/* src/vm/jit/allocator/simplereg.c - register allocator Copyright (C) 1996-2005 R. Grafl, A. Krall, C. Kruegel, C. Oates, R. Obermaisser, M. Platter, M. Probst, S. Ring, E. Steiner, C. Thalinger, D. Thuernbeck, P. Tomsich, C. Ullrich, J. Wenninger, Institut f. Computersprachen - TU Wien This file is part of CACAO. 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, 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. Contact: cacao@complang.tuwien.ac.at Authors: Andreas Krall Changes: Stefan Ring Christian Thalinger Christian Ullrich Michael Starzinger Edwin Steiner $Id: simplereg.c 5909 2006-11-05 10:22:37Z edwin $ */ #include "config.h" #include "vm/types.h" #include #include "arch.h" #include "md-abi.h" #include "vm/builtin.h" #include "vm/exceptions.h" #include "mm/memory.h" #include "vm/method.h" #include "vm/options.h" #include "vm/resolve.h" #include "vm/stringlocal.h" #include "vm/jit/reg.h" #include "vm/jit/allocator/simplereg.h" #include "vm/jit/show.h" #if 0 # define LOG(args) printf args #else # define LOG(args) #endif /* function prototypes for this file ******************************************/ static void simplereg_allocate_interfaces(jitdata *jd); static void simplereg_allocate_locals(jitdata *jd); static void simplereg_allocate_temporaries(jitdata *jd); /* total number of registers */ #if defined(HAS_ADDRESS_REGISTER_FILE) #define TOTAL_REG_CNT (INT_REG_CNT + FLT_REG_CNT + ADR_REG_CNT) #else #define TOTAL_REG_CNT (INT_REG_CNT + FLT_REG_CNT) #endif /* macros for handling register stacks ****************************************/ #define AVAIL_FRONT(cnt, limit) ((cnt) < (limit)) #define AVAIL_BACK(cnt) ((cnt) > 0) #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) #define AVAIL_FRONT_INT(cnt, limit) ((cnt) < (limit) - intregsneeded) #define AVAIL_BACK_INT(cnt) ((cnt) > intregsneeded) #else #define AVAIL_FRONT_INT(cnt, limit) AVAIL_FRONT(cnt, limit) #define AVAIL_BACK_INT(cnt) AVAIL_BACK(cnt) #endif #define POP_FRONT(stk, cnt, reg) do { reg = stk[cnt++]; } while (0) #define POP_BACK(stk, cnt, reg) do { reg = stk[--cnt]; } while (0) #define PUSH_FRONT(stk, cnt, reg) do { stk[--cnt] = (reg); } while (0) #define PUSH_BACK(stk, cnt, reg) do { stk[cnt++] = (reg); } while (0) #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) #define POP_FRONT_INT(stk, cnt, reg) \ do { \ if (intregsneeded) { \ reg = PACK_REGS(stk[cnt], stk[cnt+1]); \ cnt += 2; \ } \ else \ POP_FRONT(stk, cnt, reg); \ } while (0) #else #define POP_FRONT_INT(stk, cnt, reg) POP_FRONT(stk, cnt, reg) #endif #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) #define POP_BACK_INT(stk, cnt, reg) \ do { \ if (intregsneeded) { \ cnt -= 2; \ reg = PACK_REGS(stk[cnt], stk[cnt+1]); \ } \ else \ POP_BACK(stk, cnt, reg); \ } while (0) #else #define POP_BACK_INT(stk, cnt, reg) POP_BACK(stk, cnt, reg) #endif #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) #define PUSH_BACK_INT(stk, cnt, reg) \ do { \ if (intregsneeded) { \ stk[cnt] = GET_LOW_REG(reg); \ stk[cnt + 1] = GET_HIGH_REG(reg); \ cnt += 2; \ } \ else \ PUSH_BACK(stk, cnt, reg); \ } while (0) #else #define PUSH_BACK_INT(stk, cnt, reg) PUSH_BACK(stk, cnt, reg) #endif #define AVAIL_ARG_FLT AVAIL_FRONT(rd->argfltreguse, FLT_ARG_CNT) #define AVAIL_TMP_FLT AVAIL_BACK(rd->tmpfltreguse) #define AVAIL_SAV_FLT AVAIL_BACK(rd->savfltreguse) #define AVAIL_ARG_ADR AVAIL_FRONT(rd->argadrreguse, ADR_ARG_CNT) #define AVAIL_TMP_ADR AVAIL_BACK(rd->tmpadrreguse) #define AVAIL_SAV_ADR AVAIL_BACK(rd->savadrreguse) #define AVAIL_ARG_INT AVAIL_FRONT_INT(rd->argintreguse, INT_ARG_CNT) #define AVAIL_TMP_INT AVAIL_BACK_INT(rd->tmpintreguse) #define AVAIL_SAV_INT AVAIL_BACK_INT(rd->savintreguse) #define AVAIL_FREE_ARG_FLT AVAIL_BACK(rd->freeargflttop) #define AVAIL_FREE_TMP_FLT AVAIL_BACK(rd->freetmpflttop) #define AVAIL_FREE_SAV_FLT AVAIL_BACK(rd->freesavflttop) #define AVAIL_FREE_ARG_ADR AVAIL_BACK(rd->freeargadrtop) #define AVAIL_FREE_TMP_ADR AVAIL_BACK(rd->freetmpadrtop) #define AVAIL_FREE_SAV_ADR AVAIL_BACK(rd->freesavadrtop) #define AVAIL_FREE_ARG_INT AVAIL_BACK_INT(rd->freearginttop) #define AVAIL_FREE_TMP_INT AVAIL_BACK_INT(rd->freetmpinttop) #define AVAIL_FREE_SAV_INT AVAIL_BACK_INT(rd->freesavinttop) #define TAKE_ARG_FLT(r) POP_FRONT(rd->argfltregs, rd->argfltreguse, r) #define TAKE_TMP_FLT(r) POP_BACK(rd->tmpfltregs, rd->tmpfltreguse, r) #define TAKE_SAV_FLT(r) POP_BACK(rd->savfltregs, rd->savfltreguse, r) #define TAKE_ARG_ADR(r) POP_FRONT(rd->argadrregs, rd->argadrreguse, r) #define TAKE_TMP_ADR(r) POP_BACK(rd->tmpadrregs, rd->tmpadrreguse, r) #define TAKE_SAV_ADR(r) POP_BACK(rd->savadrregs, rd->savadrreguse, r) #define TAKE_ARG_INT(r) POP_FRONT_INT(rd->argintregs, rd->argintreguse, r) #define TAKE_TMP_INT(r) POP_BACK_INT(rd->tmpintregs, rd->tmpintreguse, r) #define TAKE_SAV_INT(r) POP_BACK_INT(rd->savintregs, rd->savintreguse, r) #define TAKE_FREE_ARG_FLT(r) POP_BACK(rd->freeargfltregs, rd->freeargflttop, r) #define TAKE_FREE_TMP_FLT(r) POP_BACK(rd->freetmpfltregs, rd->freetmpflttop, r) #define TAKE_FREE_SAV_FLT(r) POP_BACK(rd->freesavfltregs, rd->freesavflttop, r) #define TAKE_FREE_ARG_ADR(r) POP_BACK(rd->freeargadrregs, rd->freeargadrtop, r) #define TAKE_FREE_TMP_ADR(r) POP_BACK(rd->freetmpadrregs, rd->freetmpadrtop, r) #define