/* * arm_codegen.h - Code generation macros for the ARM processor. * * Copyright (C) 2003, 2004 Southern Storm Software, Pty Ltd. * * 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 */ #ifndef _ARM_CODEGEN_H #define _ARM_CODEGEN_H #ifdef __cplusplus extern "C" { #endif /* * Register numbers. */ typedef enum { ARM_R0 = 0, ARM_R1 = 1, ARM_R2 = 2, ARM_R3 = 3, ARM_R4 = 4, ARM_R5 = 5, ARM_R6 = 6, ARM_R7 = 7, ARM_R8 = 8, ARM_R9 = 9, ARM_R10 = 10, ARM_R11 = 11, ARM_R12 = 12, ARM_R13 = 13, ARM_R14 = 14, ARM_R15 = 15, ARM_FP = ARM_R11, /* Frame pointer */ ARM_LINK = ARM_R14, /* Link register */ ARM_PC = ARM_R15, /* Program counter */ ARM_WORK = ARM_R12, /* Work register that we can destroy */ ARM_SP = ARM_R13 /* Stack pointer */ } ARM_REG; /* * Floating-point register numbers. */ typedef enum { ARM_F0 = 0, ARM_F1 = 1, ARM_F2 = 2, ARM_F3 = 3, ARM_F4 = 4, ARM_F5 = 5, ARM_F6 = 6, ARM_F7 = 7 } ARM_FREG; /* * Condition codes. */ typedef enum { ARM_CC_EQ = 0, /* Equal */ ARM_CC_NE = 1, /* Not equal */ ARM_CC_CS = 2, /* Carry set */ ARM_CC_CC = 3, /* Carry clear */ ARM_CC_MI = 4, /* Negative */ ARM_CC_PL = 5, /* Positive */ ARM_CC_VS = 6, /* Overflow set */ ARM_CC_VC = 7, /* Overflow clear */ ARM_CC_HI = 8, /* Higher */ ARM_CC_LS = 9, /* Lower or same */ ARM_CC_GE = 10, /* Signed greater than or equal */ ARM_CC_LT = 11, /* Signed less than */ ARM_CC_GT = 12, /* Signed greater than */ ARM_CC_LE = 13, /* Signed less than or equal */ ARM_CC_AL = 14, /* Always */ ARM_CC_NV = 15, /* Never */ ARM_CC_GE_UN = ARM_CC_CS, /* Unsigned greater than or equal */ ARM_CC_LT_UN = ARM_CC_CC, /* Unsigned less than */ ARM_CC_GT_UN = ARM_CC_HI, /* Unsigned greater than */ ARM_CC_LE_UN = ARM_CC_LS /* Unsigned less than or equal */ } ARM_CC; /* * Arithmetic and logical operations. */ typedef enum { ARM_AND = 0, /* Bitwise AND */ ARM_EOR = 1, /* Bitwise XOR */ ARM_SUB = 2, /* Subtract */ ARM_RSB = 3, /* Reverse subtract */ ARM_ADD = 4, /* Add */ ARM_ADC = 5, /* Add with carry */ ARM_SBC = 6, /* Subtract with carry */ ARM_RSC = 7, /* Reverse subtract with carry */ ARM_TST = 8, /* Test with AND */ ARM_TEQ = 9, /* Test with XOR */ ARM_CMP = 10, /* Test with SUB (compare) */ ARM_CMN = 11, /* Test with ADD */ ARM_ORR = 12, /* Bitwise OR */ ARM_MOV = 13, /* Move */ ARM_BIC = 14, /* Test with Op1 & ~Op2 */ ARM_MVN = 15 /* Bitwise NOT */ } ARM_OP; /* * Shift operators. */ typedef enum { ARM_SHL = 0, /* Logical left */ ARM_SHR = 1, /* Logical right */ ARM_SAR = 2, /* Arithmetic right */ ARM_ROR = 3 /* Rotate right */ } ARM_SHIFT; /* * Floating-point unary operators. */ typedef enum { ARM_MVF = 0, /* Move */ ARM_MNF = 1, /* Move negative */ ARM_ABS = 2, /* Absolute value */ ARM_RND = 3, /* Round */ ARM_SQT = 4, /* Square root */ ARM_LOG = 5, /* log10 */ ARM_LGN = 6, /* ln */ ARM_EXP = 7, /* exp */ ARM_SIN = 8, /* sin */ ARM_COS = 9, /* cos */ ARM_TAN = 10, /* tan */ ARM_ASN = 11, /* asin */ ARM_ACS = 12, /* acos */ ARM_ATN = 13 /* atan */ } ARM_FUNARY; /* * Floating-point binary operators. */ typedef enum { ARM_ADF = 0, /* Add */ ARM_MUF = 1, /* Multiply */ ARM_SUF = 2, /* Subtract */ ARM_RSF = 3, /* Reverse subtract */ ARM_DVF = 4, /* Divide */ ARM_RDF = 5, /* Reverse divide */ ARM_POW = 6, /* pow */ ARM_RPW = 