/*---------------------------------------------------------------*/ /*--- begin guest_arm_helpers.c ---*/ /*---------------------------------------------------------------*/ /* This file is part of Valgrind, a dynamic binary instrumentation framework. Copyright (C) 2004-2017 OpenWorks LLP info@open-works.net 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. 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, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. The GNU General Public License is contained in the file COPYING. */ #include "libvex_basictypes.h" #include "libvex_emnote.h" #include "libvex_guest_arm.h" #include "libvex_ir.h" #include "libvex.h" #include "main_util.h" #include "main_globals.h" #include "guest_generic_bb_to_IR.h" #include "guest_arm_defs.h" #include "guest_arm64_defs.h" /* for crypto helper functions */ /* This file contains helper functions for arm guest code. Calls to these functions are generated by the back end. These calls are of course in the host machine code and this file will be compiled to host machine code, so that all makes sense. Only change the signatures of these helper functions very carefully. If you change the signature here, you'll have to change the parameters passed to it in the IR calls constructed by guest-arm/toIR.c. */ /* Set to 1 to get detailed profiling info about individual N, Z, C and V flag evaluation. */ #define PROFILE_NZCV_FLAGS 0 #if PROFILE_NZCV_FLAGS static UInt tab_n_eval[ARMG_CC_OP_NUMBER]; static UInt tab_z_eval[ARMG_CC_OP_NUMBER]; static UInt tab_c_eval[ARMG_CC_OP_NUMBER]; static UInt tab_v_eval[ARMG_CC_OP_NUMBER]; static UInt initted = 0; static UInt tot_evals = 0; static void initCounts ( void ) { UInt i; for (i = 0; i < ARMG_CC_OP_NUMBER; i++) { tab_n_eval[i] = tab_z_eval[i] = tab_c_eval[i] = tab_v_eval[i] = 0; } initted = 1; } static void showCounts ( void ) { UInt i; vex_printf("\n N Z C V\n"); vex_printf( "---------------------------------------------------\n"); for (i = 0; i < ARMG_CC_OP_NUMBER; i++) { vex_printf("CC_OP=%d %9d %9d %9d %9d\n", i, tab_n_eval[i], tab_z_eval[i], tab_c_eval[i], tab_v_eval[i] ); } } #define NOTE_N_EVAL(_cc_op) NOTE_EVAL(_cc_op, tab_n_eval) #define NOTE_Z_EVAL(_cc_op) NOTE_EVAL(_cc_op, tab_z_eval) #define NOTE_C_EVAL(_cc_op) NOTE_EVAL(_cc_op, tab_c_eval) #define NOTE_V_EVAL(_cc_op) NOTE_EVAL(_cc_op, tab_v_eval) #define NOTE_EVAL(_cc_op, _tab) \ do { \ if (!initted) initCounts(); \ vassert( ((UInt)(_cc_op)) < ARMG_CC_OP_NUMBER); \ _tab[(UInt)(_cc_op)]++; \ tot_evals++; \ if (0 == (tot_evals & 0xFFFFF)) \ showCounts(); \ } while (0) #endif /* PROFILE_NZCV_FLAGS */ /* Calculate the N flag from the supplied thunk components, in the least significant bit of the word. Returned bits 31:1 are zero. */ static UInt armg_calculate_flag_n ( UInt cc_op, UInt cc_dep1, UInt cc_dep2, UInt cc_dep3 ) { # if PROFILE_NZCV_FLAGS NOTE_N_EVAL(cc_op); # endif switch (cc_op) { case ARMG_CC_OP_COPY: { /* (nzcv:28x0, unused, unused) */ UInt nf = (cc_dep1 >> ARMG_CC_SHIFT_N) & 1; return nf; } case ARMG_CC_OP_ADD: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL + argR; UInt nf = res >> 31; return nf; } case ARMG_CC_OP_SUB: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL - argR; UInt nf = res >> 31; return nf; } case ARMG_CC_OP_ADC: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL + argR + oldC; UInt nf = res >> 31; return nf; } case ARMG_CC_OP_SBB: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL - argR - (oldC ^ 1); UInt nf = res >> 31; return nf; } case ARMG_CC_OP_LOGIC: { /* (res, shco, oldV) */ UInt res = cc_dep1; UInt nf = res >> 31; return nf; } case ARMG_CC_OP_MUL: { /* (res, unused, oldC:oldV) */ UInt res = cc_dep1; UInt nf = res >> 31; return nf; } case ARMG_CC_OP_MULL: { /* (resLo32, resHi32, oldC:oldV) */ UInt resHi32 = cc_dep2; UInt nf = resHi32 >> 31; return nf; } default: /* shouldn't really make these calls from generated code */ vex_printf("armg_calculate_flag_n" "( op=%u, dep1=0x%x, dep2=0x%x, dep3=0x%x )\n", cc_op, cc_dep1, cc_dep2, cc_dep3 ); vpanic("armg_calculate_flags_n"); } } /* Calculate