mirror of
https://github.com/retro100/dosbox-wii.git
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1332 lines
52 KiB
C
1332 lines
52 KiB
C
/*
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* Copyright (C) 2002-2010 The DOSBox Team
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
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*/
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/* $Id: risc_armv4le-thumb-niw.h,v 1.5 2009-06-27 12:51:10 c2woody Exp $ */
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/* ARMv4 (little endian) backend by M-HT (thumb version with data pool) */
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// temporary "lo" registers
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#define templo1 HOST_v3
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#define templo2 HOST_v4
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#define templo3 HOST_v2
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// register that holds function return values
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#define FC_RETOP HOST_a1
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// register used for address calculations,
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#define FC_ADDR HOST_v1 // has to be saved across calls, see DRC_PROTECT_ADDR_REG
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// register that holds the first parameter
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#define FC_OP1 HOST_a1
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// register that holds the second parameter
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#define FC_OP2 HOST_a2
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// special register that holds the third parameter for _R3 calls (byte accessible)
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#define FC_OP3 HOST_a4
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// register that holds byte-accessible temporary values
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#define FC_TMP_BA1 HOST_a1
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// register that holds byte-accessible temporary values
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#define FC_TMP_BA2 HOST_a2
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// temporary register for LEA
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#define TEMP_REG_DRC HOST_a4
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#ifdef DRC_USE_REGS_ADDR
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// used to hold the address of "cpu_regs" - preferably filled in function gen_run_code
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#define FC_REGS_ADDR HOST_v7
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#endif
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#ifdef DRC_USE_SEGS_ADDR
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// used to hold the address of "Segs" - preferably filled in function gen_run_code
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#define FC_SEGS_ADDR HOST_v8
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#endif
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// instruction encodings
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// move
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// mov dst, #imm @ 0 <= imm <= 255
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#define MOV_IMM(dst, imm) (0x2000 + ((dst) << 8) + (imm) )
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// mov dst, src
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#define MOV_REG(dst, src) ADD_IMM3(dst, src, 0)
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// mov dst, src
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#define MOV_LO_HI(dst, src) (0x4640 + (dst) + (((src) - HOST_r8) << 3) )
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// mov dst, src
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#define MOV_HI_LO(dst, src) (0x4680 + ((dst) - HOST_r8) + ((src) << 3) )
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// arithmetic
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// add dst, src, #imm @ 0 <= imm <= 7
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#define ADD_IMM3(dst, src, imm) (0x1c00 + (dst) + ((src) << 3) + ((imm) << 6) )
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// add dst, #imm @ 0 <= imm <= 255
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#define ADD_IMM8(dst, imm) (0x3000 + ((dst) << 8) + (imm) )
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// add dst, src1, src2
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#define ADD_REG(dst, src1, src2) (0x1800 + (dst) + ((src1) << 3) + ((src2) << 6) )
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// add dst, pc, #imm @ 0 <= imm < 1024 & imm mod 4 = 0
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#define ADD_LO_PC_IMM(dst, imm) (0xa000 + ((dst) << 8) + ((imm) >> 2) )
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// sub dst, src1, src2
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#define SUB_REG(dst, src1, src2) (0x1a00 + (dst) + ((src1) << 3) + ((src2) << 6) )
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// sub dst, src, #imm @ 0 <= imm <= 7
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#define SUB_IMM3(dst, src, imm) (0x1e00 + (dst) + ((src) << 3) + ((imm) << 6) )
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// sub dst, #imm @ 0 <= imm <= 255
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#define SUB_IMM8(dst, imm) (0x3800 + ((dst) << 8) + (imm) )
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// neg dst, src
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#define NEG(dst, src) (0x4240 + (dst) + ((src) << 3) )
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// cmp dst, #imm @ 0 <= imm <= 255
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#define CMP_IMM(dst, imm) (0x2800 + ((dst) << 8) + (imm) )
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// nop
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#define NOP (0x46c0)
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// logical
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// and dst, src
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#define AND(dst, src) (0x4000 + (dst) + ((src) << 3) )
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// eor dst, src
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#define EOR(dst, src) (0x4040 + (dst) + ((src) << 3) )
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// orr dst, src
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#define ORR(dst, src) (0x4300 + (dst) + ((src) << 3) )
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// shift/rotate
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// lsl dst, src, #imm
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#define LSL_IMM(dst, src, imm) (0x0000 + (dst) + ((src) << 3) + ((imm) << 6) )
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// lsl dst, reg
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#define LSL_REG(dst, reg) (0x4080 + (dst) + ((reg) << 3) )
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// lsr dst, src, #imm
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#define LSR_IMM(dst, src, imm) (0x0800 + (dst) + ((src) << 3) + ((imm) << 6) )
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// lsr dst, reg
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#define LSR_REG(dst, reg) (0x40c0 + (dst) + ((reg) << 3) )
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// asr dst, src, #imm
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#define ASR_IMM(dst, src, imm) (0x1000 + (dst) + ((src) << 3) + ((imm) << 6) )
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// asr dst, reg
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#define ASR_REG(dst, reg) (0x4100 + (dst) + ((reg) << 3) )
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// ror dst, reg
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#define ROR_REG(dst, reg) (0x41c0 + (dst) + ((reg) << 3) )
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// load
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// ldr reg, [addr, #imm] @ 0 <= imm < 128 & imm mod 4 = 0
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#define LDR_IMM(reg, addr, imm) (0x6800 + (reg) + ((addr) << 3) + ((imm) << 4) )
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// ldrh reg, [addr, #imm] @ 0 <= imm < 64 & imm mod 2 = 0
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#define LDRH_IMM(reg, addr, imm) (0x8800 + (reg) + ((addr) << 3) + ((imm) << 5) )
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// ldrb reg, [addr, #imm] @ 0 <= imm < 32
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#define LDRB_IMM(reg, addr, imm) (0x7800 + (reg) + ((addr) << 3) + ((imm) << 6) )
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// ldr reg, [pc, #imm] @ 0 <= imm < 1024 & imm mod 4 = 0
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#define LDR_PC_IMM(reg, imm) (0x4800 + ((reg) << 8) + ((imm) >> 2) )
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// store
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// str reg, [addr, #imm] @ 0 <= imm < 128 & imm mod 4 = 0
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#define STR_IMM(reg, addr, imm) (0x6000 + (reg) + ((addr) << 3) + ((imm) << 4) )
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// strh reg, [addr, #imm] @ 0 <= imm < 64 & imm mod 2 = 0
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#define STRH_IMM(reg, addr, imm) (0x8000 + (reg) + ((addr) << 3) + ((imm) << 5) )
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// strb reg, [addr, #imm] @ 0 <= imm < 32
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#define STRB_IMM(reg, addr, imm) (0x7000 + (reg) + ((addr) << 3) + ((imm) << 6) )
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// branch
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// beq pc+imm @ 0 <= imm < 256 & imm mod 2 = 0
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#define BEQ_FWD(imm) (0xd000 + ((imm) >> 1) )
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// bne pc+imm @ 0 <= imm < 256 & imm mod 2 = 0
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#define BNE_FWD(imm) (0xd100 + ((imm) >> 1) )
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// bgt pc+imm @ 0 <= imm < 256 & imm mod 2 = 0
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#define BGT_FWD(imm) (0xdc00 + ((imm) >> 1) )
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// b pc+imm @ 0 <= imm < 2048 & imm mod 2 = 0
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#define B_FWD(imm) (0xe000 + ((imm) >> 1) )
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// bx reg
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#define BX(reg) (0x4700 + ((reg) << 3) )
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// data pool defines
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#define CACHE_DATA_JUMP (2)
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#define CACHE_DATA_ALIGN (32)
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#define CACHE_DATA_MIN (32)
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#define CACHE_DATA_MAX (288)
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// data pool variables
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static Bit8u * cache_datapos = NULL; // position of data pool in the cache block
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static Bit32u cache_datasize = 0; // total size of data pool
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static Bit32u cache_dataindex = 0; // used size of data pool = index of free data item (in bytes) in data pool
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// forwarded function
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static void INLINE gen_create_branch_short(void * func);
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// function to check distance to data pool
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// if too close, then generate jump after data pool
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static void cache_checkinstr(Bit32u size) {
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if (cache_datasize == 0) {