TAKE_FREE_SAV_ADR(r) POP_BACK(rd->freesavadrregs, rd->freesavadrtop, r) #define TAKE_FREE_ARG_INT(r) POP_BACK_INT(rd->freeargintregs, rd->freearginttop, r) #define TAKE_FREE_TMP_INT(r) POP_BACK_INT(rd->freetmpintregs, rd->freetmpinttop, r) #define TAKE_FREE_SAV_INT(r) POP_BACK_INT(rd->freesavintregs, rd->freesavinttop, r) #define PUSH_FREE_ARG_FLT(r) PUSH_BACK(rd->freeargfltregs, rd->freeargflttop, r) #define PUSH_FREE_TMP_FLT(r) PUSH_BACK(rd->freetmpfltregs, rd->freetmpflttop, r) #define PUSH_FREE_SAV_FLT(r) PUSH_BACK(rd->freesavfltregs, rd->freesavflttop, r) #define PUSH_FREE_ARG_ADR(r) PUSH_BACK(rd->freeargadrregs, rd->freeargadrtop, r) #define PUSH_FREE_TMP_ADR(r) PUSH_BACK(rd->freetmpadrregs, rd->freetmpadrtop, r) #define PUSH_FREE_SAV_ADR(r) PUSH_BACK(rd->freesavadrregs, rd->freesavadrtop, r) #define PUSH_FREE_ARG_INT(r) PUSH_BACK_INT(rd->freeargintregs, rd->freearginttop, r) #define PUSH_FREE_TMP_INT(r) PUSH_BACK_INT(rd->freetmpintregs, rd->freetmpinttop, r) #define PUSH_FREE_SAV_INT(r) PUSH_BACK_INT(rd->freesavintregs, rd->freesavinttop, r) /* macros for allocating memory slots ****************************************/ #define NEW_MEM_SLOT(r) \ do { \ (r) = rd->memuse; \ rd->memuse += memneeded + 1; \ } while (0) #define NEW_MEM_SLOT_ALIGNED(r) \ do { \ if ( (memneeded) && (rd->memuse & 1)) \ rd->memuse++; \ (r) = rd->memuse; \ rd->memuse += memneeded + 1; \ } while (0) #define NEW_MEM_SLOT_ALIGNED_REUSE_PADDING(r) \ do { \ if ( (memneeded) && (rd->memuse & 1)) { \ PUSH_BACK(rd->freemem, rd->freememtop, rd->memuse); \ rd->memuse++; \ } \ (r) = rd->memuse; \ rd->memuse += memneeded + 1; \ } while (0) #if defined(ALIGN_LONGS_IN_MEMORY) #define NEW_MEM_SLOT_INT_LNG(r) NEW_MEM_SLOT_ALIGNED(r) #else #define NEW_MEM_SLOT_INT_LNG(r) NEW_MEM_SLOT(r) #endif #if defined(ALIGN_DOUBLES_IN_MEMORY) #define NEW_MEM_SLOT_FLT_DBL(r) NEW_MEM_SLOT_ALIGNED(r) #else #define NEW_MEM_SLOT_FLT_DBL(r) NEW_MEM_SLOT(r) #endif #if defined(ALIGN_LONGS_IN_MEMORY) || defined(ALIGN_DOUBLES_IN_MEMORY) #define NEW_MEM_SLOT_REUSE_PADDING(r) NEW_MEM_SLOT_ALIGNED_REUSE_PADDING(r) #else #define NEW_MEM_SLOT_REUSE_PADDING(r) NEW_MEM_SLOT(r) #endif /* macros for creating/freeing temporary variables ***************************/ #define NEW_TEMP_REG(index) \ if ( ((index) >= jd->localcount) \ && (!(VAR(index)->flags & (INOUT | PREALLOC))) ) \ simplereg_new_temp(jd, (index)) #define FREE_TEMP_REG(index) \ if (((index) > jd->localcount) \ && (!(VAR(index)->flags & (PREALLOC)))) \ simplereg_free_temp(jd, (index)) /* macro for getting a unique register index *********************************/ #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) #define REG_INDEX_NON_ADR(regoff, type) \ (IS_FLT_DBL_TYPE(type) ? (INT_REG_CNT + (regoff)) : (GET_LOW_REG(regoff))) #else #define REG_INDEX_NON_ADR(regoff, type) \ (IS_FLT_DBL_TYPE(type) ? (INT_REG_CNT + (regoff)) : (regoff)) #endif #if defined(HAS_ADDRESS_REGISTER_FILE) #define REG_INDEX(regoff, type) \ (IS_ADR_TYPE(type) ? (regoff) : (ADR_REG_CNT + REG_INDEX_NON_ADR(regoff, type))) #else #define REG_INDEX(regoff, type) REG_INDEX_NON_ADR(regoff, type) #endif /* regalloc ******************************************************************** Does a simple register allocation. *******************************************************************************/ bool regalloc(jitdata *jd) { /* There is a problem with the use of unused float argument registers in leafmethods for stackslots on c7 (2 * Dual Core AMD Opteron(tm) Processor 270) - runtime for the jvm98 _mtrt benchmark is heaviliy increased. This could be prevented by setting rd->argfltreguse to FLT_ARG_CNT before calling simplereg_allocate_temporaries and setting it back to the original value before calling simplereg_allocate_locals. */ simplereg_allocate_interfaces(jd); simplereg_allocate_temporaries(jd); simplereg_allocate_locals(jd); /* everthing's ok */ return true; } /* simplereg_allocate_interfaces *********************************************** Allocates registers for all interface variables. *******************************************************************************/ static void simplereg_allocate_interfaces(jitdata *jd) { methodinfo *m; codegendata *cd; registerdata *rd; int s, t, tt, saved; int intalloc, fltalloc; /* Remember allocated Register/Memory offset */ /* in case more vars are packed into this interface slot */ int memneeded = 0; /* Allocate LNG and DBL types first to ensure 2 memory slots or */ /* registers on HAS_4BYTE_STACKSLOT architectures. */ int typeloop[] = { TYPE_LNG, TYPE_DBL, TYPE_INT, TYPE_FLT, TYPE_ADR }; int flags, regoff; #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) int intregsneeded; #endif /* get required compiler data */ m = jd->m; cd = jd->cd; rd = jd->rd; /* rd->memuse was already set in stack.c to allocate stack space for passing arguments to called methods. */ #if defined(__I386__) if (checksync && (m->flags & ACC_SYNCHRONIZED)) { /* reserve 0(%esp) for Monitorenter/exit Argument on i386 */ if (rd->memuse < 1) rd->memuse = 1; } #endif if (jd->isleafmethod) { /* Reserve argument register, which will be used for Locals acting */ /* as Parameters */ if (rd->argintreguse < m->parseddesc->argintreguse) rd->argintreguse = m->parseddesc->argintreguse; if (rd->argfltreguse < m->parseddesc->argfltreguse) rd->argfltreguse = m->parseddesc->argfltreguse; #ifdef HAS_ADDRESS_REGISTER_FILE if (rd->argadrreguse < m->parseddesc->argadrreguse) rd->argadrreguse = m->parseddesc->argadrreguse; #endif } for (s = 0; s < jd->maxinterfaces; s++) { intalloc = -1; fltalloc = -1; /* check if the interface at this stack depth must be a SAVEDVAR */ saved = 0; for (tt = 0; tt <=4; tt++) { if ((t = jd->interface_map[s * 5 + tt].flags) != UNUSED) { saved |= t & SAVEDVAR; } } /* allocate reg/mem for each type the interface is used as */ for (tt = 0; tt <= 4; tt++) { t = typeloop[tt]; if (jd->interface_map[s * 5 + t].flags == UNUSED) continue; flags = saved; regoff = -1; /* initialize to invalid value */ #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) intregsneeded = (IS_2_WORD_TYPE(t)) ? 1 : 0; #endif #if defined(HAS_4BYTE_STACKSLOT) memneeded = (IS_2_WORD_TYPE(t)) ? 1 : 0; #endif if (!saved) { #if defined(HAS_ADDRESS_REGISTER_FILE) if (IS_ADR_TYPE(t)) { if (!jd->isleafmethod && AVAIL_ARG_ADR) { flags |= ARGREG; TAKE_ARG_ADR(regoff); } else if (AVAIL_TMP_ADR) { TAKE_TMP_ADR(regoff); } else if (AVAIL_SAV_ADR) { flags |= SAVREG; TAKE_SAV_ADR(regoff); } else { flags |= INMEMORY; regoff = rd->memuse++; } } else /* !IS_ADR_TYPE */ #endif /* defined(HAS_ADDRESS_REGISTER_FILE) */ { if (IS_FLT_DBL_TYPE(t)) { if (fltalloc >= 0) { /* Reuse memory slot(s)/register(s) for shared interface slots */ flags |= jd->interface_map[fltalloc].flags & ~SAVEDVAR; regoff = jd->interface_map[fltalloc].regoff; } else if (AVAIL_ARG_FLT) { flags |= ARGREG; TAKE_ARG_FLT(regoff); } else if (AVAIL_TMP_FLT) { TAKE_TMP_FLT(regoff); } else if (AVAIL_SAV_FLT) { flags |= SAVREG; TAKE_SAV_FLT(regoff); } else { flags |= INMEMORY; NEW_MEM_SLOT_FLT_DBL(regoff); } fltalloc = s * 5 + t; } else { /* !IS_FLT_DBL_TYPE(t) */ #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* * for i386 put all longs in memory */ if (IS_2_WORD_TYPE(t)) { flags |= INMEMORY; NEW_MEM_SLOT_INT_LNG(regoff); } else #endif /* defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE...GISTERS) */ if (intalloc >= 0) { /* Reuse memory slot(s)/register(s) for shared interface slots */ flags |= jd->interface_map[intalloc].flags & ~SAVEDVAR; regoff = jd->interface_map[intalloc].regoff; #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* reuse lower half */ if (!(flags & INMEMORY) && IS_2_WORD_TYPE(intalloc % 5)) regoff = GET_LOW_REG(regoff); #endif } else { if (AVAIL_ARG_INT) { flags |= ARGREG; TAKE_ARG_INT(regoff); } else if (AVAIL_TMP_INT) { TAKE_TMP_INT(regoff); } else if (AVAIL_SAV_INT) { flags |= SAVREG; TAKE_SAV_INT(regoff); } else { flags |= INMEMORY; NEW_MEM_SLOT_INT_LNG(regoff); } } intalloc = s * 5 + t; } /* if (IS_FLT_DBL_TYPE(t)) */ } } else { /* (saved) */ /* now the same like above, but without a chance to take a temporary register */ #ifdef HAS_ADDRESS_REGISTER_FILE if (IS_ADR_TYPE(t)) { if (AVAIL_SAV_ADR) { TAKE_SAV_ADR(regoff); } else { flags |= INMEMORY; regoff = rd->memuse++; } } else #endif { if (IS_FLT_DBL_TYPE(t)) { if (fltalloc >= 0) { flags |= jd->interface_map[fltalloc].flags & ~SAVEDVAR; regoff = jd->interface_map[fltalloc].regoff; } else { if (AVAIL_SAV_FLT) { TAKE_SAV_FLT(regoff); } else { flags |= INMEMORY; NEW_MEM_SLOT_FLT_DBL(regoff); } } fltalloc = s * 5 + t; } else { /* IS_INT_LNG */ #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* * for i386 put all longs in memory */ if (IS_2_WORD_TYPE(t)) { flags |= INMEMORY; NEW_MEM_SLOT_INT_LNG(regoff); } else #endif { if (intalloc >= 0) { flags |= jd->interface_map[intalloc].flags & ~SAVEDVAR; regoff = jd->interface_map[intalloc].regoff; #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* reuse lower half */ if (!(flags & INMEMORY) && IS_2_WORD_TYPE(intalloc % 5)) regoff = GET_LOW_REG(regoff); #endif } else { if (AVAIL_SAV_INT) { TAKE_SAV_INT(regoff); } else { flags |= INMEMORY; NEW_MEM_SLOT_INT_LNG(regoff); } } intalloc = s*5 + t; } } /* if (IS_FLT_DBL_TYPE(t) else */ } /* if (IS_ADR_TYPE(t)) else */ } /* if (saved) else */ /* if (type >= 0) */ assert(regoff >= 0); jd->interface_map[5*s + t].flags = flags | INOUT; jd->interface_map[5*s + t].regoff = regoff; } /* for t */ } /* for s */ } /* simplereg_allocate_locals_leafmethod **************************************** Allocates registers for all local variables of a leafmethod. *******************************************************************************/ static void simplereg_allocate_locals_leafmethod(jitdata *jd) { methodinfo *m; codegendata *cd; registerdata *rd; methoddesc *md; int p, s, t, tt, lm; int intalloc, fltalloc; varinfo *v; int intregsneeded = 0; int memneeded = 0; int typeloop[] = { TYPE_LNG, TYPE_DBL, TYPE_INT, TYPE_FLT, TYPE_ADR }; int fargcnt, iargcnt; #ifdef HAS_ADDRESS_REGISTER_FILE int aargcnt; #endif /* get required compiler data */ m = jd->m; cd = jd->cd; rd = jd->rd; md = m->parseddesc; iargcnt = rd->argintreguse; fargcnt = rd->argfltreguse; #ifdef HAS_ADDRESS_REGISTER_FILE aargcnt = rd->argadrreguse; #endif for (p = 0, s = 0; s < cd->maxlocals; s++, p++) { intalloc = -1; fltalloc = -1; for (tt = 0; tt <= 4; tt++) { t = typeloop[tt]; lm = jd->local_map[s * 5 + t]; if (lm == UNUSED) continue; v = VAR(lm); #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) intregsneeded = (IS_2_WORD_TYPE(t)) ? 