/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Mupen64plus/PCSX - assem_arm.c * * Copyright (C) 2009-2011 Ari64 * * Copyright (C) 2010-2021 GraÅžvydas "notaz" Ignotas * * * * 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. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ #include // ffs #define FLAGLESS #include "../gte.h" #undef FLAGLESS #include "../gte_arm.h" #include "../gte_neon.h" #include "pcnt.h" #include "arm_features.h" #ifdef TC_WRITE_OFFSET #error "not implemented" #endif #ifdef DRC_DBG #pragma GCC diagnostic ignored "-Wunused-function" #pragma GCC diagnostic ignored "-Wunused-variable" #pragma GCC diagnostic ignored "-Wunused-but-set-variable" #endif void indirect_jump_indexed(); void indirect_jump(); void do_interrupt(); void jump_vaddr_r0(); void jump_vaddr_r1(); void jump_vaddr_r2(); void jump_vaddr_r3(); void jump_vaddr_r4(); void jump_vaddr_r5(); void jump_vaddr_r6(); void jump_vaddr_r7(); void jump_vaddr_r8(); void jump_vaddr_r9(); void jump_vaddr_r10(); void jump_vaddr_r12(); void * const jump_vaddr_reg[16] = { jump_vaddr_r0, jump_vaddr_r1, jump_vaddr_r2, jump_vaddr_r3, jump_vaddr_r4, jump_vaddr_r5, jump_vaddr_r6, jump_vaddr_r7, jump_vaddr_r8, jump_vaddr_r9, jump_vaddr_r10, 0, jump_vaddr_r12, 0, 0, 0 }; void invalidate_addr_r0(); void invalidate_addr_r1(); void invalidate_addr_r2(); void invalidate_addr_r3(); void invalidate_addr_r4(); void invalidate_addr_r5(); void invalidate_addr_r6(); void invalidate_addr_r7(); void invalidate_addr_r8(); void invalidate_addr_r9(); void invalidate_addr_r10(); void invalidate_addr_r12(); const void *invalidate_addr_reg[16] = { invalidate_addr_r0, invalidate_addr_r1, invalidate_addr_r2, invalidate_addr_r3, invalidate_addr_r4, invalidate_addr_r5, invalidate_addr_r6, invalidate_addr_r7, invalidate_addr_r8, invalidate_addr_r9, invalidate_addr_r10, 0, invalidate_addr_r12, 0, 0, 0 }; /* Linker */ static void set_jump_target_far1(u_int *insn, void *target) { u_int ni = *insn & 0xff000000; ni |= (((u_int)target - (u_int)insn - 8u) << 6) >> 8; assert((ni & 0x0e000000) == 0x0a000000); *insn = ni; } static void set_jump_target(void *addr, void *target_) { const u_int target = (u_int)target_; const u_char *ptr = addr; u_int *ptr2 = (u_int *)ptr; if(ptr[3]==0xe2) { assert((target-(u_int)ptr2-8)<1024); assert(((uintptr_t)addr&3)==0); assert((target&3)==0); *ptr2=(*ptr2&0xFFFFF000)|((target-(u_int)ptr2-8)>>2)|0xF00; //printf("target=%x addr=%p insn=%x\n",target,addr,*ptr2); } else if(ptr[3]==0x72) { // generated by emit_jno_unlikely if((target-(u_int)ptr2-8)<1024) { assert(((uintptr_t)addr&3)==0); assert((target&3)==0); *ptr2=(*ptr2&0xFFFFF000)|((target-(u_int)ptr2-8)>>2)|0xF00; } else if((target-(u_int)ptr2-8)<4096&&!((target-(u_int)ptr2-8)&15)) { assert(((uintptr_t)addr&3)==0); assert((target&3)==0); *ptr2=(*ptr2&0xFFFFF000)|((target-(u_int)ptr2-8)>>4)|0xE00; } else *ptr2=(0x7A000000)|(((target-(u_int)ptr2-8)<<6)>>8); } else { set_jump_target_far1(ptr2, target_); } } /* Literal pool */ static void add_literal(int addr,int val) { assert(literalcountregmap[n]==reg) { dirty=(cur->dirty>>n)&1; cur->regmap[n]=-1; } } assert(n == hr || cur->regmap[hr] < 0 || !((cur->noevict >> hr) & 1)); cur->regmap[hr] = reg; cur->dirty &= ~(1 << hr); cur->dirty |= dirty << hr; cur->isconst &= ~(1u << hr); cur->noevict |= 1u << hr; } // Alloc cycle count into dedicated register static void alloc_cc(struct regstat *cur, int i) { alloc_arm_reg(cur, i, CCREG, HOST_CCREG); } static void alloc_cc_optional(struct regstat *cur, int i) { if (cur->regmap[HOST_CCREG] < 0) { alloc_arm_reg(cur, i, CCREG, HOST_CCREG); cur->noevict &= ~(1u << HOST_CCREG); } } /* Assembler */ static attr_unused char regname[16][4] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "fp", "r12", "sp", "lr", "pc"}; static void output_w32(u_int word) { *((u_int *)out)=word; out+=4; } static u_int rd_rn_rm(u_int rd, u_int rn, u_int rm) { assert(rd<16); assert(rn<16); assert(rm<16); return((rn<<16)|(rd<<12)|rm); } static u_int rd_rn_imm_shift(u_int rd, u_int rn, u_int imm, u_int shift) { assert(rd<16); assert(rn<16); assert(imm<256); assert((shift&1)==0); return((rn<<16)|(rd<<12)|(((32-shift)&30)<<7)|imm); } static u_int genimm(u_int imm,u_int *encoded) { *encoded=0; if(imm==0) return 1; int i=32; while(i>0) { if(imm<256) { *encoded=((i&30)<<7)|imm; return 1; } imm=(imm>>2)|(imm<<30);i-=2; } return 0; } static void genimm_checked(u_int imm,u_int *encoded) { u_int ret=genimm(imm,encoded); assert(ret); (void)ret; } static u_int genjmp(u_int addr) { if (addr < 3) return 0; // a branch that will be patched later int offset = addr-(int)out-8; if (offset < -33554432 || offset >= 33554432) { SysPrintf("genjmp: out of range: %08x\n", offset); abort(); return 0; } return ((u_int)offset>>2)&0xffffff; } static attr_unused void emit_breakpoint(void) { assem_debug("bkpt #0\n"); //output_w32(0xe1200070); output_w32(0xe7f001f0); } static void emit_mov(int rs,int rt) { assem_debug("mov %s,%s\n",regname[rt],regname[rs]); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)); } static void emit_movs(int rs,int rt) { assem_debug("movs %s,%s\n",regname[rt],regname[rs]); output_w32(0xe1b00000|rd_rn_rm(rt,0,rs)); } static void emit_add(int rs1,int rs2,int rt) { assem_debug("add %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0800000|rd_rn_rm(rt,rs1,rs2)); } static void emit_adds(int rs1,int rs2,int rt) { assem_debug("adds %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0900000|rd_rn_rm(rt,rs1,rs2)); } #define emit_adds_ptr emit_adds static void emit_adcs(int rs1,int rs2,int rt) { assem_debug("adcs %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0b00000|rd_rn_rm(rt,rs1,rs2)); } static void emit_neg(int rs, int rt) { assem_debug("rsb %s,%s,#0\n",regname[rt],regname[rs]); output_w32(0xe2600000|rd_rn_rm(rt,rs,0)); } static void emit_negs(int rs, int rt) { assem_debug("rsbs %s,%s,#0\n",regname[rt],regname[rs]); output_w32(0xe2700000|rd_rn_rm(rt,rs,0)); } static void emit_sub(int rs1,int rs2,int rt) { assem_debug("sub %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0400000|rd_rn_rm(rt,rs1,rs2)); } static void emit_subs(int rs1,int rs2,int rt) { assem_debug("subs %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0500000|rd_rn_rm(rt,rs1,rs2)); } static void emit_zeroreg(int rt) { assem_debug("mov %s,#0\n",regname[rt]); output_w32(0xe3a00000|rd_rn_rm(rt,0,0)); } static void emit_loadlp(u_int imm,u_int rt) { add_literal((int)out,imm); assem_debug("ldr %s,pc+? [=%x]\n",regname[rt],imm); output_w32(0xe5900000|rd_rn_rm(rt,15,0)); } #ifdef HAVE_ARMV7 static void emit_movw(u_int imm,u_int rt) { assert(imm<65536); assem_debug("movw %s,#%d (0x%x)\n",regname[rt],imm,imm); output_w32(0xe3000000|rd_rn_rm(rt,0,0)|(imm&0xfff)|((imm<<4)&0xf0000)); } static void emit_movt(u_int imm,u_int rt) { assem_debug("movt %s,#%d (0x%x)\n",regname[rt],imm&0xffff0000,imm&0xffff0000); output_w32(0xe3400000|rd_rn_rm(rt,0,0)|((imm>>16)&0xfff)|((imm>>12)&0xf0000)); } #endif static void emit_movimm(u_int imm,u_int rt) { u_int armval; if(genimm(imm,&armval)) { assem_debug("mov %s,#%d\n",regname[rt],imm); output_w32(0xe3a00000|rd_rn_rm(rt,0,0)|armval); }else if(genimm(~imm,&armval)) { assem_debug("mvn %s,#%d\n",regname[rt],imm); output_w32(0xe3e00000|rd_rn_rm(rt,0,0)|armval); }else if(imm<65536) { #ifndef HAVE_ARMV7 assem_debug("mov %s,#%d\n",regname[rt],imm&0xFF00); output_w32(0xe3a00000|rd_rn_imm_shift(rt,0,imm>>8,8)); assem_debug("add %s,%s,#%d\n",regname[rt],regname[rt],imm&0xFF); output_w32(0xe2800000|rd_rn_imm_shift(rt,rt,imm&0xff,0)); #else emit_movw(imm,rt); #endif }else{ #ifndef HAVE_ARMV7 emit_loadlp(imm,rt); #else emit_movw(imm&0x0000FFFF,rt); emit_movt(imm&0xFFFF0000,rt); #endif } } static void emit_pcreladdr(u_int rt) { assem_debug("add %s,pc,#?