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if (cache_datapos != NULL) {
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if (cache.pos + size + CACHE_DATA_JUMP >= cache_datapos) {
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cache_datapos = NULL;
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}
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}
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return;
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}
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if (cache.pos + size + CACHE_DATA_JUMP <= cache_datapos) return;
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{
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register Bit8u * newcachepos;
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newcachepos = cache_datapos + cache_datasize;
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gen_create_branch_short(newcachepos);
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cache.pos = newcachepos;
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}
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if (cache.pos + CACHE_DATA_MAX + CACHE_DATA_ALIGN >= cache.block.active->cache.start + cache.block.active->cache.size &&
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cache.pos + CACHE_DATA_MIN + CACHE_DATA_ALIGN + (CACHE_DATA_ALIGN - CACHE_ALIGN) < cache.block.active->cache.start + cache.block.active->cache.size)
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{
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cache_datapos = (Bit8u *) (((Bitu)cache.block.active->cache.start + cache.block.active->cache.size - CACHE_DATA_ALIGN) & ~(CACHE_DATA_ALIGN - 1));
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} else {
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register Bit32u cachemodsize;
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cachemodsize = (cache.pos - cache.block.active->cache.start) & (CACHE_MAXSIZE - 1);
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if (cachemodsize + CACHE_DATA_MAX + CACHE_DATA_ALIGN <= CACHE_MAXSIZE ||
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cachemodsize + CACHE_DATA_MIN + CACHE_DATA_ALIGN + (CACHE_DATA_ALIGN - CACHE_ALIGN) > CACHE_MAXSIZE)
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{
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cache_datapos = (Bit8u *) (((Bitu)cache.pos + CACHE_DATA_MAX) & ~(CACHE_DATA_ALIGN - 1));
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} else {
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cache_datapos = (Bit8u *) (((Bitu)cache.pos + (CACHE_MAXSIZE - CACHE_DATA_ALIGN) - cachemodsize) & ~(CACHE_DATA_ALIGN - 1));
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}
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}
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cache_datasize = 0;
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cache_dataindex = 0;
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}
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// function to reserve item in data pool
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// returns address of item
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static Bit8u * cache_reservedata(void) {
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// if data pool not yet initialized, then initialize data pool
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if (GCC_UNLIKELY(cache_datapos == NULL)) {
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if (cache.pos + CACHE_DATA_MIN + CACHE_DATA_ALIGN < cache.block.active->cache.start + CACHE_DATA_MAX) {
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cache_datapos = (Bit8u *) (((Bitu)cache.block.active->cache.start + CACHE_DATA_MAX) & ~(CACHE_DATA_ALIGN - 1));
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}
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}
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// if data pool not yet used, then set data pool
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if (cache_datasize == 0) {
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// set data pool address is too close (or behind) cache.pos then set new data pool size
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if (cache.pos + CACHE_DATA_MIN + CACHE_DATA_JUMP /*+ CACHE_DATA_ALIGN*/ > cache_datapos) {
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if (cache.pos + CACHE_DATA_MAX + CACHE_DATA_ALIGN >= cache.block.active->cache.start + cache.block.active->cache.size &&
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cache.pos + CACHE_DATA_MIN + CACHE_DATA_ALIGN + (CACHE_DATA_ALIGN - CACHE_ALIGN) < cache.block.active->cache.start + cache.block.active->cache.size)
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{
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cache_datapos = (Bit8u *) (((Bitu)cache.block.active->cache.start + cache.block.active->cache.size - CACHE_DATA_ALIGN) & ~(CACHE_DATA_ALIGN - 1));
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} else {
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register Bit32u cachemodsize;
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cachemodsize = (cache.pos - cache.block.active->cache.start) & (CACHE_MAXSIZE - 1);
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if (cachemodsize + CACHE_DATA_MAX + CACHE_DATA_ALIGN <= CACHE_MAXSIZE ||
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cachemodsize + CACHE_DATA_MIN + CACHE_DATA_ALIGN + (CACHE_DATA_ALIGN - CACHE_ALIGN) > CACHE_MAXSIZE)
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{
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cache_datapos = (Bit8u *) (((Bitu)cache.pos + CACHE_DATA_MAX) & ~(CACHE_DATA_ALIGN - 1));
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} else {
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cache_datapos = (Bit8u *) (((Bitu)cache.pos + (CACHE_MAXSIZE - CACHE_DATA_ALIGN) - cachemodsize) & ~(CACHE_DATA_ALIGN - 1));
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}
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}
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}
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// set initial data pool size
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cache_datasize = CACHE_DATA_ALIGN;
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}
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// if data pool is full, then enlarge data pool
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if (cache_dataindex == cache_datasize) {
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cache_datasize += CACHE_DATA_ALIGN;
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}
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cache_dataindex += 4;
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return (cache_datapos + (cache_dataindex - 4));
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}
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static void cache_block_before_close(void) {
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// if data pool in use, then resize cache block to include the data pool
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if (cache_datasize != 0)
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{
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cache.pos = cache_datapos + cache_dataindex;
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}
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// clear the values before next use
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cache_datapos = NULL;
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cache_datasize = 0;
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cache_dataindex = 0;
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}
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// move a full register from reg_src to reg_dst
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static void gen_mov_regs(HostReg reg_dst,HostReg reg_src) {
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if(reg_src == reg_dst) return;
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cache_checkinstr(2);
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cache_addw( MOV_REG(reg_dst, reg_src) ); // mov reg_dst, reg_src
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}
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// move a 32bit constant value into dest_reg
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static void gen_mov_dword_to_reg_imm(HostReg dest_reg,Bit32u imm) {
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if ((imm & 0xffffff00) == 0) {
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cache_checkinstr(2);
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cache_addw( MOV_IMM(dest_reg, imm) ); // mov dest_reg, #(imm)
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} else if ((imm & 0xffff00ff) == 0) {
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cache_checkinstr(4);
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cache_addw( MOV_IMM(dest_reg, imm >> 8) ); // mov dest_reg, #(imm >> 8)
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cache_addw( LSL_IMM(dest_reg, dest_reg, 8) ); // lsl dest_reg, dest_reg, #8
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} else if ((imm & 0xff00ffff) == 0) {
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cache_checkinstr(4);
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cache_addw( MOV_IMM(dest_reg, imm >> 16) ); // mov dest_reg, #(imm >> 16)
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cache_addw( LSL_IMM(dest_reg, dest_reg, 16) ); // lsl dest_reg, dest_reg, #16
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} else if ((imm & 0x00ffffff) == 0) {
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cache_checkinstr(4);
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cache_addw( MOV_IMM(dest_reg, imm >> 24) ); // mov dest_reg, #(imm >> 24)
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cache_addw( LSL_IMM(dest_reg, dest_reg, 24) ); // lsl dest_reg, dest_reg, #24
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} else {
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Bit32u diff;
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cache_checkinstr(4);
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diff = imm - ((Bit32u)cache.pos+4);
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if ((diff < 1024) && ((imm & 0x03) == 0)) {
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if (((Bit32u)cache.pos & 0x03) == 0) {
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cache_addw( ADD_LO_PC_IMM(dest_reg, diff >> 2) ); // add dest_reg, pc, #(diff >> 2)
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} else {
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cache_addw( NOP ); // nop
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cache_addw( ADD_LO_PC_IMM(dest_reg, (diff - 2) >> 2) ); // add dest_reg, pc, #((diff - 2) >> 2)
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}
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} else {
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Bit8u *datapos;
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datapos = cache_reservedata();
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*(Bit32u*)datapos=imm;
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if (((Bit32u)cache.pos & 0x03) == 0) {
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cache_addw( LDR_PC_IMM(dest_reg, datapos - (cache.pos + 4)) ); // ldr dest_reg, [pc, datapos]
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} else {
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cache_addw( LDR_PC_IMM(dest_reg, datapos - (cache.pos + 2)) ); // ldr dest_reg, [pc, datapos]
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}
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}
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}
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}
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// helper function for gen_mov_word_to_reg
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static void gen_mov_word_to_reg_helper(HostReg dest_reg,void* data,bool dword,HostReg data_reg) {
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// alignment....