7, /* Reverse pow */ ARM_RMF = 8, /* Remainder */ ARM_FML = 9, /* Fast multiply (32-bit only) */ ARM_FDV = 10, /* Fast divide (32-bit only) */ ARM_FRD = 11, /* Fast reverse divide (32-bit only) */ ARM_POL = 12 /* Polar angle */ } ARM_FBINARY; /* * Number of registers that are used for parameters (r0-r3). */ #define ARM_NUM_PARAM_REGS 4 /* * Type that keeps track of the instruction buffer. */ typedef unsigned int arm_inst_word; typedef struct { arm_inst_word *current; arm_inst_word *limit; } arm_inst_buf; #define arm_inst_get_posn(inst) ((inst).current) #define arm_inst_get_limit(inst) ((inst).limit) /* * Build an instruction prefix from a condition code and a mask value. */ #define arm_build_prefix(cond,mask) \ ((((unsigned int)(cond)) << 28) | ((unsigned int)(mask))) /* * Build an "always" instruction prefix for a regular instruction. */ #define arm_prefix(mask) (arm_build_prefix(ARM_CC_AL, (mask))) /* * Build special "always" prefixes. */ #define arm_always (arm_build_prefix(ARM_CC_AL, 0)) #define arm_always_cc (arm_build_prefix(ARM_CC_AL, (1 << 20))) #define arm_always_imm (arm_build_prefix(ARM_CC_AL, (1 << 25))) /* * Wrappers for "arm_always*" that allow higher-level routines * to change code generation to be based on a condition. This is * used to perform branch elimination. */ #ifndef arm_execute #define arm_execute arm_always #define arm_execute_cc arm_always_cc #define arm_execute_imm arm_always_imm #endif /* * Initialize an instruction buffer. */ #define arm_inst_buf_init(inst,start,end) \ do { \ (inst).current = (arm_inst_word *)(start); \ (inst).limit = (arm_inst_word *)(end); \ } while (0) /* * Add an instruction to an instruction buffer. */ #define arm_inst_add(inst,value) \ do { \ if((inst).current < (inst).limit) \ { \ *((inst).current)++ = (value); \ } \ } while (0) /* * Arithmetic or logical operation which doesn't set condition codes. */ #define arm_alu_reg_reg(inst,opc,dreg,sreg1,sreg2) \ do { \ arm_inst_add((inst), arm_execute | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg1)) << 16) | \ ((unsigned int)(sreg2))); \ } while (0) #define arm_alu_reg_imm8(inst,opc,dreg,sreg,imm) \ do { \ arm_inst_add((inst), arm_execute_imm | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg)) << 16) | \ ((unsigned int)((imm) & 0xFF))); \ } while (0) #define arm_alu_reg_imm8_cond(inst,opc,dreg,sreg,imm,cond) \ do { \ arm_inst_add((inst), arm_build_prefix((cond), (1 << 25)) | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg)) << 16) | \ ((unsigned int)((imm) & 0xFF))); \ } while (0) #define arm_alu_reg_imm8_rotate(inst,opc,dreg,sreg,imm,rotate) \ do { \ arm_inst_add((inst), arm_execute_imm | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg)) << 16) | \ (((unsigned int)(rotate)) << 8) | \ ((unsigned int)((imm) & 0xFF))); \ } while (0) extern void _arm_alu_reg_imm (arm_inst_buf *inst, int opc, int dreg, int sreg, int imm, int saveWork, int execute_prefix); #define arm_alu_reg_imm(inst,opc,dreg,sreg,imm) \ do { \ int __alu_imm = (int)(imm); \ if(__alu_imm >= 0 && __alu_imm < 256) \ { \ arm_alu_reg_imm8 \ ((inst), (opc), (dreg), (sreg), __alu_imm); \ } \ else \ { \ _arm_alu_reg_imm \ (&(inst), (opc), (dreg), (sreg), __alu_imm, 0, \ arm_execute); \ } \ } while (0) #define