From b5e65245948647b94dfd60c1288f030a76c69a83 Mon Sep 17 00:00:00 2001 From: bunnei Date: Wed, 10 Sep 2014 21:27:14 -0400 Subject: ARM: Reorganized file structure to move shared SkyEye code to a more common area. Removed s_ prefix --- src/core/arm/skyeye_common/vfp/vfpinstr.cpp | 5123 +++++++++++++++++++++++++++ 1 file changed, 5123 insertions(+) create mode 100644 src/core/arm/skyeye_common/vfp/vfpinstr.cpp (limited to 'src/core/arm/skyeye_common/vfp/vfpinstr.cpp') diff --git a/src/core/arm/skyeye_common/vfp/vfpinstr.cpp b/src/core/arm/skyeye_common/vfp/vfpinstr.cpp new file mode 100644 index 00000000..a5704791 --- /dev/null +++ b/src/core/arm/skyeye_common/vfp/vfpinstr.cpp @@ -0,0 +1,5123 @@ +/* + vfp/vfpinstr.c - ARM VFPv3 emulation unit - Individual instructions data + Copyright (C) 2003 Skyeye Develop Group + for help please send mail to + + 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA +*/ + +/* Notice: this file should not be compiled as is, and is meant to be + included in other files only. */ + +/* ----------------------------------------------------------------------- */ +/* CDP instructions */ +/* cond 1110 opc1 CRn- CRd- copr op20 CRm- CDP */ + +/* ----------------------------------------------------------------------- */ +/* VMLA */ +/* cond 1110 0D00 Vn-- Vd-- 101X N0M0 Vm-- */ +#define vfpinstr vmla +#define vfpinstr_inst vmla_inst +#define VFPLABEL_INST VMLA_INST +#ifdef VFP_DECODE +{"vmla", 4, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x0, 9, 11, 0x5, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmla", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmla_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VMLA :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0 && (OPC_2 & 0x2) == 0) +{ + DBG("VMLA :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int add = (BIT(6) == 0); + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG32(tmp); + mm = FR32(d); + tmp = FPADD(mm,tmp); + //LETS(d,tmp); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + //mm = SITOFP(32,RSPR(m)); + //LETS(d,tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * m))); + nn = ZEXT64(IBITCAST32(FR32(2 * m + 1))); + tmp = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(tmp); + tmp = ZEXT64(IBITCAST32(FR32(2 * n))); + nn = ZEXT64(IBITCAST32(FR32(2 * n + 1))); + nn = OR(SHL(nn,CONST64(32)),tmp); + nn = FPBITCAST64(nn); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG64(tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * d))); + nn = ZEXT64(IBITCAST32(FR32(2 * d + 1))); + mm = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(mm); + tmp = FPADD(mm,tmp); + mm = TRUNC32(LSHR(IBITCAST64(tmp),CONST64(32))); + nn = TRUNC32(AND(IBITCAST64(tmp),CONST64(0xffffffff))); + LETFPS(2*d ,FPBITCAST32(nn)); + LETFPS(d*2 + 1 , FPBITCAST32(mm)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VNMLS */ +/* cond 1110 0D00 Vn-- Vd-- 101X N1M0 Vm-- */ +#define vfpinstr vmls +#define vfpinstr_inst vmls_inst +#define VFPLABEL_INST VMLS_INST +#ifdef VFP_DECODE +{"vmls", 7, ARMVFP2, 28 , 31, 0xF, 25, 27, 0x1, 23, 23, 1, 11, 11, 0, 8, 9, 0x2, 6, 6, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmls", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmls_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VMLS :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0 && (OPC_2 & 0x2) == 2) +{ + DBG("VMLS :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s VMLS instruction is executed out of here.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int add = (BIT(6) == 0); + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG32(tmp); + mm = FR32(d); + tmp = FPADD(mm,tmp); + //LETS(d,tmp); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + //mm = SITOFP(32,RSPR(m)); + //LETS(d,tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * m))); + nn = ZEXT64(IBITCAST32(FR32(2 * m + 1))); + tmp = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(tmp); + tmp = ZEXT64(IBITCAST32(FR32(2 * n))); + nn = ZEXT64(IBITCAST32(FR32(2 * n + 1))); + nn = OR(SHL(nn,CONST64(32)),tmp); + nn = FPBITCAST64(nn); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG64(tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * d))); + nn = ZEXT64(IBITCAST32(FR32(2 * d + 1))); + mm = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(mm); + tmp = FPADD(mm,tmp); + mm = TRUNC32(LSHR(IBITCAST64(tmp),CONST64(32))); + nn = TRUNC32(AND(IBITCAST64(tmp),CONST64(0xffffffff))); + LETFPS(2*d ,FPBITCAST32(nn)); + LETFPS(d*2 + 1 , FPBITCAST32(mm)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VNMLA */ +/* cond 1110 0D01 Vn-- Vd-- 101X N1M0 Vm-- */ +#define vfpinstr vnmla +#define vfpinstr_inst vnmla_inst +#define VFPLABEL_INST VNMLA_INST +#ifdef VFP_DECODE +//{"vnmla", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x0, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +{"vnmla", 4, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x1, 9, 11, 0x5, 4, 4, 0}, +{"vnmla", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x2, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +//{"vnmla", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x2, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vnmla", 0, ARMVFP2, 0}, +{"vnmla", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vnmla_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VNMLA :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 1 && (OPC_2 & 0x2) == 2) +{ + DBG("VNMLA :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s VNMLA instruction is executed out of here.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int add = (BIT(6) == 0); + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG32(tmp); + mm = FR32(d); + tmp = FPADD(FPNEG32(mm),tmp); + //LETS(d,tmp); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + //mm = SITOFP(32,RSPR(m)); + //LETS(d,tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * m))); + nn = ZEXT64(IBITCAST32(FR32(2 * m + 1))); + tmp = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(tmp); + tmp = ZEXT64(IBITCAST32(FR32(2 * n))); + nn = ZEXT64(IBITCAST32(FR32(2 * n + 1))); + nn = OR(SHL(nn,CONST64(32)),tmp); + nn = FPBITCAST64(nn); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG64(tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * d))); + nn = ZEXT64(IBITCAST32(FR32(2 * d + 1))); + mm = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(mm); + tmp = FPADD(FPNEG64(mm),tmp); + mm = TRUNC32(LSHR(IBITCAST64(tmp),CONST64(32))); + nn = TRUNC32(AND(IBITCAST64(tmp),CONST64(0xffffffff))); + LETFPS(2*d ,FPBITCAST32(nn)); + LETFPS(d*2 + 1 , FPBITCAST32(mm)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VNMLS */ +/* cond 1110 0D01 Vn-- Vd-- 101X N0M0 Vm-- */ +#define vfpinstr vnmls +#define vfpinstr_inst vnmls_inst +#define VFPLABEL_INST VNMLS_INST +#ifdef VFP_DECODE +{"vnmls", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x1, 9, 11, 0x5, 6, 6, 0, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vnmls", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vnmls_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VNMLS :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 1 && (OPC_2 & 0x2) == 0) +{ + DBG("VNMLS :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int add = (BIT(6) == 0); + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG32(tmp); + mm = FR32(d); + tmp = FPADD(FPNEG32(mm),tmp); + //LETS(d,tmp); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + //mm = SITOFP(32,RSPR(m)); + //LETS(d,tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * m))); + nn = ZEXT64(IBITCAST32(FR32(2 * m + 1))); + tmp = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(tmp); + tmp = ZEXT64(IBITCAST32(FR32(2 * n))); + nn = ZEXT64(IBITCAST32(FR32(2 * n + 1))); + nn = OR(SHL(nn,CONST64(32)),tmp); + nn = FPBITCAST64(nn); + tmp = FPMUL(nn,mm); + if(!add) + tmp = FPNEG64(tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * d))); + nn = ZEXT64(IBITCAST32(FR32(2 * d + 1))); + mm = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(mm); + tmp = FPADD(FPNEG64(mm),tmp); + mm = TRUNC32(LSHR(IBITCAST64(tmp),CONST64(32))); + nn = TRUNC32(AND(IBITCAST64(tmp),CONST64(0xffffffff))); + LETFPS(2*d ,FPBITCAST32(nn)); + LETFPS(d*2 + 1 , FPBITCAST32(mm)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VNMUL */ +/* cond 1110 0D10 Vn-- Vd-- 101X N0M0 Vm-- */ +#define vfpinstr vnmul +#define vfpinstr_inst vnmul_inst +#define VFPLABEL_INST VNMUL_INST +#ifdef VFP_DECODE +{"vnmul", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x2, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vnmul", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vnmul_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VNMUL :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 2 && (OPC_2 & 0x2) == 2) +{ + DBG("VNMUL :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int add = (BIT(6) == 0); + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPMUL(nn,mm); + //LETS(d,tmp); + LETFPS(d,FPNEG32(tmp)); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + //mm = SITOFP(32,RSPR(m)); + //LETS(d,tmp); + mm = ZEXT64(IBITCAST32(FR32(2 * m))); + nn = ZEXT64(IBITCAST32(FR32(2 * m + 1))); + tmp = OR(SHL(nn,CONST64(32)),mm); + mm = FPBITCAST64(tmp); + tmp = ZEXT64(IBITCAST32(FR32(2 * n))); + nn = ZEXT64(IBITCAST32(FR32(2 * n + 1))); + nn = OR(SHL(nn,CONST64(32)),tmp); + nn = FPBITCAST64(nn); + tmp = FPMUL(nn,mm); + tmp = FPNEG64(tmp); + mm = TRUNC32(LSHR(IBITCAST64(tmp),CONST64(32))); + nn = TRUNC32(AND(IBITCAST64(tmp),CONST64(0xffffffff))); + LETFPS(2*d ,FPBITCAST32(nn)); + LETFPS(d*2 + 1 , FPBITCAST32(mm)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMUL */ +/* cond 1110 0D10 Vn-- Vd-- 101X N0M0 Vm-- */ +#define vfpinstr vmul +#define vfpinstr_inst vmul_inst +#define VFPLABEL_INST VMUL_INST +#ifdef VFP_DECODE +{"vmul", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x2, 9, 11, 0x5, 6, 6, 0, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmul", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmul_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VMUL :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 2 && (OPC_2 & 0x2) == 0) +{ + DBG("VMUL :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //printf("\n\n\t\tin %s instruction is executed out.