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if (dword) {
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if ((Bit32u)data & 3) {
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if ( ((Bit32u)data & 3) == 2 ) {
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cache_checkinstr(8);
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cache_addw( LDRH_IMM(dest_reg, data_reg, 0) ); // ldrh dest_reg, [data_reg]
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cache_addw( LDRH_IMM(templo1, data_reg, 2) ); // ldrh templo1, [data_reg, #2]
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cache_addw( LSL_IMM(templo1, templo1, 16) ); // lsl templo1, templo1, #16
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cache_addw( ORR(dest_reg, templo1) ); // orr dest_reg, templo1
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} else {
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cache_checkinstr(16);
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cache_addw( LDRB_IMM(dest_reg, data_reg, 0) ); // ldrb dest_reg, [data_reg]
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cache_addw( ADD_IMM3(templo1, data_reg, 1) ); // add templo1, data_reg, #1
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cache_addw( LDRH_IMM(templo1, templo1, 0) ); // ldrh templo1, [templo1]
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cache_addw( LSL_IMM(templo1, templo1, 8) ); // lsl templo1, templo1, #8
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cache_addw( ORR(dest_reg, templo1) ); // orr dest_reg, templo1
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cache_addw( LDRB_IMM(templo1, data_reg, 3) ); // ldrb templo1, [data_reg, #3]
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cache_addw( LSL_IMM(templo1, templo1, 24) ); // lsl templo1, templo1, #24
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cache_addw( ORR(dest_reg, templo1) ); // orr dest_reg, templo1
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}
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} else {
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cache_checkinstr(2);
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cache_addw( LDR_IMM(dest_reg, data_reg, 0) ); // ldr dest_reg, [data_reg]
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}
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} else {
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if ((Bit32u)data & 1) {
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cache_checkinstr(8);
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cache_addw( LDRB_IMM(dest_reg, data_reg, 0) ); // ldrb dest_reg, [data_reg]
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cache_addw( LDRB_IMM(templo1, data_reg, 1) ); // ldrb templo1, [data_reg, #1]
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cache_addw( LSL_IMM(templo1, templo1, 8) ); // lsl templo1, templo1, #8
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cache_addw( ORR(dest_reg, templo1) ); // orr dest_reg, templo1
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} else {
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cache_checkinstr(2);
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cache_addw( LDRH_IMM(dest_reg, data_reg, 0) ); // ldrh dest_reg, [data_reg]
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}
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}
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}
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// move a 32bit (dword==true) or 16bit (dword==false) value from memory into dest_reg
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// 16bit moves may destroy the upper 16bit of the destination register
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static void gen_mov_word_to_reg(HostReg dest_reg,void* data,bool dword) {
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gen_mov_dword_to_reg_imm(templo2, (Bit32u)data);
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gen_mov_word_to_reg_helper(dest_reg, data, dword, templo2);
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}
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// move a 16bit constant value into dest_reg
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// the upper 16bit of the destination register may be destroyed
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static void INLINE gen_mov_word_to_reg_imm(HostReg dest_reg,Bit16u imm) {
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gen_mov_dword_to_reg_imm(dest_reg, (Bit32u)imm);
|
|
}
|
|
|
|
// helper function for gen_mov_word_from_reg
|
|
static void gen_mov_word_from_reg_helper(HostReg src_reg,void* dest,bool dword, HostReg data_reg) {
|
|
// alignment....
|
|
if (dword) {
|
|
if ((Bit32u)dest & 3) {
|
|
if ( ((Bit32u)dest & 3) == 2 ) {
|
|
cache_checkinstr(8);
|
|
cache_addw( STRH_IMM(src_reg, data_reg, 0) ); // strh src_reg, [data_reg]
|
|
cache_addw( MOV_REG(templo1, src_reg) ); // mov templo1, src_reg
|
|
cache_addw( LSR_IMM(templo1, templo1, 16) ); // lsr templo1, templo1, #16
|
|
cache_addw( STRH_IMM(templo1, data_reg, 2) ); // strh templo1, [data_reg, #2]
|
|
} else {
|
|
cache_checkinstr(20);
|
|
cache_addw( STRB_IMM(src_reg, data_reg, 0) ); // strb src_reg, [data_reg]
|
|
cache_addw( MOV_REG(templo1, src_reg) ); // mov templo1, src_reg
|
|
cache_addw( LSR_IMM(templo1, templo1, 8) ); // lsr templo1, templo1, #8
|
|
cache_addw( STRB_IMM(templo1, data_reg, 1) ); // strb templo1, [data_reg, #1]
|
|
cache_addw( MOV_REG(templo1, src_reg) ); // mov templo1, src_reg
|
|
cache_addw( LSR_IMM(templo1, templo1, 16) ); // lsr templo1, templo1, #16
|
|
cache_addw( STRB_IMM(templo1, data_reg, 2) ); // strb templo1, [data_reg, #2]
|
|
cache_addw( MOV_REG(templo1, src_reg) ); // mov templo1, src_reg
|
|
cache_addw( LSR_IMM(templo1, templo1, 24) ); // lsr templo1, templo1, #24
|
|
cache_addw( STRB_IMM(templo1, data_reg, 3) ); // strb templo1, [data_reg, #3]
|
|
}
|
|
} else {
|
|
cache_checkinstr(2);
|
|
cache_addw( STR_IMM(src_reg, data_reg, 0) ); // str src_reg, [data_reg]
|
|
}
|
|
} else {
|
|
if ((Bit32u)dest & 1) {
|
|
cache_checkinstr(8);
|
|
cache_addw( STRB_IMM(src_reg, data_reg, 0) ); // strb src_reg, [data_reg]
|
|
cache_addw( MOV_REG(templo1, src_reg) ); // mov templo1, src_reg
|
|
cache_addw( LSR_IMM(templo1, templo1, 8) ); // lsr templo1, templo1, #8
|
|
cache_addw( STRB_IMM(templo1, data_reg, 1) ); // strb templo1, [data_reg, #1]
|
|
} else {
|
|
cache_checkinstr(2);
|
|
cache_addw( STRH_IMM(src_reg, data_reg, 0) ); // strh src_reg, [data_reg]
|
|
}
|
|
}
|
|
}
|
|
|
|
// move 32bit (dword==true) or 16bit (dword==false) of a register into memory
|
|
static void gen_mov_word_from_reg(HostReg src_reg,void* dest,bool dword) {
|
|
gen_mov_dword_to_reg_imm(templo2, (Bit32u)dest);
|
|
gen_mov_word_from_reg_helper(src_reg, dest, dword, templo2);
|
|
}
|
|
|
|
// move an 8bit value from memory into dest_reg