\n",regname[rt]); output_w32(0xe2800000|rd_rn_rm(rt,15,0)); } static void emit_loadreg(int r, int hr) { assert(hr != EXCLUDE_REG); if (r == 0) emit_zeroreg(hr); else { void *addr; switch (r) { //case HIREG: addr = &hi; break; //case LOREG: addr = &lo; break; case CCREG: addr = &cycle_count; break; case INVCP: addr = &invc_ptr; break; case ROREG: addr = &ram_offset; break; default: assert(r < 34); addr = &psxRegs.GPR.r[r]; break; } u_int offset = (u_char *)addr - (u_char *)&dynarec_local; assert(offset<4096); assem_debug("ldr %s,fp+%d # r%d\n",regname[hr],offset,r); output_w32(0xe5900000|rd_rn_rm(hr,FP,0)|offset); } } static void emit_storereg(int r, int hr) { assert(hr != EXCLUDE_REG); void *addr; switch (r) { //case HIREG: addr = &hi; break; //case LOREG: addr = &lo; break; case CCREG: addr = &cycle_count; break; default: assert(r < 34u); addr = &psxRegs.GPR.r[r]; break; } uintptr_t offset = (char *)addr - (char *)&dynarec_local; assert(offset < 4096u); assem_debug("str %s,fp+%d # r%d\n",regname[hr],offset,r); output_w32(0xe5800000|rd_rn_rm(hr,FP,0)|offset); } static void emit_test(int rs, int rt) { assem_debug("tst %s,%s\n",regname[rs],regname[rt]); output_w32(0xe1100000|rd_rn_rm(0,rs,rt)); } static void emit_testimm(int rs,int imm) { u_int armval; assem_debug("tst %s,#%d\n",regname[rs],imm); genimm_checked(imm,&armval); output_w32(0xe3100000|rd_rn_rm(0,rs,0)|armval); } static void emit_testeqimm(int rs,int imm) { u_int armval; assem_debug("tsteq %s,$%d\n",regname[rs],imm); genimm_checked(imm,&armval); output_w32(0x03100000|rd_rn_rm(0,rs,0)|armval); } static void emit_not(int rs,int rt) { assem_debug("mvn %s,%s\n",regname[rt],regname[rs]); output_w32(0xe1e00000|rd_rn_rm(rt,0,rs)); } static void emit_mvneq(int rs,int rt) { assem_debug("mvneq %s,%s\n",regname[rt],regname[rs]); output_w32(0x01e00000|rd_rn_rm(rt,0,rs)); } static void emit_and(u_int rs1,u_int rs2,u_int rt) { assem_debug("and %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0000000|rd_rn_rm(rt,rs1,rs2)); } static void emit_or(u_int rs1,u_int rs2,u_int rt) { assem_debug("orr %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe1800000|rd_rn_rm(rt,rs1,rs2)); } static void emit_orrshl_imm(u_int rs,u_int imm,u_int rt) { assert(rs<16); assert(rt<16); assert(imm<32); assem_debug("orr %s,%s,%s,lsl #%d\n",regname[rt],regname[rt],regname[rs],imm); output_w32(0xe1800000|rd_rn_rm(rt,rt,rs)|(imm<<7)); } static void emit_orrshr_imm(u_int rs,u_int imm,u_int rt) { assert(rs<16); assert(rt<16); assert(imm<32); assem_debug("orr %s,%s,%s,lsr #%d\n",regname[rt],regname[rt],regname[rs],imm); output_w32(0xe1800020|rd_rn_rm(rt,rt,rs)|(imm<<7)); } static void emit_xor(u_int rs1,u_int rs2,u_int rt) { assem_debug("eor %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe0200000|rd_rn_rm(rt,rs1,rs2)); } static void emit_xorsar_imm(u_int rs1,u_int rs2,u_int imm,u_int rt) { assem_debug("eor %s,%s,%s,asr #%d\n",regname[rt],regname[rs1],regname[rs2],imm); output_w32(0xe0200040|rd_rn_rm(rt,rs1,rs2)|(imm<<7)); } static void emit_addimm(u_int rs,int imm,u_int rt) { assert(rs<16); assert(rt<16); if(imm!=0) { u_int armval; if(genimm(imm,&armval)) { assem_debug("add %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe2800000|rd_rn_rm(rt,rs,0)|armval); }else if(genimm(-imm,&armval)) { assem_debug("sub %s,%s,#%d\n",regname[rt],regname[rs],-imm); output_w32(0xe2400000|rd_rn_rm(rt,rs,0)|armval); #ifdef HAVE_ARMV7 }else if(rt!=rs&&(u_int)imm<65536) { emit_movw(imm&0x0000ffff,rt); emit_add(rs,rt,rt); }else if(rt!=rs&&(u_int)-imm<65536) { emit_movw(-imm&0x0000ffff,rt); emit_sub(rs,rt,rt); #endif }else if((u_int)-imm<65536) { assem_debug("sub %s,%s,#%d\n",regname[rt],regname[rs],(-imm)&0xFF00); assem_debug("sub %s,%s,#%d\n",regname[rt],regname[rt],(-imm)&0xFF); output_w32(0xe2400000|rd_rn_imm_shift(rt,rs,(-imm)>>8,8)); output_w32(0xe2400000|rd_rn_imm_shift(rt,rt,(-imm)&0xff,0)); }else { do { int shift = (ffs(imm) - 1) & ~1; int imm8 = imm & (0xff << shift); genimm_checked(imm8,&armval); assem_debug("add %s,%s,#0x%x\n",regname[rt],regname[rs],imm8); output_w32(0xe2800000|rd_rn_rm(rt,rs,0)|armval); rs = rt; imm &= ~imm8; } while (imm != 0); } } else if(rs!=rt) emit_mov(rs,rt); } static void emit_addimm_ptr(u_int rs, uintptr_t imm, u_int rt) { emit_addimm(rs, imm, rt); } static void emit_addimm_and_set_flags3(u_int rs, int imm, u_int rt) { assert(imm>-65536&&imm<65536); u_int armval; if (genimm(imm, &armval)) { assem_debug("adds %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe2900000|rd_rn_rm(rt,rs,0)|armval); } else if (genimm(-imm, &armval)) { assem_debug("subs %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe2500000|rd_rn_rm(rt,rs,0)|armval); } else if (rs != rt) { emit_movimm(imm, rt); emit_adds(rs, rt, rt); } else if (imm < 0) { assem_debug("sub %s,%s,#%d\n",regname[rt],regname[rs],(-imm)&0xFF00); assem_debug("subs %s,%s,#%d\n",regname[rt],regname[rt],(-imm)&0xFF); output_w32(0xe2400000|rd_rn_imm_shift(rt,rs,(-imm)>>8,8)); output_w32(0xe2500000|rd_rn_imm_shift(rt,rt,(-imm)&0xff,0)); } else { assem_debug("add %s,%s,#%d\n",regname[rt],regname[rs],imm&0xFF00); assem_debug("adds %s,%s,#%d\n",regname[rt],regname[rt],imm&0xFF); output_w32(0xe2800000|rd_rn_imm_shift(rt,rs,imm>>8,8)); output_w32(0xe2900000|rd_rn_imm_shift(rt,rt,imm&0xff,0)); } } static void emit_addimm_and_set_flags(int imm, u_int rt) { emit_addimm_and_set_flags3(rt, imm, rt); } static void emit_addnop(u_int r) { assert(r<16); assem_debug("add %s,%s,#0 (nop)\n",regname[r],regname[r]); output_w32(0xe2800000|rd_rn_rm(r,r,0)); } static void emit_andimm(int rs,int imm,int rt) { u_int armval; if(imm==0) { emit_zeroreg(rt); }else if(genimm(imm,&armval)) { assem_debug("and %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe2000000|rd_rn_rm(rt,rs,0)|armval); }else if(genimm(~imm,&armval)) { assem_debug("bic %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe3c00000|rd_rn_rm(rt,rs,0)|armval); }else if(imm==65535) { #ifndef HAVE_ARMV6 assem_debug("bic %s,%s,#FF000000\n",regname[rt],regname[rs]); output_w32(0xe3c00000|rd_rn_rm(rt,rs,0)|0x4FF); assem_debug("bic %s,%s,#00FF0000\n",regname[rt],regname[rt]); output_w32(0xe3c00000|rd_rn_rm(rt,rt,0)|0x8FF); #else assem_debug("uxth %s,%s\n",regname[rt],regname[rs]); output_w32(0xe6ff0070|rd_rn_rm(rt,0,rs)); #endif }else{ assert(imm>0&&imm<65535); #ifndef HAVE_ARMV7 assem_debug("mov r14,#%d\n",imm&0xFF00); output_w32(0xe3a00000|rd_rn_imm_shift(HOST_TEMPREG,0,imm>>8,8)); assem_debug("add r14,r14,#%d\n",imm&0xFF); output_w32(0xe2800000|rd_rn_imm_shift(HOST_TEMPREG,HOST_TEMPREG,imm&0xff,0)); #else emit_movw(imm,HOST_TEMPREG); #endif assem_debug("and %s,%s,r14\n",regname[rt],regname[rs]); output_w32(0xe0000000|rd_rn_rm(rt,rs,HOST_TEMPREG)); } } static void emit_orimm(int rs,int imm,int rt) { u_int armval; if(imm==0) { if(rs!