{ $Id$ Copyright (c) 1998-2002 by Florian Klaempfl Contains the base types for the PowerPC 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., 675 Mass Ave, Cambridge, MA 02139, USA. **************************************************************************** } { This Unit contains the base types for the PowerPC } unit cpubase; {$i fpcdefs.inc} interface uses strings,cutils,cclasses,aasmbase,cpuinfo,cginfo; {***************************************************************************** Assembler Opcodes *****************************************************************************} type TAsmOp=(A_None, { normal opcodes } a_add, a_add_, a_addo, a_addo_, a_addc, a_addc_, a_addco, a_addco_, a_adde, a_adde_, a_addeo, a_addeo_, a_addi, a_addic, a_addic_, a_addis, a_addme, a_addme_, a_addmeo, a_addmeo_, a_addze, a_addze_, a_addzeo, a_addzeo_, a_and, a_and_, a_andc, a_andc_, a_andi_, a_andis_, a_b, a_ba, a_bl, a_bla, a_bc, a_bca, a_bcl, a_bcla, a_bcctr, a_bcctrl, a_bclr, a_bclrl, a_cmp, a_cmpi, a_cmpl, a_cmpli, a_cntlzw, a_cntlzw_, a_crand, a_crandc, a_creqv, a_crnand, a_crnor, a_cror, a_crorc, a_crxor, a_dcba, a_dcbf, a_dcbi, a_dcbst, a_dcbt, a_divw, a_divw_, a_divwo, a_divwo_, a_divwu, a_divwu_, a_divwuo, a_divwuo_, a_eciwx, a_ecowx, a_eieio, a_eqv, a_eqv_, a_extsb, a_extsb_, a_extsh, a_extsh_, a_fabs, a_fabs_, a_fadd, a_fadd_, a_fadds, a_fadds_, a_fcmpo, a_fcmpu, a_fctiw, a_fctw_, a_fctwz, a_fctwz_, a_fdiv, a_fdiv_, a_fdivs, a_fdivs_, a_fmadd, a_fmadd_, a_fmadds, a_fmadds_, a_fmr, a_fmsub, a_fmsub_, a_fmsubs, a_fmsubs_, a_fmul, a_fmul_, a_fmuls, a_fmuls_, a_fnabs, a_fnabs_, a_fneg, a_fneg_, a_fnmadd, a_fnmadd_, a_fnmadds, a_fnmadds_, a_fnmsub, a_fnmsub_, a_fnmsubs, a_fnmsubs_, a_fres, a_fres_, a_frsp, a_frsp_, a_frsqrte, a_frsqrte_, a_fsel, a_fsel_, a_fsqrt, a_fsqrt_, a_fsqrts, a_fsqrts_, a_fsub, a_fsub_, a_fsubs, a_fsubs_, a_icbi, a_isync, a_lbz, a_lbzu, a_lbzux, a_lbzx, a_lfd, a_lfdu, a_lfdux, a_lfdx, a_lfs, a_lfsu, a_lfsux, a_lfsx, a_lha, a_lhau, a_lhaux, a_lhax, a_hbrx, a_lhz, a_lhzu, a_lhzux, a_lhzx, a_lmw, a_lswi, a_lswx, a_lwarx, a_lwbrx, a_lwz, a_lwzu, a_lwzux, a_lwzx, a_mcrf, a_mcrfs, a_mcrxr, a_lcrxe, a_mfcr, a_mffs, a_maffs_, a_mfmsr, a_mfspr, a_mfsr, a_mfsrin, a_mftb, a_mtfcrf, a_a_mtfd0, a_mtfsb1, a_mtfsf, a_mtfsf_, a_mtfsfi, a_mtfsfi_, a_mtmsr, a_mtspr, a_mtsr, a_mtsrin, a_mulhw, a_mulhw_, a_mulhwu, a_mulhwu_, a_mulli, a_mullw, a_mullw_, a_mullwo, a_mullwo_, a_nand, a_nand_, a_neg, a_neg_, a_nego, a_nego_, a_nor, a_nor_, a_or, a_or_, a_orc, a_orc_, a_ori, a_oris, a_rfi, a_rlwimi, a_rlwimi_, a_rlwinm, a_rlwinm_, a_rlwnm, a_sc, a_slw, a_slw_, a_sraw, a_sraw_, a_srawi, a_srawi_,a_srw, a_srw_, a_stb, a_stbu, a_stbux, a_stbx, a_stfd, a_stfdu, a_stfdux, a_stfdx, a_stfiwx, a_stfs, a_stfsu, a_stfsux, a_stfsx, a_sth, a_sthbrx, a_sthu, a_sthux, a_sthx, a_stmw, a_stswi, a_stswx, a_stw, a_stwbrx, a_stwx_, a_stwu, a_stwux, a_stwx, a_subf, a_subf_, a_subfo, a_subfo_, a_subfc, a_subfc_, a_subfco, a_subfco_, a_subfe, a_subfe_, a_subfeo, a_subfeo_, a_subfic, a_subfme, a_subfme_, a_subfmeo, a_subfmeo_, a_subfze, a_subfze_, a_subfzeo, a_subfzeo_, a_sync, a_tlbia, a_tlbie, a_tlbsync, a_tw, a_twi, a_xor, a_xor_, a_xori, a_xoris, { simplified mnemonics } a_subi, a_subis, a_subic, a_subic_, a_sub, a_sub_, a_subo, a_subo_, a_subc, a_subc_, a_subco, a_subco_, a_cmpwi, a_cmpw, a_cmplwi, a_cmplw, a_extlwi, a_extlwi_, a_extrwi, a_extrwi_, a_inslwi, a_inslwi_, a_insrwi, a_insrwi_, a_rotlwi, a_rotlwi_, a_rotlw, a_rotlw_, a_slwi, a_slwi_, a_srwi, a_srwi_, a_clrlwi, a_clrlwi_, a_clrrwi, a_clrrwi_, a_clrslwi, a_clrslwi_, a_blr, a_bctr, a_blrl, a_bctrl, a_crset, a_crclr, a_crmove, a_crnot, a_mt {move to special prupose reg}, a_mf {move from special purpose reg}, a_nop, a_li, a_lis, a_la, a_mr, a_mr_, a_not, a_mtcr, a_mtlr, a_mflr, a_mtctr, a_mfctr); {# This should define the array of instructions as string } op2strtable=array[tasmop] of string[8]; Const {# First value of opcode enumeration } firstop = low(tasmop); {# Last value of opcode enumeration } lastop = high(tasmop); {***************************************************************************** Registers *****************************************************************************} type tregister = (R_NO, R_0,R_1,R_2,R_3,R_4,R_5,R_6,R_7,R_8,R_9,R_10,R_11,R_12,R_13,R_14,R_15,R_16, R_17,R_18,R_19,R_20,R_21,R_22,R_23,R_24,R_25,R_26,R_27,R_28,R_29,R_30,R_31, R_F0,R_F1,R_F2,R_F3,R_F4,R_F5,R_F6,R_F7,R_F8,R_F9,R_F10,R_F11,R_F12, R_F13,R_F14,R_F15,R_F16,R_F17, R_F18,R_F19,R_F20,R_F21,R_F22, R_F23,R_F24, R_F25,R_F26,R_F27,R_F28,R_F29,R_F30,R_F31, R_M0,R_M1,R_M2,R_M3,R_M4,R_M5,R_M6,R_M7,R_M8,R_M9,R_M10,R_M11,R_M12, R_M13,R_M14,R_M15,R_M16,R_M17,R_M18,R_M19,R_M20,R_M21,R_M22, R_M23,R_M24, R_M25,R_M26,R_M27,R_M28,R_M29,R_M30,R_M31, R_CR,R_CR0,R_CR1,R_CR2,R_CR3,R_CR4,R_CR5,R_CR6,R_CR7, R_XER,R_LR,R_CTR,R_FPSCR ); {# Set type definition for registers } tregisterset = set of tregister; { A type to store register locations for 64 Bit values. } tregister64 = packed record reglo,reghi : tregister; end; { alias for compact code } treg64 = tregister64; {# Type definition for the array of string of register nnames } treg2strtable = array[tregister] of string[5]; Const {# First register in the tregister enumeration } firstreg = low(tregister); {# Last register in the tregister enumeration } lastreg = high(tregister); R_SPR1 = R_XER; R_SPR8 = R_LR; R_SPR9 = R_CTR; R_TOC = R_2; { CR0 = 0; CR1 = 4; CR2 = 8; CR3 = 12; CR4 = 16; CR5 = 20; CR6 = 24; CR7 = 28; LT = 0; GT = 1; EQ = 2; SO = 3; FX = 4; FEX = 5; VX = 6; OX = 7;} mot_reg2str : treg2strtable = ('', 'r0','r1','r2','r3','r4','r5','r6','r7','r8','r9','r10','r11','r12','r13', 'r14','r15','r16','r17','r18','r19','r20','r21','r22','r23','r24','r25', 'r26','r27','r28','r29','r30','r31', 'F0','F1','F2','F3','F4','F5','F6','F7', 'F8','F9','F10','F11','F12', 'F13','F14','F15','F16','F17', 'F18','F19','F20','F21','F22', 'F23','F24', 'F25','F26','F27','F28','F29','F30','F31', 'M0','M1','M2','M3','M4','M5','M6','M7','M8','M9','M10','M11','M12', 'M13','M14','M15','M16','M17','M18','M19','M20','M21','M22', 'M23','M24', 'M25','M26','M27','M28','M29','M30','M31', 'CR','CR0','CR1','CR2','CR3','CR4','CR5','CR6','CR7', 'XER','LR','CTR','FPSCR' ); std_reg2str : treg2strtable = ('', 'r0','r1','r2','r3','r4','r5','r6','r7','r8','r9','r10','r11','r12','r13', 'r14','r15','r16','r17','r18','r19','r20','r21','r22','r23','r24','r25', 'r26','r27','r28','r29','r30','r31', 'F0','F1','F2','F3','F4','F5','F6','F7', 'F8','F9','F10','F11','F12', 'F13','F14','F15','F16','F17', 'F18','F19','F20','F21','F22', 'F23','F24', 'F25','F26','F27','F28','F29','F30','F31', 'M0','M1','M2','M3','M4','M5','M6','M7','M8','M9','M10','M11','M12', 'M13','M14','M15','M16','M17','M18','M19','M20','M21','M22', 'M23','M24', 'M25','M26','M27','M28','M29','M30','M31', 'CR','CR0','CR1','CR2','CR3','CR4','CR5','CR6','CR7', 