|
|
// the upper 24bit of the destination register can be destroyed
|
|
// this function does not use FC_OP1/FC_OP2 as dest_reg as these
|
|
// registers might not be directly byte-accessible on some architectures
|
|
static void gen_mov_byte_to_reg_low(HostReg dest_reg,void* data) {
|
|
gen_mov_dword_to_reg_imm(templo1, (Bit32u)data);
|
|
cache_checkinstr(2);
|
|
cache_addw( LDRB_IMM(dest_reg, templo1, 0) ); // ldrb dest_reg, [templo1]
|
|
}
|
|
|
|
// move an 8bit value from memory into dest_reg
|
|
// the upper 24bit of the destination register can be destroyed
|
|
// this function can use FC_OP1/FC_OP2 as dest_reg which are
|
|
// not directly byte-accessible on some architectures
|
|
static void INLINE gen_mov_byte_to_reg_low_canuseword(HostReg dest_reg,void* data) {
|
|
gen_mov_byte_to_reg_low(dest_reg, data);
|
|
}
|
|
|
|
// move an 8bit constant value into dest_reg
|
|
// the upper 24bit of the destination register can be destroyed
|
|
// this function does not use FC_OP1/FC_OP2 as dest_reg as these
|
|
// registers might not be directly byte-accessible on some architectures
|
|
static void gen_mov_byte_to_reg_low_imm(HostReg dest_reg,Bit8u imm) {
|
|
cache_checkinstr(2);
|
|
cache_addw( MOV_IMM(dest_reg, imm) ); // mov dest_reg, #(imm)
|
|
}
|
|
|
|
// move an 8bit constant value into dest_reg
|
|
// the upper 24bit of the destination register can be destroyed
|
|
// this function can use FC_OP1/FC_OP2 as dest_reg which are
|
|
// not directly byte-accessible on some architectures
|
|
static void INLINE gen_mov_byte_to_reg_low_imm_canuseword(HostReg dest_reg,Bit8u imm) {
|
|
gen_mov_byte_to_reg_low_imm(dest_reg, imm);
|
|
}
|
|
|
|
// move the lowest 8bit of a register into memory
|
|
static void gen_mov_byte_from_reg_low(HostReg src_reg,void* dest) {
|
|
gen_mov_dword_to_reg_imm(templo1, (Bit32u)dest);
|
|
cache_checkinstr(2);
|
|
cache_addw( STRB_IMM(src_reg, templo1, 0) ); // strb src_reg, [templo1]
|
|
}
|
|
|
|
|
|
|
|
// convert an 8bit word to a 32bit dword
|
|
// the register is zero-extended (sign==false) or sign-extended (sign==true)
|
|
static void gen_extend_byte(bool sign,HostReg reg) {
|
|
cache_checkinstr(4);
|
|
cache_addw( LSL_IMM(reg, reg, 24) ); // lsl reg, reg, #24
|
|
|
|
if (sign) {
|
|
cache_addw( ASR_IMM(reg, reg, 24) ); // asr reg, reg, #24
|
|
} else {
|
|
cache_addw( LSR_IMM(reg, reg, 24) ); // lsr reg, reg, #24
|
|
}
|
|
}
|
|
|
|
// convert a 16bit word to a 32bit dword
|
|
// the register is zero-extended (sign==false) or sign-extended (sign==true)
|
|
static void gen_extend_word(bool sign,HostReg reg) {
|
|
cache_checkinstr(4);
|
|
cache_addw( LSL_IMM(reg, reg, 16) ); // lsl reg, reg, #16
|
|
|
|
if (sign) {
|
|
cache_addw( ASR_IMM(reg, reg, 16) ); // asr reg, reg, #16
|
|
} else {
|
|
cache_addw( LSR_IMM(reg, reg, 16) ); // lsr reg, reg, #16
|
|
}
|
|
}
|
|
|
|
// add a 32bit value from memory to a full register
|
|
static void gen_add(HostReg reg,void* op) {
|
|
gen_mov_word_to_reg(templo3, op, 1);
|
|
cache_checkinstr(2);
|
|
cache_addw( ADD_REG(reg, reg, templo3) ); // add reg, reg, templo3
|
|
}
|
|
|
|
// add a 32bit constant value to a full register
|
|
static void gen_add_imm(HostReg reg,Bit32u imm) {
|
|
if(!imm) return;
|
|
gen_mov_dword_to_reg_imm(templo1, imm);
|
|
cache_checkinstr(2);
|
|
cache_addw( ADD_REG(reg, reg, templo1) ); // add reg, reg, templo1
|
|
}
|
|
|
|
// and a 32bit constant value with a full register
|
|
static void gen_and_imm(HostReg reg,Bit32u imm) {
|
|
if(imm == 0xffffffff) return;
|
|
gen_mov_dword_to_reg_imm(templo1, imm);
|
|
cache_checkinstr(2);
|
|
cache_addw( AND(reg, templo1) ); // and reg, templo1
|
|
}
|
|
|
|
|
|
// move a 32bit constant value into memory
|
|
static void gen_mov_direct_dword(void* dest,Bit32u imm) {
|
|
gen_mov_dword_to_reg_imm(templo3, imm);
|
|
gen_mov_word_from_reg(templo3, dest, 1);
|
|
}
|
|
|
|
// move an address into memory
|
|
static void INLINE gen_mov_direct_ptr(void* dest,DRC_PTR_SIZE_IM imm) {
|
|
gen_mov_direct_dword(dest,(Bit32u)imm);
|
|
}
|
|
|
|
// add an 8bit constant value to a dword memory value
|
|
static void gen_add_direct_byte(void* dest,Bit8s imm) {
|
|
if(!imm) return;
|
|
gen_mov_dword_to_reg_imm(templo2, (Bit32u)dest);
|
|
gen_mov_word_to_reg_helper(templo3, dest, 1, templo2);
|
|
cache_checkinstr(2);
|
|
if (imm >= 0) {
|
|
cache_addw( ADD_IMM8(templo3, (Bit32s)imm) ); // add templo3, #(imm)
|
|
} else {
|
|
cache_addw( SUB_IMM8(templo3, -((Bit32s)imm)) ); // sub templo3, #(-imm)
|
|
}
|
|
gen_mov_word_from_reg_helper(templo3, dest, 1, templo2);
|
|
}
|
|
|
|
// add a 32bit (dword==true) or 16bit (dword==false) constant value to a memory value
|
|
static void gen_add_direct_word(void* dest,Bit32u imm,bool dword) {
|
|
if(!imm) return;
|
|
if (dword && ( (imm<128) || (imm>=0xffffff80) ) ) {
|
|
gen_add_direct_byte(dest,(Bit8s)imm);
|
|
return;
|
|
}
|
|
gen_mov_dword_to_reg_imm(templo2, (Bit32u)dest);
|
|
gen_mov_word_to_reg_helper(templo3, dest, dword, templo2);
|
|
if (dword) {
|
|
gen_mov_dword_to_reg_imm(templo1, imm);
|
|
} else {
|
|
gen_mov_word_to_reg_imm(templo1, (Bit16u)imm);
|
|
}
|
|
cache_checkinstr(2);
|
|
cache_addw( ADD_REG(templo3, templo3, templo1) ); // add templo3, templo3, templo1
|
|
gen_mov_word_from_reg_helper(templo3, dest, dword, templo2);
|
|
}
|
|
|
|
// subtract an 8bit constant value from a dword memory value
|
|
static void gen_sub_direct_byte(void* dest,Bit8s imm) {
|
|
if(!imm) return;
|
|
gen_mov_dword_to_reg_imm(templo2, (Bit32u)dest);
|
|
gen_mov_word_to_reg_helper(templo3, dest, 1, templo2);
|
|
cache_checkinstr(2);
|
|
if (imm >= 0) {
|
|
cache_addw( SUB_IMM8(templo3, (Bit32s)imm) ); // sub templo3, #(imm)
|
|
} else {
|
|
cache_addw( ADD_IMM8(templo3, -((Bit32s)imm)) ); // add templo3, #(-imm)
|
|
}
|
|
gen_mov_word_from_reg_helper(templo3, dest, 1, templo2);
|
|
}
|
|
|
|
// subtract a 32bit (dword==true) or 16bit (dword==false) constant value from a memory value
|
|
static void gen_sub_direct_word(void* dest,Bit32u imm,bool dword) {
|
|
if(!imm) return;
|
|
if (dword && ( (imm<128) || (imm>=0xffffff80) ) ) {
|
|
gen_sub_direct_byte(dest,(Bit8s)imm);
|
|
return;
|
|
}
|
|
gen_mov_dword_to_reg_imm(templo2, (Bit32u)dest);
|
|
gen_mov_word_to_reg_helper(templo3, dest, dword, templo2);
|
|
if (dword) {
|
|
gen_mov_dword_to_reg_imm(templo1, imm);
|
|
} else {
|
|
gen_mov_word_to_reg_imm(templo1, (Bit16u)imm);
|
|
}
|
|
cache_checkinstr(2);
|
|
cache_addw( SUB_REG(templo3, templo3, templo1) ); // sub templo3, templo3, templo1
|
|
gen_mov_word_from_reg_helper(templo3, dest, dword, templo2);
|
|
}
|
|
|
|
// effective address calculation, destination is dest_reg
|
|
// scale_reg is scaled by scale (scale_reg*(2^scale)) and
|
|
// added to dest_reg, then the immediate value is added
|
|
static INLINE void gen_lea(HostReg dest_reg,HostReg scale_reg,Bitu scale,Bits imm) {
|
|
if (scale) {
|
|
cache_checkinstr(4);