arm_alu_reg_imm_save_work(inst,opc,dreg,sreg,imm) \ do { \ int __alu_imm_save = (int)(imm); \ if(__alu_imm_save >= 0 && __alu_imm_save < 256) \ { \ arm_alu_reg_imm8 \ ((inst), (opc), (dreg), (sreg), __alu_imm_save); \ } \ else \ { \ _arm_alu_reg_imm \ (&(inst), (opc), (dreg), (sreg), __alu_imm_save, 1, \ arm_execute); \ } \ } while (0) #define arm_alu_reg(inst,opc,dreg,sreg) \ do { \ arm_inst_add((inst), arm_execute | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ ((unsigned int)(sreg))); \ } while (0) #define arm_alu_reg_cond(inst,opc,dreg,sreg,cond) \ do { \ arm_inst_add((inst), arm_build_prefix((cond), 0) | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ ((unsigned int)(sreg))); \ } while (0) /* * Arithmetic or logical operation which sets condition codes. */ #define arm_alu_cc_reg_reg(inst,opc,dreg,sreg1,sreg2) \ do { \ arm_inst_add((inst), arm_execute_cc | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg1)) << 16) | \ ((unsigned int)(sreg2))); \ } while (0) #define arm_alu_cc_reg_imm8(inst,opc,dreg,sreg,imm) \ do { \ arm_inst_add((inst), arm_execute_imm | arm_execute_cc | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg)) << 16) | \ ((unsigned int)((imm) & 0xFF))); \ } while (0) #define arm_alu_cc_reg(inst,opc,dreg,sreg) \ do { \ arm_inst_add((inst), = arm_execute_cc | \ (((unsigned int)(opc)) << 21) | \ (((unsigned int)(dreg)) << 12) | \ ((unsigned int)(sreg))); \ } while (0) /* * Test operation, which sets the condition codes but has no other result. */ #define arm_test_reg_reg(inst,opc,sreg1,sreg2) \ do { \ arm_alu_cc_reg_reg((inst), (opc), 0, (sreg1), (sreg2)); \ } while (0) #define arm_test_reg_imm8(inst,opc,sreg,imm) \ do { \ arm_alu_cc_reg_imm8((inst), (opc), 0, (sreg), (imm)); \ } while (0) #define arm_test_reg_imm(inst,opc,sreg,imm) \ do { \ int __test_imm = (int)(imm); \ if(__test_imm >= 0 && __test_imm < 256) \ { \ arm_alu_cc_reg_imm8((inst), (opc), 0, (sreg), __test_imm); \ } \ else \ { \ arm_mov_reg_imm((inst), ARM_WORK, __test_imm); \ arm_test_reg_reg((inst), (opc), (sreg), ARM_WORK); \ } \ } while (0) /* * Move a value between registers. */ #define arm_mov_reg_reg(inst,dreg,sreg) \ do { \ arm_alu_reg((inst), ARM_MOV, (dreg), (sreg)); \ } while (0) /* * Move an immediate value into a register. This is hard because * ARM lacks an instruction to load a 32-bit immediate value directly. * We handle the simple cases and then bail out to a function for the rest. */ #define arm_mov_reg_imm8(inst,reg,imm) \ do { \ arm_alu_reg_imm8((inst), ARM_MOV, (reg), 0, (imm)); \ } while (0) #define arm_mov_reg_imm8_rotate(inst,reg,imm,rotate) \ do { \ arm_alu_reg_imm8_rotate((inst), ARM_MOV, (reg), \ 0, (imm), (rotate)); \ } while (0) extern void _arm_mov_reg_imm (arm_inst_buf *inst, int reg, int value, int execute_prefix); extern int arm_is_complex_imm(int value); #define arm_mov_reg_imm(inst,reg,imm) \ do { \ int __imm = (int)(imm); \ if(__imm >= 0 && __imm < 256) \ { \ arm_mov_reg_imm8((inst), (reg), __imm); \ } \ else if((reg) == ARM_PC) \ { \ _arm_mov_reg_imm \ (&(inst), ARM_WORK, __imm, arm_execute); \ arm_mov_reg_reg((inst), ARM_PC, ARM_WORK); \ } \ else if(__imm > -256 && __imm < 0) \ { \ arm_mov_reg_imm8((inst), (reg), ~(__imm)); \ arm_alu_reg((inst), ARM_MVN, (reg), (reg)); \ } \ else \ { \ _arm_mov_reg_imm(&(inst), (reg), __imm, arm_execute); \ } \ } while (0) /* * Clear a register to zero. */ #define arm_clear_reg(inst,reg) \ do { \ arm_mov_reg_imm8((inst), (reg), 0); \ } while (0) /* * No-operation instruction. */ #define arm_nop(inst) arm_mov_reg_reg((inst), ARM_R0, ARM_R0) /* * Perform a shift operation. */ #define arm_shift_reg_reg(inst,opc,dreg,sreg1,sreg2) \ do { \ arm_inst_add((inst), arm_execute | \ (((unsigned int)ARM_MOV) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg2)) << 8) | \ (((unsigned int)(opc)) << 5) | \ ((unsigned int)(1 << 4)) | \ ((unsigned int)(sreg1))); \ } while (0) #define arm_shift_reg_imm8(inst,opc,dreg,sreg,imm) \ do { \ arm_inst_add((inst), arm_execute | \ (((unsigned int)ARM_MOV) << 21) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(opc)) << 5) | \ (((unsigned int)(imm)) << 7) | \ ((unsigned int)(sreg))); \ } while (0) /* * Perform a multiplication instruction. Note: ARM instruction rules * say that dreg should not be the same as sreg2, so we swap the order * of the arguments if that situation occurs. We assume that sreg1 * and sreg2 are distinct registers. */ #define arm_mul_reg_reg(inst,dreg,sreg1,sreg2) \ do { \ if((dreg) != (sreg2)) \ { \ arm_inst_add((inst), arm_prefix(0x00000090) | \ (((unsigned int)(dreg)) << 16) | \ (((unsigned int)(sreg1)) << 8) | \ ((unsigned int)(sreg2))); \ } \ else \ { \ arm_inst_add((inst), arm_prefix(0x00000090) | \ (((unsigned int)(dreg)) << 16) | \ (((unsigned int)(sreg2)) << 8) | \ ((unsigned int)(sreg1))); \ } \ } while (0) /* * Perform a binary operation on floating-point arguments. */ #define arm_alu_freg_freg(inst,opc,dreg,sreg1,sreg2) \ do { \ arm_inst_add((inst), arm_prefix(0x0E000180) | \ (((unsigned int)(opc)) << 20) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg1)) << 16) | \ ((unsigned int)(sreg2))); \ } while (0) #define arm_alu_freg_freg_32(inst,opc,dreg,sreg1,sreg2) \ do { \ arm_inst_add((inst), arm_prefix(0x0E000100) | \ (((unsigned int)(opc)) << 20) | \ (((unsigned int)(dreg)) << 12) | \ (((unsigned int)(sreg1)) << 16) | \ ((unsigned int)(sreg2))); \ } while (0) /* * Perform a unary operation on floating-point arguments. */ #define arm_alu_freg(inst,opc,dreg,sreg) \ do { \ arm_inst_add((inst), arm_prefix(0x0E008180) | \ (((unsigned int)(opc)) << 20) | \ (((unsigned int)(dreg)) << 12) | \ ((unsigned int)(sreg))); \ } while (0) #define arm_alu_freg_32(inst,opc,dreg,sreg) \ do { \ arm_inst_add((inst), arm_prefix(0x0E008100) | \ (((unsigned int)(opc)) << 20) | \ (((unsigned int)(dreg)) << 12) | \ ((unsigned int)(sreg))); \ } while (0) /* * Branch or jump immediate by a byte offset. The offset is * assumed to be +/- 32 Mbytes. */ #define arm_branch_imm(inst,cond,imm) \ do { \ arm_inst_add((inst), arm_build_prefix((cond), 0x0A000000) | \ (((unsigned int)(((int)(imm)) >> 2)) & \ 0x00FFFFFF)); \ } while (0) #define arm_jump_imm(inst,imm) arm_branch_imm((inst), ARM_CC_AL, (imm)) /* * Branch or jump to a specific target location. The offset is * assumed to be +/- 32 Mbytes. */ #define arm_branch(inst,cond,target) \ do { \ int __br_offset = (int)(((unsigned char *)(target)) - \ (((unsigned char *)((inst).current)) + 