\n\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + //mm = SITOFP(32,FR(m)); + //nn = SITOFP(32,FRn)); + mm = FR32(m); + nn = FR32(n); + tmp = FPMUL(nn,mm); + //LETS(d,tmp); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + //mm = SITOFP(32,RSPR(m)); + //LETS(d,tmp); + Value *lo = FR32(2 * m); + Value *hi = FR32(2 * m + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + Value *hi64 = ZEXT64(hi); + Value* lo64 = ZEXT64(lo); + Value* v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value* m0 = FPBITCAST64(v64); + lo = FR32(2 * n); + hi = FR32(2 * n + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + hi64 = ZEXT64(hi); + lo64 = ZEXT64(lo); + v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value *n0 = FPBITCAST64(v64); + tmp = FPMUL(n0,m0); + Value *val64 = IBITCAST64(tmp); + hi = LSHR(val64,CONST64(32)); + lo = AND(val64,CONST64(0xffffffff)); + hi = TRUNC32(hi); + lo = TRUNC32(lo); + hi = FPBITCAST32(hi); + lo = FPBITCAST32(lo); + LETFPS(2*d ,lo); + LETFPS(d*2 + 1 , hi); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VADD */ +/* cond 1110 0D11 Vn-- Vd-- 101X N0M0 Vm-- */ +#define vfpinstr vadd +#define vfpinstr_inst vadd_inst +#define VFPLABEL_INST VADD_INST +#ifdef VFP_DECODE +{"vadd", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x3, 9, 11, 0x5, 6, 6, 0, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vadd", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vadd_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VADD :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 3 && (OPC_2 & 0x2) == 0) +{ + DBG("VADD :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction will implement out of JIT.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPADD(nn,mm); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + Value *lo = FR32(2 * m); + Value *hi = FR32(2 * m + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + Value *hi64 = ZEXT64(hi); + Value* lo64 = ZEXT64(lo); + Value* v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value* m0 = FPBITCAST64(v64); + lo = FR32(2 * n); + hi = FR32(2 * n + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + hi64 = ZEXT64(hi); + lo64 = ZEXT64(lo); + v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value *n0 = FPBITCAST64(v64); + tmp = FPADD(n0,m0); + Value *val64 = IBITCAST64(tmp); + hi = LSHR(val64,CONST64(32)); + lo = AND(val64,CONST64(0xffffffff)); + hi = TRUNC32(hi); + lo = TRUNC32(lo); + hi = FPBITCAST32(hi); + lo = FPBITCAST32(lo); + LETFPS(2*d ,lo); + LETFPS(d*2 + 1 , hi); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VSUB */ +/* cond 1110 0D11 Vn-- Vd-- 101X N1M0 Vm-- */ +#define vfpinstr vsub +#define vfpinstr_inst vsub_inst +#define VFPLABEL_INST VSUB_INST +#ifdef VFP_DECODE +{"vsub", 5, ARMVFP2, 23, 27, 0x1c, 20, 21, 0x3, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vsub", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vsub_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VSUB :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 3 && (OPC_2 & 0x2) == 2) +{ + DBG("VSUB :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instr=0x%x, instruction is executed out of JIT.\n", __FUNCTION__, instr); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPSUB(nn,mm); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + Value *lo = FR32(2 * m); + Value *hi = FR32(2 * m + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + Value *hi64 = ZEXT64(hi); + Value* lo64 = ZEXT64(lo); + Value* v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value* m0 = FPBITCAST64(v64); + lo = FR32(2 * n); + hi = FR32(2 * n + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + hi64 = ZEXT64(hi); + lo64 = ZEXT64(lo); + v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value *n0 = FPBITCAST64(v64); + tmp = FPSUB(n0,m0); + Value *val64 = IBITCAST64(tmp); + hi = LSHR(val64,CONST64(32)); + lo = AND(val64,CONST64(0xffffffff)); + hi = TRUNC32(hi); + lo = TRUNC32(lo); + hi = FPBITCAST32(hi); + lo = FPBITCAST32(lo); + LETFPS(2*d ,lo); + LETFPS(d*2 + 1 , hi); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VDIV */ +/* cond 1110 1D00 Vn-- Vd-- 101X N0M0 Vm-- */ +#define vfpinstr vdiv +#define vfpinstr_inst vdiv_inst +#define VFPLABEL_INST VDIV_INST +#ifdef VFP_DECODE +{"vdiv", 5, ARMVFP2, 23, 27, 0x1d, 20, 21, 0x0, 9, 11, 0x5, 6, 6, 0, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vdiv", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vdiv_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VDIV :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xA && (OPC_2 & 0x2) == 0) +{ + DBG("VDIV :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int m; + int n; + int d ; + int s = BIT(8) == 0; + Value *mm; + Value *nn; + Value *tmp; + if(s){ + m = BIT(5) | BITS(0,3) << 1; + n = BIT(7) | BITS(16,19) << 1; + d = BIT(22) | BITS(12,15) << 1; + mm = FR32(m); + nn = FR32(n); + tmp = FPDIV(nn,mm); + LETFPS(d,tmp); + }else { + m = BITS(0,3) | BIT(5) << 4; + n = BITS(16,19) | BIT(7) << 4; + d = BIT(22) << 4 | BITS(12,15); + Value *lo = FR32(2 * m); + Value *hi = FR32(2 * m + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + Value *hi64 = ZEXT64(hi); + Value* lo64 = ZEXT64(lo); + Value* v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value* m0 = FPBITCAST64(v64); + lo = FR32(2 * n); + hi = FR32(2 * n + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + hi64 = ZEXT64(hi); + lo64 = ZEXT64(lo); + v64 = OR(SHL(hi64,CONST64(32)),lo64); + Value *n0 = FPBITCAST64(v64); + tmp = FPDIV(n0,m0); + Value *val64 = IBITCAST64(tmp); + hi = LSHR(val64,CONST64(32)); + lo = AND(val64,CONST64(0xffffffff)); + hi = TRUNC32(hi); + lo = TRUNC32(lo); + hi = FPBITCAST32(hi); + lo = FPBITCAST32(lo); + LETFPS(2*d ,lo); + LETFPS(d*2 + 1 , hi); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMOVI move immediate */ +/* cond 1110 1D11 im4H Vd-- 101X 0000 im4L */ +/* cond 1110 opc1 CRn- CRd- copr op20 CRm- CDP */ +#define vfpinstr vmovi +#define vfpinstr_inst vmovi_inst +#define VFPLABEL_INST VMOVI_INST +#ifdef VFP_DECODE +{"vmov(i)", 4, ARMVFP3, 23, 27, 0x1d, 20, 21, 0x3, 9, 11, 0x5, 4, 7, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmov(i)", 0, ARMVFP3, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovi_inst { + unsigned int single; + unsigned int d; + unsigned int imm; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->d = (inst_cream->single ? BITS(inst,12,15)<<1 | BIT(inst,22) : BITS(inst,12,15) | BIT(inst,22)<<4); + unsigned int imm8 = BITS(inst, 16, 19) << 4 | BITS(inst, 0, 3); + if (inst_cream->single) + inst_cream->imm = BIT(imm8, 7)<<31 | (BIT(imm8, 6)==0)<<30 | (BIT(imm8, 6) ? 0x1f : 0)<<25 | BITS(imm8, 0, 5)<<19; + else + inst_cream->imm = BIT(imm8, 7)<<31 | (BIT(imm8, 6)==0)<<30 | (BIT(imm8, 6) ? 0xff : 0)<<22 | BITS(imm8, 0, 5)<<16; + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VMOVI(cpu, inst_cream->single, inst_cream->d, inst_cream->imm); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ( (OPC_1 & 0xb) == 0xb && BITS(4, 7) == 0) +{ + unsigned int single = BIT(8) == 0; + unsigned int d = (single ? BITS(12,15)<<1 | BIT(22) : BITS(12,15) | BIT(22)<<4); + unsigned int imm; + instr = BITS(16, 19) << 4 | BITS(0, 3); /* FIXME dirty workaround to get a correct imm */ + if (single) { + imm = BIT(7)<<31 | (BIT(6)==0)<<30 | (BIT(6) ? 0x1f : 0)<<25 | BITS(0, 5)<<19; + } else { + imm = BIT(7)<<31 | (BIT(6)==0)<<30 | (BIT(6) ? 0xff : 0)<<22 | BITS(0, 5)<<16; + } + VMOVI(state, single, d, imm); + return ARMul_DONE; +} +#endif +#ifdef VFP_CDP_IMPL +void VMOVI(ARMul_State * state, ARMword single, ARMword d, ARMword imm) +{ + DBG("VMOV(I) :\n"); + + if (single) + { + DBG("\ts%d <= [%x]\n", d, imm); + state->ExtReg[d] = imm; + } + else + { + /* Check endian please */ + DBG("\ts[%d-%d] <= [%x-%x]\n", d*2+1, d*2, imm, 0); + state->ExtReg[d*2+1] = imm; + state->ExtReg[d*2] = 0; + } +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int single = (BIT(8) == 0); + int d; + int imm32; + Value *v; + Value *tmp; + v = CONST32(BITS(0,3) | BITS(16,19) << 4); + //v = CONST64(0x3ff0000000000000); + if(single){ + d = BIT(22) | BITS(12,15) << 1; + }else { + d = BITS(12,15) | BIT(22) << 4; + } + if(single){ + LETFPS(d,FPBITCAST32(v)); + }else { + //v = UITOFP(64,v); + //tmp = IBITCAST64(v); + LETFPS(d*2 ,FPBITCAST32(TRUNC32(AND(v,CONST64(0xffffffff))))); + LETFPS(d * 2 + 1,FPBITCAST32(TRUNC32(LSHR(v,CONST64(32))))); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMOVR move register */ +/* cond 1110 1D11 0000 Vd-- 101X 01M0 Vm-- */ +/* cond 1110 opc1 CRn- CRd- copr op20 CRm- CDP */ +#define vfpinstr vmovr +#define vfpinstr_inst vmovr_inst +#define VFPLABEL_INST VMOVR_INST +#ifdef VFP_DECODE +{"vmov(r)", 5, ARMVFP3, 23, 27, 0x1d, 16, 21, 0x30, 9, 11, 0x5, 6, 7, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmov(r)", 0, ARMVFP3, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovr_inst { + unsigned int single; + unsigned int d; + unsigned int m; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + VFP_DEBUG_UNTESTED(VMOVR); + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->d = (inst_cream->single ? BITS(inst,12,15)<<1 | BIT(inst,22) : BITS(inst,12,15) | BIT(inst,22)<<4); + inst_cream->m = (inst_cream->single ? BITS(inst, 0, 3)<<1 | BIT(inst, 5) : BITS(inst, 0, 3) | BIT(inst, 5)<<4); + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VMOVR(cpu, inst_cream->single, inst_cream->d, inst_cream->m); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ( (OPC_1 & 0xb) == 0xb && CRn == 0 && (OPC_2 & 0x6) == 0x2 ) +{ + unsigned int single = BIT(8) == 0; + unsigned int d = (single ? BITS(12,15)<<1 | BIT(22) : BITS(12,15) | BIT(22)<<4); + unsigned int m = (single ? BITS( 0, 3)<<1 | BIT( 5) : BITS( 0, 3) | BIT( 5)<<4);; + VMOVR(state, single, d, m); + return ARMul_DONE; +} +#endif +#ifdef VFP_CDP_IMPL +void VMOVR(ARMul_State * state, ARMword single, ARMword d, ARMword m) +{ + DBG("VMOV(R) :\n"); + + if (single) + { + DBG("\ts%d <= s%d[%x]\n", d, m, state->ExtReg[m]); + state->ExtReg[d] = state->ExtReg[m]; + } + else + { + /* Check endian please */ + DBG("\ts[%d-%d] <= s[%d-%d][%x-%x]\n", d*2+1, d*2, m*2+1, m*2, state->ExtReg[m*2+1], state->ExtReg[m*2]); + state->ExtReg[d*2+1] = state->ExtReg[m*2+1]; + state->ExtReg[d*2] = state->ExtReg[m*2]; + } +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s VMOV \n", __FUNCTION__); + int single = BIT(8) == 0; + int d = (single ? BITS(12,15)<<1 | BIT(22) : BIT(22) << 4 | BITS(12,15)); + int m = (single ? BITS(0, 3)<<1 | BIT(5) : BITS(0, 3) | BIT(5)<<4); + + if (single) + { + LETFPS(d, FR32(m)); + } + else + { + /* Check endian please */ + LETFPS((d*2 + 1), FR32(m*2 + 1)); + LETFPS((d * 2), FR32(m * 2)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VABS */ +/* cond 1110 1D11 0000 Vd-- 101X 11M0 Vm-- */ +#define vfpinstr vabs +#define vfpinstr_inst vabs_inst +#define VFPLABEL_INST VABS_INST +#ifdef VFP_DECODE +{"vabs", 5, ARMVFP2, 23, 27, 0x1d, 16, 21, 0x30, 9, 11, 0x5, 6, 7, 3, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vabs", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vabs_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE;VFP_DEBUG_UNTESTED(VABS); + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VABS :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn == 0 && (OPC_2 & 0x7) == 6) +{ + DBG("VABS :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int single = BIT(8) == 0; + int d = (single ? BITS(12,15)<<1 | BIT(22) : BIT(22) << 4 | BITS(12,15)); + int m = (single ? BITS(0, 3)<<1 | BIT(5) : BITS(0, 3) | BIT(5)<<4); + Value* m0; + if (single) + { + m0 = FR32(m); + m0 = SELECT(FPCMP_OLT(m0,FPCONST32(0.0)),FPNEG32(m0),m0); + LETFPS(d,m0); + } + else + { + /* Check endian please */ + Value *lo = FR32(2 * m); + Value *hi = FR32(2 * m + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + Value *hi64 = ZEXT64(hi); + Value* lo64 = ZEXT64(lo); + Value* v64 = OR(SHL(hi64,CONST64(32)),lo64); + m0 = FPBITCAST64(v64); + m0 = SELECT(FPCMP_OLT(m0,FPCONST64(0.0)),FPNEG64(m0),m0); + Value *val64 = IBITCAST64(m0); + hi = LSHR(val64,CONST64(32)); + lo = AND(val64,CONST64(0xffffffff)); + hi = TRUNC32(hi); + lo = TRUNC32(lo); + hi = FPBITCAST32(hi); + lo = FPBITCAST32(lo); + LETFPS(2*d ,lo); + LETFPS(d*2 + 1 , hi); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VNEG */ +/* cond 1110 1D11 0001 Vd-- 101X 11M0 Vm-- */ +#define vfpinstr vneg +#define vfpinstr_inst vneg_inst +#define VFPLABEL_INST VNEG_INST +#ifdef VFP_DECODE +//{"vneg", 5, ARMVFP2, 23, 27, 0x1d, 16, 21, 0x30, 9, 11, 0x5, 6, 7, 1, 4, 4, 0}, +{"vneg", 5, ARMVFP2, 23, 27, 0x1d, 17, 21, 0x18, 9, 11, 0x5, 6, 7, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vneg", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vneg_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE;VFP_DEBUG_UNTESTED(VNEG); + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VNEG :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn == 1 && (OPC_2 & 0x7) == 2) +{ + DBG("VNEG :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int single = BIT(8) == 0; + int d = (single ? BITS(12,15)<<1 | BIT(22) : BIT(22) << 4 | BITS(12,15)); + int m = (single ? BITS(0, 3)<<1 | BIT(5) : BITS(0, 3) | BIT(5)<<4); + Value* m0; + if (single) + { + m0 = FR32(m); + m0 = FPNEG32(m0); + LETFPS(d,m0); + } + else + { + /* Check endian please */ + Value *lo = FR32(2 * m); + Value *hi = FR32(2 * m + 1); + hi = IBITCAST32(hi); + lo = IBITCAST32(lo); + Value *hi64 = ZEXT64(hi); + Value* lo64 = ZEXT64(lo); + Value* v64 = OR(SHL(hi64,CONST64(32)),lo64); + m0 = FPBITCAST64(v64); + m0 = FPNEG64(m0); + Value *val64 = IBITCAST64(m0); + hi = LSHR(val64,CONST64(32)); + lo = AND(val64,CONST64(0xffffffff)); + hi = TRUNC32(hi); + lo = TRUNC32(lo); + hi = FPBITCAST32(hi); + lo = FPBITCAST32(lo); + LETFPS(2*d ,lo); + LETFPS(d*2 + 1 , hi); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VSQRT */ +/* cond 1110 1D11 0001 Vd-- 101X 11M0 Vm-- */ +#define vfpinstr vsqrt +#define vfpinstr_inst vsqrt_inst +#define VFPLABEL_INST VSQRT_INST +#ifdef VFP_DECODE +{"vsqrt", 5, ARMVFP2, 23, 27, 0x1d, 16, 21, 0x31, 9, 11, 0x5, 6, 7, 3, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vsqrt", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vsqrt_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VSQRT :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn == 1 && (OPC_2 & 0x7) == 6) +{ + DBG("VSQRT :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int dp_op = (BIT(8) == 1); + int d = dp_op ? BITS(12,15) | BIT(22) << 4 : BIT(22) | BITS(12,15) << 1; + int m = dp_op ? BITS(0,3) | BIT(5) << 4 : BIT(5) | BITS(0,3) << 1; + Value* v; + Value* tmp; + if(dp_op){ + v = SHL(ZEXT64(IBITCAST32(FR32(2 * m + 1))),CONST64(32)); + tmp = ZEXT64(IBITCAST32(FR32(2 * m))); + v = OR(v,tmp); + v = FPSQRT(FPBITCAST64(v)); + tmp = TRUNC32(LSHR(IBITCAST64(v),CONST64(32))); + v = TRUNC32(AND(IBITCAST64(v),CONST64( 0xffffffff))); + LETFPS(2 * d , FPBITCAST32(v)); + LETFPS(2 * d + 1, FPBITCAST32(tmp)); + }else { + v = FR32(m); + v = FPSQRT(FPEXT(64,v)); + v = FPTRUNC(32,v); + LETFPS(d,v); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VCMP VCMPE */ +/* cond 1110 1D11 0100 Vd-- 101X E1M0 Vm-- Encoding 1 */ +#define vfpinstr vcmp +#define vfpinstr_inst vcmp_inst +#define VFPLABEL_INST VCMP_INST +#ifdef VFP_DECODE +{"vcmp", 5, ARMVFP2, 23, 27, 0x1d, 16, 21, 0x34, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vcmp", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vcmp_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VCMP(1) :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn == 4 && (OPC_2 & 0x2) == 2) +{ + DBG("VCMP(1) :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is executed out of JIT.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int dp_op = (BIT(8) == 1); + int d = dp_op ? BITS(12,15) | BIT(22) << 4 : BIT(22) | BITS(12,15) << 1; + int m = dp_op ? BITS(0,3) | BIT(5) << 4 : BIT(5) | BITS(0,3) << 1; + Value* v; + Value* tmp; + Value* n; + Value* z; + Value* c; + Value* vt; + Value* v1; + Value* nzcv; + if(dp_op){ + v = SHL(ZEXT64(IBITCAST32(FR32(2 * m + 1))),CONST64(32)); + tmp = ZEXT64(IBITCAST32(FR32(2 * m))); + v1 = OR(v,tmp); + v = SHL(ZEXT64(IBITCAST32(FR32(2 * d + 1))),CONST64(32)); + tmp = ZEXT64(IBITCAST32(FR32(2 * d))); + v = OR(v,tmp); + z = FPCMP_OEQ(FPBITCAST64(v),FPBITCAST64(v1)); + n = FPCMP_OLT(FPBITCAST64(v),FPBITCAST64(v1)); + c = FPCMP_OGE(FPBITCAST64(v),FPBITCAST64(v1)); + tmp = FPCMP_UNO(FPBITCAST64(v),FPBITCAST64(v1)); + v1 = tmp; + c = OR(c,tmp); + n = SHL(ZEXT32(n),CONST32(31)); + z = SHL(ZEXT32(z),CONST32(30)); + c = SHL(ZEXT32(c),CONST32(29)); + v1 = SHL(ZEXT32(v1),CONST(28)); + nzcv = OR(OR(OR(n,z),c),v1); + v = R(VFP_FPSCR); + tmp = OR(nzcv,AND(v,CONST32(0x0fffffff))); + LET(VFP_FPSCR,tmp); + }else { + z = FPCMP_OEQ(FR32(d),FR32(m)); + n = FPCMP_OLT(FR32(d),FR32(m)); + c = FPCMP_OGE(FR32(d),FR32(m)); + tmp = FPCMP_UNO(FR32(d),FR32(m)); + c = OR(c,tmp); + v1 = tmp; + n = SHL(ZEXT32(n),CONST32(31)); + z = SHL(ZEXT32(z),CONST32(30)); + c = SHL(ZEXT32(c),CONST32(29)); + v1 = SHL(ZEXT32(v1),CONST(28)); + nzcv = OR(OR(OR(n,z),c),v1); + v = R(VFP_FPSCR); + tmp = OR(nzcv,AND(v,CONST32(0x0fffffff))); + LET(VFP_FPSCR,tmp); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VCMP VCMPE */ +/* cond 1110 1D11 0100 Vd-- 101X E1M0 Vm-- Encoding 2 */ +#define vfpinstr vcmp2 +#define vfpinstr_inst vcmp2_inst +#define VFPLABEL_INST VCMP2_INST +#ifdef VFP_DECODE +{"vcmp2", 5, ARMVFP2, 23, 27, 0x1d, 16, 21, 0x35, 9, 11, 0x5, 0, 6, 0x40}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vcmp2", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vcmp2_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VCMP(2) :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn == 5 && (OPC_2 & 0x2) == 2 && CRm == 0) +{ + DBG("VCMP(2) :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction will executed out of JIT.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int dp_op = (BIT(8) == 1); + int d = dp_op ? BITS(12,15) | BIT(22) << 4 : BIT(22) | BITS(12,15) << 1; + //int m = dp_op ? BITS(0,3) | BIT(5) << 4 : BIT(5) | BITS(0,3) << 1; + Value* v; + Value* tmp; + Value* n; + Value* z; + Value* c; + Value* vt; + Value* v1; + Value* nzcv; + if(dp_op){ + v1 = CONST64(0); + v = SHL(ZEXT64(IBITCAST32(FR32(2 * d + 1))),CONST64(32)); + tmp = ZEXT64(IBITCAST32(FR32(2 * d))); + v = OR(v,tmp); + z = FPCMP_OEQ(FPBITCAST64(v),FPBITCAST64(v1)); + n = FPCMP_OLT(FPBITCAST64(v),FPBITCAST64(v1)); + c = FPCMP_OGE(FPBITCAST64(v),FPBITCAST64(v1)); + tmp = FPCMP_UNO(FPBITCAST64(v),FPBITCAST64(v1)); + v1 = tmp; + c = OR(c,tmp); + n = SHL(ZEXT32(n),CONST32(31)); + z = SHL(ZEXT32(z),CONST32(30)); + c = SHL(ZEXT32(c),CONST32(29)); + v1 = SHL(ZEXT32(v1),CONST(28)); + nzcv = OR(OR(OR(n,z),c),v1); + v = R(VFP_FPSCR); + tmp = OR(nzcv,AND(v,CONST32(0x0fffffff))); + LET(VFP_FPSCR,tmp); + }else { + v1 = CONST(0); + v1 = FPBITCAST32(v1); + z = FPCMP_OEQ(FR32(d),v1); + n = FPCMP_OLT(FR32(d),v1); + c = FPCMP_OGE(FR32(d),v1); + tmp = FPCMP_UNO(FR32(d),v1); + c = OR(c,tmp); + v1 = tmp; + n = SHL(ZEXT32(n),CONST32(31)); + z = SHL(ZEXT32(z),CONST32(30)); + c = SHL(ZEXT32(c),CONST32(29)); + v1 = SHL(ZEXT32(v1),CONST(28)); + nzcv = OR(OR(OR(n,z),c),v1); + v = R(VFP_FPSCR); + tmp = OR(nzcv,AND(v,CONST32(0x0fffffff))); + LET(VFP_FPSCR,tmp); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VCVTBDS between double and single */ +/* cond 1110 1D11 0111 Vd-- 101X 11M0 Vm-- */ +#define vfpinstr vcvtbds +#define vfpinstr_inst vcvtbds_inst +#define VFPLABEL_INST VCVTBDS_INST +#ifdef VFP_DECODE +{"vcvt(bds)", 5, ARMVFP2, 23, 27, 0x1d, 16, 21, 0x37, 9, 11, 0x5, 6, 7, 3, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vcvt(bds)", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vcvtbds_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VCVT(BDS) :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn == 7 && (OPC_2 & 0x6) == 6) +{ + DBG("VCVT(BDS) :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is executed out.