|
|
cache_addw( LSL_IMM(templo1, scale_reg, scale) ); // lsl templo1, scale_reg, #(scale)
|
|
cache_addw( ADD_REG(dest_reg, dest_reg, templo1) ); // add dest_reg, dest_reg, templo1
|
|
} else {
|
|
cache_checkinstr(2);
|
|
cache_addw( ADD_REG(dest_reg, dest_reg, scale_reg) ); // add dest_reg, dest_reg, scale_reg
|
|
}
|
|
gen_add_imm(dest_reg, imm);
|
|
}
|
|
|
|
// effective address calculation, destination is dest_reg
|
|
// dest_reg is scaled by scale (dest_reg*(2^scale)),
|
|
// then the immediate value is added
|
|
static INLINE void gen_lea(HostReg dest_reg,Bitu scale,Bits imm) {
|
|
if (scale) {
|
|
cache_checkinstr(2);
|
|
cache_addw( LSL_IMM(dest_reg, dest_reg, scale) ); // lsl dest_reg, dest_reg, #(scale)
|
|
}
|
|
gen_add_imm(dest_reg, imm);
|
|
}
|
|
|
|
// helper function for gen_call_function_raw and gen_call_function_setup
|
|
static void gen_call_function_helper(void * func) {
|
|
Bit8u *datapos;
|
|
|
|
datapos = cache_reservedata();
|
|
*(Bit32u*)datapos=(Bit32u)func;
|
|
|
|
if (((Bit32u)cache.pos & 0x03) == 0) {
|
|
cache_addw( LDR_PC_IMM(templo1, datapos - (cache.pos + 4)) ); // ldr templo1, [pc, datapos]
|
|
cache_addw( ADD_LO_PC_IMM(templo2, 4) ); // adr templo2, after_call (add templo2, pc, #4)
|
|
cache_addw( MOV_HI_LO(HOST_lr, templo2) ); // mov lr, templo2
|
|
cache_addw( BX(templo1) ); // bx templo1 --- switch to arm state
|
|
} else {
|
|
cache_addw( LDR_PC_IMM(templo1, datapos - (cache.pos + 2)) ); // ldr templo1, [pc, datapos]
|
|
cache_addw( ADD_LO_PC_IMM(templo2, 4) ); // adr templo2, after_call (add templo2, pc, #4)
|
|
cache_addw( MOV_HI_LO(HOST_lr, templo2) ); // mov lr, templo2
|
|
cache_addw( BX(templo1) ); // bx templo1 --- switch to arm state
|
|
cache_addw( NOP ); // nop
|
|
}
|
|
// after_call:
|
|
|
|
// switch from arm to thumb state
|
|
cache_addd(0xe2800000 + (templo1 << 12) + (HOST_pc << 16) + (1)); // add templo1, pc, #1
|
|
cache_addd(0xe12fff10 + (templo1)); // bx templo1
|
|
|
|
// thumb state from now on
|
|
}
|
|
|
|
// generate a call to a parameterless function
|
|
static void INLINE gen_call_function_raw(void * func) {
|
|
cache_checkinstr(18);
|
|
gen_call_function_helper(func);
|
|
}
|
|
|
|
// generate a call to a function with paramcount parameters
|
|
// note: the parameters are loaded in the architecture specific way
|
|
// using the gen_load_param_ functions below
|
|
static Bit32u INLINE gen_call_function_setup(void * func,Bitu paramcount,bool fastcall=false) {
|
|
cache_checkinstr(18);
|
|
Bit32u proc_addr = (Bit32u)cache.pos;
|
|
gen_call_function_helper(func);
|
|
return proc_addr;
|
|
// if proc_addr is on word boundary ((proc_addr & 0x03) == 0)
|
|
// then length of generated code is 16 bytes
|
|
// otherwise length of generated code is 18 bytes
|
|
}
|
|
|
|
#if (1)
|
|
// max of 4 parameters in a1-a4
|
|
|
|
// load an immediate value as param'th function parameter
|
|
static void INLINE gen_load_param_imm(Bitu imm,Bitu param) {
|
|
gen_mov_dword_to_reg_imm(param, imm);
|
|
}
|
|
|
|
// load an address as param'th function parameter
|
|
static void INLINE gen_load_param_addr(Bitu addr,Bitu param) {
|
|
gen_mov_dword_to_reg_imm(param, addr);
|
|
}
|
|
|
|
// load a host-register as param'th function parameter
|
|
static void INLINE gen_load_param_reg(Bitu reg,Bitu param) {
|
|
gen_mov_regs(param, reg);
|
|
}
|
|
|
|
// load a value from memory as param'th function parameter
|
|
static void INLINE gen_load_param_mem(Bitu mem,Bitu param) {
|
|
gen_mov_word_to_reg(param, (void *)mem, 1);
|
|
}
|
|
#else
|
|
other arm abis
|
|
#endif
|
|
|
|
// jump to an address pointed at by ptr, offset is in imm
|
|
static void gen_jmp_ptr(void * ptr,Bits imm=0) {
|
|
gen_mov_word_to_reg(templo3, ptr, 1);
|
|
|
|
if (imm) {
|
|
gen_mov_dword_to_reg_imm(templo2, imm);
|
|
cache_checkinstr(2);
|
|
cache_addw( ADD_REG(templo3, templo3, templo2) ); // add templo3, templo3, templo2
|
|
}
|
|
|
|
#if (1)
|
|
// (*ptr) should be word aligned
|
|
if ((imm & 0x03) == 0) {
|
|
cache_checkinstr(6);
|
|
cache_addw( LDR_IMM(templo2, templo3, 0) ); // ldr templo2, [templo3]
|
|
} else
|
|
#endif
|
|
{
|
|
cache_checkinstr(24);
|
|
cache_addw( LDRB_IMM(templo2, templo3, 0) ); // ldrb templo2, [templo3]
|
|
cache_addw( LDRB_IMM(templo1, templo3, 1) ); // ldrb templo1, [templo3, #1]
|
|
cache_addw( LSL_IMM(templo1, templo1, 8) ); // lsl templo1, templo1, #8
|
|
cache_addw( ORR(templo2, templo1) ); // orr templo2, templo1
|
|
cache_addw( LDRB_IMM(templo1, templo3, 2) ); // ldrb templo1, [templo3, #2]
|
|
cache_addw( LSL_IMM(templo1, templo1, 16) ); // lsl templo1, templo1, #16
|
|
cache_addw( ORR(templo2, templo1) ); // orr templo2, templo1
|
|
cache_addw( LDRB_IMM(templo1, templo3, 3) ); // ldrb templo1, [templo3, #3]
|
|
cache_addw( LSL_IMM(templo1, templo1, 24) ); // lsl templo1, templo1, #24
|
|
cache_addw( ORR(templo2, templo1) ); // orr templo2, templo1
|
|
}
|
|
|
|
// increase jmp address to keep thumb state
|
|
cache_addw( ADD_IMM3(templo2, templo2, 1) ); // add templo2, templo2, #1
|
|
|
|
cache_addw( BX(templo2) ); // bx templo2
|
|
}
|
|
|
|
// short conditional jump (+-127 bytes) if register is zero
|
|
// the destination is set by gen_fill_branch() later
|
|
static Bit32u gen_create_branch_on_zero(HostReg reg,bool dword) {
|
|
cache_checkinstr(4);
|
|
if (dword) {
|
|
cache_addw( CMP_IMM(reg, 0) ); // cmp reg, #0
|
|
} else {
|
|
cache_addw( LSL_IMM(templo1, reg, 16) ); // lsl templo1, reg, #16
|
|
}
|
|
cache_addw( BEQ_FWD(0) ); // beq j
|
|
return ((Bit32u)cache.pos-2);
|
|
}
|
|
|
|
// short conditional jump (+-127 bytes) if register is nonzero
|
|
// the destination is set by gen_fill_branch() later
|
|
static Bit32u gen_create_branch_on_nonzero(HostReg reg,bool dword) {
|
|
cache_checkinstr(4);
|
|
if (dword) {
|
|
cache_addw( CMP_IMM(reg, 0) ); // cmp reg, #0
|
|
} else {
|
|
cache_addw( LSL_IMM(templo1, reg, 16) ); // lsl templo1, reg, #16
|
|
}
|
|
cache_addw( BNE_FWD(0) ); // bne j
|
|
return ((Bit32u)cache.pos-2);
|
|
}
|
|
|
|
// calculate relative offset and fill it into the location pointed to by data
|
|
static void INLINE gen_fill_branch(DRC_PTR_SIZE_IM data) {
|
|
#if C_DEBUG
|
|
Bits len=(Bit32u)cache.pos-(data+4);
|
|
if (len<0) len=-len;
|
|
if (len>252) LOG_MSG("Big jump %d",len);
|
|
#endif
|
|
*(Bit8u*)data=(Bit8u)( ((Bit32u)cache.pos-(data+4)) >> 1 );
|
|
}
|
|
|
|
|
|
// conditional jump if register is nonzero
|
|
// for isdword==true the 32bit of the register are tested
|
|
// for isdword==false the lowest 8bit of the register are tested
|
|
static Bit32u gen_create_branch_long_nonzero(HostReg reg,bool isdword) {
|
|
Bit8u *datapos;
|
|
|
|
cache_checkinstr(8);
|
|
datapos = cache_reservedata();
|
|
|
|
if (isdword) {
|
|
cache_addw( CMP_IMM(reg, 0) ); // cmp reg, #0
|
|
} else {
|
|
cache_addw( LSL_IMM(templo2, reg, 24) ); // lsl templo2, reg, #24
|
|
}
|
|
cache_addw( BEQ_FWD(2) ); // beq nobranch (pc+2)