the Z flag from the supplied thunk components, in the least significant bit of the word. Returned bits 31:1 are zero. */ static UInt armg_calculate_flag_z ( UInt cc_op, UInt cc_dep1, UInt cc_dep2, UInt cc_dep3 ) { # if PROFILE_NZCV_FLAGS NOTE_Z_EVAL(cc_op); # endif switch (cc_op) { case ARMG_CC_OP_COPY: { /* (nzcv:28x0, unused, unused) */ UInt zf = (cc_dep1 >> ARMG_CC_SHIFT_Z) & 1; return zf; } case ARMG_CC_OP_ADD: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL + argR; UInt zf = res == 0; return zf; } case ARMG_CC_OP_SUB: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL - argR; UInt zf = res == 0; return zf; } case ARMG_CC_OP_ADC: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL + argR + oldC; UInt zf = res == 0; return zf; } case ARMG_CC_OP_SBB: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL - argR - (oldC ^ 1); UInt zf = res == 0; return zf; } case ARMG_CC_OP_LOGIC: { /* (res, shco, oldV) */ UInt res = cc_dep1; UInt zf = res == 0; return zf; } case ARMG_CC_OP_MUL: { /* (res, unused, oldC:oldV) */ UInt res = cc_dep1; UInt zf = res == 0; return zf; } case ARMG_CC_OP_MULL: { /* (resLo32, resHi32, oldC:oldV) */ UInt resLo32 = cc_dep1; UInt resHi32 = cc_dep2; UInt zf = (resHi32|resLo32) == 0; return zf; } default: /* shouldn't really make these calls from generated code */ vex_printf("armg_calculate_flags_z" "( op=%u, dep1=0x%x, dep2=0x%x, dep3=0x%x )\n", cc_op, cc_dep1, cc_dep2, cc_dep3 ); vpanic("armg_calculate_flags_z"); } } /* CALLED FROM GENERATED CODE: CLEAN HELPER */ /* Calculate the C flag from the supplied thunk components, in the least significant bit of the word. Returned bits 31:1 are zero. */ UInt armg_calculate_flag_c ( UInt cc_op, UInt cc_dep1, UInt cc_dep2, UInt cc_dep3 ) { # if PROFILE_NZCV_FLAGS NOTE_C_EVAL(cc_op); # endif switch (cc_op) { case ARMG_CC_OP_COPY: { /* (nzcv:28x0, unused, unused) */ UInt cf = (cc_dep1 >> ARMG_CC_SHIFT_C) & 1; return cf; } case ARMG_CC_OP_ADD: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL + argR; UInt cf = res < argL; return cf; } case ARMG_CC_OP_SUB: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt cf = argL >= argR; return cf; } case ARMG_CC_OP_ADC: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL + argR + oldC; UInt cf = oldC ? (res <= argL) : (res < argL); return cf; } case ARMG_CC_OP_SBB: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt cf = oldC ? (argL >= argR) : (argL > argR); return cf; } case ARMG_CC_OP_LOGIC: { /* (res, shco, oldV) */ UInt shco = cc_dep2; vassert((shco & ~1) == 0); UInt cf = shco; return cf; } case ARMG_CC_OP_MUL: { /* (res, unused, oldC:oldV) */ UInt oldC = (cc_dep3 >> 1) & 1; vassert((cc_dep3 & ~3) == 0); UInt cf = oldC; return cf; } case ARMG_CC_OP_MULL: { /* (resLo32, resHi32, oldC:oldV) */ UInt oldC = (cc_dep3 >> 1) & 1; vassert((cc_dep3 & ~3) == 0); UInt cf = oldC; return cf; } default: /* shouldn't really make these calls from generated code */ vex_printf("armg_calculate_flag_c" "( op=%u, dep1=0x%x, dep2=0x%x, dep3=0x%x )\n", cc_op, cc_dep1, cc_dep2, cc_dep3 ); vpanic("armg_calculate_flag_c"); } } /* CALLED FROM GENERATED CODE: CLEAN HELPER */ /* Calculate the V flag from the supplied thunk components, in the least significant bit of the word. Returned bits 31:1 are zero. */ UInt armg_calculate_flag_v ( UInt cc_op, UInt cc_dep1, UInt cc_dep2, UInt cc_dep3 ) { # if PROFILE_NZCV_FLAGS NOTE_V_EVAL(cc_op); # endif switch (cc_op) { case ARMG_CC_OP_COPY: { /* (nzcv:28x0, unused, unused) */ UInt vf = (cc_dep1 >> ARMG_CC_SHIFT_V) & 1; return vf; } case ARMG_CC_OP_ADD: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL + argR; UInt vf = ((res ^ argL) & (res ^ argR)) >> 31; return vf; } case ARMG_CC_OP_SUB: { /* (argL, argR, unused) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt res = argL - argR; UInt vf = ((argL ^ argR) & (argL ^ res)) >> 31; return vf; } case ARMG_CC_OP_ADC: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL + argR + oldC; UInt vf = ((res ^ argL) & (res ^ argR)) >> 31; return vf; } case ARMG_CC_OP_SBB: { /* (argL, argR, oldC) */ UInt argL = cc_dep1; UInt argR = cc_dep2; UInt oldC = cc_dep3; vassert((oldC & ~1) == 0); UInt res = argL - argR - (oldC ^ 1); UInt vf = ((argL ^ argR) & (argL ^ res)) >> 31; return vf; } case ARMG_CC_OP_LOGIC: { /* (res, shco, oldV) */ UInt oldV = cc_dep3; vassert((oldV & ~1) == 0); UInt vf = oldV; return vf; } case ARMG_CC_OP_MUL: { /* (res, unused, oldC:oldV) */ UInt oldV = (cc_dep3 >> 0) & 1; vassert((cc_dep3 & ~3) == 0); UInt vf = oldV; return vf; } case ARMG_CC_OP_MULL: { /* (resLo32, resHi32, oldC:oldV) */ UInt oldV = (cc_dep3 >> 0) & 1; vassert((cc_dep3 & ~3) == 0); UInt vf = oldV; return vf; } default: /* shouldn't really make these calls from generated code */ vex_printf("armg_calculate_flag_v" "( op=%u, dep1=0x%x, dep2=0x%x, dep3=0x%x )\n", cc_op, cc_dep1, cc_dep2, cc_dep3 ); vpanic("armg_calculate_flag_v"); } } /* CALLED FROM GENERATED CODE: CLEAN HELPER */ /* Calculate NZCV from the supplied thunk components, in the positions they appear in the CPSR, viz bits 31:28 for N Z C V respectively. Returned bits 27:0 are zero. */ UInt armg_calculate_flags_nzcv ( UInt cc_op, UInt cc_dep1, UInt cc_dep2, UInt cc_dep3 ) { UInt f; UInt res = 0; f = armg_calculate_flag_n(cc_op, cc_dep1, cc_dep2, cc_dep3); res |= (f << ARMG_CC_SHIFT_N); f = armg_calculate_flag_z(cc_op, cc_dep1, cc_dep2, cc_dep3); res |= (f << ARMG_CC_SHIFT_Z); f = armg_calculate_flag_c(cc_op, cc_dep1, cc_dep2, cc_dep3); res |= (f << ARMG_CC_SHIFT_C); f = armg_calculate_flag_v(cc_op, cc_dep1, cc_dep2, cc_dep3); res |= (f << ARMG_CC_SHIFT_V); return res; } /* CALLED FROM GENERATED CODE: CLEAN HELPER */ /* Calculate the QC flag from the arguments, in the lowest bit of the word (bit 0). Urr, having this out of line is bizarre. Push back inline. */ UInt armg_calculate_flag_qc ( UInt resL1, UInt resL2, UInt resR1, UInt resR2 ) { if (resL1 != resR1 || resL2 != resR2) return 1; else return 0; } /* CALLED FROM GENERATED CODE: CLEAN HELPER */ /* Calculate the specified condition from the thunk components, in the lowest bit of the word (bit 0). Returned bits 31:1 are zero. */ UInt armg_calculate_condition ( UInt cond_n_op /* (ARMCondcode << 4) | cc_op */, UInt cc_dep1, UInt cc_dep2, UInt cc_dep3 ) { UInt cond = cond_n_op >> 4; UInt cc_op = cond_n_op & 0xF; UInt nf, zf, vf, cf, inv; // vex_printf("XXXXXXXX %x %x %x %x\n", // cond_n_op, cc_dep1, cc_dep2, cc_dep3); // skip flags computation in this case if (cond == ARMCondAL) return 1; inv = cond & 1; switch (cond) { case ARMCondEQ: // Z=1 => z case ARMCondNE: // Z=0 zf = armg_calculate_flag_z(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ zf; case ARMCondHS: // C=1 => c case ARMCondLO: // C=0 cf = armg_calculate_flag_c(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ cf; case ARMCondMI: // N=1 => n case ARMCondPL: // N=0 nf = armg_calculate_flag_n(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ nf; case ARMCondVS: // V=1 => v case ARMCondVC: // V=0 vf = armg_calculate_flag_v(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ vf; case ARMCondHI: // C=1 && Z=0 => c & ~z case ARMCondLS: // C=0 || Z=1 cf = armg_calculate_flag_c(cc_op, cc_dep1, cc_dep2, cc_dep3); zf = armg_calculate_flag_z(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ (1 & (cf & ~zf)); case ARMCondGE: // N=V => ~(n^v) case ARMCondLT: // N!=V nf = armg_calculate_flag_n(cc_op, cc_dep1, cc_dep2, cc_dep3); vf = armg_calculate_flag_v(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ (1 & ~(nf ^ vf)); case ARMCondGT: // Z=0 && N=V => ~z & ~(n^v) => ~(z | (n^v)) case ARMCondLE: // Z=1 || N!