{ $Id$ Copyright (c) 1998-2002 by Florian Klaempfl and Peter Vreman Contains the base types for the ARM 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. **************************************************************************** } {# Base unit for processor information. This unit contains enumerations of registers, opcodes, sizes, and other such things which are processor specific. } unit cpubase; {$i fpcdefs.inc} interface uses cutils,cclasses, globals, cpuinfo, aasmbase, cginfo; {***************************************************************************** Assembler Opcodes *****************************************************************************} type TAsmOp=(A_ADC,A_ADD,A_AND,A_N,A_BIC,A_BKPT,A_BL,A_BLX,A_BX, A_CDP,A_CDP2,A_CLZ,A_CMN,A_CMP,A_EOR,A_LDC,_A_LDC2, A_LDM,A_LDR,A_LDRB,A_LDRD,A_LDRBT,A_LDRH,A_LDRSB, A_LDRSH,A_LDRT,A_MCR,A_MCR2,A_MCRR,A_MLA,A_MOV, A_MRC,A_MRC2,A_MRRC,A_RS,A_MSR,A_MUL,A_MVN, A_ORR,A_PLD,A_QADD,A_QDADD,A_QDSUB,A_QSUB,A_RSB,A_RSC, A_SBC,A_SMLAL.A_SMLA,A_SMLAL,A_SMLAW,A_SMULL,A_SMUL, A_SMULW,A_STC,A_STC2,A_STM,A_STR,A_STRB,A_STRBT,A_STRD, A_STRH,A_STRT,A_SUB,A_SWI,A_SWP,A_SWPB,A_TEQ,A_TST. A_UMLAL,A_UMULL { FPU coprocessor codes } { Vec unit coprocessor codes } ); { This should define the array of instructions as string } op2strtable=array[tasmop] of string[11]; Const { First value of opcode enumeration } firstop = low(tasmop); { Last value of opcode enumeration } lastop = high(tasmop); {***************************************************************************** Operand Sizes *****************************************************************************} type topsize = (S_NO, S_B,S_W,S_L,S_BW,S_BL,S_WL, S_IS,S_IL,S_IQ, S_FS,S_FL,S_FX,S_D,S_Q,S_FV, S_NEAR,S_FAR,S_SHORT ); {***************************************************************************** Registers *****************************************************************************} type {# Enumeration for all possible registers for cpu. It is to note that all registers of the same type (for example all FPU registers), should be grouped together. } { don't change the order } { it's used by the register size conversions } toldregister = (R_NO, R_RAX,R_RCX,R_RDX,R_RBX,R_RSP,R_RBP,R_RSI,R_RDI, R_R0,R_R1,R_R2,R_R3,R_R4,R_R5,R_R6,R_R7, R_R8,R_R9,R_R10,R_R11,R_R12,R_R13,R_R14,R_PC, R_CPSR ); type tnewregister=word; Tregister = packed record enum : Toldregister; { This is a word for now, change to cardinal when the old register coding is away.} number : Tnewregister; end; Tsuperregister = byte; Tsubregister = byte; { A type to store register locations for 64 Bit values. } tregister64 = packed record reglo,reghi : tregister; end; { alias for compact code } treg64 = tregister64; { Set type definition for registers } tregisterset = set of tregister; tsupregset = set of tsuperregister; { Type definition for the array of string of register names } reg2strtable = array[tregister] of string[6]; const {# First register in the tregister enumeration } firstreg = low(tregister); {# Last register in the tregister enumeration } lastreg = high(tregister); firstsreg = R_CS; lastsreg = R_GS; regset8bit : tregisterset = [R_AL..R_DH]; regset16bit : tregisterset = [R_AX..R_DI,R_CS..R_SS]; regset32bit : tregisterset = [R_EAX..R_EDI]; { Convert reg to opsize } reg2opsize : array[firstreg..lastreg] of topsize = (S_NO, S_L,S_L,S_L,S_L,S_L,S_L,S_L,S_L, S_W,S_W,S_W,S_W,S_W,S_W,S_W,S_W, S_B,S_B,S_B,S_B,S_B,S_B,S_B,S_B, S_W,S_W,S_W,S_W,S_W,S_W, S_FL,S_FL,S_FL,S_FL,S_FL,S_FL,S_FL,S_FL,S_FL, S_L,S_L,S_L,S_L,S_L,S_L, S_L,S_L,S_L,S_L, S_L,S_L,S_L,S_L,S_L, S_D,S_D,S_D,S_D,S_D,S_D,S_D,S_D, S_D,S_D,S_D,S_D,S_D,S_D,S_D,S_D ); {# Standard opcode string table (for each tasmop enumeration). The opcode strings should conform to the names as defined by the processor manufacturer. } std_op2str:op2strtable={$i i386int.inc} {# Standard register table (for each tregister enumeration). The register strings should conform to the the names as defined by the processor manufacturer } std_reg2str : reg2strtable = ('', 'eax','ecx','edx','ebx','esp','ebp','esi','edi', 'ax','cx','dx','bx','sp','bp','si','di', 'al','cl','dl','bl','ah','ch','bh','dh', 'cs','ds','es','ss','fs','gs', 'st','st(0)','st(1)','st(2)','st(3)','st(4)','st(5)','st(6)','st(7)', 