|
|
if (((Bit32u)cache.pos & 0x03) == 0) {
|
|
cache_addw( LDR_PC_IMM(templo1, datapos - (cache.pos + 4)) ); // ldr templo1, [pc, datapos]
|
|
} else {
|
|
cache_addw( LDR_PC_IMM(templo1, datapos - (cache.pos + 2)) ); // ldr templo1, [pc, datapos]
|
|
}
|
|
cache_addw( BX(templo1) ); // bx templo1
|
|
// nobranch:
|
|
return ((Bit32u)datapos);
|
|
}
|
|
|
|
// compare 32bit-register against zero and jump if value less/equal than zero
|
|
static Bit32u gen_create_branch_long_leqzero(HostReg reg) {
|
|
Bit8u *datapos;
|
|
|
|
cache_checkinstr(8);
|
|
datapos = cache_reservedata();
|
|
|
|
cache_addw( CMP_IMM(reg, 0) ); // cmp reg, #0
|
|
cache_addw( BGT_FWD(2) ); // bgt nobranch (pc+2)
|
|
if (((Bit32u)cache.pos & 0x03) == 0) {
|
|
cache_addw( LDR_PC_IMM(templo1, datapos - (cache.pos + 4)) ); // ldr templo1, [pc, datapos]
|
|
} else {
|
|
cache_addw( LDR_PC_IMM(templo1, datapos - (cache.pos + 2)) ); // ldr templo1, [pc, datapos]
|
|
}
|
|
cache_addw( BX(templo1) ); // bx templo1
|
|
// nobranch:
|
|
return ((Bit32u)datapos);
|
|
}
|
|
|
|
// calculate long relative offset and fill it into the location pointed to by data
|
|
static void INLINE gen_fill_branch_long(Bit32u data) {
|
|
// this is an absolute branch
|
|
*(Bit32u*)data=((Bit32u)cache.pos) + 1; // add 1 to keep processor in thumb state
|
|
}
|
|
|
|
static void gen_run_code(void) {
|
|
// switch from arm to thumb state
|
|
cache_addd(0xe2800000 + (HOST_r3 << 12) + (HOST_pc << 16) + (1)); // add r3, pc, #1
|
|
cache_addd(0xe12fff10 + (HOST_r3)); // bx r3
|
|
|
|
// thumb state from now on
|
|
cache_addw(0xb500); // push {lr}
|
|
cache_addw( MOV_LO_HI(HOST_r3, FC_SEGS_ADDR) ); // mov r3, FC_SEGS_ADDR
|
|
cache_addw( MOV_LO_HI(HOST_r2, FC_REGS_ADDR) ); // mov r2, FC_REGS_ADDR
|
|
cache_addw(0xb4fc); // push {r2,r3,v1-v4}
|
|
|
|
// adr: 16
|
|
cache_addw( LDR_PC_IMM(HOST_r3, 64 - (16 + 4)) ); // ldr r3, [pc, #(&Segs)]
|
|
// adr: 18
|
|
cache_addw( LDR_PC_IMM(HOST_r2, 68 - (18 + 2)) ); // ldr r2, [pc, #(&cpu_regs)]
|
|
cache_addw( MOV_HI_LO(FC_SEGS_ADDR, HOST_r3) ); // mov FC_SEGS_ADDR, r3
|
|
cache_addw( MOV_HI_LO(FC_REGS_ADDR, HOST_r2) ); // mov FC_REGS_ADDR, r2
|
|
|
|
// align 4
|
|
cache_addw( ADD_LO_PC_IMM(HOST_r3, 8) ); // add r3, pc, #8
|
|
cache_addw( ADD_IMM8(HOST_r0, 1) ); // add r0, #1
|
|
cache_addw( ADD_IMM8(HOST_r3, 1) ); // add r3, #1
|
|
cache_addw(0xb408); // push {r3}
|
|
cache_addw( BX(HOST_r0) ); // bx r0
|
|
cache_addw( NOP ); // nop
|
|
|
|
// align 4
|
|
cache_addw(0xbcfc); // pop {r2,r3,v1-v4}
|
|
cache_addw( MOV_HI_LO(FC_SEGS_ADDR, HOST_r3) ); // mov FC_SEGS_ADDR, r3
|
|
cache_addw( MOV_HI_LO(FC_REGS_ADDR, HOST_r2) ); // mov FC_REGS_ADDR, r2
|
|
|
|
cache_addw(0xbc08); // pop {r3}
|
|
cache_addw( BX(HOST_r3) ); // bx r3
|
|
|
|
// fill up to 64 bytes
|
|
cache_addw( NOP ); // nop
|
|
cache_addd( NOP | (NOP << 16) ); // nop, nop
|
|
cache_addd( NOP | (NOP << 16) ); // nop, nop
|
|
cache_addd( NOP | (NOP << 16) ); // nop, nop
|
|
cache_addd( NOP | (NOP << 16) ); // nop, nop
|
|
|
|
// adr: 64
|
|
cache_addd((Bit32u)&Segs); // address of "Segs"
|
|
// adr: 68
|
|
cache_addd((Bit32u)&cpu_regs); // address of "cpu_regs"
|
|
}
|
|
|
|
// return from a function
|
|
static void gen_return_function(void) {
|
|
cache_checkinstr(4);
|
|
cache_addw(0xbc08); // pop {r3}
|
|
cache_addw( BX(HOST_r3) ); // bx r3
|
|
}
|
|
|
|
|
|
// short unconditional jump (over data pool)
|
|
// must emit at most CACHE_DATA_JUMP bytes
|
|
static void INLINE gen_create_branch_short(void * func) {
|
|
cache_addw( B_FWD((Bit32u)func - ((Bit32u)cache.pos + 4)) ); // b func
|
|
}
|
|
|
|
|
|
#ifdef DRC_FLAGS_INVALIDATION
|
|
|
|
// called when a call to a function can be replaced by a
|
|
// call to a simpler function
|
|
static void gen_fill_function_ptr(Bit8u * pos,void* fct_ptr,Bitu flags_type) {
|
|
if ((*(Bit16u*)pos & 0xf000) == 0xe000) {
|
|
if ((*(Bit16u*)pos & 0x0fff) >= ((CACHE_DATA_ALIGN / 2) - 1) &&
|
|
(*(Bit16u*)pos & 0x0fff) < 0x0800)
|
|
{
|
|
pos = (Bit8u *) ( ( ( (Bit32u)(*(Bit16u*)pos & 0x0fff) ) << 1 ) + ((Bit32u)pos + 4) );
|
|
}
|
|
}
|
|
|
|
#ifdef DRC_FLAGS_INVALIDATION_DCODE
|
|
if (((Bit32u)pos & 0x03) == 0)
|
|
{
|
|
// try to avoid function calls but rather directly fill in code
|
|
switch (flags_type) {
|
|
case t_ADDb:
|
|
case t_ADDw:
|
|
case t_ADDd:
|
|
*(Bit16u*)pos=ADD_REG(HOST_a1, HOST_a1, HOST_a2); // add a1, a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_ORb:
|
|
case t_ORw:
|
|
case t_ORd:
|
|
*(Bit16u*)pos=ORR(HOST_a1, HOST_a2); // orr a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_ANDb:
|
|
case t_ANDw:
|
|
case t_ANDd:
|
|
*(Bit16u*)pos=AND(HOST_a1, HOST_a2); // and a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_SUBb:
|
|
case t_SUBw:
|
|
case t_SUBd:
|
|
*(Bit16u*)pos=SUB_REG(HOST_a1, HOST_a1, HOST_a2); // sub a1, a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_XORb:
|
|
case t_XORw:
|
|
case t_XORd:
|
|
*(Bit16u*)pos=EOR(HOST_a1, HOST_a2); // eor a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_CMPb:
|
|
case t_CMPw:
|
|
case t_CMPd:
|
|
case t_TESTb:
|
|
case t_TESTw:
|
|
case t_TESTd:
|
|
*(Bit16u*)pos=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_INCb:
|
|
case t_INCw:
|
|
case t_INCd:
|
|
*(Bit16u*)pos=ADD_IMM3(HOST_a1, HOST_a1, 1); // add a1, a1, #1
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_DECb:
|
|
case t_DECw:
|
|
case t_DECd:
|
|
*(Bit16u*)pos=SUB_IMM3(HOST_a1, HOST_a1, 1); // sub a1, a1, #1
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_SHLb:
|
|
case t_SHLw:
|
|
case t_SHLd:
|
|
*(Bit16u*)pos=LSL_REG(HOST_a1, HOST_a2); // lsl a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_SHRb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=LSR_IMM(HOST_a1, HOST_a1, 24); // lsr a1, a1, #24
|
|
*(Bit16u*)(pos+4)=LSR_REG(HOST_a1, HOST_a2); // lsr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(6); // b after_call (pc+6)
|
|
break;
|
|
case t_SHRw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=LSR_IMM(HOST_a1, HOST_a1, 16); // lsr a1, a1, #16
|
|
*(Bit16u*)(pos+4)=LSR_REG(HOST_a1, HOST_a2); // lsr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(6); // b after_call (pc+6)
|
|
break;
|
|
case t_SHRd:
|
|
*(Bit16u*)pos=LSR_REG(HOST_a1, HOST_a2); // lsr a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_SARb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=ASR_IMM(HOST_a1, HOST_a1, 24); // asr a1, a1, #24
|
|
*(Bit16u*)(pos+4)=ASR_REG(HOST_a1, HOST_a2); // asr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(6); // b after_call (pc+6)
|
|
break;
|
|
case t_SARw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=ASR_IMM(HOST_a1, HOST_a1, 16); // asr a1, a1, #16
|
|
*(Bit16u*)(pos+4)=ASR_REG(HOST_a1, HOST_a2); // asr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(6); // b after_call (pc+6)
|
|
break;
|
|
case t_SARd:
|
|