1 : 0; #endif #if defined(HAS_4BYTE_STACKSLOT) memneeded = (IS_2_WORD_TYPE(t)) ? 1 : 0; #endif /* * The order of * * #ifdef HAS_ADDRESS_REGISTER_FILE * if (IS_ADR_TYPE) { * ... * } else * #endif * if (IS_FLT_DBL) { * ... * } else { / int & lng * ... * } * * must not to be changed! */ #ifdef HAS_ADDRESS_REGISTER_FILE if (IS_ADR_TYPE(t)) { if ((p < md->paramcount) && !md->params[p].inmemory) { v->flags = 0; v->vv.regoff = rd->argadrregs[md->params[p].regoff]; } else if (AVAIL_TMP_ADR) { v->flags = 0; TAKE_TMP_ADR(v->vv.regoff); } /* use unused argument registers as local registers */ else if ((p >= md->paramcount) && (aargcnt < ADR_ARG_CNT)) { v->flags = 0; POP_FRONT(rd->argadrregs, aargcnt, v->vv.regoff); } else if (AVAIL_SAV_ADR) { v->flags = 0; TAKE_SAV_ADR(v->vv.regoff); } else { v->flags |= INMEMORY; v->vv.regoff = rd->memuse++; } } else { #endif if (IS_FLT_DBL_TYPE(t)) { if (fltalloc >= 0) { v->flags = VAR(fltalloc)->flags; v->vv.regoff = VAR(fltalloc)->vv.regoff; } #if !defined(SUPPORT_PASS_FLOATARGS_IN_INTREGS) /* We can only use float arguments as local variables, * if we do not pass them in integer registers. */ else if ((p < md->paramcount) && !md->params[p].inmemory) { v->flags = 0; v->vv.regoff = rd->argfltregs[md->params[p].regoff]; } #endif else if (AVAIL_TMP_FLT) { v->flags = 0; TAKE_TMP_FLT(v->vv.regoff); } /* use unused argument registers as local registers */ else if ((p >= md->paramcount) && (fargcnt < FLT_ARG_CNT)) { v->flags = 0; POP_FRONT(rd->argfltregs, fargcnt, v->vv.regoff); } else if (AVAIL_SAV_FLT) { v->flags = 0; TAKE_SAV_FLT(v->vv.regoff); } else { v->flags = INMEMORY; NEW_MEM_SLOT_FLT_DBL(v->vv.regoff); } fltalloc = jd->local_map[s * 5 + t]; } else { #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* * for i386 put all longs in memory */ if (IS_2_WORD_TYPE(t)) { v->flags = INMEMORY; NEW_MEM_SLOT_INT_LNG(v->vv.regoff); } else #endif { if (intalloc >= 0) { v->flags = VAR(intalloc)->flags; #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) if (!(v->flags & INMEMORY) && IS_2_WORD_TYPE(VAR(intalloc)->type)) v->vv.regoff = GET_LOW_REG( VAR(intalloc)->vv.regoff); else #endif v->vv.regoff = VAR(intalloc)->vv.regoff; } else if ((p < md->paramcount) && !md->params[p].inmemory) { v->flags = 0; #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) if (IS_2_WORD_TYPE(t)) v->vv.regoff = PACK_REGS( rd->argintregs[GET_LOW_REG(md->params[p].regoff)], rd->argintregs[GET_HIGH_REG(md->params[p].regoff)]); else #endif v->vv.regoff = rd->argintregs[md->params[p].regoff]; } else if (AVAIL_TMP_INT) { v->flags = 0; TAKE_TMP_INT(v->vv.regoff); } /* * use unused argument registers as local registers */ else if ((p >= m->parseddesc->paramcount) && (iargcnt + intregsneeded < INT_ARG_CNT)) { v->flags = 0; POP_FRONT_INT(rd->argintregs, iargcnt, v->vv.regoff); } else if (AVAIL_SAV_INT) { v->flags = 0; TAKE_SAV_INT(v->vv.regoff); } else { v->flags = INMEMORY; NEW_MEM_SLOT_INT_LNG(v->vv.regoff); } } intalloc = jd->local_map[s * 5 + t]; } #ifdef HAS_ADDRESS_REGISTER_FILE } #endif } /* for (tt=0;...) */ /* If the current parameter is a 2-word type, the next local slot */ /* is skipped. */ if (p < md->paramcount) if (IS_2_WORD_TYPE(md->paramtypes[p].type)) s++; } } /* simplereg_allocate_locals *************************************************** Allocates registers for all local variables. *******************************************************************************/ static void simplereg_allocate_locals(jitdata *jd) { codegendata *cd; registerdata *rd; int s, t, tt, lm; int intalloc, fltalloc; varinfo *v; int memneeded = 0; int typeloop[] = { TYPE_LNG, TYPE_DBL, TYPE_INT, TYPE_FLT, TYPE_ADR }; #ifdef SUPPORT_COMBINE_INTEGER_REGISTERS s4 intregsneeded; #endif /* get required compiler data */ cd = jd->cd; rd = jd->rd; if (jd->isleafmethod) { simplereg_allocate_locals_leafmethod(jd); return; } for (s = 0; s < cd->maxlocals; s++) { intalloc = -1; fltalloc = -1; for (tt=0; tt<=4; tt++) { t = typeloop[tt]; lm = jd->local_map[s * 5 + t]; if (lm == UNUSED) continue; v = VAR(lm); #ifdef SUPPORT_COMBINE_INTEGER_REGISTERS intregsneeded = (IS_2_WORD_TYPE(t)) ? 1 : 0; #endif #if defined(HAS_4BYTE_STACKSLOT) memneeded = (IS_2_WORD_TYPE(t)) ? 1 : 0; #endif #ifdef HAS_ADDRESS_REGISTER_FILE if (IS_ADR_TYPE(t)) { if (AVAIL_SAV_ADR) { v->flags = 0; TAKE_SAV_ADR(v->vv.regoff); } else { v->flags = INMEMORY; v->vv.regoff = rd->memuse++; } } else { #endif if (IS_FLT_DBL_TYPE(t)) { if (fltalloc >= 0) { v->flags = VAR(fltalloc)->flags; v->vv.regoff = VAR(fltalloc)->vv.regoff; } else if (AVAIL_SAV_FLT) { v->flags = 0; TAKE_SAV_FLT(v->vv.regoff); } else { v->flags = INMEMORY; NEW_MEM_SLOT_FLT_DBL(v->vv.regoff); } fltalloc = jd->local_map[s * 5 + t]; } else { #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* * for i386 put all longs in memory */ if (IS_2_WORD_TYPE(t)) { v->flags = INMEMORY; NEW_MEM_SLOT_INT_LNG(v->vv.regoff); } else { #endif if (intalloc >= 0) { v->flags = VAR(intalloc)->flags; #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) if (!