'dr0','dr1','dr2','dr3','dr6','dr7', 'cr0','cr2','cr3','cr4', 'tr3','tr4','tr5','tr6','tr7', 'mm0','mm1','mm2','mm3','mm4','mm5','mm6','mm7', 'xmm0','xmm1','xmm2','xmm3','xmm4','xmm5','xmm6','xmm7' ); {***************************************************************************** Conditions *****************************************************************************} type TAsmCond=(C_None, C_EQ,C_NE,C_CS,C_CC,C_MI,C_PL,C_VS,C_VC,C_HI,C_LS, C_GE,C_LT,C_GT,C_LE,C_AL,C_NV ); const cond2str:array[TAsmCond] of string[2]=('', 'eq','ne','cs','cc','mi','pl','vs','vc','hi','ls', 'ge','lt','gt','le','al','nv' ); inverse_cond:array[TAsmCond] of TAsmCond=(C_None, ); {***************************************************************************** Flags *****************************************************************************} type TResFlags = (F_E,F_NE,F_G,F_L,F_GE,F_LE,F_C,F_NC,F_A,F_AE,F_B,F_BE); {***************************************************************************** Reference *****************************************************************************} type trefoptions=(ref_none,ref_parafixup,ref_localfixup,ref_selffixup); { reference record } preference = ^treference; treference = packed record segment, base, index : tregister; scalefactor : byte; offset : longint; symbol : tasmsymbol; offsetfixup : longint; options : trefoptions; end; { reference record } pparareference = ^tparareference; tparareference = packed record index : tregister; offset : longint; end; {***************************************************************************** Operands *****************************************************************************} { Types of operand } toptype=(top_none,top_reg,top_ref,top_const,top_symbol); toper=record ot : longint; case typ : toptype of top_none : (); top_reg : (reg:tregister); top_ref : (ref:preference); top_const : (val:aword); top_symbol : (sym:tasmsymbol;symofs:longint); end; {***************************************************************************** Generic Location *****************************************************************************} type TLoc=( LOC_INVALID, { added for tracking problems} LOC_CONSTANT, { constant value } LOC_JUMP, { boolean results only, jump to false or true label } LOC_FLAGS, { boolean results only, flags are set } LOC_CREFERENCE, { in memory constant value reference (cannot change) } LOC_REFERENCE, { in memory value } LOC_REGISTER, { in a processor register } LOC_CREGISTER, { Constant register which shouldn't be modified } LOC_FPUREGISTER, { FPU stack } LOC_CFPUREGISTER, { if it is a FPU register variable on the fpu stack } LOC_MMXREGISTER, { MMX register } LOC_CMMXREGISTER, { MMX register variable } LOC_SSEREGISTER, LOC_CSSEREGISTER ); { 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; loc : TLoc; sp_fixup : longint; case TLoc of LOC_REFERENCE : (reference : tparareference); { segment in reference at the same place as in loc_register } 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); ); { it's only for better handling } LOC_MMXREGISTER,LOC_CMMXREGISTER : (mmxreg : tregister); end; tlocation = packed record loc : TLoc; size : TCGSize; case TLoc of LOC_FLAGS : (resflags : tresflags); 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_CREFERENCE, LOC_REFERENCE : (reference : treference); { segment in reference at the same place as in loc_register } LOC_REGISTER,LOC_CREGISTER : ( case longint of 1 : (register,registerhigh,segment : tregister); { overlay a registerlow } 2 : (registerlow : tregister); { overlay a 64 Bit register type } 3 : (reg64 : tregister64); 4 : (register64 : tregister64); ); { it's only for better handling } LOC_MMXREGISTER,LOC_CMMXREGISTER : (mmxreg : tregister); end; {***************************************************************************** Constants *****************************************************************************} const { declare aliases } LOC_MMREGISTER = LOC_SSEREGISTER; LOC_CMMREGISTER = LOC_CSSEREGISTER; max_operands = 3; lvaluelocations = [LOC_REFERENCE,LOC_CFPUREGISTER, LOC_CREGISTER,LOC_MMXREGISTER,LOC_CMMXREGISTER]; {# Constant defining possibly all registers which might require saving } ALL_REGISTERS = [firstreg..lastreg]; general_registers = [R_EAX,R_EBX,R_ECX,R_EDX]; {# low