*(Bit16u*)pos=ASR_REG(HOST_a1, HOST_a2); // asr a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_RORb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=LSR_IMM(templo1, HOST_a1, 8); // lsr templo1, a1, #8
|
|
*(Bit16u*)(pos+4)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+6)=NOP; // nop
|
|
*(Bit16u*)(pos+8)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+10)=NOP; // nop
|
|
*(Bit16u*)(pos+12)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+14)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
break;
|
|
case t_RORw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+4)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+6)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+8)=B_FWD(4); // b after_call (pc+4)
|
|
break;
|
|
case t_RORd:
|
|
*(Bit16u*)pos=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
case t_ROLb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=NEG(HOST_a2, HOST_a2); // neg a2, a2
|
|
*(Bit16u*)(pos+4)=LSR_IMM(templo1, HOST_a1, 8); // lsr templo1, a1, #8
|
|
*(Bit16u*)(pos+6)=ADD_IMM8(HOST_a2, 32); // add a2, #32
|
|
*(Bit16u*)(pos+8)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+10)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+12)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+14)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
break;
|
|
case t_ROLw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=NEG(HOST_a2, HOST_a2); // neg a2, a2
|
|
*(Bit16u*)(pos+4)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+6)=ADD_IMM8(HOST_a2, 32); // add a2, #32
|
|
*(Bit16u*)(pos+8)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+10)=NOP; // nop
|
|
*(Bit16u*)(pos+12)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+14)=NOP; // nop
|
|
break;
|
|
case t_ROLd:
|
|
*(Bit16u*)pos=NEG(HOST_a2, HOST_a2); // neg a2, a2
|
|
*(Bit16u*)(pos+2)=ADD_IMM8(HOST_a2, 32); // add a2, #32
|
|
*(Bit16u*)(pos+4)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(6); // b after_call (pc+6)
|
|
break;
|
|
case t_NEGb:
|
|
case t_NEGw:
|
|
case t_NEGd:
|
|
*(Bit16u*)pos=NEG(HOST_a1, HOST_a1); // neg a1, a1
|
|
*(Bit16u*)(pos+2)=B_FWD(10); // b after_call (pc+10)
|
|
break;
|
|
default:
|
|
*(Bit32u*)( ( ((Bit32u) (*pos)) << 2 ) + ((Bit32u)pos + 4) ) = (Bit32u)fct_ptr; // simple_func
|
|
break;
|
|
}
|
|
}
|
|
else
|
|
{
|
|
// try to avoid function calls but rather directly fill in code
|
|
switch (flags_type) {
|
|
case t_ADDb:
|
|
case t_ADDw:
|
|
case t_ADDd:
|
|
*(Bit16u*)pos=ADD_REG(HOST_a1, HOST_a1, HOST_a2); // add a1, a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_ORb:
|
|
case t_ORw:
|
|
case t_ORd:
|
|
*(Bit16u*)pos=ORR(HOST_a1, HOST_a2); // orr a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_ANDb:
|
|
case t_ANDw:
|
|
case t_ANDd:
|
|
*(Bit16u*)pos=AND(HOST_a1, HOST_a2); // and a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_SUBb:
|
|
case t_SUBw:
|
|
case t_SUBd:
|
|
*(Bit16u*)pos=SUB_REG(HOST_a1, HOST_a1, HOST_a2); // sub a1, a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_XORb:
|
|
case t_XORw:
|
|
case t_XORd:
|
|
*(Bit16u*)pos=EOR(HOST_a1, HOST_a2); // eor a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_CMPb:
|
|
case t_CMPw:
|
|
case t_CMPd:
|
|
case t_TESTb:
|
|
case t_TESTw:
|
|
case t_TESTd:
|
|
*(Bit16u*)pos=B_FWD(14); // b after_call (pc+14)
|
|
break;
|
|
case t_INCb:
|
|
case t_INCw:
|
|
case t_INCd:
|
|
*(Bit16u*)pos=ADD_IMM3(HOST_a1, HOST_a1, 1); // add a1, a1, #1
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_DECb:
|
|
case t_DECw:
|
|
case t_DECd:
|
|
*(Bit16u*)pos=SUB_IMM3(HOST_a1, HOST_a1, 1); // sub a1, a1, #1
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_SHLb:
|
|
case t_SHLw:
|
|
case t_SHLd:
|
|
*(Bit16u*)pos=LSL_REG(HOST_a1, HOST_a2); // lsl a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_SHRb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=LSR_IMM(HOST_a1, HOST_a1, 24); // lsr a1, a1, #24
|
|
*(Bit16u*)(pos+4)=LSR_REG(HOST_a1, HOST_a2); // lsr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(8); // b after_call (pc+8)
|
|
break;
|
|
case t_SHRw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=LSR_IMM(HOST_a1, HOST_a1, 16); // lsr a1, a1, #16
|
|
*(Bit16u*)(pos+4)=LSR_REG(HOST_a1, HOST_a2); // lsr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(8); // b after_call (pc+8)
|
|
break;
|
|
case t_SHRd:
|
|
*(Bit16u*)pos=LSR_REG(HOST_a1, HOST_a2); // lsr a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_SARb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=ASR_IMM(HOST_a1, HOST_a1, 24); // asr a1, a1, #24
|
|
*(Bit16u*)(pos+4)=ASR_REG(HOST_a1, HOST_a2); // asr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(8); // b after_call (pc+8)
|
|
break;
|
|
case t_SARw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=ASR_IMM(HOST_a1, HOST_a1, 16); // asr a1, a1, #16
|
|
*(Bit16u*)(pos+4)=ASR_REG(HOST_a1, HOST_a2); // asr a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(8); // b after_call (pc+8)
|
|
break;
|
|
case t_SARd:
|
|
*(Bit16u*)pos=ASR_REG(HOST_a1, HOST_a2); // asr a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_RORb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=LSR_IMM(templo1, HOST_a1, 8); // lsr templo1, a1, #8
|
|
*(Bit16u*)(pos+4)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+6)=NOP; // nop
|
|
*(Bit16u*)(pos+8)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+10)=NOP; // nop
|
|
*(Bit16u*)(pos+12)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+14)=NOP; // nop
|
|
*(Bit16u*)(pos+16)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
break;
|
|
case t_RORw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+4)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+6)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+8)=B_FWD(6); // b after_call (pc+6)
|
|
break;
|
|
case t_RORd:
|
|
*(Bit16u*)pos=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
case t_ROLb:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 24); // lsl a1, a1, #24
|
|
*(Bit16u*)(pos+2)=NEG(HOST_a2, HOST_a2); // neg a2, a2
|
|
*(Bit16u*)(pos+4)=LSR_IMM(templo1, HOST_a1, 8); // lsr templo1, a1, #8
|
|
*(Bit16u*)(pos+6)=ADD_IMM8(HOST_a2, 32); // add a2, #32
|
|
*(Bit16u*)(pos+8)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+10)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+12)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+14)=NOP; // nop
|
|
*(Bit16u*)(pos+16)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
break;
|
|
case t_ROLw:
|
|
*(Bit16u*)pos=LSL_IMM(HOST_a1, HOST_a1, 16); // lsl a1, a1, #16
|
|
*(Bit16u*)(pos+2)=NEG(HOST_a2, HOST_a2); // neg a2, a2
|
|
*(Bit16u*)(pos+4)=LSR_IMM(templo1, HOST_a1, 16); // lsr templo1, a1, #16
|
|
*(Bit16u*)(pos+6)=ADD_IMM8(HOST_a2, 32); // add a2, #32
|
|
*(Bit16u*)(pos+8)=ORR(HOST_a1, templo1); // orr a1, templo1
|
|
*(Bit16u*)(pos+10)=NOP; // nop
|
|
*(Bit16u*)(pos+12)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+14)=NOP; // nop
|
|
*(Bit16u*)(pos+16)=NOP; // nop
|
|
break;
|
|
case t_ROLd:
|
|
*(Bit16u*)pos=NEG(HOST_a2, HOST_a2); // neg a2, a2
|
|
*(Bit16u*)(pos+2)=ADD_IMM8(HOST_a2, 32); // add a2, #32
|
|
*(Bit16u*)(pos+4)=ROR_REG(HOST_a1, HOST_a2); // ror a1, a2
|
|
*(Bit16u*)(pos+6)=B_FWD(8); // b after_call (pc+8)
|
|
break;
|
|
case t_NEGb:
|
|
case t_NEGw:
|
|
case t_NEGd:
|
|
*(Bit16u*)pos=NEG(HOST_a1, HOST_a1); // neg a1, a1
|
|
*(Bit16u*)(pos+2)=B_FWD(12); // b after_call (pc+12)
|
|
break;
|
|
default:
|
|
*(Bit32u*)( ( ((Bit32u) (*pos)) << 2 ) + ((Bit32u)pos + 2) ) = (Bit32u)fct_ptr; // simple_func
|
|
break;
|
|
}
|
|
|
|
}
|
|
#else
|
|
if (((Bit32u)pos & 0x03) == 0)
|
|
{
|
|
*(Bit32u*)( ( ((Bit32u) (*pos)) << 2 ) + ((Bit32u)pos + 4) ) = (Bit32u)fct_ptr; // simple_func
|
|
}
|
|
else
|
|
{
|
|
*(Bit32u*)( ( ((Bit32u) (*pos)) << 2 ) + ((Bit32u)pos + 2) ) = (Bit32u)fct_ptr; // simple_func
|
|
}
|
|
#endif
|
|
}
|
|
#endif
|
|
|
|
#ifdef DRC_USE_SEGS_ADDR
|
|
|
|
// mov 16bit value from Segs[index] into dest_reg using FC_SEGS_ADDR (index modulo 2 must be zero)
|
|
// 16bit moves may destroy the upper 16bit of the destination register
|
|
static void gen_mov_seg16_to_reg(HostReg dest_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo1, FC_SEGS_ADDR) ); // mov templo1, FC_SEGS_ADDR
|
|
cache_addw( LDRH_IMM(dest_reg, templo1, index) ); // ldrh dest_reg, [templo1, #index]
|
|
}
|
|
|
|
// mov 32bit value from Segs[index] into dest_reg using FC_SEGS_ADDR (index modulo 4 must be zero)
|
|
static void gen_mov_seg32_to_reg(HostReg dest_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo1, FC_SEGS_ADDR) ); // mov templo1, FC_SEGS_ADDR
|
|
cache_addw( LDR_IMM(dest_reg, templo1, index) ); // ldr dest_reg, [templo1, #index]
|
|
}
|
|
|
|
// add a 32bit value from Segs[index] to a full register using FC_SEGS_ADDR (index modulo 4 must be zero)
|
|
static void gen_add_seg32_to_reg(HostReg reg,Bitu index) {
|
|
cache_checkinstr(6);
|
|
cache_addw( MOV_LO_HI(templo1, FC_SEGS_ADDR) ); // mov templo1, FC_SEGS_ADDR
|
|
cache_addw( LDR_IMM(templo2, templo1, index) ); // ldr templo2, [templo1, #index]
|
|
cache_addw( ADD_REG(reg, reg, templo2) ); // add reg, reg, templo2
|
|
}
|
|
|
|
#endif
|
|
|
|
#ifdef DRC_USE_REGS_ADDR
|
|
|
|
// mov 16bit value from cpu_regs[index] into dest_reg using FC_REGS_ADDR (index modulo 2 must be zero)
|
|
// 16bit moves may destroy the upper 16bit of the destination register
|
|
static void gen_mov_regval16_to_reg(HostReg dest_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo2, FC_REGS_ADDR) ); // mov templo2, FC_REGS_ADDR
|
|
cache_addw( LDRH_IMM(dest_reg, templo2, index) ); // ldrh dest_reg, [templo2, #index]
|
|
}
|
|
|
|
// mov 32bit value from cpu_regs[index] into dest_reg using FC_REGS_ADDR (index modulo 4 must be zero)
|
|
static void gen_mov_regval32_to_reg(HostReg dest_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo2, FC_REGS_ADDR) ); // mov templo2, FC_REGS_ADDR
|
|
cache_addw( LDR_IMM(dest_reg, templo2, index) ); // ldr dest_reg, [templo2, #index]
|
|
}
|
|
|
|
// move a 32bit (dword==true) or 16bit (dword==false) value from cpu_regs[index] into dest_reg using FC_REGS_ADDR (if dword==true index modulo 4 must be zero) (if dword==false index modulo 2 must be zero)
|
|
// 16bit moves may destroy the upper 16bit of the destination register
|
|
static void gen_mov_regword_to_reg(HostReg dest_reg,Bitu index,bool dword) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo2, FC_REGS_ADDR) ); // mov templo2, FC_REGS_ADDR
|
|
if (dword) {
|
|
cache_addw( LDR_IMM(dest_reg, templo2, index) ); // ldr dest_reg, [templo2, #index]
|
|
} else {
|
|
cache_addw( LDRH_IMM(dest_reg, templo2, index) ); // ldrh dest_reg, [templo2, #index]
|
|
}
|
|
}
|
|
|
|
// move an 8bit value from cpu_regs[index] into dest_reg using FC_REGS_ADDR
|
|
// the upper 24bit of the destination register can be destroyed
|
|
// this function does not use FC_OP1/FC_OP2 as dest_reg as these
|
|
// registers might not be directly byte-accessible on some architectures
|
|
static void gen_mov_regbyte_to_reg_low(HostReg dest_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo2, FC_REGS_ADDR) ); // mov templo2, FC_REGS_ADDR
|
|
cache_addw( LDRB_IMM(dest_reg, templo2, index) ); // ldrb dest_reg, [templo2, #index]
|
|
}
|
|
|
|
// move an 8bit value from cpu_regs[index] into dest_reg using FC_REGS_ADDR
|
|
// the upper 24bit of the destination register can be destroyed
|
|
// this function can use FC_OP1/FC_OP2 as dest_reg which are
|
|
// not directly byte-accessible on some architectures
|
|
static void INLINE gen_mov_regbyte_to_reg_low_canuseword(HostReg dest_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo2, FC_REGS_ADDR) ); // mov templo2, FC_REGS_ADDR
|
|
cache_addw( LDRB_IMM(dest_reg, templo2, index) ); // ldrb dest_reg, [templo2, #index]
|
|
}
|
|
|
|
|
|
// add a 32bit value from cpu_regs[index] to a full register using FC_REGS_ADDR (index modulo 4 must be zero)
|
|
static void gen_add_regval32_to_reg(HostReg reg,Bitu index) {
|
|
cache_checkinstr(6);
|
|
cache_addw( MOV_LO_HI(templo2, FC_REGS_ADDR) ); // mov templo2, FC_REGS_ADDR
|
|
cache_addw( LDR_IMM(templo1, templo2, index) ); // ldr templo1, [templo2, #index]
|
|
cache_addw( ADD_REG(reg, reg, templo1) ); // add reg, reg, templo1
|
|
}
|
|
|
|
|
|
// move 16bit of register into cpu_regs[index] using FC_REGS_ADDR (index modulo 2 must be zero)
|
|
static void gen_mov_regval16_from_reg(HostReg src_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo1, FC_REGS_ADDR) ); // mov templo1, FC_REGS_ADDR
|
|
cache_addw( STRH_IMM(src_reg, templo1, index) ); // strh src_reg, [templo1, #index]
|
|
}
|
|
|
|
// move 32bit of register into cpu_regs[index] using FC_REGS_ADDR (index modulo 4 must be zero)
|
|
static void gen_mov_regval32_from_reg(HostReg src_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo1, FC_REGS_ADDR) ); // mov templo1, FC_REGS_ADDR
|
|
cache_addw( STR_IMM(src_reg, templo1, index) ); // str src_reg, [templo1, #index]
|
|
}
|
|
|
|
// move 32bit (dword==true) or 16bit (dword==false) of a register into cpu_regs[index] using FC_REGS_ADDR (if dword==true index modulo 4 must be zero) (if dword==false index modulo 2 must be zero)
|
|
static void gen_mov_regword_from_reg(HostReg src_reg,Bitu index,bool dword) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo1, FC_REGS_ADDR) ); // mov templo1, FC_REGS_ADDR
|
|
if (dword) {
|
|
cache_addw( STR_IMM(src_reg, templo1, index) ); // str src_reg, [templo1, #index]
|
|
} else {
|
|
cache_addw( STRH_IMM(src_reg, templo1, index) ); // strh src_reg, [templo1, #index]
|
|
}
|
|
}
|
|
|
|
// move the lowest 8bit of a register into cpu_regs[index] using FC_REGS_ADDR
|
|
static void gen_mov_regbyte_from_reg_low(HostReg src_reg,Bitu index) {
|
|
cache_checkinstr(4);
|
|
cache_addw( MOV_LO_HI(templo1, FC_REGS_ADDR) ); // mov templo1, FC_REGS_ADDR
|
|
cache_addw( STRB_IMM(src_reg, templo1, index) ); // strb src_reg, [templo1, #index]
|
|
}
|
|
|
|
#endif
|