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int dp_op = (BIT(8) == 1); + int d = dp_op ? BITS(12,15) << 1 | BIT(22) : BIT(22) << 4 | BITS(12,15); + int m = dp_op ? BITS(0,3) | BIT(5) << 4 : BIT(5) | BITS(0,3) << 1; + int d2s = dp_op; + Value* v; + Value* tmp; + Value* v1; + if(d2s){ + v = SHL(ZEXT64(IBITCAST32(FR32(2 * m + 1))),CONST64(32)); + tmp = ZEXT64(IBITCAST32(FR32(2 * m))); + v1 = OR(v,tmp); + tmp = FPTRUNC(32,FPBITCAST64(v1)); + LETFPS(d,tmp); + }else { + v = FR32(m); + tmp = FPEXT(64,v); + v = IBITCAST64(tmp); + tmp = TRUNC32(AND(v,CONST64(0xffffffff))); + v1 = TRUNC32(LSHR(v,CONST64(32))); + LETFPS(2 * d, FPBITCAST32(tmp) ); + LETFPS(2 * d + 1, FPBITCAST32(v1)); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VCVTBFF between floating point and fixed point */ +/* cond 1110 1D11 1op2 Vd-- 101X X1M0 Vm-- */ +#define vfpinstr vcvtbff +#define vfpinstr_inst vcvtbff_inst +#define VFPLABEL_INST VCVTBFF_INST +#ifdef VFP_DECODE +{"vcvt(bff)", 6, ARMVFP3, 23, 27, 0x1d, 19, 21, 0x7, 17, 17, 0x1, 9, 11, 0x5, 6, 6, 1}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vcvt(bff)", 0, ARMVFP3, 4, 4, 1}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vcvtbff_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE;VFP_DEBUG_UNTESTED(VCVTBFF); + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VCVT(BFF) :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn >= 0xA && (OPC_2 & 0x2) == 2) +{ + DBG("VCVT(BFF) :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arch_arm_undef(cpu, bb, instr); + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VCVTBFI between floating point and integer */ +/* cond 1110 1D11 1op2 Vd-- 101X X1M0 Vm-- */ +#define vfpinstr vcvtbfi +#define vfpinstr_inst vcvtbfi_inst +#define VFPLABEL_INST VCVTBFI_INST +#ifdef VFP_DECODE +{"vcvt(bfi)", 5, ARMVFP2, 23, 27, 0x1d, 19, 21, 0x7, 9, 11, 0x5, 6, 6, 1, 4, 4, 0}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vcvt(bfi)", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vcvtbfi_inst { + unsigned int instr; + unsigned int dp_operation; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->dp_operation = BIT(inst, 8); + inst_cream->instr = inst; + + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + DBG("VCVT(BFI) :\n"); + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + int ret; + + if (inst_cream->dp_operation) + ret = vfp_double_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + CHECK_VFP_CDP_RET; + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_CDP_TRANS +if ((OPC_1 & 0xB) == 0xB && CRn > 7 && (OPC_2 & 0x2) == 2) +{ + DBG("VCVT(BFI) :\n"); +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + DBG("\t\tin %s, instruction will be executed out of JIT.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s, instruction will be executed out of JIT.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + unsigned int opc2 = BITS(16,18); + int to_integer = ((opc2 >> 2) == 1); + int dp_op = (BIT(8) == 1); + unsigned int op = BIT(7); + int m,d; + Value* v; + Value* hi; + Value* lo; + Value* v64; + if(to_integer){ + d = BIT(22) | (BITS(12,15) << 1); + if(dp_op) + m = BITS(0,3) | BIT(5) << 4; + else + m = BIT(5) | BITS(0,3) << 1; + }else { + m = BIT(5) | BITS(0,3) << 1; + if(dp_op) + d = BITS(12,15) | BIT(22) << 4; + else + d = BIT(22) | BITS(12,15) << 1; + } + if(to_integer){ + if(dp_op){ + lo = FR32(m * 2); + hi = FR32(m * 2 + 1); + hi = ZEXT64(IBITCAST32(hi)); + lo = ZEXT64(IBITCAST32(lo)); + v64 = OR(SHL(hi,CONST64(32)),lo); + if(BIT(16)){ + v = FPTOSI(32,FPBITCAST64(v64)); + } + else + v = FPTOUI(32,FPBITCAST64(v64)); + + v = FPBITCAST32(v); + LETFPS(d,v); + }else { + v = FR32(m); + if(BIT(16)){ + + v = FPTOSI(32,v); + } + else + v = FPTOUI(32,v); + LETFPS(d,FPBITCAST32(v)); + } + }else { + if(dp_op){ + v = IBITCAST32(FR32(m)); + if(BIT(7)) + v64 = SITOFP(64,v); + else + v64 = UITOFP(64,v); + v = IBITCAST64(v64); + hi = FPBITCAST32(TRUNC32(LSHR(v,CONST64(32)))); + lo = FPBITCAST32(TRUNC32(AND(v,CONST64(0xffffffff)))); + LETFPS(2 * d , lo); + LETFPS(2 * d + 1, hi); + }else { + v = IBITCAST32(FR32(m)); + if(BIT(7)) + v = SITOFP(32,v); + else + v = UITOFP(32,v); + LETFPS(d,v); + } + } + return No_exp; +} + +/** +* @brief The implementation of c language for vcvtbfi instruction of dyncom +* +* @param cpu +* @param instr +* +* @return +*/ +int vcvtbfi_instr_impl(arm_core_t* cpu, uint32 instr){ + int dp_operation = BIT(8); + int ret; + if (dp_operation) + ret = vfp_double_cpdo(cpu, instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + else + ret = vfp_single_cpdo(cpu, instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + + vfp_raise_exceptions(cpu, ret, instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + return 0; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* MRC / MCR instructions */ +/* cond 1110 AAAL XXXX XXXX 101C XBB1 XXXX */ +/* cond 1110 op11 CRn- Rt-- copr op21 CRm- */ + +/* ----------------------------------------------------------------------- */ +/* VMOVBRS between register and single precision */ +/* cond 1110 000o Vn-- Rt-- 1010 N001 0000 */ +/* cond 1110 op11 CRn- Rt-- copr op21 CRm- MRC */ +#define vfpinstr vmovbrs +#define vfpinstr_inst vmovbrs_inst +#define VFPLABEL_INST VMOVBRS_INST +#ifdef VFP_DECODE +{"vmovbrs", 3, ARMVFP2, 21, 27, 0x70, 8, 11, 0xA, 0, 6, 0x10}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmovbrs", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovbrs_inst { + unsigned int to_arm; + unsigned int t; + unsigned int n; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->to_arm = BIT(inst, 20) == 1; + inst_cream->t = BITS(inst, 12, 15); + inst_cream->n = BIT(inst, 7) | BITS(inst, 16, 19)<<1; + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VMOVBRS(cpu, inst_cream->to_arm, inst_cream->t, inst_cream->n, &(cpu->Reg[inst_cream->t])); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MRC_TRANS +if (OPC_1 == 0x0 && CRm == 0 && (OPC_2 & 0x3) == 0) +{ + /* VMOV r to s */ + /* Transfering Rt is not mandatory, as the value of interest is pointed by value */ + VMOVBRS(state, BIT(20), Rt, BIT(7)|CRn<<1, value); + return ARMul_DONE; +} +#endif +#ifdef VFP_MCR_TRANS +if (OPC_1 == 0x0 && CRm == 0 && (OPC_2 & 0x3) == 0) +{ + /* VMOV s to r */ + /* Transfering Rt is not mandatory, as the value of interest is pointed by value */ + VMOVBRS(state, BIT(20), Rt, BIT(7)|CRn<<1, &value); + return ARMul_DONE; +} +#endif +#ifdef VFP_MRC_IMPL +void VMOVBRS(ARMul_State * state, ARMword to_arm, ARMword t, ARMword n, ARMword *value) +{ + DBG("VMOV(BRS) :\n"); + if (to_arm) + { + DBG("\tr%d <= s%d=[%x]\n", t, n, state->ExtReg[n]); + *value = state->ExtReg[n]; + } + else + { + DBG("\ts%d <= r%d=[%x]\n", n, t, *value); + state->ExtReg[n] = *value; + } +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("VMOV(BRS) :\n"); + int to_arm = BIT(20) == 1; + int t = BITS(12, 15); + int n = BIT(7) | BITS(16, 19)<<1; + + if (to_arm) + { + DBG("\tr%d <= s%d\n", t, n); + LET(t, IBITCAST32(FR32(n))); + } + else + { + DBG("\ts%d <= r%d\n", n, t); + LETFPS(n, FPBITCAST32(R(t))); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMSR */ +/* cond 1110 1110 reg- Rt-- 1010 0001 0000 */ +/* cond 1110 op10 CRn- Rt-- copr op21 CRm- MCR */ +#define vfpinstr vmsr +#define vfpinstr_inst vmsr_inst +#define VFPLABEL_INST VMSR_INST +#ifdef VFP_DECODE +{"vmsr", 2, ARMVFP2, 20, 27, 0xEE, 0, 11, 0xA10}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmsr", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmsr_inst { + unsigned int reg; + unsigned int Rd; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->reg = BITS(inst, 16, 19); + inst_cream->Rd = BITS(inst, 12, 15); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + /* FIXME: special case for access to FPSID and FPEXC, VFP must be disabled , + and in privilegied mode */ + /* Exceptions must be checked, according to v7 ref manual */ + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VMSR(cpu, inst_cream->reg, inst_cream->Rd); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MCR_TRANS +if (OPC_1 == 0x7 && CRm == 0 && OPC_2 == 0) +{ + VMSR(state, CRn, Rt); + return ARMul_DONE; +} +#endif +#ifdef VFP_MCR_IMPL +void VMSR(ARMul_State * state, ARMword reg, ARMword Rt) +{ + if (reg == 1) + { + DBG("VMSR :\tfpscr <= r%d=[%x]\n", Rt, state->Reg[Rt]); + state->VFP[VFP_OFFSET(VFP_FPSCR)] = state->Reg[Rt]; + } + else if (reg == 8) + { + DBG("VMSR :\tfpexc <= r%d=[%x]\n", Rt, state->Reg[Rt]); + state->VFP[VFP_OFFSET(VFP_FPEXC)] = state->Reg[Rt]; + } +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + DBG("VMSR :"); + if(RD == 15) { + printf("in %s is not implementation.\n", __FUNCTION__); + exit(-1); + } + + Value *data = NULL; + int reg = RN; + int Rt = RD; + if (reg == 1) + { + LET(VFP_FPSCR, R(Rt)); + DBG("\tflags <= fpscr\n"); + } + else + { + switch (reg) + { + case 8: + LET(VFP_FPEXC, R(Rt)); + DBG("\tfpexc <= r%d \n", Rt); + break; + default: + DBG("\tSUBARCHITECTURE DEFINED\n"); + break; + } + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMOVBRC register to scalar */ +/* cond 1110 0XX0 Vd-- Rt-- 1011 DXX1 0000 */ +/* cond 1110 op10 CRn- Rt-- copr op21 CRm- MCR */ +#define vfpinstr vmovbrc +#define vfpinstr_inst vmovbrc_inst +#define VFPLABEL_INST VMOVBRC_INST +#ifdef VFP_DECODE +{"vmovbrc", 4, ARMVFP2, 23, 27, 0x1C, 20, 20, 0x0, 8,11,0xB, 0,4,0x10}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmovbrc", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovbrc_inst { + unsigned int esize; + unsigned int index; + unsigned int d; + unsigned int t; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->d = BITS(inst, 16, 19)|BIT(inst, 7)<<4; + inst_cream->t = BITS(inst, 12, 15); + /* VFP variant of instruction */ + inst_cream->esize = 32; + inst_cream->index = BIT(inst, 21); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VFP_DEBUG_UNIMPLEMENTED(VMOVBRC); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MCR_TRANS +if ((OPC_1 & 0x4) == 0 && CoProc == 11 && CRm == 0) +{ + VFP_DEBUG_UNIMPLEMENTED(VMOVBRC); + return ARMul_DONE; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arch_arm_undef(cpu, bb, instr); + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMRS */ +/* cond 1110 1111 CRn- Rt-- 1010 0001 0000 */ +/* cond 1110 op11 CRn- Rt-- copr op21 CRm- MRC */ +#define vfpinstr vmrs +#define vfpinstr_inst vmrs_inst +#define VFPLABEL_INST VMRS_INST +#ifdef VFP_DECODE +{"vmrs", 2, ARMVFP2, 20, 27, 0xEF, 0, 11, 0xa10}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmrs", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmrs_inst { + unsigned int reg; + unsigned int Rt; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->reg = BITS(inst, 16, 19); + inst_cream->Rt = BITS(inst, 12, 15); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + /* FIXME: special case for access to FPSID and FPEXC, VFP must be disabled, + and in privilegied mode */ + /* Exceptions must be checked, according to v7 ref manual */ + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + DBG("VMRS :"); + + if (inst_cream->reg == 1) /* FPSCR */ + { + if (inst_cream->Rt != 15) + { + cpu->Reg[inst_cream->Rt] = cpu->VFP[VFP_OFFSET(VFP_FPSCR)]; + DBG("\tr%d <= fpscr[%08x]\n", inst_cream->Rt, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); + } + else + { + cpu->NFlag = (cpu->VFP[VFP_OFFSET(VFP_FPSCR)] >> 31) & 1; + cpu->ZFlag = (cpu->VFP[VFP_OFFSET(VFP_FPSCR)] >> 30) & 1; + cpu->CFlag = (cpu->VFP[VFP_OFFSET(VFP_FPSCR)] >> 29) & 1; + cpu->VFlag = (cpu->VFP[VFP_OFFSET(VFP_FPSCR)] >> 28) & 1; + DBG("\tflags <= fpscr[%1xxxxxxxx]\n", cpu->VFP[VFP_OFFSET(VFP_FPSCR)]>>28); + } + } + else + { + switch (inst_cream->reg) + { + case 0: + cpu->Reg[inst_cream->Rt] = cpu->VFP[VFP_OFFSET(VFP_FPSID)]; + DBG("\tr%d <= fpsid[%08x]\n", inst_cream->Rt, cpu->VFP[VFP_OFFSET(VFP_FPSID)]); + break; + case 6: + /* MVFR1, VFPv3 only ? */ + DBG("\tr%d <= MVFR1 unimplemented\n", inst_cream->Rt); + break; + case 7: + /* MVFR0, VFPv3 only? */ + DBG("\tr%d <= MVFR0 unimplemented\n", inst_cream->Rt); + break; + case 8: + cpu->Reg[inst_cream->Rt] = cpu->VFP[VFP_OFFSET(VFP_FPEXC)]; + DBG("\tr%d <= fpexc[%08x]\n", inst_cream->Rt, cpu->VFP[VFP_OFFSET(VFP_FPEXC)]); + break; + default: + DBG("\tSUBARCHITECTURE DEFINED\n"); + break; + } + } + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MRC_TRANS +if (OPC_1 == 0x7 && CRm == 0 && OPC_2 == 0) +{ + VMRS(state, CRn, Rt, value); + return ARMul_DONE; +} +#endif +#ifdef VFP_MRC_IMPL +void VMRS(ARMul_State * state, ARMword reg, ARMword Rt, ARMword * value) +{ + DBG("VMRS :"); + if (reg == 1) + { + if (Rt != 15) + { + *value = state->VFP[VFP_OFFSET(VFP_FPSCR)]; + DBG("\tr%d <= fpscr[%08x]\n", Rt, state->VFP[VFP_OFFSET(VFP_FPSCR)]); + } + else + { + *value = state->VFP[VFP_OFFSET(VFP_FPSCR)] ; + DBG("\tflags <= fpscr[%1xxxxxxxx]\n", state->VFP[VFP_OFFSET(VFP_FPSCR)]>>28); + } + } + else + { + switch (reg) + { + case 0: + *value = state->VFP[VFP_OFFSET(VFP_FPSID)]; + DBG("\tr%d <= fpsid[%08x]\n", Rt, state->VFP[VFP_OFFSET(VFP_FPSID)]); + break; + case 6: + /* MVFR1, VFPv3 only ? */ + DBG("\tr%d <= MVFR1 unimplemented\n", Rt); + break; + case 7: + /* MVFR0, VFPv3 only? */ + DBG("\tr%d <= MVFR0 unimplemented\n", Rt); + break; + case 8: + *value = state->VFP[VFP_OFFSET(VFP_FPEXC)]; + DBG("\tr%d <= fpexc[%08x]\n", Rt, state->VFP[VFP_OFFSET(VFP_FPEXC)]); + break; + default: + DBG("\tSUBARCHITECTURE DEFINED\n"); + break; + } + } +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + DBG("\t\tin %s .\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + + Value *data = NULL; + int reg = BITS(16, 19);; + int Rt = BITS(12, 15); + DBG("VMRS : reg=%d, Rt=%d\n", reg, Rt); + if (reg == 1) + { + if (Rt != 15) + { + LET(Rt, R(VFP_FPSCR)); + DBG("\tr%d <= fpscr\n", Rt); + } + else + { + //LET(Rt, R(VFP_FPSCR)); + update_cond_from_fpscr(cpu, instr, bb, pc); + DBG("In %s, \tflags <= fpscr\n", __FUNCTION__); + } + } + else + { + switch (reg) + { + case 0: + LET(Rt, R(VFP_FPSID)); + DBG("\tr%d <= fpsid\n", Rt); + break; + case 6: + /* MVFR1, VFPv3 only ? */ + DBG("\tr%d <= MVFR1 unimplemented\n", Rt); + break; + case 7: + /* MVFR0, VFPv3 only? */ + DBG("\tr%d <= MVFR0 unimplemented\n", Rt); + break; + case 8: + LET(Rt, R(VFP_FPEXC)); + DBG("\tr%d <= fpexc\n", Rt); + break; + default: + DBG("\tSUBARCHITECTURE DEFINED\n"); + break; + } + } + + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMOVBCR scalar to register */ +/* cond 1110 XXX1 Vd-- Rt-- 1011 NXX1 0000 */ +/* cond 1110 op11 CRn- Rt-- copr op21 CRm- MCR */ +#define vfpinstr vmovbcr +#define vfpinstr_inst vmovbcr_inst +#define VFPLABEL_INST VMOVBCR_INST +#ifdef VFP_DECODE +{"vmovbcr", 4, ARMVFP2, 24, 27, 0xE, 20, 20, 1, 8, 11,0xB, 0,4, 0x10}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmovbcr", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovbcr_inst { + unsigned int esize; + unsigned int index; + unsigned int d; + unsigned int t; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->d = BITS(inst, 16, 19)|BIT(inst, 7)<<4; + inst_cream->t = BITS(inst, 12, 15); + /* VFP variant of instruction */ + inst_cream->esize = 32; + inst_cream->index = BIT(inst, 21); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VFP_DEBUG_UNIMPLEMENTED(VMOVBCR); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MCR_TRANS +if (CoProc == 11 && CRm == 0) +{ + VFP_DEBUG_UNIMPLEMENTED(VMOVBCR); + return ARMul_DONE; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arch_arm_undef(cpu, bb, instr); + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* MRRC / MCRR instructions */ +/* cond 1100 0101 Rt2- Rt-- copr opc1 CRm- MRRC */ +/* cond 1100 0100 Rt2- Rt-- copr opc1 CRm- MCRR */ + +/* ----------------------------------------------------------------------- */ +/* VMOVBRRSS between 2 registers to 2 singles */ +/* cond 1100 010X Rt2- Rt-- 1010 00X1 Vm-- */ +/* cond 1100 0101 Rt2- Rt-- copr opc1 CRm- MRRC */ +#define vfpinstr vmovbrrss +#define vfpinstr_inst vmovbrrss_inst +#define VFPLABEL_INST VMOVBRRSS_INST +#ifdef VFP_DECODE +{"vmovbrrss", 3, ARMVFP2, 21, 27, 0x62, 8, 11, 0xA, 4, 4, 1}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmovbrrss", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovbrrss_inst { + unsigned int to_arm; + unsigned int t; + unsigned int t2; + unsigned int m; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->to_arm = BIT(inst, 20) == 1; + inst_cream->t = BITS(inst, 12, 15); + inst_cream->t2 = BITS(inst, 16, 19); + inst_cream->m = BITS(inst, 0, 3)<<1|BIT(inst, 5); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VFP_DEBUG_UNIMPLEMENTED(VMOVBRRSS); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MCRR_TRANS +if (CoProc == 10 && (OPC_1 & 0xD) == 1) +{ + VFP_DEBUG_UNIMPLEMENTED(VMOVBRRSS); + return ARMul_DONE; +} +#endif +#ifdef VFP_MRRC_TRANS +if (CoProc == 10 && (OPC_1 & 0xD) == 1) +{ + VFP_DEBUG_UNIMPLEMENTED(VMOVBRRSS); + return ARMul_DONE; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arch_arm_undef(cpu, bb, instr); + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VMOVBRRD between 2 registers and 1 double */ +/* cond 1100 010X Rt2- Rt-- 1011 00X1 Vm-- */ +/* cond 1100 0101 Rt2- Rt-- copr opc1 CRm- MRRC */ +#define vfpinstr vmovbrrd +#define vfpinstr_inst vmovbrrd_inst +#define VFPLABEL_INST VMOVBRRD_INST +#ifdef VFP_DECODE +{"vmovbrrd", 3, ARMVFP2, 21, 27, 0x62, 6, 11, 0x2c, 4, 4, 1}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vmovbrrd", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vmovbrrd_inst { + unsigned int to_arm; + unsigned int t; + unsigned int t2; + unsigned int m; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->to_arm = BIT(inst, 20) == 1; + inst_cream->t = BITS(inst, 12, 15); + inst_cream->t2 = BITS(inst, 16, 19); + inst_cream->m = BIT(inst, 5)<<4 | BITS(inst, 0, 3); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + VMOVBRRD(cpu, inst_cream->to_arm, inst_cream->t, inst_cream->t2, inst_cream->m, + &(cpu->Reg[inst_cream->t]), &(cpu->Reg[inst_cream->t2])); + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_MCRR_TRANS +if (CoProc == 11 && (OPC_1 & 0xD) == 1) +{ + /* Transfering Rt and Rt2 is not mandatory, as the value of interest is pointed by value1 and value2 */ + VMOVBRRD(state, BIT(20), Rt, Rt2, BIT(5)<<4|CRm, &value1, &value2); + return ARMul_DONE; +} +#endif +#ifdef VFP_MRRC_TRANS +if (CoProc == 11 && (OPC_1 & 0xD) == 1) +{ + /* Transfering Rt and Rt2 is not mandatory, as the value of interest is pointed by value1 and value2 */ + VMOVBRRD(state, BIT(20), Rt, Rt2, BIT(5)<<4|CRm, value1, value2); + return ARMul_DONE; +} +#endif +#ifdef VFP_MRRC_IMPL +void VMOVBRRD(ARMul_State * state, ARMword to_arm, ARMword t, ARMword t2, ARMword n, ARMword *value1, ARMword *value2) +{ + DBG("VMOV(BRRD) :\n"); + if (to_arm) + { + DBG("\tr[%d-%d] <= s[%d-%d]=[%x-%x]\n", t2, t, n*2+1, n*2, state->ExtReg[n*2+1], state->ExtReg[n*2]); + *value2 = state->ExtReg[n*2+1]; + *value1 = state->ExtReg[n*2]; + } + else + { + DBG("\ts[%d-%d] <= r[%d-%d]=[%x-%x]\n", n*2+1, n*2, t2, t, *value2, *value1); + state->ExtReg[n*2+1] = *value2; + state->ExtReg[n*2] = *value1; + } +} + +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int to_arm = BIT(20) == 1; + int t = BITS(12, 15); + int t2 = BITS(16, 19); + int n = BIT(5)<<4 | BITS(0, 3); + if(to_arm){ + LET(t, IBITCAST32(FR32(n * 2))); + LET(t2, IBITCAST32(FR32(n * 2 + 1))); + } + else{ + LETFPS(n * 2, FPBITCAST32(R(t))); + LETFPS(n * 2 + 1, FPBITCAST32(R(t2))); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* LDC/STC between 2 registers and 1 double */ +/* cond 110X XXX1 Rn-- CRd- copr imm- imm- LDC */ +/* cond 110X XXX0 Rn-- CRd- copr imm8 imm8 STC */ + +/* ----------------------------------------------------------------------- */ +/* VSTR */ +/* cond 1101 UD00 Rn-- Vd-- 101X imm8 imm8 */ +#define vfpinstr vstr +#define vfpinstr_inst vstr_inst +#define VFPLABEL_INST VSTR_INST +#ifdef VFP_DECODE +{"vstr", 3, ARMVFP2, 24, 27, 0xd, 20, 21, 0, 9, 11, 0x5}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vstr", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vstr_inst { + unsigned int single; + unsigned int n; + unsigned int d; + unsigned int imm32; + unsigned int add; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->add = BIT(inst, 23); + inst_cream->imm32 = BITS(inst, 0,7) << 2; + inst_cream->d = (inst_cream->single ? BITS(inst, 12, 15)<<1|BIT(inst, 22) : BITS(inst, 12, 15)|BIT(inst, 22)<<4); + inst_cream->n = BITS(inst, 16, 19); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + unsigned int base = (inst_cream->n == 15 ? (cpu->Reg[inst_cream->n] & 0xFFFFFFFC) + 8 : cpu->Reg[inst_cream->n]); + addr = (inst_cream->add ? base + inst_cream->imm32 : base - inst_cream->imm32); + DBG("VSTR :\n"); + + + if (inst_cream->single) + { + fault = check_address_validity(cpu, addr, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\taddr[%x] <= s%d=[%x]\n", addr, inst_cream->d, cpu->ExtReg[inst_cream->d]); + } + else + { + fault = check_address_validity(cpu, addr, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + + /* Check endianness */ + fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d*2], 32); + if (fault) goto MMU_EXCEPTION; + + fault = check_address_validity(cpu, addr + 4, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_write_memory(core, addr + 4, phys_addr, cpu->ExtReg[inst_cream->d*2+1], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\taddr[%x-%x] <= s[%d-%d]=[%x-%x]\n", addr+4, addr, inst_cream->d*2+1, inst_cream->d*2, cpu->ExtReg[inst_cream->d*2+1], cpu->ExtReg[inst_cream->d*2]); + } + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_STC_TRANS +if (P == 1 && W == 0) +{ + return VSTR(state, type, instr, value); +} +#endif +#ifdef VFP_STC_IMPL +int VSTR(ARMul_State * state, int type, ARMword instr, ARMword * value) +{ + static int i = 0; + static int single_reg, add, d, n, imm32, regs; + if (type == ARMul_FIRST) + { + single_reg = BIT(8) == 0; /* Double precision */ + add = BIT(23); /* */ + imm32 = BITS(0,7)<<2; /* may not be used */ + d = single_reg ? BITS(12, 15)<<1|BIT(22) : BIT(22)<<4|BITS(12, 15); /* Base register */ + n = BITS(16, 19); /* destination register */ + + DBG("VSTR :\n"); + + i = 0; + regs = 1; + + return