(v->flags & INMEMORY) && IS_2_WORD_TYPE(VAR(intalloc)->type)) v->vv.regoff = GET_LOW_REG( VAR(intalloc)->vv.regoff); else #endif v->vv.regoff = VAR(intalloc)->vv.regoff; } else if (AVAIL_SAV_INT) { v->flags = 0; TAKE_SAV_INT(v->vv.regoff); } else { v->flags = INMEMORY; NEW_MEM_SLOT_INT_LNG(v->vv.regoff); } #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) } #endif intalloc = jd->local_map[s * 5 + t]; } #ifdef HAS_ADDRESS_REGISTER_FILE } #endif } } } static void simplereg_init(jitdata *jd, registerdata *rd) { int i; rd->freememtop = 0; #if defined(HAS_4BYTE_STACKSLOT) rd->freememtop_2 = 0; #endif rd->freetmpinttop = 0; rd->freesavinttop = 0; rd->freetmpflttop = 0; rd->freesavflttop = 0; #ifdef HAS_ADDRESS_REGISTER_FILE rd->freetmpadrtop = 0; rd->freesavadrtop = 0; #endif rd->freearginttop = 0; rd->freeargflttop = 0; #ifdef HAS_ADDRESS_REGISTER_FILE rd->freeargadrtop = 0; #endif rd->regisoutvar = DMNEW(int, TOTAL_REG_CNT); rd->regcopycount = DMNEW(int, TOTAL_REG_CNT); MZERO(rd->regcopycount, int, TOTAL_REG_CNT); /* memcopycount is dynamically allocated when needed */ rd->memcopycount = NULL; rd->memcopycountsize = 0; rd->intusedinout = DMNEW(int, INT_REG_CNT); MZERO(rd->intusedinout, int, INT_REG_CNT); rd->fltusedinout = DMNEW(int, FLT_REG_CNT); MZERO(rd->fltusedinout, int, FLT_REG_CNT); /* record the interface registers as used */ for (i=0; iargintreguse; ++i) rd->intusedinout[rd->argintregs[i]] = 1; for (i=rd->tmpintreguse; iintusedinout[rd->tmpintregs[i]] = 1; for (i=rd->savintreguse; iintusedinout[rd->savintregs[i]] = 1; for (i=0; iargfltreguse; ++i) rd->fltusedinout[rd->argfltregs[i]] = 1; for (i=rd->tmpfltreguse; ifltusedinout[rd->tmpfltregs[i]] = 1; for (i=rd->savfltreguse; ifltusedinout[rd->savfltregs[i]] = 1; #ifdef HAS_ADDRESS_REGISTER_FILE rd->adrusedinout = DMNEW(int, ADR_REG_CNT); MZERO(rd->adrusedinout, int, ADR_REG_CNT); for (i=0; iargadrreguse; ++i) rd->adrusedinout[rd->argadrregs[i]] = 1; for (i=rd->tmpadrreguse; iadrusedinout[rd->tmpadrregs[i]] = 1; for (i=rd->savadrreguse; iadrusedinout[rd->savadrregs[i]] = 1; #endif } static void simplereg_init_block(registerdata *rd) { int i; /* remove all interface registers from the free lists */ for (i=0; ifreearginttop; ++i) if (rd->intusedinout[rd->freeargintregs[i]]) { rd->freeargintregs[i--] = rd->freeargintregs[--rd->freearginttop]; } for (i=0; ifreetmpinttop; ++i) if (rd->intusedinout[rd->freetmpintregs[i]]) { rd->freetmpintregs[i--] = rd->freetmpintregs[--rd->freetmpinttop]; } for (i=0; ifreesavinttop; ++i) if (rd->intusedinout[rd->freesavintregs[i]]) { rd->freesavintregs[i--] = rd->freesavintregs[--rd->freesavinttop]; } for (i=0; ifreeargflttop; ++i) if (rd->fltusedinout[rd->freeargfltregs[i]]) { rd->freeargfltregs[i--] = rd->freeargfltregs[--rd->freeargflttop]; } for (i=0; ifreetmpflttop; ++i) if (rd->fltusedinout[rd->freetmpfltregs[i]]) { rd->freetmpfltregs[i--] = rd->freetmpfltregs[--rd->freetmpflttop]; } for (i=0; ifreesavflttop; ++i) if (rd->fltusedinout[rd->freesavfltregs[i]]) { rd->freesavfltregs[i--] = rd->freesavfltregs[--rd->freesavflttop]; } #ifdef HAS_ADDRESS_REGISTER_FILE for (i=0; ifreeargadrtop; ++i) if (rd->adrusedinout[rd->freeargadrregs[i]]) { rd->freeargadrregs[i--] = rd->freeargadrregs[--rd->freeargadrtop]; } for (i=0; ifreetmpadrtop; ++i) if (rd->adrusedinout[rd->freetmpadrregs[i]]) { rd->freetmpadrregs[i--] = rd->freetmpadrregs[--rd->freetmpadrtop]; } for (i=0; ifreesavadrtop; ++i) if (rd->adrusedinout[rd->freesavadrregs[i]]) { rd->freesavadrregs[i--] = rd->freesavadrregs[--rd->freesavadrtop]; } #endif } static void simplereg_new_temp(jitdata *jd, s4 index) { #ifdef SUPPORT_COMBINE_INTEGER_REGISTERS s4 intregsneeded; #endif s4 memneeded; s4 tryagain; registerdata *rd; varinfo *v; rd = jd->rd; v = VAR(index); /* Try to allocate a saved register if there is no temporary one */ /* available. This is what happens during the second run. */ tryagain = (v->flags & SAVEDVAR) ? 1 : 2; #ifdef SUPPORT_COMBINE_INTEGER_REGISTERS intregsneeded = (IS_2_WORD_TYPE(v->type)) ? 1 : 0; #endif #if defined(HAS_4BYTE_STACKSLOT) memneeded = (IS_2_WORD_TYPE(v->type)) ? 1 : 0; #else memneeded = 0; #endif for(; tryagain; --tryagain) { if (tryagain == 1) { if (!(v->flags & SAVEDVAR)) v->flags |= SAVREG; #ifdef HAS_ADDRESS_REGISTER_FILE if (IS_ADR_TYPE(v->type)) { if (AVAIL_FREE_SAV_ADR) { TAKE_FREE_SAV_ADR(v->vv.regoff); return; } else if (AVAIL_SAV_ADR) { TAKE_SAV_ADR(v->vv.regoff); return; } } else #endif { if (IS_FLT_DBL_TYPE(v->type)) { if (AVAIL_FREE_SAV_FLT) { TAKE_FREE_SAV_FLT(v->vv.regoff); return; } else if (AVAIL_SAV_FLT) { TAKE_SAV_FLT(v->vv.regoff); return; } } else { #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* * for i386 put all longs in memory */ if (!IS_2_WORD_TYPE(v->type)) #endif { if (AVAIL_FREE_SAV_INT) { TAKE_FREE_SAV_INT(v->vv.regoff); return; } else if (AVAIL_SAV_INT) { TAKE_SAV_INT(v->vv.regoff); return; } } } } } else { /* tryagain == 2 */ #ifdef HAS_ADDRESS_REGISTER_FILE if (IS_ADR_TYPE(v->type)) { if (AVAIL_FREE_TMP_ADR) { TAKE_FREE_TMP_ADR(v->vv.regoff); return; } else if (AVAIL_TMP_ADR) { TAKE_TMP_ADR(v->vv.regoff); return; } } else #endif { if (IS_FLT_DBL_TYPE(v->type)) { if (AVAIL_FREE_ARG_FLT) { v->flags |= ARGREG; TAKE_FREE_ARG_FLT(v->vv.regoff); return; } else if (AVAIL_ARG_FLT) { v->flags |= ARGREG; TAKE_ARG_FLT(v->vv.regoff); return; } else if (AVAIL_FREE_TMP_FLT) { TAKE_FREE_TMP_FLT(v->vv.regoff); return; } else if (AVAIL_TMP_FLT) { TAKE_TMP_FLT(v->vv.regoff); return; } } else { #if defined(HAS_4BYTE_STACKSLOT) && !defined(SUPPORT_COMBINE_INTEGER_REGISTERS) /* * for i386 put all longs in memory */ if (!IS_2_WORD_TYPE(v->type)) #endif { if (AVAIL_FREE_ARG_INT) { v->flags |= ARGREG; TAKE_FREE_ARG_INT(v->vv.regoff); return; } else if (AVAIL_ARG_INT) { v->flags |= ARGREG; TAKE_ARG_INT(v->vv.regoff); return; } else if (AVAIL_FREE_TMP_INT) { TAKE_FREE_TMP_INT(v->vv.regoff); return; } else if (AVAIL_TMP_INT) { TAKE_TMP_INT(v->vv.regoff); return; } } /* if (!IS_2_WORD_TYPE(s->type)) */ } /* if (IS_FLT_DBL_TYPE(s->type)) */ } /* if (IS_ADR_TYPE(s->type)) */ } /* if (tryagain == 1) else */ } /* for(; tryagain; --tryagain) */ /* spill to memory */ v->flags |= INMEMORY; #if defined(HAS_4BYTE_STACKSLOT) if ((memneeded == 1) && (rd->freememtop_2 > 0)) POP_BACK(rd->freemem_2, rd->freememtop_2, v->vv.regoff); else #endif /*defined(HAS_4BYTE_STACKSLOT) */ if ((memneeded == 0) && (rd->freememtop > 0)) POP_BACK(rd->freemem, rd->freememtop, v->vv.regoff); else NEW_MEM_SLOT_REUSE_PADDING(v->vv.regoff); } static void simplereg_free(registerdata *rd, s4 flags, s4 regoff, s4 type) { /* if this is a copy of another variable, just decrement the copy counter */ /* XXX split reg/mem variables on arm may need special handling here */ if (flags & INMEMORY) { if (flags & INOUT) return; if (regoff < rd->memcopycountsize && rd->memcopycount[regoff]) { rd->memcopycount[regoff]--; return; } } else { s4 regindex; regindex = REG_INDEX(regoff, type); /* do not free interface registers that are needed as outvars */ if (flags & INOUT) { if (rd->regisoutvar[regindex]) { LOG(("DONT FREE f=%02x r=%d t=%d\n", flags, regoff, type)); return; } LOG(("FREEING INVAR f=%02x r=%d t=%d\n", flags, regoff, type)); } if (rd->regcopycount[regindex]) { rd->regcopycount[regindex]--; return; } } if (flags & INMEMORY) { #if defined(HAS_4BYTE_STACKSLOT) if (IS_2_WORD_TYPE(type)) PUSH_BACK(rd->freemem_2, rd->freememtop_2, regoff); else #endif PUSH_BACK(rd->freemem, rd->freememtop, regoff); return; } /* freeing a register */ #ifdef HAS_ADDRESS_REGISTER_FILE if (IS_ADR_TYPE(type)) { if (flags & (SAVEDVAR | SAVREG)) PUSH_FREE_SAV_ADR(regoff); else PUSH_FREE_TMP_ADR(regoff); } #endif else if (IS_FLT_DBL_TYPE(type)) { if (flags & (SAVEDVAR | SAVREG)) PUSH_FREE_SAV_FLT(regoff); else if (flags & ARGREG) PUSH_FREE_ARG_FLT(regoff); else PUSH_FREE_TMP_FLT(regoff); } else { /* IS_INT_LNG_TYPE */ #if defined(SUPPORT_COMBINE_INTEGER_REGISTERS) s4 intregsneeded = (IS_2_WORD_TYPE(type)) ? 1 : 0; #endif if (flags & (SAVEDVAR | SAVREG)) PUSH_FREE_SAV_INT(regoff); else if (flags & ARGREG) PUSH_FREE_ARG_INT(regoff); else PUSH_FREE_TMP_INT(regoff); } } static inline void simplereg_free_temp(jitdata *jd, s4 index) { varinfo *v; v = VAR(index); simplereg_free(jd->rd, v->flags, v->vv.regoff, v->type); } static bool simplereg_alloc_dup(jitdata *jd, s4 srcindex, s4 dstindex) { varinfo *sv; varinfo *dv; /* do not coalesce local variables here */ if (srcindex <= jd->localcount || dstindex <= jd->localcount) return false; sv = VAR(srcindex); dv = VAR(dstindex); /* do not coalesce in/out vars or preallocated variables here */ if ((sv->flags | dv->flags) & (INOUT | PREALLOC)) return false; /* if the source is in memory, we can coalesce in any case */ if (sv->flags & INMEMORY) { dv->flags |= INMEMORY; dv->vv.regoff = sv->vv.regoff; return true; } /* we do not allocate a REG_TMP to a REG_SAV variable */ if ((sv->flags & SAVEDVAR) != (dv->flags & SAVEDVAR)) return false; /* coalesce */ dv->vv.regoff = sv->vv.regoff; dv->flags |= sv->flags & (SAVREG | ARGREG); return true; } /* simplereg_allocate_temporaries ********************************************** Allocate temporary (non-interface, non-local) registers. *******************************************************************************/ static void simplereg_allocate_temporaries(jitdata *jd) { methodinfo *m; registerdata *rd; s4 i; s4 len; instruction *iptr; basicblock *bptr; builtintable_entry *bte; methoddesc *md; s4 *argp; varinfo *v; s4 flags; s4 regoff; s4 type; s4 regindex; /* get required compiler data */ m = jd->m; rd = jd->rd; /* initialize temp registers */ simplereg_init(jd, rd); bptr = jd->basicblocks; while (bptr != NULL) { if (bptr->flags >= BBREACHED) { LOG(("\nallocating block L%03d\n", bptr->nr)); simplereg_init_block(rd); /* assert that all copy counts are zero */ #if !defined(NDEBUG) for (i=0; i < TOTAL_REG_CNT; ++i) assert(rd->regcopycount[i] == 0); #endif /* reset outvar flags */ MZERO(rd->regisoutvar, int, TOTAL_REG_CNT); /* set allocation of invars */ for (i=0; iindepth; ++i) { v = VAR(bptr->invars[i]); v->vv.regoff = jd->interface_map[5*i + v->type].regoff; v->flags = jd->interface_map[5*i + v->type].flags; if (!(v->flags & INMEMORY)) rd->regcopycount[REG_INDEX(v->vv.regoff, v->type)] = 1; } /* set allocation of outvars */ for (i=0; ioutdepth; ++i) { v = VAR(bptr->outvars[i]); v->vv.regoff = jd->interface_map[5*i + v->type].regoff; v->flags = jd->interface_map[5*i + v->type].flags; if (!(v->flags & INMEMORY)) { regindex = REG_INDEX(v->vv.regoff, v->type); rd->regcopycount[regindex] = 1; rd->regisoutvar[regindex] = 1; } } /* free interface registers not used in this block */ for (i=0; i < 5 * jd->maxinterfaces; ++i) { type = i%5; regoff = jd->interface_map[i].regoff; flags = jd->interface_map[i].flags; if (!