=rt) emit_mov(rs,rt); }else if(genimm(imm,&armval)) { assem_debug("orr %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe3800000|rd_rn_rm(rt,rs,0)|armval); }else{ assert(imm>0&&imm<65536); assem_debug("orr %s,%s,#%d\n",regname[rt],regname[rs],imm&0xFF00); assem_debug("orr %s,%s,#%d\n",regname[rt],regname[rs],imm&0xFF); output_w32(0xe3800000|rd_rn_imm_shift(rt,rs,imm>>8,8)); output_w32(0xe3800000|rd_rn_imm_shift(rt,rt,imm&0xff,0)); } } static void emit_xorimm(int rs,int imm,int rt) { u_int armval; if(imm==0) { if(rs!=rt) emit_mov(rs,rt); }else if(genimm(imm,&armval)) { assem_debug("eor %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe2200000|rd_rn_rm(rt,rs,0)|armval); }else{ assert(imm>0&&imm<65536); assem_debug("eor %s,%s,#%d\n",regname[rt],regname[rs],imm&0xFF00); assem_debug("eor %s,%s,#%d\n",regname[rt],regname[rs],imm&0xFF); output_w32(0xe2200000|rd_rn_imm_shift(rt,rs,imm>>8,8)); output_w32(0xe2200000|rd_rn_imm_shift(rt,rt,imm&0xff,0)); } } static void emit_shlimm(int rs,u_int imm,int rt) { assert(imm>0); assert(imm<32); //if(imm==1) ... assem_debug("lsl %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|(imm<<7)); } static void emit_lsls_imm(int rs,int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("lsls %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe1b00000|rd_rn_rm(rt,0,rs)|(imm<<7)); } static attr_unused void emit_lslpls_imm(int rs,int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("lslpls %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0x51b00000|rd_rn_rm(rt,0,rs)|(imm<<7)); } static void emit_shrimm(int rs,u_int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("lsr %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|0x20|(imm<<7)); } static void emit_sarimm(int rs,u_int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("asr %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|0x40|(imm<<7)); } static void emit_rorimm(int rs,u_int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("ror %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|0x60|(imm<<7)); } static void emit_signextend16(int rs,int rt) { #ifndef HAVE_ARMV6 emit_shlimm(rs,16,rt); emit_sarimm(rt,16,rt); #else assem_debug("sxth %s,%s\n",regname[rt],regname[rs]); output_w32(0xe6bf0070|rd_rn_rm(rt,0,rs)); #endif } static void emit_signextend8(int rs,int rt) { #ifndef HAVE_ARMV6 emit_shlimm(rs,24,rt); emit_sarimm(rt,24,rt); #else assem_debug("sxtb %s,%s\n",regname[rt],regname[rs]); output_w32(0xe6af0070|rd_rn_rm(rt,0,rs)); #endif } static void emit_shl(u_int rs,u_int shift,u_int rt) { assert(rs<16); assert(rt<16); assert(shift<16); //if(imm==1) ... assem_debug("lsl %s,%s,%s\n",regname[rt],regname[rs],regname[shift]); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|0x10|(shift<<8)); } static void emit_shr(u_int rs,u_int shift,u_int rt) { assert(rs<16); assert(rt<16); assert(shift<16); assem_debug("lsr %s,%s,%s\n",regname[rt],regname[rs],regname[shift]); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|0x30|(shift<<8)); } static void emit_sar(u_int rs,u_int shift,u_int rt) { assert(rs<16); assert(rt<16); assert(shift<16); assem_debug("asr %s,%s,%s\n",regname[rt],regname[rs],regname[shift]); output_w32(0xe1a00000|rd_rn_rm(rt,0,rs)|0x50|(shift<<8)); } static attr_unused void emit_orrshl(u_int rs,u_int shift,u_int rt) { assert(rs<16); assert(rt<16); assert(shift<16); assem_debug("orr %s,%s,%s,lsl %s\n",regname[rt],regname[rt],regname[rs],regname[shift]); output_w32(0xe1800000|rd_rn_rm(rt,rt,rs)|0x10|(shift<<8)); } static attr_unused void emit_orrshr(u_int rs,u_int shift,u_int rt) { assert(rs<16); assert(rt<16); assert(shift<16); assem_debug("orr %s,%s,%s,lsr %s\n",regname[rt],regname[rt],regname[rs],regname[shift]); output_w32(0xe1800000|rd_rn_rm(rt,rt,rs)|0x30|(shift<<8)); } static void emit_cmpimm(int rs,int imm) { u_int armval; if(genimm(imm,&armval)) { assem_debug("cmp %s,#%d\n",regname[rs],imm); output_w32(0xe3500000|rd_rn_rm(0,rs,0)|armval); }else if(genimm(-imm,&armval)) { assem_debug("cmn %s,#%d\n",regname[rs],imm); output_w32(0xe3700000|rd_rn_rm(0,rs,0)|armval); }else if(imm>0) { assert(imm<65536); emit_movimm(imm,HOST_TEMPREG); assem_debug("cmp %s,r14\n",regname[rs]); output_w32(0xe1500000|rd_rn_rm(0,rs,HOST_TEMPREG)); }else{ assert(imm>-65536); emit_movimm(-imm,HOST_TEMPREG); assem_debug("cmn %s,r14\n",regname[rs]); output_w32(0xe1700000|rd_rn_rm(0,rs,HOST_TEMPREG)); } } static void emit_cmovne_imm(int imm,int rt) { assem_debug("movne %s,#%d\n",regname[rt],imm); u_int armval; genimm_checked(imm,&armval); output_w32(0x13a00000|rd_rn_rm(rt,0,0)|armval); } static void emit_cmovl_imm(int imm,int rt) { assem_debug("movlt %s,#%d\n",regname[rt],imm); u_int armval; genimm_checked(imm,&armval); output_w32(0xb3a00000|rd_rn_rm(rt,0,0)|armval); } static void emit_cmovb_imm(int imm,int rt) { assem_debug("movcc %s,#%d\n",regname[rt],imm); u_int armval; genimm_checked(imm,&armval); output_w32(0x33a00000|rd_rn_rm(rt,0,0)|armval); } static void emit_cmovae_imm(int imm,int rt) { assem_debug("movcs %s,#%d\n",regname[rt],imm); u_int armval; genimm_checked(imm,&armval); output_w32(0x23a00000|rd_rn_rm(rt,0,0)|armval); } static void emit_cmovs_imm(int imm,int rt) { assem_debug("movmi %s,#%d\n",regname[rt],imm); u_int armval; genimm_checked(imm,&armval); output_w32(0x43a00000|rd_rn_rm(rt,0,0)|armval); } static attr_unused void emit_cmovne_reg(int rs,int rt) { assem_debug("movne %s,%s\n",regname[rt],regname[rs]); output_w32(0x11a00000|rd_rn_rm(rt,0,rs)); } static void emit_cmovl_reg(int rs,int rt) { assem_debug("movlt %s,%s\n",regname[rt],regname[rs]); output_w32(0xb1a00000|rd_rn_rm(rt,0,rs)); } static void emit_cmovb_reg(int rs,int rt) { assem_debug("movcc %s,%s\n",regname[rt],regname[rs]); output_w32(0x31a00000|rd_rn_rm(rt,0,rs)); } static void emit_cmovs_reg(int rs,int rt) { assem_debug("movmi %s,%s\n",regname[rt],regname[rs]); output_w32(0x41a00000|rd_rn_rm(rt,0,rs)); } static void emit_slti32(int rs,int imm,int rt) { if(rs!