/* Copyright (c) 2013-2014 Jeffrey Pfau * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "isa-arm.h" #include "arm.h" #include "emitter-arm.h" #include "isa-inlines.h" #define PSR_USER_MASK 0xF0000000 #define PSR_PRIV_MASK 0x000000CF #define PSR_STATE_MASK 0x00000020 // Addressing mode 1 static inline void _shiftLSL(struct ARMCore* cpu, uint32_t opcode) { int rm = opcode & 0x0000000F; if (opcode & 0x00000010) { int rs = (opcode >> 8) & 0x0000000F; ++cpu->cycles; int shift = cpu->gprs[rs]; if (rs == ARM_PC) { shift += 4; } shift &= 0xFF; int32_t shiftVal = cpu->gprs[rm]; if (rm == ARM_PC) { shiftVal += 4; } if (!shift) { cpu->shifterOperand = shiftVal; cpu->shifterCarryOut = cpu->cpsr.c; } else if (shift < 32) { cpu->shifterOperand = shiftVal << shift; cpu->shifterCarryOut = (shiftVal >> (32 - shift)) & 1; } else if (shift == 32) { cpu->shifterOperand = 0; cpu->shifterCarryOut = shiftVal & 1; } else { cpu->shifterOperand = 0; cpu->shifterCarryOut = 0; } } else { int immediate = (opcode & 0x00000F80) >> 7; if (!immediate) { cpu->shifterOperand = cpu->gprs[rm]; cpu->shifterCarryOut = cpu->cpsr.c; } else { cpu->shifterOperand = cpu->gprs[rm] << immediate; cpu->shifterCarryOut = (cpu->gprs[rm] >> (32 - immediate)) & 1; } } } static inline void _shiftLSR(struct ARMCore* cpu, uint32_t opcode) { int rm = opcode & 0x0000000F; if (opcode & 0x00000010) { int rs = (opcode >> 8) & 0x0000000F; ++cpu->cycles; int shift = cpu->gprs[rs]; if (rs == ARM_PC) { shift += 4; } shift &= 0xFF; uint32_t shiftVal = cpu->gprs[rm]; if (rm == ARM_PC) { shiftVal += 4; } if (!shift) { cpu->shifterOperand = shiftVal; cpu->shifterCarryOut = cpu->cpsr.c; } else if (shift < 32) { cpu->shifterOperand = shiftVal >> shift; cpu->shifterCarryOut = (shiftVal >> (shift - 1)) & 1; } else if (shift == 32) { cpu->shifterOperand = 0; cpu->shifterCarryOut = shiftVal >> 31; } else { cpu->shifterOperand = 0; cpu->shifterCarryOut = 0; } } else { int immediate = (opcode & 0x00000F80) >> 7; if (immediate) { cpu->shifterOperand = ((uint32_t) cpu->gprs[rm]) >> immediate; cpu->shifterCarryOut = (cpu->gprs[rm] >> (immediate - 1)) & 1; } else { cpu->shifterOperand = 0; cpu->shifterCarryOut = ARM_SIGN(cpu->gprs[rm]); } } } static inline void _shiftASR(struct ARMCore* cpu, uint32_t opcode) { int rm = opcode & 0x0000000F; if (opcode & 0x00000010) { int rs = (opcode >> 8) & 0x0000000F; ++cpu->cycles; int shift = cpu->gprs[rs]; if (rs == ARM_PC) { shift += 4; } shift &= 0xFF; int shiftVal = cpu->gprs[rm]; if (rm == ARM_PC) { shiftVal += 4; } if (!shift) { cpu->shifterOperand = shiftVal; cpu->shifterCarryOut = cpu->cpsr.c; } else if (shift < 32) { cpu->shifterOperand = shiftVal >> shift; cpu->shifterCarryOut = (shiftVal >> (shift - 1)) & 1; } else if (cpu->gprs[rm] >> 31) { cpu->shifterOperand = 0xFFFFFFFF; cpu->shifterCarryOut = 1; } else { cpu->shifterOperand = 0; cpu->shifterCarryOut = 0; } } else { int immediate = (opcode & 0x00000F80) >> 7; if (immediate) { cpu->shifterOperand = cpu->gprs[rm] >> immediate; cpu->shifterCarryOut = (cpu->gprs[rm] >> (immediate - 1)) & 1; } else { cpu->shifterCarryOut = ARM_SIGN(cpu->gprs[rm]); cpu->shifterOperand = cpu->shifterCarryOut; } } } static inline void _shiftROR(struct ARMCore* cpu, uint32_t opcode) { int rm = opcode & 0x0000000F; if (opcode & 0x00000010) { int rs = (opcode >> 8) & 0x0000000F; ++cpu->cycles; int shift = cpu->gprs[rs]; if (rs == ARM_PC) { shift += 4; } shift &= 0xFF; int shiftVal = cpu->gprs[rm]; if (rm == ARM_PC) { shiftVal += 4; } int rotate = shift & 0x1F; if (!shift) { cpu->shifterOperand = shiftVal; cpu->shifterCarryOut = cpu->cpsr.c; } else if (rotate) { cpu->shifterOperand = ROR(shiftVal, rotate); cpu->shifterCarryOut = (shiftVal >> (rotate - 1)) & 1; } else { cpu->shifterOperand = shiftVal; cpu->shifterCarryOut = ARM_SIGN(shiftVal); } } else { int immediate = (opcode & 0x00000F80) >> 7; if (immediate) { cpu->shifterOperand = ROR(cpu->gprs[rm], immediate); cpu->shifterCarryOut = (cpu->gprs[rm] >> (immediate - 1)) & 1; } else { // RRX cpu->shifterOperand = (cpu->cpsr.c << 31) | (((uint32_t) cpu->gprs[rm]) >> 1); cpu->shifterCarryOut = cpu->gprs[rm] & 0x00000001; } } } static inline void _immediate(struct ARMCore* cpu, uint32_t opcode) { int rotate = (opcode & 0x00000F00) >> 7; int immediate = opcode & 0x000000FF; if (!rotate) { cpu->shifterOperand = immediate; cpu->shifterCarryOut = cpu->cpsr.c; } else { cpu->shifterOperand = ROR(immediate, rotate); cpu->shifterCarryOut = ARM_SIGN(cpu->shifterOperand); } } // Instruction definitions // Beware pre-processor antics ATTRIBUTE_NOINLINE static void _additionS(struct ARMCore* cpu, int32_t m, int32_t n, int32_t d) { cpu->cpsr.flags = 0; cpu->cpsr.n = ARM_SIGN(d); cpu->cpsr.z = !d; cpu->cpsr.c = ARM_CARRY_FROM(m, n, d); cpu->cpsr.v = ARM_V_ADDITION(m, n, d); } ATTRIBUTE_NOINLINE static void _subtractionS(struct ARMCore* cpu, int32_t m, int32_t n, int32_t d) { cpu->cpsr.flags = 0; cpu->cpsr.n = ARM_SIGN(d); cpu->cpsr.z = !d; cpu->cpsr.c = ARM_BORROW_FROM(m, n, d); cpu->cpsr.v = ARM_V_SUBTRACTION(m, n, d); } ATTRIBUTE_NOINLINE static void _neutralS(struct ARMCore* cpu, int32_t d) { cpu->cpsr.n = ARM_SIGN(d); cpu->cpsr.z = !d; \ cpu->cpsr.c = cpu->shifterCarryOut; \ } #define ARM_ADDITION_S(M, N, D) \ if (rd == ARM_PC && _ARMModeHasSPSR(cpu->cpsr.priv)) { \ cpu->cpsr = cpu->spsr; \ _ARMReadCPSR(cpu); \ } else { \ _additionS(cpu, M, N, D); \ } #define ARM_SUBTRACTION_S(M, N, D) \ if (rd == ARM_PC && _ARMModeHasSPSR(cpu->cpsr.priv)) { \ cpu->cpsr = cpu->spsr; \ _ARMReadCPSR(cpu); \ } else { \ _subtractionS(cpu, M, N, D); \ } #define ARM_SUBTRACTION_CARRY_S(M, N, D, C) \ if (rd == ARM_PC && _ARMModeHasSPSR(cpu->cpsr.priv)) { \ cpu->cpsr = cpu->spsr; \ _ARMReadCPSR(cpu); \ } else { \ cpu->cpsr.n = ARM_SIGN(D); \ cpu->cpsr.z = !(D); \ cpu->cpsr.c = ARM_BORROW_FROM_CARRY(M, N, D, C); \ cpu->cpsr.v = ARM_V_SUBTRACTION(M, N, D); \ } #define ARM_NEUTRAL_S(M, N, D) \ if (rd == ARM_PC && _ARMModeHasSPSR(cpu->cpsr.priv)) { \ cpu->cpsr = cpu->spsr; \ _ARMReadCPSR(cpu); \ } else { \ _neutralS(cpu, D); \ } #define ARM_NEUTRAL_HI_S(DLO, DHI) \ cpu->cpsr.n = ARM_SIGN(DHI); \ cpu->cpsr.z = !((DHI) | (DLO)); #define ADDR_MODE_2_I_TEST (opcode & 0x00000F80) #define ADDR_MODE_2_I ((opcode & 0x00000F80) >> 7) #define ADDR_MODE_2_ADDRESS (address) #define ADDR_MODE_2_RN (cpu->gprs[rn]) #define ADDR_MODE_2_RM (cpu->gprs[rm]) #define ADDR_MODE_2_IMMEDIATE (opcode & 0x00000FFF) #define ADDR_MODE_2_INDEX(U_OP, M) (cpu->gprs[rn] U_OP M) #define ADDR_MODE_2_WRITEBACK(ADDR) \ cpu->gprs[rn] = ADDR; \ if (UNLIKELY(rn == ARM_PC)) { \ currentCycles += ARMWritePC(cpu); \ } #define ADDR_MODE_2_WRITEBACK_PRE_STORE(WB) #define ADDR_MODE_2_WRITEBACK_POST_STORE(WB) WB #define ADDR_MODE_2_WRITEBACK_PRE_LOAD(WB) WB #define ADDR_MODE_2_WRITEBACK_POST_LOAD(WB) #define ADDR_MODE_2_LSL (cpu->gprs[rm] << ADDR_MODE_2_I) #define ADDR_MODE_2_LSR (ADDR_MODE_2_I_TEST ? ((uint32_t) cpu->gprs[rm]) >> ADDR_MODE_2_I : 0) #define ADDR_MODE_2_ASR (ADDR_MODE_2_I_TEST ? ((int32_t) cpu->gprs[rm]) >> ADDR_MODE_2_I : ((int32_t) cpu->gprs[rm]) >> 31) #define ADDR_MODE_2_ROR (ADDR_MODE_2_I_TEST ? ROR(cpu->gprs[rm], ADDR_MODE_2_I) : (cpu->cpsr.c << 31) | (((uint32_t) cpu->gprs[rm]) >> 1)) #define ADDR_MODE_3_ADDRESS ADDR_MODE_2_ADDRESS #define ADDR_MODE_3_RN ADDR_MODE_2_RN #define ADDR_MODE_3_RM ADDR_MODE_2_RM #define ADDR_MODE_3_IMMEDIATE (((opcode & 0x00000F00) >> 4) | (opcode & 0x0000000F)) #define ADDR_MODE_3_INDEX(U_OP, M) ADDR_MODE_2_INDEX(U_OP, M) #define ADDR_MODE_3_WRITEBACK(ADDR) ADDR_MODE_2_WRITEBACK(ADDR) #define ADDR_MODE_4_WRITEBACK_LDM \ if (!