8)); \ arm_branch_imm((inst), (cond), __br_offset); \ } while (0) #define arm_jump(inst,target) arm_branch((inst), ARM_CC_AL, (target)) /* * Jump to a specific target location that may be greater than * 32 Mbytes away from the current location. */ #define arm_jump_long(inst,target) \ do { \ int __jmp_offset = (int)(((unsigned char *)(target)) - \ (((unsigned char *)((inst).current)) + 8)); \ if(__jmp_offset >= -0x04000000 && __jmp_offset < 0x04000000) \ { \ arm_jump_imm((inst), __jmp_offset); \ } \ else \ { \ arm_mov_reg_imm((inst), ARM_PC, (int)(target)); \ } \ } while (0) /* * Back-patch a branch instruction. */ #define arm_patch(inst,posn,target) \ do { \ int __p_offset = (int)(((unsigned char *)(target)) - \ (((unsigned char *)(posn)) + 8)); \ __p_offset = (__p_offset >> 2) & 0x00FFFFFF; \ if(((arm_inst_word *)(posn)) < (inst).limit) \ { \ *((int *)(posn)) = (*((int *)(posn)) & 0xFF000000) | \ __p_offset; \ } \ } while (0) /* * Call a subroutine immediate by a byte offset. */ #define arm_call_imm(inst,imm) \ do { \ arm_inst_add((inst), arm_prefix(0x0B000000) | \ (((unsigned int)(((int)(imm)) >> 2)) & \ 0x00FFFFFF)); \ } while (0) /* * Call a subroutine at a specific target location. */ #define arm_call(inst,target) \ do { \ int __call_offset = (int)(((unsigned char *)(target)) - \ (((unsigned char *)((inst).current)) + 8)); \ if(__call_offset >= -0x04000000 && __call_offset < 0x04000000) \ { \ arm_call_imm((inst), __call_offset); \ } \ else \ { \ arm_load_membase((inst), ARM_WORK, ARM_PC, 4); \ arm_alu_reg_imm8((inst), ARM_ADD, ARM_LINK, ARM_PC, 4); \ arm_mov_reg_reg((inst), ARM_PC, ARM_WORK); \ arm_inst_add((inst), (int)(target)); \ } \ } while (0) /* * Return from a subroutine, where the return address is in the link register. */ #define arm_return(inst) \ do { \ arm_mov_reg_reg((inst), ARM_PC, ARM_LINK); \ } while (0) /* * Push a register onto the system stack. */ #define arm_push_reg(inst,reg) \ do { \ arm_inst_add((inst), arm_prefix(0x05200004) | \ (((unsigned int)ARM_SP) << 16) | \ (((unsigned int)(reg)) << 12)); \ } while (0) /* * Pop a register from the system stack. */ #define arm_pop_reg(inst,reg) \ do { \ arm_inst_add((inst), arm_prefix(0x04900004) | \ (((unsigned int)ARM_SP) << 16) | \ (((unsigned int)(reg)) << 12)); \ } while (0) /* * Set up a local variable frame, and save the registers in "regset". */ #define arm_setup_frame(inst,regset) \ do { \ arm_mov_reg_reg((inst), ARM_WORK, ARM_SP); \ arm_inst_add((inst), arm_prefix(0x0920D800) | \ (((unsigned int)ARM_SP) << 16) | \ (((unsigned int)(regset)))); \ arm_alu_reg_imm8((inst), ARM_SUB, ARM_FP, ARM_WORK, 4); \ } while (0) /* * Pop a local variable frame, restore the registers in "regset", * and return to the caller. */ #define arm_pop_frame(inst,regset) \ do { \ arm_inst_add((inst), arm_prefix(0x0910A800) | \ (((unsigned int)ARM_FP) << 16) | \ (((unsigned int)(regset)))); \ } while (0) /* * Pop a local variable frame, in preparation for a tail call. * This restores "lr" to its original value, but does not set "pc". */ #define arm_pop_frame_tail(inst,regset) \ do { \ arm_inst_add((inst), arm_prefix(0x09106800) | \ (((unsigned int)ARM_FP) << 16) | \ (((unsigned int)(regset)))); \ } while (0) /* * Load a word value