=rt) emit_zeroreg(rt); emit_cmpimm(rs,imm); if(rs==rt) emit_movimm(0,rt); emit_cmovl_imm(1,rt); } static void emit_sltiu32(int rs,int imm,int rt) { if(rs!=rt) emit_zeroreg(rt); emit_cmpimm(rs,imm); if(rs==rt) emit_movimm(0,rt); emit_cmovb_imm(1,rt); } static void emit_cmp(int rs,int rt) { assem_debug("cmp %s,%s\n",regname[rs],regname[rt]); output_w32(0xe1500000|rd_rn_rm(0,rs,rt)); } static void emit_cmpcs(int rs,int rt) { assem_debug("cmpcs %s,%s\n",regname[rs],regname[rt]); output_w32(0x21500000|rd_rn_rm(0,rs,rt)); } static void emit_set_gz32(int rs, int rt) { //assem_debug("set_gz32\n"); emit_cmpimm(rs,1); emit_movimm(1,rt); emit_cmovl_imm(0,rt); } static void emit_set_nz32(int rs, int rt) { //assem_debug("set_nz32\n"); if(rs!=rt) emit_movs(rs,rt); else emit_test(rs,rs); emit_cmovne_imm(1,rt); } static void emit_set_if_less32(int rs1, int rs2, int rt) { //assem_debug("set if less (%%%s,%%%s),%%%s\n",regname[rs1],regname[rs2],regname[rt]); if(rs1!=rt&&rs2!=rt) emit_zeroreg(rt); emit_cmp(rs1,rs2); if(rs1==rt||rs2==rt) emit_movimm(0,rt); emit_cmovl_imm(1,rt); } static void emit_set_if_carry32(int rs1, int rs2, int rt) { //assem_debug("set if carry (%%%s,%%%s),%%%s\n",regname[rs1],regname[rs2],regname[rt]); if(rs1!=rt&&rs2!=rt) emit_zeroreg(rt); emit_cmp(rs1,rs2); if(rs1==rt||rs2==rt) emit_movimm(0,rt); emit_cmovb_imm(1,rt); } static int can_jump_or_call(const void *a) { intptr_t offset = (u_char *)a - out - 8; return (-33554432 <= offset && offset < 33554432); } static void emit_call(const void *a_) { int a = (int)a_; assem_debug("bl %p%s\n", log_addr(a_), func_name(a_)); u_int offset=genjmp(a); output_w32(0xeb000000|offset); } static void emit_jmp(const void *a_) { int a = (int)a_; assem_debug("b %p%s\n", log_addr(a_), func_name(a_)); u_int offset=genjmp(a); output_w32(0xea000000|offset); } static void emit_jne(const void *a_) { int a = (int)a_; assem_debug("bne %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x1a000000|offset); } static void emit_jeq(const void *a_) { int a = (int)a_; assem_debug("beq %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x0a000000|offset); } static void emit_js(const void *a_) { int a = (int)a_; assem_debug("bmi %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x4a000000|offset); } static void emit_jns(const void *a_) { int a = (int)a_; assem_debug("bpl %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x5a000000|offset); } static void emit_jl(const void *a_) { int a = (int)a_; assem_debug("blt %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0xba000000|offset); } static void emit_jge(const void *a_) { int a = (int)a_; assem_debug("bge %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0xaa000000|offset); } static void emit_jo(const void *a_) { int a = (int)a_; assem_debug("bvs %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x6a000000|offset); } static void emit_jno(const void *a_) { int a = (int)a_; assem_debug("bvc %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x7a000000|offset); } static void emit_jc(const void *a_) { int a = (int)a_; assem_debug("bcs %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x2a000000|offset); } static void emit_jcc(const void *a_) { int a = (int)a_; assem_debug("bcc %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x3a000000|offset); } static void *emit_cbz(int rs, const void *a) { void *ret; emit_test(rs, rs); ret = out; emit_jeq(a); return ret; } static attr_unused void emit_callreg(u_int r) { assert(r<15); assem_debug("blx %s\n",regname[r]); output_w32(0xe12fff30|r); } static void emit_jmpreg(u_int r) { assem_debug("mov pc,%s\n",regname[r]); output_w32(0xe1a00000|rd_rn_rm(15,0,r)); } static void emit_ret(void) { emit_jmpreg(14); } static void emit_readword_indexed(int offset, int rs, int rt) { assert(offset>-4096&&offset<4096); assem_debug("ldr %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe5900000|rd_rn_rm(rt,rs,0)|offset); }else{ output_w32(0xe5100000|rd_rn_rm(rt,rs,0)|(-offset)); } } static void emit_readword_dualindexedx4(int rs1, int rs2, int rt) { assem_debug("ldr %s,%s,%s lsl #2\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe7900000|rd_rn_rm(rt,rs1,rs2)|0x100); } #define emit_readptr_dualindexedx_ptrlen emit_readword_dualindexedx4 static void emit_ldr_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldr %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe7900000|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrcc_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrcc %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x37900000|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrb_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrb %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe7d00000|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrccb_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrccb %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x37d00000|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrsb_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrsb %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe19000d0|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrccsb_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrccsb %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x319000d0|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrh_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrh %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe19000b0|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrcch_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrcch %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x319000b0|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrsh_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrsh %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe19000f0|rd_rn_rm(rt,rs1,rs2)); } static void emit_ldrccsh_dualindexed(int rs1, int rs2, int rt) { assem_debug("ldrccsh %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x319000f0|rd_rn_rm(rt,rs1,rs2)); } static void emit_str_dualindexed(int rs1, int rs2, int rt) { assem_debug("str %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe7800000|rd_rn_rm(rt,rs1,rs2)); } static void emit_strb_dualindexed(int rs1, int rs2, int rt) { assem_debug("strb %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe7c00000|rd_rn_rm(rt,rs1,rs2)); } static void emit_strh_dualindexed(int rs1, int rs2, int rt) { assem_debug("strh %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0xe18000b0|rd_rn_rm(rt,rs1,rs2)); } static void emit_movsbl_indexed(int offset, int rs, int rt) { assert(offset>-256&&offset<256); assem_debug("ldrsb %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe1d000d0|rd_rn_rm(rt,rs,0)|((offset<<4)&0xf00)|(offset&0xf)); }else{ output_w32(0xe15000d0|rd_rn_rm(rt,rs,0)|(((-offset)<<4)&0xf00)|((-offset)&0xf)); } } static void emit_movswl_indexed(int offset, int rs, int rt) { assert(offset>-256&&offset<256); assem_debug("ldrsh %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe1d000f0|rd_rn_rm(rt,rs,0)|((offset<<4)&0xf00)|(offset&0xf)); }else{ output_w32(0xe15000f0|rd_rn_rm(rt,rs,0)|(((-offset)<<4)&0xf00)|((-offset)&0xf)); } } static void emit_movzbl_indexed(int offset, int rs, int rt) { assert(offset>-4096&&offset<4096); assem_debug("ldrb %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe5d00000|rd_rn_rm(rt,rs,0)|offset); }else{ output_w32(0xe5500000|rd_rn_rm(rt,rs,0)|(-offset)); } } static void emit_movzwl_indexed(int offset, int rs, int rt) { assert(offset>-256&&offset<256); assem_debug("ldrh %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe1d000b0|rd_rn_rm(rt,rs,0)|((offset<<4)&0xf00)|(offset&0xf)); }else{ output_w32(0xe15000b0|rd_rn_rm(rt,rs,0)|(((-offset)<<4)&0xf00)|((-offset)&0xf)); } } static void emit_ldrd(int offset, int rs, int rt) { assert(offset>-256&&offset<256); assem_debug("ldrd %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe1c000d0|rd_rn_rm(rt,rs,0)|((offset<<4)&0xf00)|(offset&0xf)); }else{ output_w32(0xe14000d0|rd_rn_rm(rt,rs,0)|(((-offset)<<4)&0xf00)|((-offset)&0xf)); } } static void emit_readword(void *addr, int rt) { uintptr_t offset = (u_char *)addr - (u_char *)&dynarec_local; assert(offset<4096); assem_debug("ldr %s,fp+%#x%s\n", regname[rt], offset, fpofs_name(offset)); output_w32(0xe5900000|rd_rn_rm(rt,FP,0)|offset); } #define emit_readptr emit_readword static void emit_writeword_indexed(int rt, int offset, int rs) { assert(offset>-4096&&offset<4096); assem_debug("str %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe5800000|rd_rn_rm(rt,rs,0)|offset); }else{ output_w32(0xe5000000|rd_rn_rm(rt,rs,0)|(-offset)); } } static void emit_writehword_indexed(int rt, int offset, int rs) { assert(offset>-256&&offset<256); assem_debug("strh %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe1c000b0|rd_rn_rm(rt,rs,0)|((offset<<4)&0xf00)|(offset&0xf)); }else{ output_w32(0xe14000b0|rd_rn_rm(rt,rs,0)|(((-offset)<<4)&0xf00)|((-offset)&0xf)); } } static void emit_writebyte_indexed(int rt, int offset, int rs) { assert(offset>-4096&&offset<4096); assem_debug("strb %s,%s+%d\n",regname[rt],regname[rs],offset); if(offset>=0) { output_w32(0xe5c00000|rd_rn_rm(rt,rs,0)|offset); }else{ output_w32(0xe5400000|rd_rn_rm(rt,rs,0)|(-offset)); } } static void emit_strcc_dualindexed(int rs1, int rs2, int rt) { assem_debug("strcc %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x37800000|rd_rn_rm(rt,rs1,rs2)); } static void emit_strccb_dualindexed(int rs1, int rs2, int rt) { assem_debug("strccb %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x37c00000|rd_rn_rm(rt,rs1,rs2)); } static void emit_strcch_dualindexed(int rs1, int rs2, int rt) { assem_debug("strcch %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x318000b0|rd_rn_rm(rt,rs1,rs2)); } static void emit_writeword(int rt, void *addr) { uintptr_t offset = (u_char *)addr - (u_char *)&dynarec_local; assert(offset<4096); assem_debug("str %s,fp+%#x%s\n", regname[rt], offset, fpofs_name(offset)); output_w32(0xe5800000|rd_rn_rm(rt,FP,0)|offset); } static void emit_umull(u_int rs1, u_int rs2, u_int hi, u_int lo) { assem_debug("umull %s, %s, %s, %s\n",regname[lo],regname[hi],regname[rs1],regname[rs2]); assert(rs1<16); assert(rs2<16); assert(hi<16); assert(lo<16); output_w32(0xe0800090|(hi<<16)|(lo<<12)|(rs2<<8)|rs1); } static void emit_smull(u_int rs1, u_int rs2, u_int hi, u_int lo) { assem_debug("smull %s, %s, %s, %s\n",regname[lo],regname[hi],regname[rs1],regname[rs2]); assert(rs1<16); assert(rs2<16); assert(hi<16); assert(lo<16); output_w32(0xe0c00090|(hi<<16)|(lo<<12)|(rs2<<8)|rs1); } static void emit_clz(int rs,int rt) { assem_debug("clz %s,%s\n",regname[rt],regname[rs]); output_w32(0xe16f0f10|rd_rn_rm(rt,0,rs)); } static void emit_subcs(int rs1,int rs2,int rt) { assem_debug("subcs %s,%s,%s\n",regname[rt],regname[rs1],regname[rs2]); output_w32(0x20400000|rd_rn_rm(rt,rs1,rs2)); } static void emit_shrcc_imm(int rs,u_int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("lsrcc %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0x31a00000|rd_rn_rm(rt,0,rs)|0x20|(imm<<7)); } static void emit_shrne_imm(int rs,u_int imm,int rt) { assert(imm>0); assert(imm<32); assem_debug("lsrne %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0x11a00000|rd_rn_rm(rt,0,rs)|0x20|(imm<<7)); } static void emit_negmi(int rs, int rt) { assem_debug("rsbmi %s,%s,#0\n",regname[rt],regname[rs]); output_w32(0x42600000|rd_rn_rm(rt,rs,0)); } static void emit_negsmi(int rs, int rt) { assem_debug("rsbsmi %s,%s,#0\n",regname[rt],regname[rs]); output_w32(0x42700000|rd_rn_rm(rt,rs,0)); } static void emit_bic_lsl(u_int rs1,u_int rs2,u_int shift,u_int rt) { assem_debug("bic %s,%s,%s lsl %s\n",regname[rt],regname[rs1],regname[rs2],regname[shift]); output_w32(0xe1C00000|rd_rn_rm(rt,rs1,rs2)|0x10|(shift<<8)); } static void emit_bic_lsr(u_int rs1,u_int rs2,u_int shift,u_int rt) { assem_debug("bic %s,%s,%s lsr %s\n",regname[rt],regname[rs1],regname[rs2],regname[shift]); output_w32(0xe1C00000|rd_rn_rm(rt,rs1,rs2)|0x30|(shift<<8)); } static void emit_teq(int rs, int rt) { assem_debug("teq %s,%s\n",regname[rs],regname[rt]); output_w32(0xe1300000|rd_rn_rm(0,rs,rt)); } static attr_unused void emit_rsbimm(int rs, int imm, int rt) { u_int armval; genimm_checked(imm,&armval); assem_debug("rsb %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0xe2600000|rd_rn_rm(rt,rs,0)|armval); } // Conditionally select one of two immediates, optimizing for small code size // This will only be called if HAVE_CMOV_IMM is defined static void emit_cmov2imm_e_ne_compact(int imm1,int imm2,u_int rt) { u_int armval; if(genimm(imm2-imm1,&armval)) { emit_movimm(imm1,rt); assem_debug("addne %s,%s,#%d\n",regname[rt],regname[rt],imm2-imm1); output_w32(0x12800000|rd_rn_rm(rt,rt,0)|armval); }else if(genimm(imm1-imm2,&armval)) { emit_movimm(imm1,rt); assem_debug("subne %s,%s,#%d\n",regname[rt],regname[rt],imm1-imm2); output_w32(0x12400000|rd_rn_rm(rt,rt,0)|armval); } else { #ifndef HAVE_ARMV7 emit_movimm(imm1,rt); add_literal((int)out,imm2); assem_debug("ldrne %s,pc+? [=%x]\n",regname[rt],imm2); output_w32(0x15900000|rd_rn_rm(rt,15,0)); #else emit_movw(imm1&0x0000FFFF,rt); if((imm1&0xFFFF)!=(imm2&0xFFFF)) { assem_debug("movwne %s,#%d (0x%x)\n",regname[rt],imm2&0xFFFF,imm2&0xFFFF); output_w32(0x13000000|rd_rn_rm(rt,0,0)|(imm2&0xfff)|((imm2<<4)&0xf0000)); } emit_movt(imm1&0xFFFF0000,rt); if((imm1&0xFFFF0000)!