((1 << rn) & rs)) { \ cpu->gprs[rn] = address; \ } #define ADDR_MODE_4_WRITEBACK_STM cpu->gprs[rn] = address; #define ARM_LOAD_POST_BODY \ currentCycles += cpu->memory.activeNonseqCycles32 - cpu->memory.activeSeqCycles32; \ if (rd == ARM_PC) { \ currentCycles += ARMWritePC(cpu); \ } #define ARM_STORE_POST_BODY \ currentCycles += cpu->memory.activeNonseqCycles32 - cpu->memory.activeSeqCycles32; #define DEFINE_INSTRUCTION_ARM(NAME, BODY) \ static void _ARMInstruction ## NAME (struct ARMCore* cpu, uint32_t opcode) { \ int currentCycles = ARM_PREFETCH_CYCLES; \ BODY; \ cpu->cycles += currentCycles; \ } #define DEFINE_ALU_INSTRUCTION_EX_ARM(NAME, S_BODY, SHIFTER, BODY) \ DEFINE_INSTRUCTION_ARM(NAME, \ int rd = (opcode >> 12) & 0xF; \ int rn = (opcode >> 16) & 0xF; \ UNUSED(rn); \ SHIFTER(cpu, opcode); \ BODY; \ S_BODY; \ if (rd == ARM_PC) { \ currentCycles += ARMWritePC(cpu); \ }) #define DEFINE_ALU_INSTRUCTION_ARM(NAME, S_BODY, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _LSL, , _shiftLSL, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## S_LSL, S_BODY, _shiftLSL, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _LSR, , _shiftLSR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## S_LSR, S_BODY, _shiftLSR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _ASR, , _shiftASR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## S_ASR, S_BODY, _shiftASR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _ROR, , _shiftROR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## S_ROR, S_BODY, _shiftROR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## I, , _immediate, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## SI, S_BODY, _immediate, BODY) #define DEFINE_ALU_INSTRUCTION_S_ONLY_ARM(NAME, S_BODY, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _LSL, S_BODY, _shiftLSL, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _LSR, S_BODY, _shiftLSR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _ASR, S_BODY, _shiftASR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## _ROR, S_BODY, _shiftROR, BODY) \ DEFINE_ALU_INSTRUCTION_EX_ARM(NAME ## I, S_BODY, _immediate, BODY) #define DEFINE_MULTIPLY_INSTRUCTION_EX_ARM(NAME, BODY, S_BODY) \ DEFINE_INSTRUCTION_ARM(NAME, \ int rd = (opcode >> 16) & 0xF; \ int rs = (opcode >> 8) & 0xF; \ int rm = opcode & 0xF; \ if (rd == ARM_PC) { \ return; \ } \ ARM_WAIT_MUL(cpu->gprs[rs]); \ BODY; \ S_BODY; \ currentCycles += cpu->memory.activeNonseqCycles32 - cpu->memory.activeSeqCycles32) #define DEFINE_MULTIPLY_INSTRUCTION_2_EX_ARM(NAME, BODY, S_BODY, WAIT) \ DEFINE_INSTRUCTION_ARM(NAME, \ int rd = (opcode >> 12) & 0xF; \ int rdHi = (opcode >> 16) & 0xF; \ int rs = (opcode >> 8) & 0xF; \ int rm = opcode & 0xF; \ if (rdHi == ARM_PC || rd == ARM_PC) { \ return; \ } \ currentCycles += cpu->memory.stall(cpu, WAIT); \ BODY; \ S_BODY; \ currentCycles += cpu->memory.activeNonseqCycles32 - cpu->memory.activeSeqCycles32) #define DEFINE_MULTIPLY_INSTRUCTION_ARM(NAME, BODY, S_BODY) \ DEFINE_MULTIPLY_INSTRUCTION_EX_ARM(NAME, BODY, ) \ DEFINE_MULTIPLY_INSTRUCTION_EX_ARM(NAME ## S, BODY, S_BODY) #define DEFINE_MULTIPLY_INSTRUCTION_2_ARM(NAME, BODY, S_BODY, WAIT) \ DEFINE_MULTIPLY_INSTRUCTION_2_EX_ARM(NAME, BODY, , WAIT) \ DEFINE_MULTIPLY_INSTRUCTION_2_EX_ARM(NAME ## S, BODY, S_BODY, WAIT) #define DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME, ADDRESS, WRITEBACK, LS, BODY) \ DEFINE_INSTRUCTION_ARM(NAME, \ uint32_t address; \ int rn = (opcode >> 16) & 0xF; \ int rd = (opcode >> 12) & 0xF; \ int rm = opcode & 0xF; \ UNUSED(rm); \ address = ADDRESS; \ ADDR_MODE_2_WRITEBACK_PRE_ ## LS (WRITEBACK); \ BODY; \ ADDR_MODE_2_WRITEBACK_POST_ ## LS (WRITEBACK);) #define