=V nf = armg_calculate_flag_n(cc_op, cc_dep1, cc_dep2, cc_dep3); vf = armg_calculate_flag_v(cc_op, cc_dep1, cc_dep2, cc_dep3); zf = armg_calculate_flag_z(cc_op, cc_dep1, cc_dep2, cc_dep3); return inv ^ (1 & ~(zf | (nf ^ vf))); case ARMCondAL: // handled above case ARMCondNV: // should never get here: Illegal instr default: /* shouldn't really make these calls from generated code */ vex_printf("armg_calculate_condition(ARM)" "( %u, %u, 0x%x, 0x%x, 0x%x )\n", cond, cc_op, cc_dep1, cc_dep2, cc_dep3 ); vpanic("armg_calculate_condition(ARM)"); } } /*---------------------------------------------------------------*/ /*--- Crypto instruction helpers ---*/ /*---------------------------------------------------------------*/ /* DIRTY HELPERS for doing AES support: * AESE (SubBytes, then ShiftRows) * AESD (InvShiftRows, then InvSubBytes) * AESMC (MixColumns) * AESIMC (InvMixColumns) These don't actually have to be dirty helpers -- they could be clean, but for the fact that they return a V128 and a clean helper can't do that. These just call onwards to the implementations of the same in guest_arm64_helpers.c. In all of these cases, we expect |res| to be at least 8 aligned. */ /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_AESE ( /*OUT*/V128* res, UInt arg32_3, UInt arg32_2, UInt arg32_1, UInt arg32_0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argHi = (((ULong)arg32_3) << 32) | ((ULong)arg32_2); ULong argLo = (((ULong)arg32_1) << 32) | ((ULong)arg32_0); arm64g_dirtyhelper_AESE(res, argHi, argLo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_AESD ( /*OUT*/V128* res, UInt arg32_3, UInt arg32_2, UInt arg32_1, UInt arg32_0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argHi = (((ULong)arg32_3) << 32) | ((ULong)arg32_2); ULong argLo = (((ULong)arg32_1) << 32) | ((ULong)arg32_0); arm64g_dirtyhelper_AESD(res, argHi, argLo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_AESMC ( /*OUT*/V128* res, UInt arg32_3, UInt arg32_2, UInt arg32_1, UInt arg32_0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argHi = (((ULong)arg32_3) << 32) | ((ULong)arg32_2); ULong argLo = (((ULong)arg32_1) << 32) | ((ULong)arg32_0); arm64g_dirtyhelper_AESMC(res, argHi, argLo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_AESIMC ( /*OUT*/V128* res, UInt arg32_3, UInt arg32_2, UInt arg32_1, UInt arg32_0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argHi = (((ULong)arg32_3) << 32) | ((ULong)arg32_2); ULong argLo = (((ULong)arg32_1) << 32) | ((ULong)arg32_0); arm64g_dirtyhelper_AESIMC(res, argHi, argLo); } /* DIRTY HELPERS for the SHA instruction family. Same comments as for the AES group above apply. */ /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA1C ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA1C(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA1P ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA1P(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA1M ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA1M(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA1SU0 ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA1SU0(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA256H ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA256H(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA256H2 ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA256H2(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA256SU1 ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argN3, UInt argN2, UInt argN1, UInt argN0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argNhi = (((ULong)argN3) << 32) | ((ULong)argN2); ULong argNlo = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA256SU1(res, argDhi, argDlo, argNhi, argNlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA1SU1 ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA1SU1(res, argDhi, argDlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA256SU0 ( /*OUT*/V128* res, UInt argD3, UInt argD2, UInt argD1, UInt argD0, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argDhi = (((ULong)argD3) << 32) | ((ULong)argD2); ULong argDlo = (((ULong)argD1) << 32) | ((ULong)argD0); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA256SU0(res, argDhi, argDlo, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_SHA1H ( /*OUT*/V128* res, UInt argM3, UInt argM2, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argMhi = (((ULong)argM3) << 32) | ((ULong)argM2); ULong argMlo = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_SHA1H(res, argMhi, argMlo); } /* CALLED FROM GENERATED CODE */ void armg_dirtyhelper_VMULLP64 ( /*OUT*/V128* res, UInt argN1, UInt argN0, UInt argM1, UInt argM0 ) { vassert(0 == (((HWord)res) & (8-1))); ULong argN = (((ULong)argN1) << 32) | ((ULong)argN0); ULong argM = (((ULong)argM1) << 32) | ((ULong)argM0); arm64g_dirtyhelper_PMULLQ(res, argN, argM); } /*---------------------------------------------------------------*/ /*--- Flag-helpers translation-time function specialisers. ---*/ /*--- These help iropt specialise calls the above run-time ---*/ /*--- flags functions. ---*/ /*---------------------------------------------------------------*/ /* Used by the optimiser to try specialisations. Returns an equivalent expression, or NULL if none. */ static Bool isU32 ( IRExpr* e, UInt n ) { return toBool( e->tag == Iex_Const && e->Iex.Const.con->tag == Ico_U32 && e->Iex.Const.con->Ico.U32 == n ); } IRExpr* guest_arm_spechelper ( const HChar* function_name, IRExpr** args, IRStmt** precedingStmts, Int n_precedingStmts ) { # define unop(_op,_a1) IRExpr_Unop((_op),(_a1)) # define binop(_op,_a1,_a2) IRExpr_Binop((_op),(_a1),(_a2)) # define mkU32(_n) IRExpr_Const(IRConst_U32(_n)) # define mkU8(_n) IRExpr_Const(IRConst_U8(_n)) Int i, arity = 0; for (i = 0; args[i]; i++) arity++; # if 0 vex_printf("spec request:\n"); vex_printf(" %s ", function_name); for (i = 0; i < arity; i++) { vex_printf(" "); ppIRExpr(args[i]); } vex_printf("\n"); # endif /* --------- specialising "armg_calculate_condition" --------- */ if (vex_streq(function_name, "armg_calculate_condition")) { /* specialise calls to the "armg_calculate_condition" function. Not sure whether this is strictly necessary, but: the replacement IR must produce only the values 0 or 1. Bits 31:1 are required to be zero. */ IRExpr *cond_n_op, *cc_dep1, *cc_dep2, *cc_ndep; vassert(arity == 4); cond_n_op = args[0]; /* (ARMCondcode << 4) | ARMG_CC_OP_* */ cc_dep1 = args[1]; cc_dep2 = args[2]; cc_ndep = args[3]; /*---------------- SUB ----------------*/ if (isU32(cond_n_op, (ARMCondEQ << 4) | ARMG_CC_OP_SUB)) { /* EQ after SUB --> test argL == argR */ return unop(Iop_1Uto32, binop(Iop_CmpEQ32, cc_dep1, cc_dep2)); } if (isU32(cond_n_op, (ARMCondNE << 4) | ARMG_CC_OP_SUB)) { /* NE after SUB --> test argL != argR */ return unop(Iop_1Uto32, binop(Iop_CmpNE32, cc_dep1, cc_dep2)); } if (isU32(cond_n_op, (ARMCondGT << 4) | ARMG_CC_OP_SUB)) { /* GT after SUB --> test argL >s argR --> test argR test argL <=s argR */ return unop(Iop_1Uto32, binop(Iop_CmpLE32S, cc_dep1, cc_dep2)); } if (isU32(cond_n_op, (ARMCondLT << 4) | ARMG_CC_OP_SUB)) { /* LT after SUB --> test argL test argL >=s argR --> test argR <=s argL */ return unop(Iop_1Uto32, binop(Iop_CmpLE32S, cc_dep2, cc_dep1)); } if (isU32(cond_n_op, (ARMCondHS << 4) | ARMG_CC_OP_SUB)) { /* HS after SUB --> test argL >=u argR --> test argR <=u argL */ return unop(Iop_1Uto32, binop(Iop_CmpLE32U, cc_dep2, cc_dep1)); } if (isU32(cond_n_op, (ARMCondLO << 4) | ARMG_CC_OP_SUB)) { /* LO after SUB --> test argL test argL <=u argR */ return unop(Iop_1Uto32, binop(Iop_CmpLE32U, cc_dep1, cc_dep2)); } if (isU32(cond_n_op, (ARMCondHI << 4) | ARMG_CC_OP_SUB)) { /* HI after SUB --> test argL >u argR --> test argR oldC ? (argL >=u argR) : (argL >u argR) --> oldC ? (argR <=u argL) : (argR test res == 0 */ return unop(Iop_1Uto32, binop(Iop_CmpEQ32, cc_dep1, mkU32(0))); } if (isU32(cond_n_op, (ARMCondNE << 4) | ARMG_CC_OP_LOGIC)) { /* NE after LOGIC --> test res != 0 */ return unop(Iop_1Uto32, binop(Iop_CmpNE32, cc_dep1, mkU32(0))); } if (isU32(cond_n_op, (ARMCondPL << 4) | ARMG_CC_OP_LOGIC)) { /* PL after LOGIC --> test (res >> 31) == 0 */ return unop(Iop_1Uto32, binop(Iop_CmpEQ32, binop(Iop_Shr32, cc_dep1, mkU8(31)), mkU32(0))); } if (isU32(cond_n_op, (ARMCondMI << 4) | ARMG_CC_OP_LOGIC)) { /* MI after LOGIC --> test (res >> 31) == 1 */ return unop(Iop_1Uto32, binop(Iop_CmpEQ32, binop(Iop_Shr32, cc_dep1, mkU8(31)), mkU32(1))); } /*---------------- COPY ----------------*/ /* --- 0,1 --- */ if (isU32(cond_n_op, (ARMCondEQ << 4) | ARMG_CC_OP_COPY)) { /* EQ after COPY --> (cc_dep1 >> ARMG_CC_SHIFT_Z) & 1 */ return