ARMul_DONE; + } + else if (type == ARMul_DATA) + { + if (single_reg) + { + *value = state->ExtReg[d+i]; + DBG("\taddr[?] <= s%d=[%x]\n", d+i, state->ExtReg[d+i]); + i++; + if (i < regs) + return ARMul_INC; + else + return ARMul_DONE; + } + else + { + /* FIXME Careful of endianness, may need to rework this */ + *value = state->ExtReg[d*2+i]; + DBG("\taddr[?] <= s[%d]=[%x]\n", d*2+i, state->ExtReg[d*2+i]); + i++; + if (i < regs*2) + return ARMul_INC; + else + return ARMul_DONE; + } + } + + return -1; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + *tag |= TAG_NEW_BB; + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + int single = BIT(8) == 0; + int add = BIT(23); + int imm32 = BITS(0,7) << 2; + int d = (single ? BITS(12, 15)<<1|BIT(22) : BITS(12, 15)|(BIT(22)<<4)); + int n = BITS(16, 19); + + Value* base = (n == 15) ? ADD(AND(R(n), CONST(0xFFFFFFFC)), CONST(8)): R(n); + Value* Addr = add ? ADD(base, CONST(imm32)) : SUB(base, CONST(imm32)); + DBG("VSTR :\n"); + //if(single) + // bb = arch_check_mm(cpu, bb, Addr, 4, 0, cpu->dyncom_engine->bb_trap); + //else + // bb = arch_check_mm(cpu, bb, Addr, 8, 0, cpu->dyncom_engine->bb_trap); + //Value* phys_addr; + if(single){ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR(d), 32); + #endif + //memory_write(cpu, bb, Addr, RSPR(d), 32); + memory_write(cpu, bb, Addr, IBITCAST32(FR32(d)), 32); + bb = cpu->dyncom_engine->bb; + } + else{ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR(d * 2), 32); + #endif + //memory_write(cpu, bb, Addr, RSPR(d * 2), 32); + memory_write(cpu, bb, Addr, IBITCAST32(FR32(d * 2)), 32); + bb = cpu->dyncom_engine->bb; + #if 0 + phys_addr = get_phys_addr(cpu, bb, ADD(Addr, CONST(4)), 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR(d * 2 + 1), 32); + #endif + //memory_write(cpu, bb, ADD(Addr, CONST(4)), RSPR(d * 2 + 1), 32); + memory_write(cpu, bb, ADD(Addr, CONST(4)), IBITCAST32(FR32(d * 2 + 1)), 32); + bb = cpu->dyncom_engine->bb; + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VPUSH */ +/* cond 1101 0D10 1101 Vd-- 101X imm8 imm8 */ +#define vfpinstr vpush +#define vfpinstr_inst vpush_inst +#define VFPLABEL_INST VPUSH_INST +#ifdef VFP_DECODE +{"vpush", 3, ARMVFP2, 23, 27, 0x1a, 16, 21, 0x2d, 9, 11, 0x5}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vpush", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vpush_inst { + unsigned int single; + unsigned int d; + unsigned int imm32; + unsigned int regs; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->d = (inst_cream->single ? BITS(inst, 12, 15)<<1|BIT(inst, 22) : BITS(inst, 12, 15)|BIT(inst, 22)<<4); + inst_cream->imm32 = BITS(inst, 0, 7)<<2; + inst_cream->regs = (inst_cream->single ? BITS(inst, 0, 7) : BITS(inst, 1, 7)); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + int i; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + DBG("VPUSH :\n"); + + addr = cpu->Reg[R13] - inst_cream->imm32; + + + for (i = 0; i < inst_cream->regs; i++) + { + if (inst_cream->single) + { + fault = check_address_validity(cpu, addr, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d+i], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\taddr[%x] <= s%d=[%x]\n", addr, inst_cream->d+i, cpu->ExtReg[inst_cream->d+i]); + addr += 4; + } + else + { + /* Careful of endianness, little by default */ + fault = check_address_validity(cpu, addr, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2], 32); + if (fault) goto MMU_EXCEPTION; + + fault = check_address_validity(cpu, addr + 4, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_write_memory(core, addr + 4, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2 + 1], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\taddr[%x-%x] <= s[%d-%d]=[%x-%x]\n", addr+4, addr, (inst_cream->d+i)*2+1, (inst_cream->d+i)*2, cpu->ExtReg[(inst_cream->d+i)*2+1], cpu->ExtReg[(inst_cream->d+i)*2]); + addr += 8; + } + } + DBG("\tsp[%x]", cpu->Reg[R13]); + cpu->Reg[R13] = cpu->Reg[R13] - inst_cream->imm32; + DBG("=>[%x]\n", cpu->Reg[R13]); + + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vpush_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_STC_TRANS +if (P == 1 && U == 0 && W == 1 && Rn == 0xD) +{ + return VPUSH(state, type, instr, value); +} +#endif +#ifdef VFP_STC_IMPL +int VPUSH(ARMul_State * state, int type, ARMword instr, ARMword * value) +{ + static int i = 0; + static int single_regs, add, wback, d, n, imm32, regs; + if (type == ARMul_FIRST) + { + single_regs = BIT(8) == 0; /* Single precision */ + d = single_regs ? BITS(12, 15)<<1|BIT(22) : BIT(22)<<4|BITS(12, 15); /* Base register */ + imm32 = BITS(0,7)<<2; /* may not be used */ + regs = single_regs ? BITS(0, 7) : BITS(1, 7); /* FSTMX if regs is odd */ + + DBG("VPUSH :\n"); + DBG("\tsp[%x]", state->Reg[R13]); + state->Reg[R13] = state->Reg[R13] - imm32; + DBG("=>[%x]\n", state->Reg[R13]); + + i = 0; + + return ARMul_DONE; + } + else if (type == ARMul_DATA) + { + if (single_regs) + { + *value = state->ExtReg[d + i]; + DBG("\taddr[?] <= s%d=[%x]\n", d+i, state->ExtReg[d + i]); + i++; + if (i < regs) + return ARMul_INC; + else + return ARMul_DONE; + } + else + { + /* FIXME Careful of endianness, may need to rework this */ + *value = state->ExtReg[d*2 + i]; + DBG("\taddr[?] <= s[%d]=[%x]\n", d*2 + i, state->ExtReg[d*2 + i]); + i++; + if (i < regs*2) + return ARMul_INC; + else + return ARMul_DONE; + } + } + + return -1; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + *tag |= TAG_NEW_BB; + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + int single = BIT(8) == 0; + int d = (single ? BITS(12, 15)<<1|BIT(22) : BITS(12, 15)|(BIT(22)<<4)); + int imm32 = BITS(0, 7)<<2; + int regs = (single ? BITS(0, 7) : BITS(1, 7)); + + DBG("\t\tin %s \n", __FUNCTION__); + Value* Addr = SUB(R(13), CONST(imm32)); + //if(single) + // bb = arch_check_mm(cpu, bb, Addr, regs * 4, 0, cpu->dyncom_engine->bb_trap); + //else + // bb = arch_check_mm(cpu, bb, Addr, regs * 8, 0, cpu->dyncom_engine->bb_trap); + //Value* phys_addr; + int i; + for (i = 0; i < regs; i++) + { + if (single) + { + //fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d+i], 32); + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR(d + i), 32); + #endif + //memory_write(cpu, bb, Addr, RSPR(d + i), 32); + memory_write(cpu, bb, Addr, IBITCAST32(FR32(d + i)), 32); + bb = cpu->dyncom_engine->bb; + Addr = ADD(Addr, CONST(4)); + } + else + { + /* Careful of endianness, little by default */ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR((d + i) * 2), 32); + #endif + //memory_write(cpu, bb, Addr, RSPR((d + i) * 2), 32); + memory_write(cpu, bb, Addr, IBITCAST32(FR32((d + i) * 2)), 32); + bb = cpu->dyncom_engine->bb; + #if 0 + phys_addr = get_phys_addr(cpu, bb, ADD(Addr, CONST(4)), 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR((d + i) * 2 + 1), 32); + #endif + //memory_write(cpu, bb, ADD(Addr, CONST(4)), RSPR((d + i) * 2 + 1), 32); + memory_write(cpu, bb, ADD(Addr, CONST(4)), IBITCAST32(FR32((d + i) * 2 + 1)), 32); + bb = cpu->dyncom_engine->bb; + + Addr = ADD(Addr, CONST(8)); + } + } + LET(13, SUB(R(13), CONST(imm32))); + + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VSTM */ +/* cond 110P UDW0 Rn-- Vd-- 101X imm8 imm8 */ +#define vfpinstr vstm +#define vfpinstr_inst vstm_inst +#define VFPLABEL_INST VSTM_INST +#ifdef VFP_DECODE +{"vstm", 3, ARMVFP2, 25, 27, 0x6, 20, 20, 0, 9, 11, 0x5}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vstm", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vstm_inst { + unsigned int single; + unsigned int add; + unsigned int wback; + unsigned int d; + unsigned int n; + unsigned int imm32; + unsigned int regs; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->add = BIT(inst, 23); + inst_cream->wback = BIT(inst, 21); + inst_cream->d = (inst_cream->single ? BITS(inst, 12, 15)<<1|BIT(inst, 22) : BITS(inst, 12, 15)|BIT(inst, 22)<<4); + inst_cream->n = BITS(inst, 16, 19); + inst_cream->imm32 = BITS(inst, 0, 7)<<2; + inst_cream->regs = (inst_cream->single ? BITS(inst, 0, 7) : BITS(inst, 1, 7)); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: /* encoding 1 */ +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + int i; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + addr = (inst_cream->add ? cpu->Reg[inst_cream->n] : cpu->Reg[inst_cream->n] - inst_cream->imm32); + DBG("VSTM : addr[%x]\n", addr); + + + for (i = 0; i < inst_cream->regs; i++) + { + if (inst_cream->single) + { + fault = check_address_validity(cpu, addr, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d+i], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\taddr[%x] <= s%d=[%x]\n", addr, inst_cream->d+i, cpu->ExtReg[inst_cream->d+i]); + addr += 4; + } + else + { + /* Careful of endianness, little by default */ + fault = check_address_validity(cpu, addr, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2], 32); + if (fault) goto MMU_EXCEPTION; + + fault = check_address_validity(cpu, addr + 4, &phys_addr, 0); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_write_memory(core, addr + 4, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2 + 1], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\taddr[%x-%x] <= s[%d-%d]=[%x-%x]\n", addr+4, addr, (inst_cream->d+i)*2+1, (inst_cream->d+i)*2, cpu->ExtReg[(inst_cream->d+i)*2+1], cpu->ExtReg[(inst_cream->d+i)*2]); + addr += 8; + } + } + if (inst_cream->wback){ + cpu->Reg[inst_cream->n] = (inst_cream->add ? cpu->Reg[inst_cream->n] + inst_cream->imm32 : + cpu->Reg[inst_cream->n] - inst_cream->imm32); + DBG("\twback r%d[%x]\n", inst_cream->n, cpu->Reg[inst_cream->n]); + } + + } + cpu->Reg[15] += 4; + INC_PC(sizeof(vstm_inst)); + + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_STC_TRANS +/* Should be the last operation of STC */ +return VSTM(state, type, instr, value); +#endif +#ifdef VFP_STC_IMPL +int VSTM(ARMul_State * state, int type, ARMword instr, ARMword * value) +{ + static int i = 0; + static int single_regs, add, wback, d, n, imm32, regs; + if (type == ARMul_FIRST) + { + single_regs = BIT(8) == 0; /* Single precision */ + add = BIT(23); /* */ + wback = BIT(21); /* write-back */ + d = single_regs ? BITS(12, 15)<<1|BIT(22) : BIT(22)<<4|BITS(12, 15); /* Base register */ + n = BITS(16, 19); /* destination register */ + imm32 = BITS(0,7) * 4; /* may not be used */ + regs = single_regs ? BITS(0, 7) : BITS(0, 7)>>1; /* FSTMX if regs is odd */ + + DBG("VSTM :\n"); + + if (wback) { + state->Reg[n] = (add ? state->Reg[n] + imm32 : state->Reg[n] - imm32); + DBG("\twback