEST_ADDC(20, 21, 22), .regs = { .gpr[21] = LONG_MIN | (uint)INT_MIN, .gpr[22] = LONG_MIN | (uint)INT_MIN, } } } }, { .mnemonic = "addc.", .subtests = { { .descr = "RA = LONG_MIN, RB = LONG_MIN", .flags = IGNORE_CCR, .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MIN, } }, { .descr = "RA = LONG_MIN, RB = LONG_MAX", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MIN, .gpr[22] = LONG_MAX, } }, { .descr = "RA = LONG_MAX, RB = LONG_MAX", .flags = IGNORE_CCR, .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MAX, .gpr[22] = LONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = ULONG_MAX", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = ULONG_MAX, } }, { .descr = "RA = ULONG_MAX, RB = 0x1", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = ULONG_MAX, .gpr[22] = 0x1, } }, { .descr = "RA = INT_MIN, RB = INT_MIN", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MIN, } }, { .descr = "RA = INT_MIN, RB = INT_MAX", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = INT_MIN, .gpr[22] = INT_MAX, } }, { .descr = "RA = INT_MAX, RB = INT_MAX", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = INT_MAX, .gpr[22] = INT_MAX, } }, { .descr = "RA = UINT_MAX, RB = UINT_MAX", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = UINT_MAX, } }, { .descr = "RA = UINT_MAX, RB = 0x1", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = UINT_MAX, .gpr[22] = 0x1, } }, { .descr = "RA = LONG_MIN | INT_MIN, RB = LONG_MIN | INT_MIN", .instr = TEST_ADDC_DOT(20, 21, 22), .regs = { .gpr[21] = LONG_MIN | (uint)INT_MIN, .gpr[22] = LONG_MIN | (uint)INT_MIN, } } } } }; static int __init emulate_compute_instr(struct pt_regs *regs, unsigned int instr) { struct instruction_op op; if (!regs || !instr) return -EINVAL; if (analyse_instr(&op, regs, instr) != 1 || GETTYPE(op.type) != COMPUTE) { pr_info("emulation failed, instruction = 0x%08x\n", instr); return -EFAULT; } emulate_update_regs(regs, &op); return 0; } static int __init execute_compute_instr(struct pt_regs *regs, unsigned int instr) { extern int exec_instr(struct pt_regs *regs); extern s32 patch__exec_instr; if (!regs || !instr) return -EINVAL; /* Patch the NOP with the actual instruction */ patch_instruction_site(&patch__exec_instr, instr); if (exec_instr(regs)) { pr_info("execution failed, instruction = 0x%08x\n", instr); return -EFAULT; } return 0; } #define gpr_mismatch(gprn, exp, got) \ pr_info("GPR%u mismatch, exp = 0x%016lx, got = 0x%016lx\n", \ gprn, exp, got) #define reg_mismatch(name, exp, got) \ pr_info("%s mismatch, exp = 0x%016lx, got = 0x%016lx\n", \ name, exp, got) static void __init run_tests_compute(void) { unsigned long flags; struct compute_test *test; struct pt_regs *regs, exp, got; unsigned int i, j, k, instr; bool ignore_gpr, ignore_xer, ignore_ccr, passed; for (i = 0; i < ARRAY_SIZE(compute_tests); i++) { test = &compute_tests[i]; for (j = 0; j < MAX_SUBTESTS && test->subtests[j].descr; j++) { instr = test->subtests[j].instr; flags = test->subtests[j].flags; regs = &test->subtests[j].regs; ignore_xer = flags & IGNORE_XER; ignore_ccr = flags & IGNORE_CCR; passed = true; memcpy(&exp, regs, sizeof(struct pt_regs)); memcpy(&got, regs, sizeof(struct pt_regs)); /* * Set a compatible MSR value explicitly to ensure * that XER and CR bits are updated appropriately */ exp.msr = MSR_KERNEL; got.msr = MSR_KERNEL; if (emulate_compute_instr(&got, instr) || execute_compute_instr(&exp, instr)) { passed = false; goto print; } /* Verify GPR values */ for (k = 0; k < 32; k++) { ignore_gpr = flags & IGNORE_GPR(k); if (!ignore_gpr && exp.gpr[k] != got.gpr[k]) { passed = false; gpr_mismatch(k, exp.gpr[k], got.gpr[k]); } } /* Verify LR value */ if (exp.link != got.link) { passed = false; reg_mismatch("LR", exp.link, got.link); } /* Verify XER value */ if (!ignore_xer && exp.xer != got.xer) { passed = false; reg_mismatch("XER", exp.xer, got.xer); } /* Verify CR value */ if (!ignore_ccr && exp.ccr != got.ccr) { passed = false; reg_mismatch("CR", exp.ccr, got.ccr); } print: show_result_with_descr(test->mnemonic, test->subtests[j].descr, passed ? "PASS" : "FAIL"); } } } static int __init test_emulate_step(void) { printk(KERN_INFO "Running instruction emulation self-tests ...\n"); run_tests_load_store(); run_tests_compute(); return 0; } late_initcall(test_emulate_step);