=(imm2&0xFFFF0000)) { assem_debug("movtne %s,#%d (0x%x)\n",regname[rt],imm2&0xffff0000,imm2&0xffff0000); output_w32(0x13400000|rd_rn_rm(rt,0,0)|((imm2>>16)&0xfff)|((imm2>>12)&0xf0000)); } #endif } } // special case for checking invalid_code static void emit_ldrb_indexedsr12_reg(int base, int r, int rt) { assem_debug("ldrb %s,%s,%s lsr #12\n",regname[rt],regname[base],regname[r]); output_w32(0xe7d00000|rd_rn_rm(rt,base,r)|0x620); } static void emit_callne(const void *a_) { int a = (int)a_; assem_debug("blne %p\n", log_addr(a_)); u_int offset=genjmp(a); output_w32(0x1b000000|offset); } // Used to preload hash table entries static attr_unused void emit_prefetchreg(int r) { assem_debug("pld %s\n",regname[r]); output_w32(0xf5d0f000|rd_rn_rm(0,r,0)); } // Special case for mini_ht static void emit_ldreq_indexed(int rs, u_int offset, int rt) { assert(offset<4096); assem_debug("ldreq %s,[%s, #%d]\n",regname[rt],regname[rs],offset); output_w32(0x05900000|rd_rn_rm(rt,rs,0)|offset); } static void emit_orrne_imm(int rs,int imm,int rt) { u_int armval; genimm_checked(imm,&armval); assem_debug("orrne %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0x13800000|rd_rn_rm(rt,rs,0)|armval); } static attr_unused void emit_addpl_imm(int rs,int imm,int rt) { u_int armval; genimm_checked(imm,&armval); assem_debug("addpl %s,%s,#%d\n",regname[rt],regname[rs],imm); output_w32(0x52800000|rd_rn_rm(rt,rs,0)|armval); } static void emit_jno_unlikely(void *a_) { //emit_jno(a_); assert(a_ == NULL); assem_debug("addvc pc,pc,#? (%p)\n", /*a-(int)out-8,*/ log_addr(a_)); output_w32(0x72800000|rd_rn_rm(15,15,0)); } static void save_regs_all(u_int reglist) { int i; if(!reglist) return; assem_debug("stmia fp,{"); for(i=0;i<16;i++) if(reglist&(1<translation_cache <= addr && addr < ndrc->translation_cache + sizeof(ndrc->translation_cache)); emit_far_jump(dyna_linker); } // from a pointer to external jump stub (which was produced by emit_extjump_stub) // find where the jumping insn is static void *find_extjump_insn(void *stub) { int *ptr=(int *)(stub+4); assert((*ptr&0x0fff0000)==0x059f0000); // ldr rx, [pc, #ofs] u_int offset=*ptr&0xfff; void **l_ptr=(void *)ptr+offset+8; return *l_ptr; } static void check_extjump2(void *src) { u_int *ptr = src; assert((ptr[1] & 0x0fff0000) == 0x059f0000); // ldr rx, [pc, #ofs] (void)ptr; } // put rt_val into rt, potentially making use of rs with value rs_val static void emit_movimm_from(u_int rs_val,int rs,u_int rt_val,int rt) { u_int armval; int diff; if(genimm(rt_val,&armval)) { assem_debug("mov %s,#%d\n",regname[rt],rt_val); output_w32(0xe3a00000|rd_rn_rm(rt,0,0)|armval); return; } if(genimm(~rt_val,&armval)) { assem_debug("mvn %s,#%d\n",regname[rt],rt_val); output_w32(0xe3e00000|rd_rn_rm(rt,0,0)|armval); return; } diff=rt_val-rs_val; if(genimm(diff,&armval)) { assem_debug("add %s,%s,#%d\n",regname[rt],regname[rs],diff); output_w32(0xe2800000|rd_rn_rm(rt,rs,0)|armval); return; }else if(genimm(-diff,&armval)) { assem_debug("sub %s,%s,#%d\n",regname[rt],regname[rs],-diff); output_w32(0xe2400000|rd_rn_rm(rt,rs,0)|armval); return; } emit_movimm(rt_val,rt); } // return 1 if above function can do it's job cheaply static int is_similar_value(u_int v1,u_int v2) { u_int xs; int diff; if(v1==v2) return 1; diff=v2-v1; for(xs=diff;xs!=0&&(xs&3)==0;xs>>=2) ; if(xs<0x100) return 1; for(xs=-diff;xs!=0&&(xs&3)==0;xs>>=2) ; if(xs<0x100) return 1; return 0; } static void mov_loadtype_adj(enum stub_type type,int rs,int rt) { switch(type) { case LOADB_STUB: emit_signextend8(rs,rt); break; case LOADBU_STUB: emit_andimm(rs,0xff,rt); break; case LOADH_STUB: emit_signextend16(rs,rt); break; case LOADHU_STUB: emit_andimm(rs,0xffff,rt); break; case LOADW_STUB: if(rs!=rt) emit_mov(rs,rt); break; default: assert(0); } } #include "pcsxmem.h" #include "pcsxmem_inline.c" static void do_readstub(struct compile_state *st, int n) { assem_debug("do_readstub %x\n", st->start + stubs[n].a*4); literal_pool(256); set_jump_target(stubs[n].addr, out); enum stub_type type=stubs[n].type; int i=stubs[n].a; int rs=stubs[n].b; const struct regstat *i_regs=(struct regstat *)stubs[n].c; u_int reglist=stubs[n].e; const signed char *i_regmap=i_regs->regmap; int rt; if(dops[i].itype==C2LS||dops[i].itype==LOADLR) { rt=get_reg(i_regmap,FTEMP); }else{ rt=get_reg(i_regmap,dops[i].rt1); } assert(rs>=0); int r,temp=-1,temp2=HOST_TEMPREG,regs_saved=0; void *restore_jump = NULL; reglist|=(1<=0&&dops[i].rt1!=0) reglist&=~(1<=0&&dops[i].rt1!=0)) { switch(type) { case LOADB_STUB: emit_ldrccsb_dualindexed(temp2,rs,rt); break; case LOADBU_STUB: emit_ldrccb_dualindexed(temp2,rs,rt); break; case LOADH_STUB: emit_ldrccsh_dualindexed(temp2,rs,rt); break; case LOADHU_STUB: emit_ldrcch_dualindexed(temp2,rs,rt); break; case LOADW_STUB: emit_ldrcc_dualindexed(temp2,rs,rt); break; default: assert(0); } } if(regs_saved) { restore_jump=out; emit_jcc(0); // jump to reg restore } else emit_jcc(stubs[n].retaddr); // return address if(!regs_saved) save_regs(reglist); void *handler=NULL; if(type==LOADB_STUB||type==LOADBU_STUB) handler=jump_handler_read8; if(type==LOADH_STUB||type==LOADHU_STUB) handler=jump_handler_read16; if(type==LOADW_STUB) handler=jump_handler_read32; assert(handler); pass_args(rs,temp2); int cc=get_reg(i_regmap,CCREG); if(cc<0) emit_loadreg(CCREG,2); emit_addimm(cc<0?2:cc,(int)stubs[n].d,2); emit_far_call(handler); #if 0 if (type == LOADW_STUB) { // new cycle_count returned in r2 emit_addimm(2, -(int)stubs[n].d, cc<0?2:cc); if (cc < 0) emit_storereg(CCREG, 2); } #endif if(dops[i].itype==C2LS||(rt>=0&&dops[i].rt1!=0)) { mov_loadtype_adj(type,0,rt); } if(restore_jump) set_jump_target(restore_jump, out); restore_regs(reglist); emit_jmp(stubs[n].retaddr); // return address } static void inline_readstub(enum stub_type type, int i, u_int addr, const signed char regmap[], int target, int adj, u_int reglist) { int ra = cinfo[i].addr; int rt = get_reg(regmap,target); assert(ra >= 0); u_int is_dynamic; uintptr_t host_addr = 0; void *handler; int cc=get_reg(regmap,CCREG); if(pcsx_direct_read(type,addr,adj,cc,target?ra:-1,rt)) return; handler = get_direct_memhandler(mem_rtab, addr, type, &host_addr); if (handler == NULL) { if(rt<0||dops[i].rt1==0) return; if(addr!=host_addr) emit_movimm_from(addr,ra,host_addr,ra); switch(type) { case LOADB_STUB: emit_movsbl_indexed(0,ra,rt); break; case LOADBU_STUB: emit_movzbl_indexed(0,ra,rt); break; case LOADH_STUB: emit_movswl_indexed(0,ra,rt); break; case LOADHU_STUB: emit_movzwl_indexed(0,ra,rt); break; case LOADW_STUB: emit_readword_indexed(0,ra,rt); break; default: assert(0); } return; } is_dynamic=pcsxmem_is_handler_dynamic(addr); if(is_dynamic) { if(type==LOADB_STUB||type==LOADBU_STUB) handler=jump_handler_read8; if(type==LOADH_STUB||type==LOADHU_STUB) handler=jump_handler_read16; if(type==LOADW_STUB) handler=jump_handler_read32; } // call a memhandler if(rt>=0&&dops[i].rt1!