r%d[%x]\n", n, state->Reg[n]); + } + + i = 0; + + return ARMul_DONE; + } + else if (type == ARMul_DATA) + { + if (single_regs) + { + *value = state->ExtReg[d + i]; + DBG("\taddr[?] <= s%d=[%x]\n", d+i, state->ExtReg[d + i]); + i++; + if (i < regs) + return ARMul_INC; + else + return ARMul_DONE; + } + else + { + /* FIXME Careful of endianness, may need to rework this */ + *value = state->ExtReg[d*2 + i]; + DBG("\taddr[?] <= s[%d]=[%x]\n", d*2 + i, state->ExtReg[d*2 + i]); + i++; + if (i < regs*2) + return ARMul_INC; + else + return ARMul_DONE; + } + } + + return -1; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + *tag |= TAG_NEW_BB; + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + //arch_arm_undef(cpu, bb, instr); + int single = BIT(8) == 0; + int add = BIT(23); + int wback = BIT(21); + int d = single ? BITS(12, 15)<<1|BIT(22) : BITS(12, 15)|(BIT(22)<<4); + int n = BITS(16, 19); + int imm32 = BITS(0, 7)<<2; + int regs = single ? BITS(0, 7) : BITS(1, 7); + + Value* Addr = SELECT(CONST1(add), R(n), SUB(R(n), CONST(imm32))); + DBG("VSTM \n"); + //if(single) + // bb = arch_check_mm(cpu, bb, Addr, regs * 4, 0, cpu->dyncom_engine->bb_trap); + //else + // bb = arch_check_mm(cpu, bb, Addr, regs * 8, 0, cpu->dyncom_engine->bb_trap); + + int i; + Value* phys_addr; + for (i = 0; i < regs; i++) + { + if (single) + { + + //fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d+i], 32); + /* if R(i) is R15? */ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR(d + i), 32); + #endif + //memory_write(cpu, bb, Addr, RSPR(d + i), 32); + memory_write(cpu, bb, Addr, IBITCAST32(FR32(d + i)),32); + bb = cpu->dyncom_engine->bb; + //if (fault) goto MMU_EXCEPTION; + //DBG("\taddr[%x] <= s%d=[%x]\n", addr, inst_cream->d+i, cpu->ExtReg[inst_cream->d+i]); + Addr = ADD(Addr, CONST(4)); + } + else + { + + //fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2], 32); + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR((d + i) * 2), 32); + #endif + //memory_write(cpu, bb, Addr, RSPR((d + i) * 2), 32); + memory_write(cpu, bb, Addr, IBITCAST32(FR32((d + i) * 2)),32); + bb = cpu->dyncom_engine->bb; + //if (fault) goto MMU_EXCEPTION; + + //fault = interpreter_write_memory(core, addr + 4, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2 + 1], 32); + #if 0 + phys_addr = get_phys_addr(cpu, bb, ADD(Addr, CONST(4)), 0); + bb = cpu->dyncom_engine->bb; + arch_write_memory(cpu, bb, phys_addr, RSPR((d + i) * 2 + 1), 32); + #endif + //memory_write(cpu, bb, ADD(Addr, CONST(4)), RSPR((d + i) * 2 + 1), 32); + memory_write(cpu, bb, ADD(Addr, CONST(4)), IBITCAST32(FR32((d + i) * 2 + 1)), 32); + bb = cpu->dyncom_engine->bb; + //if (fault) goto MMU_EXCEPTION; + //DBG("\taddr[%x-%x] <= s[%d-%d]=[%x-%x]\n", addr+4, addr, (inst_cream->d+i)*2+1, (inst_cream->d+i)*2, cpu->ExtReg[(inst_cream->d+i)*2+1], cpu->ExtReg[(inst_cream->d+i)*2]); + //addr += 8; + Addr = ADD(Addr, CONST(8)); + } + } + if (wback){ + //cpu->Reg[n] = (add ? cpu->Reg[n] + imm32 : + // cpu->Reg[n] - imm32); + LET(n, SELECT(CONST1(add), ADD(R(n), CONST(imm32)), SUB(R(n), CONST(imm32)))); + DBG("\twback r%d, add=%d, imm32=%d\n", n, add, imm32); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VPOP */ +/* cond 1100 1D11 1101 Vd-- 101X imm8 imm8 */ +#define vfpinstr vpop +#define vfpinstr_inst vpop_inst +#define VFPLABEL_INST VPOP_INST +#ifdef VFP_DECODE +{"vpop", 3, ARMVFP2, 23, 27, 0x19, 16, 21, 0x3d, 9, 11, 0x5}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vpop", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vpop_inst { + unsigned int single; + unsigned int d; + unsigned int imm32; + unsigned int regs; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->d = (inst_cream->single ? (BITS(inst, 12, 15)<<1)|BIT(inst, 22) : BITS(inst, 12, 15)|(BIT(inst, 22)<<4)); + inst_cream->imm32 = BITS(inst, 0, 7)<<2; + inst_cream->regs = (inst_cream->single ? BITS(inst, 0, 7) : BITS(inst, 1, 7)); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + int i; + unsigned int value1, value2; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + DBG("VPOP :\n"); + + addr = cpu->Reg[R13]; + + + for (i = 0; i < inst_cream->regs; i++) + { + if (inst_cream->single) + { + fault = check_address_validity(cpu, addr, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_read_memory(core, addr, phys_addr, value1, 32); + if (fault) goto MMU_EXCEPTION; + DBG("\ts%d <= [%x] addr[%x]\n", inst_cream->d+i, value1, addr); + cpu->ExtReg[inst_cream->d+i] = value1; + addr += 4; + } + else + { + /* Careful of endianness, little by default */ + fault = check_address_validity(cpu, addr, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_read_memory(core, addr, phys_addr, value1, 32); + if (fault) goto MMU_EXCEPTION; + + fault = check_address_validity(cpu, addr + 4, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + + fault = interpreter_read_memory(core, addr + 4, phys_addr, value2, 32); + if (fault) goto MMU_EXCEPTION; + DBG("\ts[%d-%d] <= [%x-%x] addr[%x-%x]\n", (inst_cream->d+i)*2+1, (inst_cream->d+i)*2, value2, value1, addr+4, addr); + cpu->ExtReg[(inst_cream->d+i)*2] = value1; + cpu->ExtReg[(inst_cream->d+i)*2 + 1] = value2; + addr += 8; + } + } + DBG("\tsp[%x]", cpu->Reg[R13]); + cpu->Reg[R13] = cpu->Reg[R13] + inst_cream->imm32; + DBG("=>[%x]\n", cpu->Reg[R13]); + + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vpop_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_LDC_TRANS +if (P == 0 && U == 1 && W == 1 && Rn == 0xD) +{ + return VPOP(state, type, instr, value); +} +#endif +#ifdef VFP_LDC_IMPL +int VPOP(ARMul_State * state, int type, ARMword instr, ARMword value) +{ + static int i = 0; + static int single_regs, add, wback, d, n, imm32, regs; + if (type == ARMul_FIRST) + { + single_regs = BIT(8) == 0; /* Single precision */ + d = single_regs ? BITS(12, 15)<<1|BIT(22) : BIT(22)<<4|BITS(12, 15); /* Base register */ + imm32 = BITS(0,7)<<2; /* may not be used */ + regs = single_regs ? BITS(0, 7) : BITS(1, 7); /* FLDMX if regs is odd */ + + DBG("VPOP :\n"); + DBG("\tsp[%x]", state->Reg[R13]); + state->Reg[R13] = state->Reg[R13] + imm32; + DBG("=>[%x]\n", state->Reg[R13]); + + i = 0; + + return ARMul_DONE; + } + else if (type == ARMul_TRANSFER) + { + return ARMul_DONE; + } + else if (type == ARMul_DATA) + { + if (single_regs) + { + state->ExtReg[d + i] = value; + DBG("\ts%d <= [%x]\n", d + i, value); + i++; + if (i < regs) + return ARMul_INC; + else + return ARMul_DONE; + } + else + { + /* FIXME Careful of endianness, may need to rework this */ + state->ExtReg[d*2 + i] = value; + DBG("\ts%d <= [%x]\n", d*2 + i, value); + i++; + if (i < regs*2) + return ARMul_INC; + else + return ARMul_DONE; + } + } + + return -1; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + /* Should check if PC is destination register */ + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + *tag |= TAG_NEW_BB; + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + DBG("\t\tin %s instruction .\n", __FUNCTION__); + //arch_arm_undef(cpu, bb, instr); + int single = BIT(8) == 0; + int d = (single ? BITS(12, 15)<<1|BIT(22) : BITS(12, 15)|(BIT(22)<<4)); + int imm32 = BITS(0, 7)<<2; + int regs = (single ? BITS(0, 7) : BITS(1, 7)); + + int i; + unsigned int value1, value2; + + DBG("VPOP :\n"); + + Value* Addr = R(13); + Value* val; + //if(single) + // bb = arch_check_mm(cpu, bb, Addr, regs * 4, 1, cpu->dyncom_engine->bb_trap); + //else + // bb = arch_check_mm(cpu, bb, Addr, regs * 4, 1, cpu->dyncom_engine->bb_trap); + //Value* phys_addr; + for (i = 0; i < regs; i++) + { + if (single) + { + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + LETFPS(d + i, FPBITCAST32(val)); + Addr = ADD(Addr, CONST(4)); + } + else + { + /* Careful of endianness, little by default */ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + LETFPS((d + i) * 2, FPBITCAST32(val)); + #if 0 + phys_addr = get_phys_addr(cpu, bb, ADD(Addr, CONST(4)), 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, ADD(Addr, CONST(4)), 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + LETFPS((d + i) * 2 + 1, FPBITCAST32(val)); + + Addr = ADD(Addr, CONST(8)); + } + } + LET(13, ADD(R(13), CONST(imm32))); + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VLDR */ +/* cond 1101 UD01 Rn-- Vd-- 101X imm8 imm8 */ +#define vfpinstr vldr +#define vfpinstr_inst vldr_inst +#define VFPLABEL_INST VLDR_INST +#ifdef VFP_DECODE +{"vldr", 3, ARMVFP2, 24, 27, 0xd, 20, 21, 0x1, 9, 11, 0x5}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vldr", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vldr_inst { + unsigned int single; + unsigned int n; + unsigned int d; + unsigned int imm32; + unsigned int add; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->add = BIT(inst, 23); + inst_cream->imm32 = BITS(inst, 0,7) << 2; + inst_cream->d = (inst_cream->single ? BITS(inst, 12, 15)<<1|BIT(inst, 22) : BITS(inst, 12, 15)|BIT(inst, 22)<<4); + inst_cream->n = BITS(inst, 16, 19); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + unsigned int base = (inst_cream->n == 15 ? (cpu->Reg[inst_cream->n] & 0xFFFFFFFC) + 8 : cpu->Reg[inst_cream->n]); + addr = (inst_cream->add ? base + inst_cream->imm32 : base - inst_cream->imm32); + DBG("VLDR :\n", addr); + + + if (inst_cream->single) + { + fault = check_address_validity(cpu, addr, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_read_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\ts%d <= [%x] addr[%x]\n", inst_cream->d, cpu->ExtReg[inst_cream->d], addr); + } + else + { + unsigned int word1, word2; + fault = check_address_validity(cpu, addr, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_read_memory(core, addr, phys_addr, word1, 32); + if (fault) goto MMU_EXCEPTION; + + fault = check_address_validity(cpu, addr + 4, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_read_memory(core, addr + 4, phys_addr, word2, 32); + if (fault) goto MMU_EXCEPTION; + /* Check endianness */ + cpu->ExtReg[inst_cream->d*2] = word1; + cpu->ExtReg[inst_cream->d*2+1] = word2; + DBG("\ts[%d-%d] <= [%x-%x] addr[%x-%x]\n", inst_cream->d*2+1, inst_cream->d*2, word2, word1, addr+4, addr); + } + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vldr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_LDC_TRANS +if (P == 1 && W == 0) +{ + return VLDR(state, type, instr, value); +} +#endif +#ifdef VFP_LDC_IMPL +int VLDR(ARMul_State * state, int type, ARMword instr, ARMword value) +{ + static int i = 0; + static int single_reg, add, d, n, imm32, regs; + if (type == ARMul_FIRST) + { + single_reg = BIT(8) == 0; /* Double precision */ + add = BIT(23); /* */ + imm32 = BITS(0,7)<<2; /* may not be used */ + d = single_reg ? BITS(12, 15)<<1|BIT(22) : BIT(22)<<4|BITS(12, 15); /* Base register */ + n = BITS(16, 19); /* destination register */ + + DBG("VLDR :\n"); + + i = 0; + regs = 1; + + return ARMul_DONE; + } + else if (type == ARMul_TRANSFER) + { + return ARMul_DONE; + } + else if (type == ARMul_DATA) + { + if (single_reg) + { + state->ExtReg[d+i] = value; + DBG("\ts%d <= [%x]\n", d+i, value); + i++; + if (i < regs) + return ARMul_INC; + else + return ARMul_DONE; + } + else + { + /* FIXME Careful of endianness, may need to rework this */ + state->ExtReg[d*2+i] = value; + DBG("\ts[%d] <= [%x]\n", d*2+i, value); + i++; + if (i < regs*2) + return ARMul_INC; + else + return ARMul_DONE; + } + } + + return -1; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + /* Should check if PC is destination register */ + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + *tag |= TAG_NEW_BB; + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + int single = BIT(8) == 0; + int add = BIT(23); + int wback = BIT(21); + int d = (single ? BITS(12, 15)<<1|BIT(22) : BITS(12, 15)|(BIT(22)<<4)); + int n = BITS(16, 19); + int imm32 = BITS(0, 7)<<2; + int regs = (single ? BITS(0, 7) : BITS(1, 7)); + Value* base = R(n); + DBG("\t\tin %s .