binop(Iop_And32, binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_Z)), mkU32(1)); } if (isU32(cond_n_op, (ARMCondNE << 4) | ARMG_CC_OP_COPY)) { /* NE after COPY --> ((cc_dep1 >> ARMG_CC_SHIFT_Z) ^ 1) & 1 */ return binop(Iop_And32, binop(Iop_Xor32, binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_Z)), mkU32(1)), mkU32(1)); } /* --- 4,5 --- */ if (isU32(cond_n_op, (ARMCondMI << 4) | ARMG_CC_OP_COPY)) { /* MI after COPY --> (cc_dep1 >> ARMG_CC_SHIFT_N) & 1 */ return binop(Iop_And32, binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_N)), mkU32(1)); } if (isU32(cond_n_op, (ARMCondPL << 4) | ARMG_CC_OP_COPY)) { /* PL after COPY --> ((cc_dep1 >> ARMG_CC_SHIFT_N) ^ 1) & 1 */ return binop(Iop_And32, binop(Iop_Xor32, binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_N)), mkU32(1)), mkU32(1)); } /* --- 12,13 --- */ if (isU32(cond_n_op, (ARMCondGT << 4) | ARMG_CC_OP_COPY)) { /* GT after COPY --> ((z | (n^v)) & 1) ^ 1 */ IRExpr* n = binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_N)); IRExpr* v = binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_V)); IRExpr* z = binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_Z)); return binop(Iop_Xor32, binop(Iop_And32, binop(Iop_Or32, z, binop(Iop_Xor32, n, v)), mkU32(1)), mkU32(1)); } if (isU32(cond_n_op, (ARMCondLE << 4) | ARMG_CC_OP_COPY)) { /* LE after COPY --> ((z | (n^v)) & 1) ^ 0 */ IRExpr* n = binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_N)); IRExpr* v = binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_V)); IRExpr* z = binop(Iop_Shr32, cc_dep1, mkU8(ARMG_CC_SHIFT_Z)); return binop(Iop_Xor32, binop(Iop_And32, binop(Iop_Or32, z, binop(Iop_Xor32, n, v)), mkU32(1)), mkU32(0)); } /*----------------- AL -----------------*/ /* A critically important case for Thumb code. What we're trying to spot is the case where cond_n_op is an expression of the form Or32(..., 0xE0) since that means the caller is asking for CondAL and we can simply return 1 without caring what the ... part is. This is a potentially dodgy kludge in that it assumes that the ... part has zeroes in bits 7:4, so that the result of the Or32 is guaranteed to be 0xE in bits 7:4. Given that the places where this first arg are constructed (in guest_arm_toIR.c) are very constrained, we can get away with this. To make this guaranteed safe would require to have a new primop, Slice44 or some such, thusly Slice44(arg1, arg2) = 0--(24)--0 arg1[7:4] arg2[3:0] and we would then look for Slice44(0xE0, ...) which would give the required safety property. It would be infeasibly expensive to scan backwards through the entire block looking for an assignment to the temp, so just look at the previous 16 statements. That should find it if it is an interesting case, as a result of how the boilerplate guff at the start of each Thumb insn translation is made. */ if (cond_n_op->tag == Iex_RdTmp) { Int j; IRTemp look_for = cond_n_op->Iex.RdTmp.tmp; Int limit = n_precedingStmts - 16; if (limit < 0) limit = 0; if (0) vex_printf("scanning %d .. %d\n", n_precedingStmts-1, limit); for (j = n_precedingStmts - 1; j >= limit; j--) { IRStmt* st = precedingStmts[j]; if (st->tag == Ist_WrTmp && st->Ist.WrTmp.tmp == look_for && st->Ist.WrTmp.data->tag == Iex_Binop && st->Ist.WrTmp.data->Iex.Binop.op == Iop_Or32 && isU32(st->Ist.WrTmp.data->Iex.Binop.arg2, (ARMCondAL << 4))) return mkU32(1); } /* Didn't find any useful binding to the first arg in the previous 16 stmts. */ } } /* --------- specialising "armg_calculate_flag_c" --------- */ else if (vex_streq(function_name, "armg_calculate_flag_c")) { /* specialise calls to the "armg_calculate_flag_c" function. Note that the returned value must be either 0 or 1; nonzero bits 31:1 are not allowed. In turn, incoming oldV and oldC values (from the thunk) are assumed to have bits 31:1 clear. */ IRExpr *cc_op, *cc_dep1, *cc_dep2, *cc_ndep; vassert(arity == 4); cc_op = args[0]; /* ARMG_CC_OP_* */ cc_dep1 = args[1]; cc_dep2 = args[2]; cc_ndep = args[3]; if (isU32(cc_op, ARMG_CC_OP_LOGIC)) { /* Thunk args are (result, shco, oldV) */ /* C