'XER','LR','CTR','FPSCR' ); {***************************************************************************** Conditions *****************************************************************************} type TAsmCondFlag = (C_None { unconditional jumps }, { conditions when not using ctr decrement etc } C_LT,C_LE,C_EQ,C_GE,C_GT,C_NL,C_NE,C_NG,C_SO,C_NS,C_UN,C_NU, { conditions when using ctr decrement etc } C_T,C_F,C_DNZ,C_DNZT,C_DNZF,C_DZ,C_DZT,C_DZF); const { these are in the XER, but when moved to CR_x they correspond with the } { bits below (still needs to be verified!!!) } C_OV = C_EQ; C_CA = C_GT; type TAsmCond = packed record case simple: boolean of false: (BO, BI: byte); true: ( cond: TAsmCondFlag; case byte of 0: (); { specifies in which part of the cr the bit has to be } { tested for blt,bgt,beq,..,bnu } 1: (cr: R_CR0..R_CR7); { specifies the bit to test for bt,bf,bdz,..,bdzf } 2: (crbit: byte) ); end; const AsmCondFlag2BO: Array[C_T..C_DZF] of Byte = (12,4,16,8,0,18,10,2); AsmCondFlag2BI: Array[C_LT..C_NU] of Byte = (0,1,2,0,1,0,2,1,3,3,3,3); AsmCondFlagTF: Array[TAsmCondFlag] of Boolean = (false,true,false,true,false,true,false,false,false,true,false,true,false, true,false,false,true,false,false,true,false); AsmCondFlag2Str: Array[TAsmCondFlag] of string[4] = ({cf_none}'', { conditions when not using ctr decrement etc} 'lt','le','eq','ge','gt','nl','ne','ng','so','ns','un','nu', 't','f','dnz','dzt','dnzf','dz','dzt','dzf'); const CondAsmOps=3; CondAsmOp:array[0..CondAsmOps-1] of TasmOp=( A_BC, A_TW, A_TWI ); {***************************************************************************** Flags *****************************************************************************} type TResFlagsEnum = (F_EQ,F_NE,F_LT,F_LE,F_GT,F_GE,F_SO,F_FX,F_FEX,F_VX,F_OX); TResFlags = record cr: R_CR0..R_CR7; flag: TResFlagsEnum; end; (* const { arrays for boolean location conversions } flag_2_cond : array[TResFlags] of TAsmCond = (C_E,C_NE,C_LT,C_LE,C_GT,C_GE,???????????????); *) {***************************************************************************** Reference *****************************************************************************} type trefoptions=(ref_none,ref_parafixup,ref_localfixup,ref_selffixup); { since we have only 16 offsets, we need to be able to specify the high } { and low 16 bits of the address of a symbol } trefsymaddr = (refs_full,refs_ha,refs_l); { reference record } preference = ^treference; treference = packed record base, index : tregister; offset : longint; symbol : tasmsymbol; symaddr : trefsymaddr; offsetfixup : longint; options : trefoptions; alignment : byte; end; { reference record } pparareference = ^tparareference; tparareference = packed record index : tregister; offset : aword; end; const symaddr2str: array[trefsymaddr] of string[3] = ('','@ha','@l'); {***************************************************************************** Operand *****************************************************************************} type toptype=(top_none,top_reg,top_ref,top_const,top_symbol,top_bool); toper=record ot : longint; case typ : toptype of top_none : (); top_reg : (reg:tregister); top_ref : (ref:^treference); top_const : (val:aword); top_symbol : (sym:tasmsymbol;symofs:longint); top_bool : (b: boolean); end; {***************************************************************************** Operand Sizes *****************************************************************************} {***************************************************************************** Generic Location *****************************************************************************} type TLoc=( { added for tracking problems} LOC_INVALID, { ordinal constant } LOC_CONSTANT, { in a processor register } LOC_REGISTER, { Constant register which shouldn't be modified } LOC_CREGISTER, { FPU register} LOC_FPUREGISTER, { Constant FPU register which shouldn't be modified } LOC_CFPUREGISTER, { multimedia register } LOC_MMREGISTER, { Constant multimedia reg which shouldn't be modified } LOC_CMMREGISTER, { in memory } LOC_REFERENCE, { in memory (constant) } LOC_CREFERENCE, { boolean results only, jump to false or true label } LOC_JUMP, { boolean results only, flags are set } LOC_FLAGS ); { tparamlocation describes where a parameter for a procedure is stored. References are given from the caller's point of view. The usual TLocation isn't used, because contains a lot of unnessary fields. } tparalocation = packed record size : TCGSize; { The location type where the parameter is passed, usually LOC_REFERENCE,LOC_REGISTER or LOC_FPUREGISTER } loc : TLoc; { The stack pointer must be decreased by this value before the parameter is copied to the given destination. This allows to "encode" pushes with tparalocation. On the PowerPC, this field is unsed but it is there because several generic code accesses it. } sp_fixup : longint; case TLoc of LOC_REFERENCE : (reference : tparareference); LOC_FPUREGISTER, LOC_CFPUREGISTER, LOC_MMREGISTER, LOC_CMMREGISTER, LOC_REGISTER,LOC_CREGISTER : ( case longint of 1 : (register,registerhigh : tregister); { overlay a registerlow } 2 : (registerlow : tregister); { overlay a 64 Bit register type } 3 : (reg64 : tregister64); 4 : (register64 : tregister64); ); end; tlocation = packed record size : TCGSize; loc : tloc; case tloc of LOC_CREFERENCE,LOC_REFERENCE : (reference : treference); LOC_CONSTANT : ( case longint of 1 : (value : AWord); { can't do this, this layout depends on the host cpu. Use } { lo(valueqword)/hi(valueqword) instead (JM) } { 2 : (valuelow, valuehigh:AWord); } { overlay a complete 64 Bit value } 3 : (valueqword : qword); ); LOC_FPUREGISTER, LOC_CFPUREGISTER, LOC_MMREGISTER, LOC_CMMREGISTER, LOC_REGISTER,LOC_CREGISTER : ( case longint of 1 : (registerlow,registerhigh : tregister); 2 : (register : tregister); { overlay a 64 Bit register type } 3 : (reg64 : tregister64); 4 : (register64 : tregister64); ); LOC_FLAGS : (resflags : tresflags); end; {***************************************************************************** Constants *****************************************************************************} const max_operands = 5; lvaluelocations = [LOC_REFERENCE, LOC_CREGISTER, LOC_CFPUREGISTER, LOC_CMMREGISTER]; {# Constant defining possibly all registers which might require saving } {$warning FIX ME !!!!!!!!! } ALL_REGISTERS = [R_0..R_FPSCR]; general_registers = [R_0..R_31]; {# low and high of the available maximum width integer general purpose } { registers } LoGPReg = R_0; HiGPReg = R_31; {# low and high of every possible width general purpose register (same as } { above on most architctures apart from the 80x86) } LoReg = R_0; HiReg = R_31; {# Table of registers which can be allocated by the code generator internally, when generating the code. } { legend: } { xxxregs = set of all possibly used registers of that type in the code } { generator } { usableregsxxx = set of all 32bit components of registers that can be } { possible allocated to a regvar or using getregisterxxx (this } { excludes registers which can be only used for parameter } { passing on ABI's that define this) } { c_countusableregsxxx = amount of registers in the usableregsxxx set } maxintregs = 18; intregs = [R_0..R_31]; usableregsint = [R_13..R_27]; c_countusableregsint = 18; maxfpuregs = 31-14+1; fpuregs = [R_F0..R_F31]; usableregsfpu = [R_F14..R_F31]; c_countusableregsfpu = 31-14+1; mmregs = [R_M0..R_M31]; usableregsmm = [R_M14..R_M31]; c_countusableregsmm = 31-14+1; firstsaveintreg = R_13; lastsaveintreg = R_27; firstsavefpureg = R_F14; lastsavefpureg = R_F31; { no altivec support yet. Need to override tcgobj.a_loadmm_* first in tcgppc } firstsavemmreg = R_NO; lastsavemmreg = R_NO; maxvarregs = 18; varregs : Array [1..maxvarregs] of Tregister = (R_13,R_14,R_15,R_16,R_17,R_18,R_19,R_20,R_21,R_22,R_23,R_24,R_25, R_26,R_27,R_28,R_29,R_30); maxfpuvarregs = 31-14+1; fpuvarregs : Array [1..maxfpuvarregs] of Tregister = (R_F14,R_F15,R_F16,R_F17,R_F18,R_F19,R_F20,R_F21,R_F22,R_F23, R_F24,R_F25,R_F26,R_F27,R_F28,R_F29,R_F30,R_F31); max_param_regs_int = 8; param_regs_int: Array[1..max_param_regs_int] of tregister = (R_3,R_4,R_5,R_6,R_7,R_8,R_9,R_10); max_param_regs_fpu = 13; param_regs_fpu: Array[1..max_param_regs_fpu] of tregister = (R_F1,R_F2,R_F3,R_F4,R_F5,R_F6,R_F7,R_F8,R_F9,R_F10,R_F11,R_F12,R_F13); max_param_regs_mm = 13; param_regs_mm: Array[1..max_param_regs_mm] of tregister = (R_M1,R_M2,R_M3,R_M4,R_M5,R_M6,R_M7,R_M8,R_M9,R_M10,R_M11,R_M12,R_M13); {# Registers which are defined as scratch and no need to save across routine calls or in assembler blocks. } max_scratch_regs = 3; scratch_regs: Array[1..max_scratch_regs] of TRegister = (R_28,R_29,R_30); {***************************************************************************** Default generic sizes *****************************************************************************} {# Defines the default address size for a processor, } OS_ADDR = OS_32; {# the natural int size for a processor, } OS_INT = OS_32; {# the maximum float size for a processor, } OS_FLOAT = OS_F64; {# the size of a vector register for a processor } OS_VECTOR = OS_M128; {***************************************************************************** GDB Information *****************************************************************************} {# Register indexes for stabs information, when some parameters or variables are stored in registers. Taken from rs6000.h (DBX_REGISTER_NUMBER) from GCC 3.x source code. PowerPC has 1:1 mapping according to the order of the registers defined in GCC } stab_regindex : array[tregister] of shortint = ( { R_NO } -1, { R0..R7 } 0,1,2,3,4,5,6,7, { R8..R15 } 8,9,10,11,12,13,14,15, { R16..R23 } 16,17,18,19,20,21,22,23, { R24..R32 } 24,25,26,27,28,29,30,31, { F0..F7 } 32,33,34,35,36,37,38,39, { F8..F15 } 40,41,42,43,44,45,46,47, { F16..F23 } 48,49,50,51,52,53,54,55, { F24..F31 } 56,57,58,59,60,61,62,63, { M0..M7 Multimedia registers are not supported by GCC } -1,-1,-1,-1,-1,-1,-1,-1, { M8..M15 } -1,-1,-1,-1,-1,-1,-1,-1, { M16..M23 } -1,-1,-1,-1,-1,-1,-1,-1, { M24..M31 } -1,-1,-1,-1,-1,-1,-1,-1, { CR } -1, { CR0..CR7 } 68,69,70,71,72,73,74,75, { XER } 76, { LR } 65, { CTR } 66, { FPSCR } -1 ); {***************************************************************************** Generic Register names *****************************************************************************} {# Stack pointer register } stack_pointer_reg = R_1; {# Frame pointer register } frame_pointer_reg = stack_pointer_reg; {# Self pointer register : contains the instance address of an object or class. } self_pointer_reg = R_9; {# Register for addressing absolute data in a position independant way, such as in PIC code. The exact meaning is ABI specific. For further information look at GCC source : PIC_OFFSET_TABLE_REGNUM Taken from GCC rs6000.h } {$warning As indicated in rs6000.h, but can't find it anywhere else!} pic_offset_reg = R_30; {# Results are returned in this register (32-bit values) } accumulator = R_3; {# Hi-Results are returned in this register (64-bit value high register) } accumulatorhigh = R_4; { WARNING: don't change to R_ST0!! See comments above implementation of } { a_loadfpu* methods in rgcpu (JM) } fpu_result_reg = R_F1; mmresultreg = R_M0; {***************************************************************************** GCC /ABI linking information *****************************************************************************} {# Registers which must be saved when calling a routine declared as cppdecl, cdecl, stdcall, safecall, palmossyscall. The registers saved should be the ones as defined in the target ABI and / or GCC. This value can be deduced from CALLED_USED_REGISTERS array in the GCC source. } std_saved_registers = [R_13..R_29]; {# Required parameter alignment when calling a routine declared as stdcall and cdecl. The alignment value should be the one defined by GCC or the target ABI. The value of this constant is equal to the constant PARM_BOUNDARY / BITS_PER_UNIT in the GCC source. } std_param_align = 4; { for 32-bit version only } {***************************************************************************** CPU Dependent Constants *****************************************************************************} LinkageAreaSize = 24; { offset in the linkage area for the saved stack pointer } LA_SP = 0; { offset in the linkage area for the saved conditional register} LA_CR = 4; { offset in the linkage area for the saved link register} LA_LR = 8; { offset in the linkage area for the saved RTOC register} LA_RTOC = 20; {***************************************************************************** Helpers *****************************************************************************} function is_calljmp(o:tasmop):boolean; procedure inverse_flags(var r : TResFlags); procedure inverse_cond(const c: TAsmCond;var r : TAsmCond); function flags_to_cond(const f: TResFlags) : TAsmCond; procedure create_cond_imm(BO,BI:byte;var r : TAsmCond); procedure create_cond_norm(cond: TAsmCondFlag; cr: byte;var r : TasmCond); implementation uses verbose; {***************************************************************************** Helpers *****************************************************************************} function is_calljmp(o:tasmop):boolean; begin is_calljmp:=false; case o of A_B,A_BA,A_BL,A_BLA,A_BC,A_BCA,A_BCL,A_BCLA,A_BCCTR,A_BCCTRL,A_BCLR, A_BCLRL,A_TW,A_TWI: is_calljmp:=true; end; end; procedure inverse_flags(var r: TResFlags); const inv_flags: array[F_EQ..F_GE] of TResFlagsEnum = (F_NE,F_EQ,F_GE,F_GE,F_LE,F_LT); begin r.flag := inv_flags[r.flag]; end; procedure inverse_cond(const