DEFINE_LOAD_STORE_INSTRUCTION_SHIFTER_ARM(NAME, SHIFTER, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME, ADDR_MODE_2_RN, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(-, SHIFTER)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## U, ADDR_MODE_2_RN, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(+, SHIFTER)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## P, ADDR_MODE_2_INDEX(-, SHIFTER), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## PW, ADDR_MODE_2_INDEX(-, SHIFTER), ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_ADDRESS), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## PU, ADDR_MODE_2_INDEX(+, SHIFTER), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## PUW, ADDR_MODE_2_INDEX(+, SHIFTER), ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_ADDRESS), LS, BODY) #define DEFINE_LOAD_STORE_INSTRUCTION_ARM(NAME, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_SHIFTER_ARM(NAME ## _LSL_, ADDR_MODE_2_LSL, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_SHIFTER_ARM(NAME ## _LSR_, ADDR_MODE_2_LSR, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_SHIFTER_ARM(NAME ## _ASR_, ADDR_MODE_2_ASR, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_SHIFTER_ARM(NAME ## _ROR_, ADDR_MODE_2_ROR, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## I, ADDR_MODE_2_RN, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(-, ADDR_MODE_2_IMMEDIATE)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IU, ADDR_MODE_2_RN, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(+, ADDR_MODE_2_IMMEDIATE)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IP, ADDR_MODE_2_INDEX(-, ADDR_MODE_2_IMMEDIATE), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IPW, ADDR_MODE_2_INDEX(-, ADDR_MODE_2_IMMEDIATE), ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_ADDRESS), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IPU, ADDR_MODE_2_INDEX(+, ADDR_MODE_2_IMMEDIATE), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IPUW, ADDR_MODE_2_INDEX(+, ADDR_MODE_2_IMMEDIATE), ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_ADDRESS), LS, BODY) \ #define DEFINE_LOAD_STORE_MODE_3_INSTRUCTION_ARM(NAME, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME, ADDR_MODE_3_RN, ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_INDEX(-, ADDR_MODE_3_RM)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## U, ADDR_MODE_3_RN, ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_INDEX(+, ADDR_MODE_3_RM)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## P, ADDR_MODE_3_INDEX(-, ADDR_MODE_3_RM), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## PW, ADDR_MODE_3_INDEX(-, ADDR_MODE_3_RM), ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_ADDRESS), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## PU, ADDR_MODE_3_INDEX(+, ADDR_MODE_3_RM), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## PUW, ADDR_MODE_3_INDEX(+, ADDR_MODE_3_RM), ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_ADDRESS), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## I, ADDR_MODE_3_RN, ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_INDEX(-, ADDR_MODE_3_IMMEDIATE)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IU, ADDR_MODE_3_RN, ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_INDEX(+, ADDR_MODE_3_IMMEDIATE)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IP, ADDR_MODE_3_INDEX(-, ADDR_MODE_3_IMMEDIATE), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IPW, ADDR_MODE_3_INDEX(-, ADDR_MODE_3_IMMEDIATE), ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_ADDRESS), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IPU, ADDR_MODE_3_INDEX(+, ADDR_MODE_3_IMMEDIATE), , LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IPUW, ADDR_MODE_3_INDEX(+, ADDR_MODE_3_IMMEDIATE), ADDR_MODE_3_WRITEBACK(ADDR_MODE_3_ADDRESS), LS, BODY) \ #define DEFINE_LOAD_STORE_T_INSTRUCTION_SHIFTER_ARM(NAME, SHIFTER, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME, SHIFTER, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(-, ADDR_MODE_2_RM)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## U, SHIFTER, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(+, ADDR_MODE_2_RM)), LS, BODY) \ #define DEFINE_LOAD_STORE_T_INSTRUCTION_ARM(NAME, LS, BODY) \ DEFINE_LOAD_STORE_T_INSTRUCTION_SHIFTER_ARM(NAME ## _LSL_, ADDR_MODE_2_LSL, LS, BODY) \ DEFINE_LOAD_STORE_T_INSTRUCTION_SHIFTER_ARM(NAME ## _LSR_, ADDR_MODE_2_LSR, LS, BODY) \ DEFINE_LOAD_STORE_T_INSTRUCTION_SHIFTER_ARM(NAME ## _ASR_, ADDR_MODE_2_ASR, LS, BODY) \ DEFINE_LOAD_STORE_T_INSTRUCTION_SHIFTER_ARM(NAME ## _ROR_, ADDR_MODE_2_ROR, LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## I, ADDR_MODE_2_RN, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(-, ADDR_MODE_2_IMMEDIATE)), LS, BODY) \ DEFINE_LOAD_STORE_INSTRUCTION_EX_ARM(NAME ## IU, ADDR_MODE_2_RN, ADDR_MODE_2_WRITEBACK(ADDR_MODE_2_INDEX(+, ADDR_MODE_2_IMMEDIATE)), LS, BODY) \ #define ARM_MS_PRE(IS_LOAD) \ enum PrivilegeMode privilegeMode = cpu->privilegeMode; \ if (!(opcode & 0x8000) || !IS_LOAD) ARMSetPrivilegeMode(cpu, MODE_USER); #define ARM_MS_POST(IS_LOAD) \ ARMSetPrivilegeMode(cpu, privilegeMode); \ if (IS_LOAD && (opcode & 0x8000)) { \ cpu->cpsr.packed = cpu->spsr.packed;\ ARMSetPrivilegeMode(cpu, cpu->cpsr.priv);\ } #define DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME, LS, WRITEBACK, S_PRE, S_POST, DIRECTION, POST_BODY) \ DEFINE_INSTRUCTION_ARM(NAME, \ int rn = (opcode >> 16) & 0xF; \ int rs = opcode & 0x0000FFFF; \ uint32_t address = cpu->gprs[rn]; \ S_PRE; \ address = cpu->memory. LS ## Multiple(cpu, address, rs, LSM_ ## DIRECTION, ¤tCycles); \ POST_BODY; \ WRITEBACK; \ S_POST; \ ) #define DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_ARM(NAME, LS, IS_LOAD, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## DA, LS, , , , DA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## DAW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, , , DA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## DB, LS, , , , DB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## DBW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, , , DB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## IA, LS, , , , IA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## IAW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, , , IA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## IB, LS, , , , IB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## IBW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, , , IB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SDA, LS, , ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), DA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SDAW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), DA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SDB, LS, , ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), DB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SDBW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), DB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SIA, LS, , ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), IA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SIAW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), IA, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SIB, LS, , ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), IB, POST_BODY) \ DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_EX_ARM(NAME ## SIBW, LS, ADDR_MODE_4_WRITEBACK_ ## NAME, ARM_MS_PRE(IS_LOAD), ARM_MS_POST(IS_LOAD), IB, POST_BODY) // Begin ALU definitions DEFINE_ALU_INSTRUCTION_ARM(ADD, ARM_ADDITION_S(n, cpu->shifterOperand, cpu->gprs[rd]), int32_t