after LOGIC --> shco */ return cc_dep2; } if (isU32(cc_op, ARMG_CC_OP_SUB)) { /* Thunk args are (argL, argR, unused) */ /* C after SUB --> argL >=u argR --> argR <=u argL */ return unop(Iop_1Uto32, binop(Iop_CmpLE32U, cc_dep2, cc_dep1)); } if (isU32(cc_op, ARMG_CC_OP_SBB)) { /* This happens occasionally in softfloat code, eg __divdf3+140 */ /* thunk is: (dep1=argL, dep2=argR, ndep=oldC) */ /* C after SBB (same as HS after SBB above) --> oldC ? (argL >=u argR) : (argL >u argR) --> oldC ? (argR <=u argL) : (argR oldV */ return cc_ndep; } if (isU32(cc_op, ARMG_CC_OP_SUB)) { /* Thunk args are (argL, argR, unused) */ /* V after SUB --> let res = argL - argR in ((argL ^ argR) & (argL ^ res)) >> 31 --> ((argL ^ argR) & (argL ^ (argL - argR))) >> 31 */ IRExpr* argL = cc_dep1; IRExpr* argR = cc_dep2; return binop(Iop_Shr32, binop(Iop_And32, binop(Iop_Xor32, argL, argR), binop(Iop_Xor32, argL, binop(Iop_Sub32, argL, argR)) ), mkU8(31) ); } if (isU32(cc_op, ARMG_CC_OP_SBB)) { /* This happens occasionally in softfloat code, eg __divdf3+140 */ /* thunk is: (dep1=argL, dep2=argR, ndep=oldC) */ /* V after SBB --> let res = argL - argR - (oldC ^ 1) in (argL ^ argR) & (argL ^ res) & 1 */ return binop( Iop_And32, binop( Iop_And32, // argL ^ argR binop(Iop_Xor32, cc_dep1, cc_dep2), // argL ^ (argL - argR - (oldC ^ 1)) binop(Iop_Xor32, cc_dep1, binop(Iop_Sub32, binop(Iop_Sub32, cc_dep1, cc_dep2), binop(Iop_Xor32, cc_ndep, mkU32(1))) ) ), mkU32(1) ); } } # undef unop # undef binop # undef mkU32 # undef mkU8 return NULL; } /*----------------------------------------------*/ /*--- The exported fns .. ---*/ /*----------------------------------------------*/ /* VISIBLE TO LIBVEX CLIENT */ #if 0 void LibVEX_GuestARM_put_flags ( UInt flags_native, /*OUT*/VexGuestARMState* vex_state ) { vassert(0); // FIXME /* Mask out everything except N Z V C. */ flags_native &= (ARMG_CC_MASK_N | ARMG_CC_MASK_Z | ARMG_CC_MASK_V | ARMG_CC_MASK_C); vex_state->guest_CC_OP = ARMG_CC_OP_COPY; vex_state->guest_CC_DEP1 = flags_native; vex_state->guest_CC_DEP2 = 0; vex_state->guest_CC_NDEP = 0; } #endif /* VISIBLE TO LIBVEX CLIENT */ UInt LibVEX_GuestARM_get_cpsr ( /*IN*/const VexGuestARMState* vex_state ) { UInt cpsr = 0; // NZCV cpsr |= armg_calculate_flags_nzcv( vex_state->guest_CC_OP, vex_state->guest_CC_DEP1, vex_state->guest_CC_DEP2, vex_state->guest_CC_NDEP ); vassert(0 == (cpsr & 0x0FFFFFFF)); // Q if (vex_state->guest_QFLAG32 > 0) cpsr |= (1 << 27); // GE if (vex_state->guest_GEFLAG0 > 0) cpsr |= (1 << 16); if (vex_state->guest_GEFLAG1 > 0) cpsr |= (1 << 17); if (vex_state->guest_GEFLAG2 > 0) cpsr |= (1 << 18); if (vex_state->guest_GEFLAG3 > 0) cpsr |= (1 << 19); // M cpsr |= (1 << 4); // 0b10000 means user-mode // J,T J (bit 24) is zero by initialisation above // T we copy from R15T[0] if (vex_state->guest_R15T & 1) cpsr |= (1 << 5); // ITSTATE we punt on for the time being. Could compute it // if needed though. // E, endianness, 0 (littleendian) from initialisation above // A,I,F disable some async exceptions. Not sure about these. // Leave as zero for the time being. return cpsr; } /* VISIBLE TO LIBVEX CLIENT */ void LibVEX_GuestARM_initialise ( /*OUT*/VexGuestARMState* vex_state ) { vex_state->host_EvC_FAILADDR = 0; vex_state->host_EvC_COUNTER = 0; vex_state->guest_R0 = 0; vex_state->guest_R1 = 0; vex_state->guest_R2 = 0; vex_state->guest_R3 = 0; vex_state->guest_R4 = 0; vex_state->guest_R5 = 0; vex_state->guest_R6 = 0; vex_state->guest_R7 = 0; vex_state->guest_R8 = 0; vex_state->guest_R9 = 0; vex_state->guest_R10 = 0; vex_state->guest_R11 = 0; vex_state->guest_R12 = 0; vex_state->guest_R13 = 0; vex_state->guest_R14 = 0; vex_state->guest_R15T = 0; /* NB: implies ARM mode */ vex_state->guest_CC_OP = ARMG_CC_OP_COPY; vex_state->guest_CC_DEP1 = 0; vex_state->guest_CC_DEP2 = 0; vex_state->guest_CC_NDEP = 0; vex_state->guest_QFLAG32 = 0; vex_state->guest_GEFLAG0 = 0; vex_state->guest_GEFLAG1 = 0; vex_state->guest_GEFLAG2 = 0; vex_state->guest_GEFLAG3 = 0; vex_state->guest_EMNOTE = EmNote_NONE; vex_state->guest_CMSTART = 0; vex_state->guest_CMLEN = 0; vex_state->guest_NRADDR = 0; vex_state->guest_IP_AT_SYSCALL = 0; vex_state->guest_D0 = 0; vex_state->guest_D1 = 0; vex_state->guest_D2 = 0; vex_state->guest_D3 = 0; vex_state->guest_D4 = 0; vex_state->guest_D5 = 0; vex_state->guest_D6 = 0; vex_state->guest_D7 = 0; vex_state->guest_D8 = 0; vex_state->guest_D9 = 0; vex_state->guest_D10 = 0; vex_state->guest_D11 = 0; vex_state->guest_D12 = 0; vex_state->guest_D13 = 0; vex_state->guest_D14 = 0; vex_state->guest_D15 = 0; vex_state->guest_D16 = 0; vex_state->guest_D17 = 0; vex_state->guest_D18 = 0; vex_state->guest_D19 = 0; vex_state->guest_D20 = 0; vex_state->guest_D21 = 0; vex_state->guest_D22 = 0; vex_state->guest_D23 = 0; vex_state->guest_D24 = 0; vex_state->guest_D25 = 0; vex_state->guest_D26 = 0; vex_state->guest_D27 = 0; vex_state->guest_D28 = 0; vex_state->guest_D29 = 0; vex_state->guest_D30 = 0; vex_state->guest_D31 = 0; /* ARM encoded; zero is the default as it happens (result flags (NZCV) cleared, FZ disabled, round to nearest, non-vector mode, all exns masked, all exn sticky bits cleared). */ vex_state->guest_FPSCR = 0; vex_state->guest_TPIDRURO = 0; /* Not in a Thumb IT block. */ vex_state->guest_ITSTATE = 0; vex_state->padding1 = 0; } /*-----------------------------------------------------------*/ /*--- Describing the arm guest state, for the benefit ---*/ /*--- of iropt and instrumenters. ---*/ /*-----------------------------------------------------------*/ /* Figure out if any part of the guest state contained in minoff .. maxoff requires precise memory exceptions. If in doubt return True (but this generates significantly slower code). We enforce precise exns for guest R13(sp), R15T(pc), R7, R11. Only R13(sp) is needed in mode VexRegUpdSpAtMemAccess. */ Bool guest_arm_state_requires_precise_mem_exns ( Int minoff, Int maxoff, VexRegisterUpdates pxControl ) { Int sp_min = offsetof(VexGuestARMState, guest_R13); Int sp_max = sp_min + 4 - 1; Int pc_min = offsetof(VexGuestARMState, guest_R15T); Int pc_max = pc_min + 4 - 1; if (maxoff < sp_min || minoff > sp_max) { /* no overlap with sp */ if (pxControl == VexRegUpdSpAtMemAccess) return False; // We only need to check stack pointer. } else { return True; } if (maxoff < pc_min || minoff > pc_max) { /* no overlap with pc */ } else { return True; } /* We appear to need precise updates of R11 in order to get proper stacktraces from non-optimised code. */ Int r11_min = offsetof(VexGuestARMState, guest_R11); Int r11_max = r11_min + 4 - 1; if (maxoff < r11_min || minoff > r11_max) { /* no overlap with r11 */ } else { return True; } /* Ditto R7, particularly needed for proper stacktraces in Thumb code. */ Int r7_min = offsetof(VexGuestARMState, guest_R7); Int r7_max = r7_min + 4 - 1; if (maxoff < r7_min || minoff > r7_max) { /* no overlap with r7 */ } else { return True; } return False; } #define ALWAYSDEFD(field) \ { offsetof(VexGuestARMState, field), \ (sizeof ((VexGuestARMState*)0)->field) } VexGuestLayout armGuest_layout = { /* Total size of the guest state, in bytes. */ .total_sizeB = sizeof(VexGuestARMState), /* Describe the stack pointer. */ .offset_SP = offsetof(VexGuestARMState,guest_R13), .sizeof_SP = 4, /* Describe the instruction pointer. */ .offset_IP = offsetof(VexGuestARMState,guest_R15T), .sizeof_IP = 4, /* Describe any sections to be regarded by Memcheck as 'always-defined'. */ .n_alwaysDefd = 10, /* flags thunk: OP is always defd, whereas DEP1 and DEP2 have to be tracked. See detailed comment in gdefs.h on meaning of thunk fields. */ .alwaysDefd = { /* 0 */ ALWAYSDEFD(guest_R15T), /* 1 */ ALWAYSDEFD(guest_CC_OP), /* 2 */ ALWAYSDEFD(guest_CC_NDEP), /* 3 */ ALWAYSDEFD(guest_EMNOTE), /* 4 */ ALWAYSDEFD(guest_CMSTART), /* 5 */ ALWAYSDEFD(guest_CMLEN), /* 6 */ ALWAYSDEFD(guest_NRADDR), /* 7 */ ALWAYSDEFD(guest_IP_AT_SYSCALL), /* 8 */ ALWAYSDEFD(guest_TPIDRURO), /* 9 */ ALWAYSDEFD(guest_ITSTATE) } }; /*---------------------------------------------------------------*/ /*--- end guest_arm_helpers.c ---*/ /*---------------------------------------------------------------*/