=0) reglist&=~(1<>12]<<1,1); emit_addimm(cc<0?2:cc,adj,2); } else { emit_readword(&last_count,3); emit_addimm(cc<0?2:cc,adj,2); emit_add(2,3,2); emit_writeword(2,&psxRegs.cycle); } emit_far_call(handler); #if 0 if (type == LOADW_STUB) { // new cycle_count returned in r2 emit_addimm(2, -adj, cc<0?2:cc); if (cc < 0) emit_storereg(CCREG, 2); } #endif if(rt>=0&&dops[i].rt1!=0) { switch(type) { case LOADB_STUB: emit_signextend8(0,rt); break; case LOADBU_STUB: emit_andimm(0,0xff,rt); break; case LOADH_STUB: emit_signextend16(0,rt); break; case LOADHU_STUB: emit_andimm(0,0xffff,rt); break; case LOADW_STUB: if(rt!=0) emit_mov(0,rt); break; default: assert(0); } } restore_regs(reglist); } static void do_writestub(struct compile_state *st, int n) { assem_debug("do_writestub %x\n", st->start + stubs[n].a*4); literal_pool(256); set_jump_target(stubs[n].addr, out); enum stub_type type=stubs[n].type; int i=stubs[n].a; int rs=stubs[n].b; const struct regstat *i_regs=(struct regstat *)stubs[n].c; u_int reglist=stubs[n].e; const signed char *i_regmap=i_regs->regmap; int rt,r; if(dops[i].itype==C2LS) { rt=get_reg(i_regmap,r=FTEMP); }else{ rt=get_reg(i_regmap,r=dops[i].rs2); } assert(rs>=0); assert(rt>=0); int rtmp,temp=-1,temp2=HOST_TEMPREG,regs_saved=0; void *restore_jump = NULL; int reglist2=reglist|(1<=0); assert(rt>=0); uintptr_t host_addr = 0; void *handler = get_direct_memhandler(mem_wtab, addr, type, &host_addr); if (handler == NULL) { if(addr!=host_addr) emit_movimm_from(addr,ra,host_addr,ra); switch(type) { case STOREB_STUB: emit_writebyte_indexed(rt,0,ra); break; case STOREH_STUB: emit_writehword_indexed(rt,0,ra); break; case STOREW_STUB: emit_writeword_indexed(rt,0,ra); break; default: assert(0); } return; } // call a memhandler save_regs(reglist); pass_args(ra,rt); int cc=get_reg(regmap,CCREG); if(cc<0) emit_loadreg(CCREG,2); emit_addimm(cc<0?2:cc,adj,2); emit_movimm((u_int)handler,3); emit_far_call(jump_handler_write_h); // new cycle_count returned in r2 emit_addimm(2,-adj,cc<0?2:cc); if(cc<0) emit_storereg(CCREG,2); restore_regs(reglist); } /* Special assem */ static void c2op_prologue(struct compile_state *st, u_int op, int i, const struct regstat *i_regs, u_int reglist) { save_regs_all(reglist); cop2_do_stall_check(st, op, i, i_regs, 0); #ifdef PCNT emit_movimm(op, 0); emit_far_call(pcnt_gte_start); #endif emit_addimm(FP, (u_char *)&psxRegs.CP2D.r[0] - (u_char *)&dynarec_local, 0); // cop2 regs } static void c2op_epilogue(u_int op,u_int reglist) { #ifdef PCNT emit_movimm(op,0); emit_far_call(pcnt_gte_end); #endif restore_regs_all(reglist); } static void c2op_call_MACtoIR(int lm,int need_flags) { if(need_flags) emit_far_call(lm?gteMACtoIR_lm1:gteMACtoIR_lm0); else emit_far_call(lm?gteMACtoIR_lm1_nf:gteMACtoIR_lm0_nf); } static void c2op_call_rgb_func(void *func,int lm,int need_ir,int need_flags) { emit_far_call(func); // func is C code and trashes r0 emit_addimm(FP,(int)&psxRegs.CP2D.r[0]-(int)&dynarec_local,0); if(need_flags||need_ir) c2op_call_MACtoIR(lm,need_flags); emit_far_call(need_flags?gteMACtoRGB:gteMACtoRGB_nf); } static void c2op_assemble(struct compile_state *st, int i, const struct regstat *i_regs) { u_int c2op = st->source[i] & 0x3f; u_int reglist_full = get_host_reglist(i_regs->regmap); u_int reglist = reglist_full & CALLER_SAVE_REGS; int need_flags, need_ir; if (gte_handlers[c2op]!=NULL) { need_flags=!(gte_unneeded[i+1]>>63); // +1 because of how liveness detection works need_ir=(gte_unneeded[i+1]&0xe00)!=0xe00; assem_debug("gte op %08x, unneeded %016llx, need_flags %d, need_ir %d\n", st->source[i], gte_unneeded[i+1], need_flags, need_ir); if(HACK_ENABLED(NDHACK_GTE_NO_FLAGS)) need_flags=0; int shift = (st->source[i] >> 19) & 1; int lm = (st->source[i] >> 10) & 1; switch(c2op) { #ifndef DRC_DBG case GTE_MVMVA: { #ifdef HAVE_ARMV5 int v = (st->source[i] >> 15) & 3; int cv = (st->source[i] >> 13) & 3; int mx = (st->source[i] >> 17) & 3; reglist=reglist_full&(CALLER_SAVE_REGS|0xf0); // +{r4-r7} c2op_prologue(st, c2op, i, i_regs, reglist); /* r4,r5 = VXYZ(v) packed; r6 = &MX11(mx); r7 = &CV1(cv) */ if(v<3) emit_ldrd(v*8,0,4); else { emit_movzwl_indexed(9*4,0,4); // gteIR emit_movzwl_indexed(10*4,0,6); emit_movzwl_indexed(11*4,0,5); emit_orrshl_imm(6,16,4); } if(mx<3) emit_addimm(0,32*4+mx*8*4,6); else emit_readword(&zeromem_ptr,6); if(cv<3) emit_addimm(0,32*4+(cv*8+5)*4,7); else emit_readword(&zeromem_ptr,7); #ifdef __ARM_NEON__ emit_movimm(st->source[i],1); // opcode emit_far_call(gteMVMVA_part_neon); if(need_flags) { emit_movimm(lm,1); emit_far_call(gteMACtoIR_flags_neon); } #else if(cv==3&&shift) emit_far_call(gteMVMVA_part_cv3sh12_arm); else { emit_movimm(shift,1); emit_far_call(need_flags?gteMVMVA_part_arm:gteMVMVA_part_nf_arm); } if(need_flags||need_ir) c2op_call_MACtoIR(lm,need_flags); #endif #else /* if not HAVE_ARMV5 */ c2op_prologue(st,c2op,i,i_regs,reglist); emit_movimm(st->source[i],1); // opcode emit_writeword(1,&psxRegs.code); emit_far_call(need_flags?gte_handlers[c2op]:gte_handlers_nf[c2op]); #endif break; } case GTE_OP: c2op_prologue(st,c2op,i,i_regs,reglist); emit_far_call(shift?gteOP_part_shift:gteOP_part_noshift); if(need_flags||need_ir) { emit_addimm(FP,(int)&psxRegs.CP2D.r[0]-(int)&dynarec_local,0); c2op_call_MACtoIR(lm,need_flags); } break; case GTE_DPCS: c2op_prologue(st,c2op,i,i_regs,reglist); c2op_call_rgb_func(shift?gteDPCS_part_shift:gteDPCS_part_noshift,lm,need_ir,need_flags); break; case GTE_INTPL: c2op_prologue(st,c2op,i,i_regs,reglist); c2op_call_rgb_func(shift?gteINTPL_part_shift:gteINTPL_part_noshift,lm,need_ir,need_flags); break; case GTE_SQR: c2op_prologue(st,c2op,i,i_regs,reglist); emit_far_call(shift?gteSQR_part_shift:gteSQR_part_noshift); if(need_flags||need_ir) { emit_addimm(FP,(int)&psxRegs.CP2D.r[0]-(int)&dynarec_local,0); c2op_call_MACtoIR(lm,need_flags); } break; case GTE_DCPL: c2op_prologue(st,c2op,i,i_regs,reglist); c2op_call_rgb_func(gteDCPL_part,lm,need_ir,need_flags); break; case GTE_GPF: c2op_prologue(st,c2op,i,i_regs,reglist); c2op_call_rgb_func(shift?gteGPF_part_shift:gteGPF_part_noshift,lm,need_ir,need_flags); break; case GTE_GPL: c2op_prologue(st,c2op,i,i_regs,reglist); c2op_call_rgb_func(shift?gteGPL_part_shift:gteGPL_part_noshift,lm,need_ir,need_flags); break; #endif default: c2op_prologue(st,c2op,i,i_regs,reglist); #ifdef DRC_DBG emit_movimm(st->source[i],1); // opcode emit_writeword(1,&psxRegs.code); #endif emit_far_call(need_flags?gte_handlers[c2op]:gte_handlers_nf[c2op]); break; } c2op_epilogue(c2op,reglist); } } static void c2op_ctc2_31_assemble(signed char sl, signed char temp) { //value = value & 0x7ffff000; //if (value & 0x7f87e000) value |= 