n = cpu->gprs[rn]; cpu->gprs[rd] = n + cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(ADC, ARM_ADDITION_S(n, cpu->shifterOperand, cpu->gprs[rd]), int32_t n = cpu->gprs[rn]; cpu->gprs[rd] = n + cpu->shifterOperand + cpu->cpsr.c;) DEFINE_ALU_INSTRUCTION_ARM(AND, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, cpu->gprs[rd]), cpu->gprs[rd] = cpu->gprs[rn] & cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(BIC, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, cpu->gprs[rd]), cpu->gprs[rd] = cpu->gprs[rn] & ~cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_S_ONLY_ARM(CMN, ARM_ADDITION_S(cpu->gprs[rn], cpu->shifterOperand, aluOut), int32_t aluOut = cpu->gprs[rn] + cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_S_ONLY_ARM(CMP, ARM_SUBTRACTION_S(cpu->gprs[rn], cpu->shifterOperand, aluOut), int32_t aluOut = cpu->gprs[rn] - cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(EOR, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, cpu->gprs[rd]), cpu->gprs[rd] = cpu->gprs[rn] ^ cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(MOV, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, cpu->gprs[rd]), cpu->gprs[rd] = cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(MVN, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, cpu->gprs[rd]), cpu->gprs[rd] = ~cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(ORR, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, cpu->gprs[rd]), cpu->gprs[rd] = cpu->gprs[rn] | cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_ARM(RSB, ARM_SUBTRACTION_S(cpu->shifterOperand, n, cpu->gprs[rd]), int32_t n = cpu->gprs[rn]; cpu->gprs[rd] = cpu->shifterOperand - n;) DEFINE_ALU_INSTRUCTION_ARM(RSC, ARM_SUBTRACTION_CARRY_S(cpu->shifterOperand, n, cpu->gprs[rd], !cpu->cpsr.c), int32_t n = cpu->gprs[rn]; cpu->gprs[rd] = cpu->shifterOperand - n - !cpu->cpsr.c;) DEFINE_ALU_INSTRUCTION_ARM(SBC, ARM_SUBTRACTION_CARRY_S(n, cpu->shifterOperand, cpu->gprs[rd], !cpu->cpsr.c), int32_t n = cpu->gprs[rn]; cpu->gprs[rd] = n - cpu->shifterOperand - !cpu->cpsr.c;) DEFINE_ALU_INSTRUCTION_ARM(SUB, ARM_SUBTRACTION_S(n, cpu->shifterOperand, cpu->gprs[rd]), int32_t n = cpu->gprs[rn]; cpu->gprs[rd] = n - cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_S_ONLY_ARM(TEQ, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, aluOut), int32_t aluOut = cpu->gprs[rn] ^ cpu->shifterOperand;) DEFINE_ALU_INSTRUCTION_S_ONLY_ARM(TST, ARM_NEUTRAL_S(cpu->gprs[rn], cpu->shifterOperand, aluOut), int32_t aluOut = cpu->gprs[rn] & cpu->shifterOperand;) // End ALU definitions // Begin multiply definitions DEFINE_MULTIPLY_INSTRUCTION_2_ARM(MLA, cpu->gprs[rdHi] = cpu->gprs[rm] * cpu->gprs[rs] + cpu->gprs[rd], ARM_NEUTRAL_S(, , cpu->gprs[rdHi]), 2) DEFINE_MULTIPLY_INSTRUCTION_ARM(MUL, cpu->gprs[rd] = cpu->gprs[rm] * cpu->gprs[rs], ARM_NEUTRAL_S(cpu->gprs[rm], cpu->gprs[rs], cpu->gprs[rd])) DEFINE_MULTIPLY_INSTRUCTION_2_ARM(SMLAL, int64_t d = ((int64_t) cpu->gprs[rm]) * ((int64_t) cpu->gprs[rs]); int32_t dm = cpu->gprs[rd]; int32_t dn = d; cpu->gprs[rd] = dm + dn; cpu->gprs[rdHi] = cpu->gprs[rdHi] + (d >> 32) + ARM_CARRY_FROM(dm, dn, cpu->gprs[rd]);, ARM_NEUTRAL_HI_S(cpu->gprs[rd], cpu->gprs[rdHi]), 3) DEFINE_MULTIPLY_INSTRUCTION_2_ARM(SMULL, int64_t d = ((int64_t) cpu->gprs[rm]) * ((int64_t) cpu->gprs[rs]); cpu->gprs[rd] = d; cpu->gprs[rdHi] = d >> 32;, ARM_NEUTRAL_HI_S(cpu->gprs[rd], cpu->gprs[rdHi]), 2) DEFINE_MULTIPLY_INSTRUCTION_2_ARM(UMLAL, uint64_t d = ARM_UXT_64(cpu->gprs[rm]) * ARM_UXT_64(cpu->gprs[rs]); int32_t dm = cpu->gprs[rd]; int32_t dn = d; cpu->gprs[rd] = dm + dn; cpu->gprs[rdHi] = cpu->gprs[rdHi] + (d >> 32) + ARM_CARRY_FROM(dm, dn, cpu->gprs[rd]);, ARM_NEUTRAL_HI_S(cpu->gprs[rd], cpu->gprs[rdHi]), 