(flags & INMEMORY)) { if (!rd->regcopycount[REG_INDEX(regoff, type)]) { LOG(("MAY REUSE interface register f=%02x r=%d t=%d\n", flags, regoff, type)); simplereg_free(rd, flags, regoff, type); /* mark it, so it is not freed again */ rd->regcopycount[REG_INDEX(regoff, type)] = -1; } } } /* reset copy counts */ MZERO(rd->regcopycount, int, TOTAL_REG_CNT); /* iterate over ICMDS to allocate temporary variables */ iptr = bptr->iinstr; len = bptr->icount; while (--len >= 0) { switch (iptr->opc) { /* pop 0 push 0 */ case ICMD_JSR: #if !defined(NDEBUG) /* avoid problems with show_allocation */ VAROP(iptr->dst)->vv.regoff = 0; #endif case ICMD_NOP: case ICMD_CHECKNULL: case ICMD_IINC: case ICMD_RET: case ICMD_RETURN: case ICMD_GOTO: case ICMD_PUTSTATICCONST: case ICMD_INLINE_START: case ICMD_INLINE_END: case ICMD_INLINE_GOTO: break; /* pop 0 push 1 const */ case ICMD_ICONST: case ICMD_LCONST: case ICMD_FCONST: case ICMD_DCONST: case ICMD_ACONST: /* pop 0 push 1 load */ case ICMD_ILOAD: case ICMD_LLOAD: case ICMD_FLOAD: case ICMD_DLOAD: case ICMD_ALOAD: NEW_TEMP_REG(iptr->dst.varindex); break; /* pop 2 push 1 */ case ICMD_IALOAD: case ICMD_LALOAD: case ICMD_FALOAD: case ICMD_DALOAD: case ICMD_AALOAD: case ICMD_BALOAD: case ICMD_CALOAD: case ICMD_SALOAD: FREE_TEMP_REG(iptr->sx.s23.s2.varindex); FREE_TEMP_REG(iptr->s1.varindex); NEW_TEMP_REG(iptr->dst.varindex); break; /* pop 3 push 0 */ case ICMD_IASTORE: case ICMD_LASTORE: case ICMD_FASTORE: case ICMD_DASTORE: case ICMD_AASTORE: case ICMD_BASTORE: case ICMD_CASTORE: case ICMD_SASTORE: FREE_TEMP_REG(iptr->sx.s23.s3.varindex); FREE_TEMP_REG(iptr->sx.s23.s2.varindex); FREE_TEMP_REG(iptr->s1.varindex); break; /* pop 1 push 0 store */ case ICMD_ISTORE: case ICMD_LSTORE: case ICMD_FSTORE: case ICMD_DSTORE: case ICMD_ASTORE: /* pop 1 push 0 */ case ICMD_POP: case ICMD_IRETURN: case ICMD_LRETURN: case ICMD_FRETURN: case ICMD_DRETURN: case ICMD_ARETURN: case ICMD_ATHROW: case ICMD_PUTSTATIC: case ICMD_PUTFIELDCONST: /* pop 1 push 0 branch */ case ICMD_IFNULL: case ICMD_IFNONNULL: case ICMD_IFEQ: case ICMD_IFNE: case ICMD_IFLT: case ICMD_IFGE: case ICMD_IFGT: case ICMD_IFLE: case ICMD_IF_LEQ: case ICMD_IF_LNE: case ICMD_IF_LLT: case ICMD_IF_LGE: case ICMD_IF_LGT: case ICMD_IF_LLE: /* pop 1 push 0 table branch */ case ICMD_TABLESWITCH: case ICMD_LOOKUPSWITCH: case ICMD_MONITORENTER: case ICMD_MONITOREXIT: FREE_TEMP_REG(iptr->s1.varindex); break; /* pop 2 push 0 branch */ case ICMD_IF_ICMPEQ: case ICMD_IF_ICMPNE: case ICMD_IF_ICMPLT: case ICMD_IF_ICMPGE: case ICMD_IF_ICMPGT: case ICMD_IF_ICMPLE: case ICMD_IF_LCMPEQ: case ICMD_IF_LCMPNE: case ICMD_IF_LCMPLT: case ICMD_IF_LCMPGE: case ICMD_IF_LCMPGT: case ICMD_IF_LCMPLE: case ICMD_IF_FCMPEQ: case ICMD_IF_FCMPNE: case ICMD_IF_FCMPL_LT: case ICMD_IF_FCMPL_GE: case ICMD_IF_FCMPL_GT: case ICMD_IF_FCMPL_LE: case ICMD_IF_FCMPG_LT: case ICMD_IF_FCMPG_GE: case ICMD_IF_FCMPG_GT: case ICMD_IF_FCMPG_LE: case ICMD_IF_DCMPEQ: case ICMD_IF_DCMPNE: case ICMD_IF_DCMPL_LT: case ICMD_IF_DCMPL_GE: case ICMD_IF_DCMPL_GT: case ICMD_IF_DCMPL_LE: case ICMD_IF_DCMPG_LT: case ICMD_IF_DCMPG_GE: case ICMD_IF_DCMPG_GT: case ICMD_IF_DCMPG_LE: case ICMD_IF_ACMPEQ: case ICMD_IF_ACMPNE: /* pop 2 push 0 */ case ICMD_POP2: case ICMD_PUTFIELD: case ICMD_IASTORECONST: case ICMD_LASTORECONST: case ICMD_AASTORECONST: case ICMD_BASTORECONST: case ICMD_CASTORECONST: case ICMD_SASTORECONST: FREE_TEMP_REG(iptr->sx.s23.s2.varindex); FREE_TEMP_REG(iptr->s1.varindex); break; /* pop 0 push 1 copy */ case ICMD_COPY: /* src === dst->prev (identical Stackslot Element) */ /* src --> dst (copied value, take same reg/mem) */ if (!simplereg_alloc_dup(jd, iptr->s1.varindex, iptr->dst.varindex)) { NEW_TEMP_REG(iptr->dst.varindex); } else { v = VAROP(iptr->dst); if (v->flags & INMEMORY) { if (v->vv.regoff >= rd->memcopycountsize) { int newsize = (v->vv.regoff + 1) * 2; i = rd->memcopycountsize; rd->memcopycount = DMREALLOC(rd->memcopycount, int, i, newsize); MZERO(rd->memcopycount + i, int, newsize - i); rd->memcopycountsize = newsize; } rd->memcopycount[v->vv.regoff]++; } else { /* XXX split reg/mem variables on arm may need special handling here */ s4 regindex = REG_INDEX(v->vv.regoff, v->type); rd->regcopycount[regindex]++; } } break; /* pop 1 push 1 move */ case ICMD_MOVE: if (!simplereg_alloc_dup(jd, iptr->s1.varindex, iptr->dst.varindex)) { NEW_TEMP_REG(iptr->dst.varindex); FREE_TEMP_REG(iptr->s1.varindex); } break; /* pop 2 push 1 */ case ICMD_IADD: case ICMD_ISUB: case ICMD_IMUL: case ICMD_IDIV: case ICMD_IREM: case ICMD_ISHL: case ICMD_ISHR: case ICMD_IUSHR: case ICMD_IAND: case ICMD_IOR: case ICMD_IXOR: case ICMD_LADD: case ICMD_LSUB: case ICMD_LMUL: case ICMD_LDIV: case ICMD_LREM: case ICMD_LOR: case ICMD_LAND: case ICMD_LXOR: case ICMD_LSHL: case ICMD_LSHR: case ICMD_LUSHR: case ICMD_FADD: case ICMD_FSUB: case ICMD_FMUL: case ICMD_FDIV: case ICMD_FREM: case ICMD_DADD: case ICMD_DSUB: case ICMD_DMUL: case ICMD_DDIV: case ICMD_DREM: case ICMD_LCMP: case ICMD_FCMPL: case ICMD_FCMPG: case ICMD_DCMPL: case ICMD_DCMPG: FREE_TEMP_REG(iptr->sx.s23.s2.varindex); FREE_TEMP_REG(iptr->s1.varindex); NEW_TEMP_REG(iptr->dst.varindex); break; /* pop 1 push 1 */ case ICMD_IADDCONST: case ICMD_ISUBCONST: case ICMD_IMULCONST: case ICMD_IMULPOW2: case ICMD_IDIVPOW2: case ICMD_IREMPOW2: case ICMD_IANDCONST: case ICMD_IORCONST: case ICMD_IXORCONST: case ICMD_ISHLCONST: case ICMD_ISHRCONST: case ICMD_IUSHRCONST: case ICMD_LADDCONST: case ICMD_LSUBCONST: case ICMD_LMULCONST: case ICMD_LMULPOW2: case ICMD_LDIVPOW2: case ICMD_LREMPOW2: case ICMD_LANDCONST: case ICMD_LORCONST: case ICMD_LXORCONST: case ICMD_LSHLCONST: case ICMD_LSHRCONST: case ICMD_LUSHRCONST: case ICMD_INEG: case ICMD_INT2BYTE: case ICMD_INT2CHAR: case ICMD_INT2SHORT: case ICMD_LNEG: case ICMD_FNEG: case ICMD_DNEG: case ICMD_I2L: case ICMD_I2F: case ICMD_I2D: case ICMD_L2I: case ICMD_L2F: case ICMD_L2D: case ICMD_F2I: case ICMD_F2L: case ICMD_F2D: case ICMD_D2I: case ICMD_D2L: case ICMD_D2F: case ICMD_CHECKCAST: case ICMD_ARRAYLENGTH: case ICMD_INSTANCEOF: case ICMD_NEWARRAY: case ICMD_ANEWARRAY: case ICMD_GETFIELD: FREE_TEMP_REG(iptr->s1.varindex); NEW_TEMP_REG(iptr->dst.varindex); break; /* pop 0 push 1 */ case ICMD_GETSTATIC: case ICMD_NEW: NEW_TEMP_REG(iptr->dst.varindex); break; /* pop many push any */ case ICMD_INVOKESTATIC: case ICMD_INVOKESPECIAL: case ICMD_INVOKEVIRTUAL: case ICMD_INVOKEINTERFACE: INSTRUCTION_GET_METHODDESC(iptr,md); i = md->paramcount; argp = iptr->sx.s23.s2.args; while (--i >= 0) { FREE_TEMP_REG(*argp); argp++; } if (md->returntype.type != TYPE_VOID) NEW_TEMP_REG(iptr->dst.varindex); break; case ICMD_BUILTIN: bte = iptr->sx.s23.s3.bte; md = bte->md; i = md->paramcount; argp = iptr->sx.s23.s2.args; while (--i >= 0) { FREE_TEMP_REG(*argp); argp++; } if (md->returntype.type != TYPE_VOID) NEW_TEMP_REG(iptr->dst.varindex); break; case ICMD_MULTIANEWARRAY: i = iptr->s1.argcount; argp = iptr->sx.s23.s2.args; while (--i >= 0) { FREE_TEMP_REG(*argp); argp++; } NEW_TEMP_REG(iptr->dst.varindex); break; default: *exceptionptr = new_internalerror("Unknown ICMD %d during register allocation", iptr->opc); return; } /* switch */ iptr++; } /* while instructions */ } /* if */ bptr = bptr->next; } /* while blocks */ } #if defined(ENABLE_STATISTICS) void simplereg_make_statistics(jitdata *jd) { methodinfo *m; codegendata *cd; registerdata *rd; int i,type; s4 len; stackptr src, src_old; stackptr dst; instruction *iptr; basicblock *bptr; int size_interface; /* == maximum size of in/out stack at basic block boundaries */ bool in_register; varinfo *var; /* get required compiler data */ m = jd->m; cd = jd->cd; rd = jd->rd; in_register = true; size_interface = 0; /* count how many local variables are held in memory or register */ for(i=0; i < jd->localcount; i++) { if (VAR(i)->flags & INMEMORY) { count_locals_spilled++; in_register=false; } else { count_locals_register++; } } /* count how many stack slots are held in memory or register */ bptr = jd->basicblocks; while (bptr != NULL) { if (bptr->flags >= BBREACHED) { #if defined(ENABLE_LSRA) || defined(ENABLE_SSA) if (!opt_lsra) { #endif /* check for memory moves from interface to BB instack */ len = bptr->indepth; if (len > size_interface) size_interface = len; while (len) { len--; var = VAR(bptr->invars[len]); /* invars statistics (currently none) */ } /* check for memory moves from BB outstack to interface */ len = bptr->outdepth; if (len > size_interface) size_interface = len; while (len) { len--; var = VAR(bptr->outvars[len]); /* outvars statistics (currently none) */ } #if defined(ENABLE_LSRA) || defined(ENABLE_SSA) } #endif #if 0 dst = bptr->instack; iptr = bptr->iinstr; len = bptr->icount; src_old = NULL; while (--len >= 0) { src = dst; dst = iptr->dst.var; if ((src!= NULL) && (src != src_old)) { /* new stackslot */ switch (src->varkind) { case TEMPVAR: case STACKVAR: if (!(src->flags & INMEMORY)) count_ss_register++; else { count_ss_spilled++; in_register=false; } break; /* case LOCALVAR: */ /* if (!(rd->locals[src->varnum][src->type].flags & INMEMORY)) */ /* count_ss_register++; */ /* else */ /* count_ss_spilled++; */ /* break; */ case ARGVAR: if (!(src->flags & INMEMORY)) count_argument_mem_ss++; else count_argument_reg_ss++; break; /* if (IS_FLT_DBL_TYPE(src->type)) { */ /* if (src->varnum < FLT_ARG_CNT) { */ /* count_ss_register++; */ /* break; */ /* } */ /* } else { */ /* #if defined(__POWERPC__) */ /* if (src->varnum < INT_ARG_CNT - (IS_2_WORD_TYPE(src->type) != 0)) { */ /* #else */ /* if (src->varnum < INT_ARG_CNT) { */ /* #endif */ /* count_ss_register++; */ /* break; */ /* } */ /* } */ /* count_ss_spilled++; */ /* break; */ } } src_old = src; iptr++; } /* while instructions */ #endif } /* if */ bptr = bptr->next; } /* while blocks */ count_interface_size += size_interface; /* accummulate the size of the interface (between bb boundaries) */ if (in_register) count_method_in_register++; if (in_register) { /* printf("INREGISTER: %s%s%s\n",m->class->name->text, m->name->text, m->descriptor->text); */ } } #endif /* defined(ENABLE_STATISTICS) */ /* * These are local overrides for various environment variables in Emacs. * Please do not remove this and leave it at the end of the file, where * Emacs will automagically detect them. * --------------------------------------------------------------------- * Local variables: * mode: c * indent-tabs-mode: t * c-basic-offset: 4 * tab-width: 4 * End: * vim:noexpandtab:sw=4:ts=4: */