/*---------------------------------------------------------------*/ /*--- begin host_generic_regs.c ---*/ /*---------------------------------------------------------------*/ /* This file is part of Valgrind, a dynamic binary instrumentation framework. Copyright (C) 2004-2010 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. Neither the names of the U.S. Department of Energy nor the University of California nor the names of its contributors may be used to endorse or promote products derived from this software without prior written permission. */ #include "libvex_basictypes.h" #include "libvex.h" #include "main_util.h" #include "host_generic_regs.h" void ppHRegClass ( HRegClass hrc ) { switch (hrc) { case HRcInt32: vex_printf("HRcInt32"); break; case HRcInt64: vex_printf("HRcInt64"); break; case HRcFlt32: vex_printf("HRcFlt32"); break; case HRcFlt64: vex_printf("HRcFlt64"); break; case HRcVec64: vex_printf("HRcVec64"); break; case HRcVec128: vex_printf("HRcVec128"); break; default: vpanic("ppHRegClass"); } } /* Generic printing for registers. */ void ppHReg ( HReg r ) { HChar* maybe_v = hregIsVirtual(r) ? "v" : ""; Int regNo = hregNumber(r); switch (hregClass(r)) { case HRcInt32: vex_printf("%%%sr%d", maybe_v, regNo); return; case HRcInt64: vex_printf("%%%sR%d", maybe_v, regNo); return; case HRcFlt32: vex_printf("%%%sF%d", maybe_v, regNo); return; case HRcFlt64: vex_printf("%%%sD%d", maybe_v, regNo); return; case HRcVec64: vex_printf("%%%sv%d", maybe_v, regNo); return; case HRcVec128: vex_printf("%%%sV%d", maybe_v, regNo); return; default: vpanic("ppHReg"); } } /*---------------------------------------------------------*/ /*--- Helpers for recording reg usage (for reg-alloc) ---*/ /*---------------------------------------------------------*/ void ppHRegUsage ( HRegUsage* tab ) { Int i; HChar* str; vex_printf("HRegUsage {\n"); for (i = 0; i < tab->n_used; i++) { switch (tab->mode[i]) { case HRmRead: str = "Read "; break; case HRmWrite: str = "Write "; break; case HRmModify: str = "Modify "; break; default: vpanic("ppHRegUsage"); } vex_printf(" %s ", str); ppHReg(tab->hreg[i]); vex_printf("\n"); } vex_printf("}\n"); } /* Add a register to a usage table. Combine incoming read uses with existing write uses into a modify use, and vice versa. Do not create duplicate entries -- each reg should only be mentioned once. */ void addHRegUse ( HRegUsage* tab, HRegMode mode, HReg reg ) { Int i; /* Find it ... */ for (i = 0; i < tab->n_used; i++) if (tab->hreg[i] == reg) break; if (i == tab->n_used) { /* Not found, add new entry. */ vassert(tab->n_used < N_HREG_USAGE); tab->hreg[tab->n_used] = reg; tab->mode[tab->n_used] = mode; tab->n_used++; } else { /* Found: combine or ignore. */ /* This is a greatest-lower-bound operation in the poset: R W \ / M Need to do: tab->mode[i] = GLB(tab->mode, mode). In this case very simple -- if tab->mode[i] != mode then result must be M. */ if (tab->mode[i] == mode) { /* duplicate, ignore */ } else { tab->mode[i] = HRmModify; } } } /*---------------------------------------------------------*/ /*--- Indicating register remappings (for reg-alloc) ---*/ /*---------------------------------------------------------*/ void ppHRegRemap ( HRegRemap* map ) { Int i; vex_printf("HRegRemap {\n"); for (i = 0; i < map->n_used; i++) { vex_printf(" "); ppHReg(map->orig[i]); vex_printf(" --> "); ppHReg(map->replacement[i]); vex_printf("\n"); } vex_printf("}\n"); } void initHRegRemap ( HRegRemap* map ) { map->n_used = 0; } void addToHRegRemap ( HRegRemap* map, HReg orig, HReg replacement ) { Int i; for (i = 0; i < map->n_used; i++) if (map->orig[i] == orig) vpanic("addToHRegMap: duplicate entry"); if (!hregIsVirtual(orig)) vpanic("addToHRegMap: orig is not a vreg"); if (hregIsVirtual(replacement)) vpanic("addToHRegMap: replacement is not a vreg"); vassert(map->n_used+1 < N_HREG_REMAP); map->orig[map->n_used] = orig; map->replacement[map->n_used] = replacement; map->n_used++; } HReg lookupHRegRemap ( HRegRemap* map, HReg orig ) { Int i; if (!hregIsVirtual(orig)) return orig; for (i = 0; i < map->n_used; i++) if (map->orig[i] == orig) return map->replacement[i]; vpanic("lookupHRegRemap: not found"); } /*---------------------------------------------------------*/ /*--- Abstract instructions ---*/ /*---------------------------------------------------------*/ HInstrArray* newHInstrArray ( void ) { HInstrArray* ha = LibVEX_Alloc(sizeof(HInstrArray)); ha->arr_size = 4; ha->arr_used = 0; ha->arr = LibVEX_Alloc(ha->arr_size * sizeof(HInstr*)); ha->n_vregs = 0; return ha; } void addHInstr ( HInstrArray* ha, HInstr* instr ) { vassert(ha->arr_used <= ha->arr_size); if (ha->arr_used < ha->arr_size) { ha->arr[ha->arr_used] = instr; ha->arr_used++; } else { Int i; HInstr** arr2 = LibVEX_Alloc(ha->arr_size * 2 * sizeof(HInstr*)); for (i = 0; i < ha->arr_size; i++) arr2[i] = ha->arr[i]; ha->arr_size *= 2; ha->arr = arr2; addHInstr(ha, instr); } } /*---------------------------------------------------------------*/ /*--- end host_generic_regs.c ---*/ /*---------------------------------------------------------------*/