3) DEFINE_MULTIPLY_INSTRUCTION_2_ARM(UMULL, uint64_t d = ARM_UXT_64(cpu->gprs[rm]) * ARM_UXT_64(cpu->gprs[rs]); cpu->gprs[rd] = d; cpu->gprs[rdHi] = d >> 32;, ARM_NEUTRAL_HI_S(cpu->gprs[rd], cpu->gprs[rdHi]), 2) // End multiply definitions // Begin load/store definitions DEFINE_LOAD_STORE_INSTRUCTION_ARM(LDR, LOAD, cpu->gprs[rd] = cpu->memory.load32(cpu, address, ¤tCycles); ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_INSTRUCTION_ARM(LDRB, LOAD, cpu->gprs[rd] = cpu->memory.load8(cpu, address, ¤tCycles); ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_MODE_3_INSTRUCTION_ARM(LDRH, LOAD, cpu->gprs[rd] = cpu->memory.load16(cpu, address, ¤tCycles); ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_MODE_3_INSTRUCTION_ARM(LDRSB, LOAD, cpu->gprs[rd] = ARM_SXT_8(cpu->memory.load8(cpu, address, ¤tCycles)); ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_MODE_3_INSTRUCTION_ARM(LDRSH, LOAD, cpu->gprs[rd] = address & 1 ? ARM_SXT_8(cpu->memory.load16(cpu, address, ¤tCycles)) : ARM_SXT_16(cpu->memory.load16(cpu, address, ¤tCycles)); ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_INSTRUCTION_ARM(STR, STORE, cpu->memory.store32(cpu, address, cpu->gprs[rd], ¤tCycles); ARM_STORE_POST_BODY;) DEFINE_LOAD_STORE_INSTRUCTION_ARM(STRB, STORE, cpu->memory.store8(cpu, address, cpu->gprs[rd], ¤tCycles); ARM_STORE_POST_BODY;) DEFINE_LOAD_STORE_MODE_3_INSTRUCTION_ARM(STRH, STORE, cpu->memory.store16(cpu, address, cpu->gprs[rd], ¤tCycles); ARM_STORE_POST_BODY;) DEFINE_LOAD_STORE_T_INSTRUCTION_ARM(LDRBT, LOAD, enum PrivilegeMode priv = cpu->privilegeMode; ARMSetPrivilegeMode(cpu, MODE_USER); int32_t r = cpu->memory.load8(cpu, address, ¤tCycles); ARMSetPrivilegeMode(cpu, priv); cpu->gprs[rd] = r; ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_T_INSTRUCTION_ARM(LDRT, LOAD, enum PrivilegeMode priv = cpu->privilegeMode; ARMSetPrivilegeMode(cpu, MODE_USER); int32_t r = cpu->memory.load32(cpu, address, ¤tCycles); ARMSetPrivilegeMode(cpu, priv); cpu->gprs[rd] = r; ARM_LOAD_POST_BODY;) DEFINE_LOAD_STORE_T_INSTRUCTION_ARM(STRBT, STORE, enum PrivilegeMode priv = cpu->privilegeMode; int32_t r = cpu->gprs[rd]; ARMSetPrivilegeMode(cpu, MODE_USER); cpu->memory.store8(cpu, address, r, ¤tCycles); ARMSetPrivilegeMode(cpu, priv); ARM_STORE_POST_BODY;) DEFINE_LOAD_STORE_T_INSTRUCTION_ARM(STRT, STORE, enum PrivilegeMode priv = cpu->privilegeMode; int32_t r = cpu->gprs[rd]; ARMSetPrivilegeMode(cpu, MODE_USER); cpu->memory.store32(cpu, address, r, ¤tCycles); ARMSetPrivilegeMode(cpu, priv); ARM_STORE_POST_BODY;) DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_ARM(LDM, load, true, currentCycles += cpu->memory.activeNonseqCycles32 - cpu->memory.activeSeqCycles32; if ((rs & 0x8000) || !rs) { currentCycles += ARMWritePC(cpu); }) DEFINE_LOAD_STORE_MULTIPLE_INSTRUCTION_ARM(STM, store, false, ARM_STORE_POST_BODY;) DEFINE_INSTRUCTION_ARM(SWP, int rm = opcode & 0xF; int rd = (opcode >> 12) & 0xF; int rn = (opcode >> 16) & 0xF; int32_t d = cpu->memory.load32(cpu, cpu->gprs[rn], ¤tCycles); cpu->memory.store32(cpu, cpu->gprs[rn], cpu->gprs[rm], ¤tCycles); cpu->gprs[rd] = d;) DEFINE_INSTRUCTION_ARM(SWPB, int rm = opcode & 0xF; int rd = (opcode >> 12) & 0xF; int rn = (opcode >> 16) & 0xF; int32_t d = cpu->memory.load8(cpu, cpu->gprs[rn], ¤tCycles); cpu->memory.store8(cpu, cpu->gprs[rn], cpu->gprs[rm], ¤tCycles); cpu->gprs[rd] = d;) // End load/store definitions // Begin branch definitions DEFINE_INSTRUCTION_ARM(B, int32_t offset = opcode << 8; offset >>= 6; cpu->gprs[ARM_PC] += offset; currentCycles += ARMWritePC(cpu);) DEFINE_INSTRUCTION_ARM(BL, int32_t immediate = (opcode & 0x00FFFFFF) << 8; cpu->gprs[ARM_LR] = cpu->gprs[ARM_PC] - 4; cpu->gprs[ARM_PC] += immediate >> 6; currentCycles += ARMWritePC(cpu);) DEFINE_INSTRUCTION_ARM(BX, int