and high of the available maximum width integer general purpose } { registers } LoGPReg = R_EAX; HiGPReg = R_EDX; {# low and high of every possible width general purpose register (same as } { above on most architctures apart from the 80x86) } LoReg = R_EAX; HiReg = R_DH; {# 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 = 4; intregs = [R_EAX..R_BL]; usableregsint = [R_EAX,R_EBX,R_ECX,R_EDX]; c_countusableregsint = 4; maxfpuregs = 8; fpuregs = [R_ST0..R_ST7]; usableregsfpu = []; c_countusableregsfpu = 0; mmregs = [R_MM0..R_MM7]; usableregsmm = [R_MM0..R_MM7]; c_countusableregsmm = 8; firstsaveintreg = R_EAX; lastsaveintreg = R_EBX; firstsavefpureg = R_NO; lastsavefpureg = R_NO; firstsavemmreg = R_MM0; lastsavemmreg = R_MM7; maxvarregs = 4; varregs : array[1..maxvarregs] of tregister = (R_EBX,R_EDX,R_ECX,R_EAX); maxfpuvarregs = 8; {# Registers which are defined as scratch and no need to save across routine calls or in assembler blocks. } max_scratch_regs = 1; scratch_regs : array[1..max_scratch_regs] of tregister = (R_EDI); {***************************************************************************** GDB Information *****************************************************************************} {# Register indexes for stabs information, when some parameters or variables are stored in registers. Taken from i386.c (dbx_register_map) and i386.h (FIXED_REGISTERS) from GCC 3.x source code } stab_regindex : array[tregister] of shortint = (-1, 0,1,2,3,4,5,6,7, 0,1,2,3,4,5,6,7, 0,1,2,3,0,1,2,3, -1,-1,-1,-1,-1,-1, 12,12,13,14,15,16,17,18,19, -1,-1,-1,-1,-1,-1, -1,-1,-1,-1, -1,-1,-1,-1,-1, 29,30,31,32,33,34,35,36, 21,22,23,24,25,26,27,28 ); {***************************************************************************** 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_F80; {# the size of a vector register for a processor } OS_VECTOR = OS_M64; {***************************************************************************** Generic Register names *****************************************************************************} {# Stack pointer register } stack_pointer_reg = R_ESP; {# Frame pointer register } frame_pointer_reg = R_EBP; {# Self pointer register : contains the instance address of an object or class. } self_pointer_reg = R_ESI; {# 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 } pic_offset_reg = R_EBX; {# Results are returned in this register (32-bit values) } accumulator = R_EAX; {# Hi-Results are returned in this register (64-bit value high register) } accumulatorhigh = R_EDX; { WARNING: don't change to R_ST0!! See comments above implementation of } { a_loadfpu* methods in rgcpu (JM) } fpu_result_reg = R_ST; mmresultreg = R_MM0; {***************************************************************************** GCC /ABI linking information *****************************************************************************} const {# 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 the CALLED_USED_REGISTERS array in the GCC source. } std_saved_registers = [R_ESI,R_EDI,R_EBX]; {# 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; {***************************************************************************** CPU Dependent Constants *****************************************************************************} {***************************************************************************** Helpers *****************************************************************************} function is_calljmp(o:tasmop):boolean; function flags_to_cond(const f: TResFlags) : TAsmCond; implementation {***************************************************************************** Helpers *****************************************************************************} function is_calljmp(o:tasmop):boolean; begin case o of A_CALL, A_JCXZ, A_JECXZ, A_JMP, A_LOOP, A_LOOPE, A_LOOPNE, A_LOOPNZ, A_LOOPZ, A_Jcc : is_calljmp:=true; else is_calljmp:=false; end; end; function flags_to_cond(const f: TResFlags) : TAsmCond; const flags_2_cond : array[TResFlags] of TAsmCond = (C_E,C_NE,C_G,C_L,C_GE,C_LE,C_C,C_NC,C_A,C_AE,C_B,C_BE); begin result := flags_2_cond[f]; end; end. { $Log$ Revision 1.2 2003-07-26 00:55:57 florian * basic stuff fixed Revision 1.1 2003/07/21 16:35:30 florian * very basic stuff for the arm }