from a pointer and then advance the pointer. */ #define arm_load_advance(inst,dreg,sreg) \ do { \ arm_inst_add((inst), arm_prefix(0x04900004) | \ (((unsigned int)(sreg)) << 16) | \ (((unsigned int)(dreg)) << 12)); \ } while (0) /* * Load a value from an address into a register. */ #define arm_load_membase_either(inst,reg,basereg,imm,mask) \ do { \ int __mb_offset = (int)(imm); \ if(__mb_offset >= 0 && __mb_offset < (1 << 12)) \ { \ arm_inst_add((inst), arm_prefix(0x05900000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)__mb_offset)); \ } \ else if(__mb_offset > -(1 << 12) && __mb_offset < 0) \ { \ arm_inst_add((inst), arm_prefix(0x05100000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)(-__mb_offset))); \ } \ else \ { \ arm_mov_reg_imm((inst), ARM_WORK, __mb_offset); \ arm_inst_add((inst), arm_prefix(0x07900000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)ARM_WORK)); \ } \ } while (0) #define arm_load_membase(inst,reg,basereg,imm) \ do { \ arm_load_membase_either((inst), (reg), (basereg), (imm), 0); \ } while (0) #define arm_load_membase_byte(inst,reg,basereg,imm) \ do { \ arm_load_membase_either((inst), (reg), (basereg), (imm), \ 0x00400000); \ } while (0) #define arm_load_membase_sbyte(inst,reg,basereg,imm) \ do { \ arm_load_membase_either((inst), (reg), (basereg), (imm), \ 0x00400000); \ arm_shift_reg_imm8((inst), ARM_SHL, (reg), (reg), 24); \ arm_shift_reg_imm8((inst), ARM_SAR, (reg), (reg), 24); \ } while (0) #define arm_load_membase_ushort(inst,reg,basereg,imm) \ do { \ arm_load_membase_byte((inst), ARM_WORK, (basereg), (imm)); \ arm_load_membase_byte((inst), (reg), (basereg), (imm) + 1); \ arm_shift_reg_imm8((inst), ARM_SHL, (reg), (reg), 8); \ arm_alu_reg_reg((inst), ARM_ORR, (reg), (reg), ARM_WORK); \ } while (0) #define arm_load_membase_short(inst,reg,basereg,imm) \ do { \ arm_load_membase_byte((inst), ARM_WORK, (basereg), (imm)); \ arm_load_membase_byte((inst), (reg), (basereg), (imm) + 1); \ arm_shift_reg_imm8((inst), ARM_SHL, (reg), (reg), 24); \ arm_shift_reg_imm8((inst), ARM_SAR, (reg), (reg), 16); \ arm_alu_reg_reg((inst), ARM_ORR, (reg), (reg), ARM_WORK); \ } while (0) /* * Load a floating-point value from an address into a register. */ #define arm_load_membase_float(inst,reg,basereg,imm,mask) \ do { \ int __mb_offset = (int)(imm); \ if(__mb_offset >= 0 && __mb_offset < (1 << 10) && \ (__mb_offset & 3) == 0) \ { \ arm_inst_add((inst), arm_prefix(0x0D900100 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)((__mb_offset / 4) & 0xFF))); \ } \ else if(__mb_offset > -(1 << 10) && __mb_offset < 0 && \ (__mb_offset & 3) == 0) \ { \ arm_inst_add((inst), arm_prefix(0x0D180100 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)(((-__mb_offset) / 4) & 0xFF)));\ } \ else \ { \ arm_mov_reg_imm((inst), ARM_WORK, __mb_offset); \ arm_alu_reg_reg((inst), ARM_ADD, ARM_WORK, \ (basereg), ARM_WORK); \ arm_inst_add((inst), arm_prefix(0x0D900100 | (mask)) | \ (((unsigned int)ARM_WORK) << 16) | \ (((unsigned int)(reg)) << 12)); \ } \ } while (0) #define arm_load_membase_float32(inst,reg,basereg,imm) \ do { \ arm_load_membase_float((inst), (reg), (basereg), (imm), 0); \ } while (0) #define arm_load_membase_float64(inst,reg,basereg,imm) \ do { \ arm_load_membase_float((inst), (reg), (basereg), \ (imm), 0x00008000); \ } while (0) /* * Store a value from a register into an address. * * Note: storing a 16-bit value destroys the value in the register. */ #define arm_store_membase_either(inst,reg,basereg,imm,mask) \ do { \ int __sm_offset = (int)(imm); \ if(__sm_offset >= 0 && __sm_offset < (1 << 12)) \ { \ arm_inst_add((inst), arm_prefix(0x05800000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)__sm_offset)); \ } \ else if(__sm_offset > -(1 << 12) && __sm_offset < 0) \ { \ arm_inst_add((inst), arm_prefix(0x05000000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)(-__sm_offset))); \ } \ else \ { \ arm_mov_reg_imm((inst), ARM_WORK, __sm_offset); \ arm_inst_add((inst), arm_prefix(0x07800000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)ARM_WORK)); \ } \ } while (0) #define arm_store_membase(inst,reg,basereg,imm) \ do { \ arm_store_membase_either((inst), (reg), (basereg), (imm), 0); \ } while (0) #define arm_store_membase_byte(inst,reg,basereg,imm) \ do { \ arm_store_membase_either((inst), (reg), (basereg), (imm), \ 0x00400000); \ } while (0) #define arm_store_membase_sbyte(inst,reg,basereg,imm) \ do { \ arm_store_membase_byte((inst), (reg), (basereg), (imm)); \ } while (0) #define arm_store_membase_short(inst,reg,basereg,imm) \ do { \ arm_store_membase_either((inst), (reg), (basereg), (imm), \ 0x00400000); \ arm_shift_reg_imm8((inst), ARM_SHR, (reg), (reg), 8); \ arm_store_membase_either((inst), (reg), (basereg), \ (imm) + 1, 0x00400000); \ } while (0) #define arm_store_membase_ushort(inst,reg,basereg,imm) \ do { \ arm_store_membase_short((inst), (reg), (basereg), (imm)); \ } while (0) /* * Store a floating-point value to a memory address. */ #define arm_store_membase_float(inst,reg,basereg,imm,mask) \ do { \ int __mb_offset = (int)(imm); \ if(__mb_offset >= 0 && __mb_offset < (1 << 10) && \ (__mb_offset & 3) == 0) \ { \ arm_inst_add((inst), arm_prefix(0x0D800100 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)((__mb_offset / 4) & 0xFF))); \ } \ else if(__mb_offset > -(1 << 10) && __mb_offset < 0 && \ (__mb_offset & 3) == 0) \ { \ arm_inst_add((inst), arm_prefix(0x0D080100 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ ((unsigned int)(((-__mb_offset) / 4) & 0xFF)));\ } \ else \ { \ arm_mov_reg_imm((inst), ARM_WORK, __mb_offset); \ arm_alu_reg_reg((inst), ARM_ADD, ARM_WORK, \ (basereg), ARM_WORK); \ arm_inst_add((inst), arm_prefix(0x0D800100 | (mask)) | \ (((unsigned int)ARM_WORK) << 16) | \ (((unsigned int)(reg)) << 12)); \ } \ } while (0) #define arm_store_membase_float32(inst,reg,basereg,imm) \ do { \ arm_store_membase_float((inst), (reg), (basereg), (imm), 0); \ } while (0) #define arm_store_membase_float64(inst,reg,basereg,imm) \ do { \ arm_store_membase_float((inst), (reg), (basereg), \ (imm), 0x00008000); \ } while (0) #define arm_push_reg_float32(inst,reg) \ do { \ arm_store_membase_float((inst), (reg), ARM_SP, \ -4, 0x00200000); \ } while (0) #define arm_push_reg_float64(inst,reg) \ do { \ arm_store_membase_float((inst), (reg), ARM_SP, \ -4, 0x00208000); \ } while (0) /* * Load a value from an indexed address into a register. */ #define arm_load_memindex_either(inst,reg,basereg,indexreg,shift,mask) \ do { \ arm_inst_add((inst), arm_prefix(0x07900000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ (((unsigned int)(shift)) << 7) | \ ((unsigned int)(indexreg))); \ } while (0) #define arm_load_memindex(inst,reg,basereg,indexreg) \ do { \ arm_load_memindex_either((inst), (reg), (basereg), \ (indexreg), 2, 0); \ } while (0) #define arm_load_memindex_byte(inst,reg,basereg,indexreg) \ do { \ arm_load_memindex_either((inst), (reg), (basereg), \ (indexreg), 0, 0x00400000); \ } while (0) #define arm_load_memindex_sbyte(inst,reg,basereg,indexreg) \ do { \ arm_load_memindex_either((inst), (reg), (basereg), \ (indexreg), 0, 0x00400000); \ arm_shift_reg_imm8((inst), ARM_SHL, (reg), (reg), 24); \ arm_shift_reg_imm8((inst), ARM_SAR, (reg), (reg), 24); \ } while (0) #define arm_load_memindex_ushort(inst,reg,basereg,indexreg) \ do { \ arm_alu_reg_reg((inst), ARM_ADD, ARM_WORK, (basereg), \ (indexreg)); \ arm_alu_reg_reg((inst), ARM_ADD, ARM_WORK, ARM_WORK, \ (indexreg)); \ arm_load_membase_byte((inst), (reg), ARM_WORK, 0); \ arm_load_membase_byte((inst), ARM_WORK, ARM_WORK, 1); \ arm_shift_reg_imm8((inst), ARM_SHL, ARM_WORK, ARM_WORK, 8); \ arm_alu_reg_reg((inst), ARM_ORR, (reg), (reg), ARM_WORK); \ } while (0) #define arm_load_memindex_short(inst,reg,basereg,indexreg) \ do { \ arm_alu_reg_reg((inst), ARM_ADD, ARM_WORK, (basereg), \ (indexreg)); \ arm_alu_reg_reg((inst), ARM_ADD, ARM_WORK, ARM_WORK, \ (indexreg)); \ arm_load_membase_byte((inst), (reg), ARM_WORK, 0); \ arm_load_membase_byte((inst), ARM_WORK, ARM_WORK, 1); \ arm_shift_reg_imm8((inst), ARM_SHL, ARM_WORK, ARM_WORK, 24); \ arm_shift_reg_imm8((inst), ARM_SAR, ARM_WORK, ARM_WORK, 16); \ arm_alu_reg_reg((inst), ARM_ORR, (reg), (reg), ARM_WORK); \ } while (0) /* * Store a value from a register into an indexed address. * * Note: storing a 16-bit value destroys the values in the base * register and the source register. */ #define arm_store_memindex_either(inst,reg,basereg,indexreg,shift,mask) \ do { \ arm_inst_add((inst), arm_prefix(0x07800000 | (mask)) | \ (((unsigned int)(basereg)) << 16) | \ (((unsigned int)(reg)) << 12) | \ (((unsigned int)(shift)) << 7) | \ ((unsigned int)(indexreg))); \ } while (0) #define arm_store_memindex(inst,reg,basereg,indexreg) \ do { \ arm_store_memindex_either((inst), (reg), (basereg), \ (indexreg), 2, 0); \ } while (0) #define arm_store_memindex_byte(inst,reg,basereg,indexreg) \ do { \ arm_store_memindex_either((inst), (reg), (basereg), \ (indexreg), 0, 0x00400000); \ } while (0) #define arm_store_memindex_sbyte(inst,reg,basereg,indexreg) \ do { \ arm_store_memindex_byte((inst), (reg), (basereg), \ (indexreg)); \ } while (0) #define arm_store_memindex_short(inst,reg,basereg,indexreg) \ do { \ arm_store_memindex_either((inst), (reg), (basereg), \ (indexreg), 1, 0x00400000); \ arm_alu_reg_imm8((inst), ARM_ADD, (basereg), (basereg), 1); \ arm_shift_reg_imm8((inst), ARM_SHR, (reg), (reg), 8); \ arm_store_memindex_either((inst), (reg), (basereg), \ (indexreg), 1, 0x00400000); \ } while (0) #define arm_store_memindex_ushort(inst,reg,basereg,indexreg) \ do { \ arm_store_memindex_short((inst), (reg), \ (basereg), (indexreg)); \ } while (0) #ifdef __cplusplus }; #endif #endif /* _ARM_CODEGEN_H */