rm = opcode & 0x0000000F; cpu->gprs[ARM_PC] = cpu->gprs[rm] & 0xFFFFFFFE; currentCycles += ARMWritePC(cpu); ) // End branch definitions // Begin coprocessor definitions DEFINE_INSTRUCTION_ARM(CDP, ARM_STUB) DEFINE_INSTRUCTION_ARM(LDC, ARM_STUB) DEFINE_INSTRUCTION_ARM(STC, ARM_STUB) DEFINE_INSTRUCTION_ARM(MCR, ARM_STUB) DEFINE_INSTRUCTION_ARM(MRC, ARM_STUB) // Begin miscellaneous definitions DEFINE_INSTRUCTION_ARM(BKPT, cpu->irqh.bkpt32(cpu, ((opcode >> 4) & 0xFFF0) | (opcode & 0xF))); // Not strictly in ARMv4T, but here for convenience DEFINE_INSTRUCTION_ARM(ILL, ARM_ILL) // Illegal opcode DEFINE_INSTRUCTION_ARM(MSR, int c = opcode & 0x00010000; int f = opcode & 0x00080000; int32_t operand = cpu->gprs[opcode & 0x0000000F]; int32_t mask = (c ? 0x000000FF : 0) | (f ? 0xFF000000 : 0); if (mask & PSR_USER_MASK) { cpu->cpsr.packed = (cpu->cpsr.packed & ~PSR_USER_MASK) | (operand & PSR_USER_MASK); } if (mask & PSR_STATE_MASK) { cpu->cpsr.packed = (cpu->cpsr.packed & ~PSR_STATE_MASK) | (operand & PSR_STATE_MASK); } if (cpu->privilegeMode != MODE_USER && (mask & PSR_PRIV_MASK)) { ARMSetPrivilegeMode(cpu, (enum PrivilegeMode) ((operand & 0x0000000F) | 0x00000010)); cpu->cpsr.packed = (cpu->cpsr.packed & ~PSR_PRIV_MASK) | (operand & PSR_PRIV_MASK); } _ARMReadCPSR(cpu); // LOAD_32(cpu->prefetch[0], (cpu->gprs[ARM_PC] - 4) & cpu->memory.activeMask, cpu->memory.activeRegion); // LOAD_32(cpu->prefetch[1], cpu->gprs[ARM_PC] & cpu->memory.activeMask, cpu->memory.activeRegion); cpu->prefetch[0] = cpu->memory.load32(cpu, cpu->gprs[ARM_PC] - 4, NULL); cpu->prefetch[1] = cpu->memory.load32(cpu, cpu->gprs[ARM_PC], NULL); ) DEFINE_INSTRUCTION_ARM(MSRR, int c = opcode & 0x00010000; int f = opcode & 0x00080000; int32_t operand = cpu->gprs[opcode & 0x0000000F]; int32_t mask = (c ? 0x000000FF : 0) | (f ? 0xFF000000 : 0); mask &= PSR_USER_MASK | PSR_PRIV_MASK | PSR_STATE_MASK; cpu->spsr.packed = (cpu->spsr.packed & ~mask) | (operand & mask) | 0x00000010;) DEFINE_INSTRUCTION_ARM(MRS, \ int rd = (opcode >> 12) & 0xF; \ cpu->gprs[rd] = cpu->cpsr.packed;) DEFINE_INSTRUCTION_ARM(MRSR, \ int rd = (opcode >> 12) & 0xF; \ cpu->gprs[rd] = cpu->spsr.packed;) DEFINE_INSTRUCTION_ARM(MSRI, int c = opcode & 0x00010000; int f = opcode & 0x00080000; int rotate = (opcode & 0x00000F00) >> 7; int32_t operand = ROR(opcode & 0x000000FF, rotate); int32_t mask = (c ? 0x000000FF : 0) | (f ? 0xFF000000 : 0); if (mask & PSR_USER_MASK) { cpu->cpsr.packed = (cpu->cpsr.packed & ~PSR_USER_MASK) | (operand & PSR_USER_MASK); } if (mask & PSR_STATE_MASK) { cpu->cpsr.packed = (cpu->cpsr.packed & ~PSR_STATE_MASK) | (operand & PSR_STATE_MASK); } if (cpu->privilegeMode != MODE_USER && (mask & PSR_PRIV_MASK)) { ARMSetPrivilegeMode(cpu, (enum PrivilegeMode) ((operand & 0x0000000F) | 0x00000010)); cpu->cpsr.packed = (cpu->cpsr.packed & ~PSR_PRIV_MASK) | (operand & PSR_PRIV_MASK); } _ARMReadCPSR(cpu); // LOAD_32(cpu->prefetch[0], (cpu->gprs[ARM_PC] - 4) & cpu->memory.activeMask, cpu->memory.activeRegion); // LOAD_32(cpu->prefetch[1], cpu->gprs[ARM_PC] & cpu->memory.activeMask, cpu->memory.activeRegion); cpu->prefetch[0] = cpu->memory.load32(cpu, cpu->gprs[ARM_PC] - 4, NULL); cpu->prefetch[1] = cpu->memory.load32(cpu, cpu->gprs[ARM_PC], NULL); ) DEFINE_INSTRUCTION_ARM(MSRRI, int c = opcode & 0x00010000; int f = opcode & 0x00080000; int rotate = (opcode & 0x00000F00) >> 7; int32_t operand = ROR(opcode & 0x000000FF, rotate); int32_t mask = (c ? 0x000000FF : 0) | (f ? 0xFF000000 : 0); mask &= PSR_USER_MASK | PSR_PRIV_MASK | PSR_STATE_MASK; cpu->spsr.packed = (cpu->spsr.packed & ~mask) | (operand & mask) | 0x00000010;) DEFINE_INSTRUCTION_ARM(SWI, cpu->irqh.swi32(cpu, opcode & 0xFFFFFF)) const ARMInstruction _armTable[0x1000] = { DECLARE_ARM_EMITTER_BLOCK(_ARMInstruction) };