\n", __FUNCTION__); + if(n == 15){ + base = ADD(AND(base, CONST(0xFFFFFFFC)), CONST(8)); + } + Value* Addr = add ? (ADD(base, CONST(imm32))) : (SUB(base, CONST(imm32))); + //if(single) + // bb = arch_check_mm(cpu, bb, Addr, 4, 1, cpu->dyncom_engine->bb_trap); + //else + // bb = arch_check_mm(cpu, bb, Addr, 8, 1, cpu->dyncom_engine->bb_trap); + //Value* phys_addr; + Value* val; + if(single){ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + //LETS(d, val); + LETFPS(d,FPBITCAST32(val)); + } + else{ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + //LETS(d * 2, val); + LETFPS(d * 2,FPBITCAST32(val)); + #if 0 + phys_addr = get_phys_addr(cpu, bb, ADD(Addr, CONST(4)), 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, ADD(Addr, CONST(4)), 0,32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + //LETS(d * 2 + 1, val); + LETFPS( d * 2 + 1,FPBITCAST32(val)); + } + + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +/* ----------------------------------------------------------------------- */ +/* VLDM */ +/* cond 110P UDW1 Rn-- Vd-- 101X imm8 imm8 */ +#define vfpinstr vldm +#define vfpinstr_inst vldm_inst +#define VFPLABEL_INST VLDM_INST +#ifdef VFP_DECODE +{"vldm", 3, ARMVFP2, 25, 27, 0x6, 20, 20, 1, 9, 11, 0x5}, +#endif +#ifdef VFP_DECODE_EXCLUSION +{"vldm", 0, ARMVFP2, 0}, +#endif +#ifdef VFP_INTERPRETER_TABLE +INTERPRETER_TRANSLATE(vfpinstr), +#endif +#ifdef VFP_INTERPRETER_LABEL +&&VFPLABEL_INST, +#endif +#ifdef VFP_INTERPRETER_STRUCT +typedef struct _vldm_inst { + unsigned int single; + unsigned int add; + unsigned int wback; + unsigned int d; + unsigned int n; + unsigned int imm32; + unsigned int regs; +} vfpinstr_inst; +#endif +#ifdef VFP_INTERPRETER_TRANS +ARM_INST_PTR INTERPRETER_TRANSLATE(vfpinstr)(unsigned int inst, int index) +{ + VFP_DEBUG_TRANSLATE; + + arm_inst *inst_base = (arm_inst *)AllocBuffer(sizeof(arm_inst) + sizeof(vfpinstr_inst)); + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + inst_base->cond = BITS(inst, 28, 31); + inst_base->idx = index; + inst_base->br = NON_BRANCH; + inst_base->load_r15 = 0; + + inst_cream->single = BIT(inst, 8) == 0; + inst_cream->add = BIT(inst, 23); + inst_cream->wback = BIT(inst, 21); + inst_cream->d = (inst_cream->single ? BITS(inst, 12, 15)<<1|BIT(inst, 22) : BITS(inst, 12, 15)|BIT(inst, 22)<<4); + inst_cream->n = BITS(inst, 16, 19); + inst_cream->imm32 = BITS(inst, 0, 7)<<2; + inst_cream->regs = (inst_cream->single ? BITS(inst, 0, 7) : BITS(inst, 1, 7)); + + return inst_base; +} +#endif +#ifdef VFP_INTERPRETER_IMPL +VFPLABEL_INST: +{ + INC_ICOUNTER; + if ((inst_base->cond == 0xe) || CondPassed(cpu, inst_base->cond)) { + CHECK_VFP_ENABLED; + + int i; + + vfpinstr_inst *inst_cream = (vfpinstr_inst *)inst_base->component; + + addr = (inst_cream->add ? cpu->Reg[inst_cream->n] : cpu->Reg[inst_cream->n] - inst_cream->imm32); + DBG("VLDM : addr[%x]\n", addr); + + for (i = 0; i < inst_cream->regs; i++) + { + if (inst_cream->single) + { + fault = check_address_validity(cpu, addr, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_read_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d+i], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\ts%d <= [%x] addr[%x]\n", inst_cream->d+i, cpu->ExtReg[inst_cream->d+i], addr); + addr += 4; + } + else + { + /* Careful of endianness, little by default */ + fault = check_address_validity(cpu, addr, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_read_memory(core, addr, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2], 32); + if (fault) goto MMU_EXCEPTION; + + fault = check_address_validity(cpu, addr + 4, &phys_addr, 1); + if (fault) goto MMU_EXCEPTION; + fault = interpreter_read_memory(core, addr + 4, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2 + 1], 32); + if (fault) goto MMU_EXCEPTION; + DBG("\ts[%d-%d] <= [%x-%x] addr[%x-%x]\n", (inst_cream->d+i)*2+1, (inst_cream->d+i)*2, cpu->ExtReg[(inst_cream->d+i)*2+1], cpu->ExtReg[(inst_cream->d+i)*2], addr+4, addr); + addr += 8; + } + } + if (inst_cream->wback){ + cpu->Reg[inst_cream->n] = (inst_cream->add ? cpu->Reg[inst_cream->n] + inst_cream->imm32 : + cpu->Reg[inst_cream->n] - inst_cream->imm32); + DBG("\twback r%d[%x]\n", inst_cream->n, cpu->Reg[inst_cream->n]); + } + + } + cpu->Reg[15] += GET_INST_SIZE(cpu); + INC_PC(sizeof(vfpinstr_inst)); + FETCH_INST; + GOTO_NEXT_INST; +} +#endif +#ifdef VFP_LDC_TRANS +/* Should be the last operation of LDC */ +return VLDM(state, type, instr, value); +#endif +#ifdef VFP_LDC_IMPL +int VLDM(ARMul_State * state, int type, ARMword instr, ARMword value) +{ + static int i = 0; + static int single_regs, add, wback, d, n, imm32, regs; + if (type == ARMul_FIRST) + { + single_regs = BIT(8) == 0; /* Single precision */ + add = BIT(23); /* */ + wback = BIT(21); /* write-back */ + d = single_regs ? BITS(12, 15)<<1|BIT(22) : BIT(22)<<4|BITS(12, 15); /* Base register */ + n = BITS(16, 19); /* destination register */ + imm32 = BITS(0,7) * 4; /* may not be used */ + regs = single_regs ? BITS(0, 7) : BITS(0, 7)>>1; /* FLDMX if regs is odd */ + + DBG("VLDM :\n"); + + if (wback) { + state->Reg[n] = (add ? state->Reg[n] + imm32 : state->Reg[n] - imm32); + DBG("\twback r%d[%x]\n", n, state->Reg[n]); + } + + i = 0; + + return ARMul_DONE; + } + else if (type == ARMul_DATA) + { + if (single_regs) + { + state->ExtReg[d + i] = value; + DBG("\ts%d <= [%x] addr[?]\n", d+i, state->ExtReg[d + i]); + i++; + if (i < regs) + return ARMul_INC; + else + return ARMul_DONE; + } + else + { + /* FIXME Careful of endianness, may need to rework this */ + state->ExtReg[d*2 + i] = value; + DBG("\ts[%d] <= [%x] addr[?]\n", d*2 + i, state->ExtReg[d*2 + i]); + i++; + if (i < regs*2) + return ARMul_INC; + else + return ARMul_DONE; + } + } + + return -1; +} +#endif +#ifdef VFP_DYNCOM_TABLE +DYNCOM_FILL_ACTION(vfpinstr), +#endif +#ifdef VFP_DYNCOM_TAG +int DYNCOM_TAG(vfpinstr)(cpu_t *cpu, addr_t pc, uint32_t instr, tag_t *tag, addr_t *new_pc, addr_t *next_pc) +{ + int instr_size = INSTR_SIZE; + //DBG("\t\tin %s instruction is not implemented.\n", __FUNCTION__); + //arm_tag_trap(cpu, pc, instr, tag, new_pc, next_pc); + arm_tag_continue(cpu, pc, instr, tag, new_pc, next_pc); + DBG("In %s, pc=0x%x, next_pc=0x%x\n", __FUNCTION__, pc, *next_pc); + *tag |= TAG_NEW_BB; + if(instr >> 28 != 0xe) + *tag |= TAG_CONDITIONAL; + + return instr_size; +} +#endif +#ifdef VFP_DYNCOM_TRANS +int DYNCOM_TRANS(vfpinstr)(cpu_t *cpu, uint32_t instr, BasicBlock *bb, addr_t pc){ + int single = BIT(8) == 0; + int add = BIT(23); + int wback = BIT(21); + int d = single ? BITS(12, 15)<<1|BIT(22) : BITS(12, 15)|BIT(22)<<4; + int n = BITS(16, 19); + int imm32 = BITS(0, 7)<<2; + int regs = single ? BITS(0, 7) : BITS(1, 7); + + Value* Addr = SELECT(CONST1(add), R(n), SUB(R(n), CONST(imm32))); + //if(single) + // bb = arch_check_mm(cpu, bb, Addr, regs * 4, 1, cpu->dyncom_engine->bb_trap); + //else + // bb = arch_check_mm(cpu, bb, Addr, regs * 4, 1, cpu->dyncom_engine->bb_trap); + + DBG("VLDM \n"); + int i; + //Value* phys_addr; + Value* val; + for (i = 0; i < regs; i++) + { + if (single) + { + + //fault = interpreter_write_memory(core, addr, phys_addr, cpu->ExtReg[inst_cream->d+i], 32); + /* if R(i) is R15? */ + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + //LETS(d + i, val); + LETFPS(d + i, FPBITCAST32(val)); + //if (fault) goto MMU_EXCEPTION; + //DBG("\taddr[%x] <= s%d=[%x]\n", addr, inst_cream->d+i, cpu->ExtReg[inst_cream->d+i]); + Addr = ADD(Addr, CONST(4)); + } + else + { + #if 0 + phys_addr = get_phys_addr(cpu, bb, Addr, 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + LETFPS((d + i) * 2, FPBITCAST32(val)); + #if 0 + phys_addr = get_phys_addr(cpu, bb, ADD(Addr, CONST(4)), 1); + bb = cpu->dyncom_engine->bb; + val = arch_read_memory(cpu,bb,phys_addr,0,32); + #endif + memory_read(cpu, bb, Addr, 0, 32); + bb = cpu->dyncom_engine->bb; + val = new LoadInst(cpu->dyncom_engine->read_value, "", false, bb); + LETFPS((d + i) * 2 + 1, FPBITCAST32(val)); + + //fault = interpreter_write_memory(core, addr + 4, phys_addr, cpu->ExtReg[(inst_cream->d+i)*2 + 1], 32); + //DBG("\taddr[%x-%x] <= s[%d-%d]=[%x-%x]\n", addr+4, addr, (inst_cream->d+i)*2+1, (inst_cream->d+i)*2, cpu->ExtReg[(inst_cream->d+i)*2+1], cpu->ExtReg[(inst_cream->d+i)*2]); + //addr += 8; + Addr = ADD(Addr, CONST(8)); + } + } + if (wback){ + //cpu->Reg[n] = (add ? cpu->Reg[n] + imm32 : + // cpu->Reg[n] - imm32); + LET(n, SELECT(CONST1(add), ADD(R(n), CONST(imm32)), SUB(R(n), CONST(imm32)))); + DBG("\twback r%d, add=%d, imm32=%d\n", n, add, imm32); + } + return No_exp; +} +#endif +#undef vfpinstr +#undef vfpinstr_inst +#undef VFPLABEL_INST + +#define VFP_DEBUG_TRANSLATE DBG("in func %s, %x\n", __FUNCTION__, inst); +#define VFP_DEBUG_UNIMPLEMENTED(x) printf("in func %s, " #x " unimplemented\n", __FUNCTION__); exit(-1); +#define VFP_DEBUG_UNTESTED(x) printf("in func %s, " #x " untested\n", __FUNCTION__); + +#define CHECK_VFP_ENABLED + +#define CHECK_VFP_CDP_RET vfp_raise_exceptions(cpu, ret, inst_cream->instr, cpu->VFP[VFP_OFFSET(VFP_FPSCR)]); //if (ret == -1) {printf("VFP CDP FAILURE %x\n", inst_cream->instr); exit(-1);} -- cgit v1.2.3