c: TAsmCond;var r : TAsmCond); const inv_condflags:array[TAsmCondFlag] of TAsmCondFlag=(C_None, C_GE,C_GT,C_NE,C_LT,C_LE,C_LT,C_EQ,C_GT,C_NS,C_SO,C_NU,C_UN, C_F,C_T,C_DNZ,C_DNZF,C_DNZT,C_DZ,C_DZF,C_DZT); begin r := c; r.cond := inv_condflags[c.cond]; end; function flags_to_cond(const f: TResFlags) : TAsmCond; const flag_2_cond: array[F_EQ..F_SO] of TAsmCondFlag = (C_EQ,C_NE,C_LT,C_LE,C_GT,C_GE,C_SO); begin if f.flag > high(flag_2_cond) then internalerror(200112301); result.simple := true; result.cr := f.cr; result.cond := flag_2_cond[f.flag]; end; procedure create_cond_imm(BO,BI:byte;var r : TAsmCond); begin r.simple := false; r.bo := bo; r.bi := bi; end; procedure create_cond_norm(cond: TAsmCondFlag; cr: byte;var r : TasmCond); begin r.simple := true; r.cond := cond; case cond of C_NONE:; C_T..C_DZF: r.crbit := cr else r.cr := tregister(ord(R_CR0)+cr); end; end; end. { $Log$ Revision 1.32 2002-09-07 15:25:14 peter * old logs removed and tabs fixed Revision 1.31 2002/09/01 21:04:49 florian * several powerpc related stuff fixed Revision 1.30 2002/08/18 22:16:15 florian + the ppc gas assembler writer adds now registers aliases to the assembler file Revision 1.29 2002/08/18 21:36:42 florian + handling of local variables in direct reader implemented Revision 1.28 2002/08/14 18:41:47 jonas - remove valuelow/valuehigh fields from tlocation, because they depend on the endianess of the host operating system -> difficult to get right. Use lo/hi(location.valueqword) instead (remember to use valueqword and not value!!) Revision 1.27 2002/08/13 21:40:58 florian * more fixes for ppc calling conventions Revision 1.26 2002/08/12 15:08:44 carl + stab register indexes for powerpc (moved from gdb to cpubase) + tprocessor enumeration moved to cpuinfo + linker in target_info is now a class * many many updates for m68k (will soon start to compile) - removed some ifdef or correct them for correct cpu Revision 1.25 2002/08/10 17:15:06 jonas * endianess fix Revision 1.24 2002/08/06 20:55:24 florian * first part of ppc calling conventions fix Revision 1.23 2002/08/04 12:57:56 jonas * more misc. fixes, mostly constant-related Revision 1.22 2002/07/27 19:57:18 jonas * some typo corrections in the instruction tables * renamed the m* registers to v* Revision 1.21 2002/07/26 12:30:51 jonas * fixed typo in instruction table (_subco_ -> a_subco) Revision 1.20 2002/07/25 18:04:10 carl + FPURESULTREG -> FPU_RESULT_REG Revision 1.19 2002/07/13 19:38:44 florian * some more generic calling stuff fixed Revision 1.18 2002/07/11 14:41:34 florian * start of the new generic parameter handling Revision 1.17 2002/07/11 07:35:36 jonas * some available registers fixes Revision 1.16 2002/07/09 19:45:01 jonas * unarynminus and shlshr node fixed for 32bit and smaller ordinals * small fixes in the assembler writer * changed scratch registers, because they were used by the linker (r11 and r12) and by the abi under linux (r31) Revision 1.15 2002/07/07 09:44:31 florian * powerpc target fixed, very simple units can be compiled Revision 1.14 2002/05/18 13:34:26 peter * readded missing revisions Revision 1.12 2002/05/14 19:35:01 peter * removed old logs and updated copyright year Revision 1.11 2002/05/14 17:28:10 peter * synchronized cpubase between powerpc and i386 * moved more tables from cpubase to cpuasm * tai_align_abstract moved to tainst, cpuasm must define the tai_align class now, which may be empty }