0x80000000; emit_shrimm(sl,12,temp); emit_shlimm(temp,12,temp); emit_testimm(temp,0x7f000000); emit_testeqimm(temp,0x00870000); emit_testeqimm(temp,0x0000e000); emit_orrne_imm(temp,0x80000000,temp); } static void do_mfc2_31_one(u_int copr,signed char temp) { emit_readword(®_cop2d[copr],temp); emit_lsls_imm(temp,16,temp); emit_cmovs_imm(0,temp); emit_cmpimm(temp,0xf80<<16); emit_andimm(temp,0xf80<<16,temp); emit_cmovae_imm(0xf80<<16,temp); } static void c2op_mfc2_29_assemble(signed char tl, signed char temp) { if (temp < 0) { host_tempreg_acquire(); temp = HOST_TEMPREG; } do_mfc2_31_one(9,temp); emit_shrimm(temp,7+16,tl); do_mfc2_31_one(10,temp); emit_orrshr_imm(temp,2+16,tl); do_mfc2_31_one(11,temp); emit_orrshr_imm(temp,-3+16,tl); emit_writeword(tl,®_cop2d[29]); if (temp == HOST_TEMPREG) host_tempreg_release(); } static void multdiv_assemble_arm(int i, const struct regstat *i_regs) { // case 0x18: MULT // case 0x19: MULTU // case 0x1A: DIV // case 0x1B: DIVU if(dops[i].rs1&&dops[i].rs2) { switch (dops[i].opcode2) { case 0x18: // MULT { signed char m1=get_reg(i_regs->regmap,dops[i].rs1); signed char m2=get_reg(i_regs->regmap,dops[i].rs2); signed char hi=get_reg(i_regs->regmap,HIREG); signed char lo=get_reg(i_regs->regmap,LOREG); assert(m1>=0); assert(m2>=0); assert(hi>=0); assert(lo>=0); emit_smull(m1,m2,hi,lo); } break; case 0x19: // MULTU { signed char m1=get_reg(i_regs->regmap,dops[i].rs1); signed char m2=get_reg(i_regs->regmap,dops[i].rs2); signed char hi=get_reg(i_regs->regmap,HIREG); signed char lo=get_reg(i_regs->regmap,LOREG); assert(m1>=0); assert(m2>=0); assert(hi>=0); assert(lo>=0); emit_umull(m1,m2,hi,lo); } break; case 0x1A: // DIV { signed char d1=get_reg(i_regs->regmap,dops[i].rs1); signed char d2=get_reg(i_regs->regmap,dops[i].rs2); signed char quotient=get_reg(i_regs->regmap,LOREG); signed char remainder=get_reg(i_regs->regmap,HIREG); void *jaddr_div0; assert(d1>=0); assert(d2>=0); assert(quotient>=0); assert(remainder>=0); emit_movs(d1,remainder); emit_movimm(0xffffffff,quotient); emit_negmi(quotient,quotient); // .. quotient and .. emit_negmi(remainder,remainder); // .. remainder for div0 case (will be negated back after jump) emit_movs(d2,HOST_TEMPREG); jaddr_div0 = out; emit_jeq(0); // Division by zero emit_negsmi(HOST_TEMPREG,HOST_TEMPREG); #ifdef HAVE_ARMV5 emit_clz(HOST_TEMPREG,quotient); emit_shl(HOST_TEMPREG,quotient,HOST_TEMPREG); // shifted divisor #else emit_movimm(0,quotient); emit_addpl_imm(quotient,1,quotient); emit_lslpls_imm(HOST_TEMPREG,1,HOST_TEMPREG); emit_jns(out-2*4); #endif emit_orimm(quotient,1<<31,quotient); emit_shr(quotient,quotient,quotient); emit_cmp(remainder,HOST_TEMPREG); emit_subcs(remainder,HOST_TEMPREG,remainder); emit_adcs(quotient,quotient,quotient); emit_shrimm(HOST_TEMPREG,1,HOST_TEMPREG); emit_jcc(out-16); // -4 emit_teq(d1,d2); emit_negmi(quotient,quotient); set_jump_target(jaddr_div0, out); emit_test(d1,d1); emit_negmi(remainder,remainder); } break; case 0x1B: // DIVU { signed char d1=get_reg(i_regs->regmap,dops[i].rs1); // dividend signed char d2=get_reg(i_regs->regmap,dops[i].rs2); // divisor signed char quotient=get_reg(i_regs->regmap,LOREG); signed char remainder=get_reg(i_regs->regmap,HIREG); void *jaddr_div0; assert(d1>=0); assert(d2>=0); assert(quotient>=0); assert(remainder>=0); emit_mov(d1,remainder); emit_movimm(0xffffffff,quotient); // div0 case emit_test(d2,d2); jaddr_div0 = out; emit_jeq(0); // Division by zero #ifdef HAVE_ARMV5 emit_clz(d2,HOST_TEMPREG); emit_movimm(1<<31,quotient); emit_shl(d2,HOST_TEMPREG,d2); #else emit_movimm(0,HOST_TEMPREG); emit_addpl_imm(HOST_TEMPREG,1,HOST_TEMPREG); emit_lslpls_imm(d2,1,d2); emit_jns(out-2*4); emit_movimm(1<<31,quotient); #endif emit_shr(quotient,HOST_TEMPREG,quotient); emit_cmp(remainder,d2); emit_subcs(remainder,d2,remainder); emit_adcs(quotient,quotient,quotient); emit_shrcc_imm(d2,1,d2); emit_jcc(out-16); // -4 set_jump_target(jaddr_div0, out); } break; } } else { signed char hr=get_reg(i_regs->regmap,HIREG); signed char lr=get_reg(i_regs->regmap,LOREG); if ((dops[i].opcode2==0x1A || dops[i].opcode2==0x1B) && dops[i].rs2==0) // div 0 { if (dops[i].rs1) { signed char numerator = get_reg(i_regs->regmap, dops[i].rs1); assert(numerator >= 0); if (hr < 0) hr = HOST_TEMPREG; emit_movs(numerator, hr); if (lr >= 0) { if (dops[i].opcode2 == 0x1A) { // DIV emit_movimm(0xffffffff, lr); emit_negmi(lr, lr); } else emit_movimm(~0, lr); } } else { if (hr >= 0) emit_zeroreg(hr); if (lr >= 0) emit_movimm(~0,lr); } } else if ((dops[i].opcode2==0x1A || dops[i].opcode2==0x1B) && dops[i].rs1==0) { signed char denominator = get_reg(i_regs->regmap, dops[i].rs2); assert(denominator >= 0); if (hr >= 0) emit_zeroreg(hr); if (lr >= 0) { emit_zeroreg(lr); emit_test(denominator, denominator); emit_mvneq(lr, lr); } } else { // Multiply by zero is zero. if (hr >= 0) emit_zeroreg(hr); if (lr >= 0) emit_zeroreg(lr); } } } #define multdiv_assemble multdiv_assemble_arm static void do_jump_vaddr(int rs) { emit_far_jump(jump_vaddr_reg[rs]); } static void do_preload_rhash(int r) { // Don't need this for ARM. On x86, this puts the value 0xf8 into the // register. On ARM the hash can be done with a single instruction (below) } static void do_preload_rhtbl(int ht) { emit_addimm(FP,(int)&mini_ht-(int)&dynarec_local,ht); } static void do_rhash(int rs,int rh) { emit_andimm(rs,0xf8,rh); } static void do_miniht_load(int ht,int rh) { assem_debug("ldr %s,[%s,%s]!\n",regname[rh],regname[ht],regname[rh]); output_w32(0xe7b00000|rd_rn_rm(rh,ht,rh)); } static void do_miniht_jump(int rs,int rh,int ht) { emit_cmp(rh,rs); emit_ldreq_indexed(ht,4,15); #ifdef CORTEX_A8_BRANCH_PREDICTION_HACK if(rs!=7) emit_mov(rs,7); rs=7; #endif do_jump_vaddr(rs); } static void do_miniht_insert(struct compile_state *st, u_int return_address, int rt, int temp) { #ifndef HAVE_ARMV7 emit_movimm(return_address,rt); // PC into link register add_to_linker(st, out, return_address, 1); emit_pcreladdr(temp); emit_writeword(rt,&mini_ht[(return_address&0xFF)>>3][0]); emit_writeword(temp,&mini_ht[(return_address&0xFF)>>3][1]); #else emit_movw(return_address&0x0000FFFF,rt); add_to_linker(st, out, return_address, 1); emit_pcreladdr(temp); emit_writeword(temp,&mini_ht[(return_address&0xFF)>>3][1]); emit_movt(return_address&0xFFFF0000,rt); emit_writeword(rt,&mini_ht[(return_address&0xFF)>>3][0]); #endif } // CPU-architecture-specific initialization static void arch_init(void) { uintptr_t diff = (u_char *)&ndrc->tramp.f - (u_char *)&ndrc->tramp.ops - 8; struct tramp_insns *ops = ndrc->tramp.ops; size_t i; assert(!(diff & 3)); assert(diff < 0x1000); start_tcache_write(ops, (u_char *)ops + sizeof(ndrc->tramp.ops)); for (i = 0; i < ARRAY_SIZE(ndrc->tramp.ops); i++) ops[i].ldrpc = 0xe5900000 | rd_rn_rm(15,15,0) | diff; // ldr pc, [=val] end_tcache_write(ops, (u_char *)ops + sizeof(ndrc->tramp.ops), 1); } // vim:shiftwidth=2:expandtab