{ Copyright (c) 1998-2002 by Florian Klaempfl This unit implements the code generator 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. **************************************************************************** } unit cgcpu; {$I fpcdefs.inc} interface uses globtype, symtype, symdef, cgbase, cgobj, aasmbase, aasmcpu, aasmtai, cpubase, cpuinfo, cgutils, rgcpu, parabase; type tcgppc = class(tcg) procedure init_register_allocators; override; procedure done_register_allocators; override; { passing parameters, per default the parameter is pushed } { nr gives the number of the parameter (enumerated from } { left to right), this allows to move the parameter to } { register, if the cpu supports register calling } { conventions } procedure a_param_const(list: taasmoutput; size: tcgsize; a: aint; const paraloc: tcgpara); override; procedure a_param_ref(list: taasmoutput; size: tcgsize; const r: treference; const paraloc: tcgpara); override; procedure a_paramaddr_ref(list: taasmoutput; const r: treference; const paraloc: tcgpara); override; procedure a_call_name(list: taasmoutput; const s: string); override; procedure a_call_reg(list: taasmoutput; reg: tregister); override; procedure a_op_const_reg(list: taasmoutput; Op: TOpCG; size: TCGSize; a: aint; reg: TRegister); override; procedure a_op_reg_reg(list: taasmoutput; Op: TOpCG; size: TCGSize; src, dst: TRegister); override; procedure a_op_const_reg_reg(list: taasmoutput; op: TOpCg; size: tcgsize; a: aint; src, dst: tregister); override; procedure a_op_reg_reg_reg(list: taasmoutput; op: TOpCg; size: tcgsize; src1, src2, dst: tregister); override; { move instructions } procedure a_load_const_reg(list: taasmoutput; size: tcgsize; a: aint; reg: tregister); override; { stores the contents of register reg to the memory location described by ref } procedure a_load_reg_ref(list: taasmoutput; fromsize, tosize: tcgsize; reg: tregister; const ref: treference); override; { loads the memory pointed to by ref into register reg } procedure a_load_ref_reg(list: taasmoutput; fromsize, tosize: tcgsize; const Ref: treference; reg: tregister); override; procedure a_load_reg_reg(list: taasmoutput; fromsize, tosize: tcgsize; reg1, reg2: tregister); override; { fpu move instructions } procedure a_loadfpu_reg_reg(list: taasmoutput; size: tcgsize; reg1, reg2: tregister); override; procedure a_loadfpu_ref_reg(list: taasmoutput; size: tcgsize; const ref: treference; reg: tregister); override; procedure a_loadfpu_reg_ref(list: taasmoutput; size: tcgsize; reg: tregister; const ref: treference); override; { comparison operations } procedure a_cmp_const_reg_label(list: taasmoutput; size: tcgsize; cmp_op: topcmp; a: aint; reg: tregister; l: tasmlabel); override; procedure a_cmp_reg_reg_label(list: taasmoutput; size: tcgsize; cmp_op: topcmp; reg1, reg2: tregister; l: tasmlabel); override; procedure a_jmp_name(list: taasmoutput; const s: string); override; procedure a_jmp_always(list: taasmoutput; l: tasmlabel); override; procedure a_jmp_flags(list: taasmoutput; const f: TResFlags; l: tasmlabel); override; procedure g_flags2reg(list: taasmoutput; size: TCgSize; const f: TResFlags; reg: TRegister); override; procedure g_proc_entry(list: taasmoutput; localsize: longint; nostackframe: boolean); override; procedure g_proc_exit(list: taasmoutput; parasize: longint; nostackframe: boolean); override; procedure g_save_standard_registers(list: Taasmoutput); override; procedure g_restore_standard_registers(list: Taasmoutput); override; procedure a_loadaddr_ref_reg(list: taasmoutput; const ref: treference; r: tregister); override; procedure g_concatcopy(list: taasmoutput; const source, dest: treference; len: aint); override; procedure g_overflowcheck(list: taasmoutput; const l: tlocation; def: tdef); override; procedure a_jmp_cond(list: taasmoutput; cond: TOpCmp; l: tasmlabel); procedure g_intf_wrapper(list: TAAsmoutput; procdef: tprocdef; const labelname: string; ioffset: longint); override; private { Make sure ref is a valid reference for the PowerPC and sets the } { base to the value of the index if (base = R_NO). } { Returns true if the reference contained a base, index and an } { offset or symbol, in which case the base will have been changed } { to a tempreg (which has to be freed by the caller) containing } { the sum of part of the original reference } function fixref(list: taasmoutput; var ref: treference; const size : TCgsize): boolean; function load_got_symbol(list : taasmoutput; symbol : string) : tregister; { returns whether a reference can be used immediately in a powerpc } { instruction } function issimpleref(const ref: treference): boolean; { contains the common code of a_load_reg_ref and a_load_ref_reg } procedure a_load_store(list: taasmoutput; op: tasmop; reg: tregister; ref: treference); { creates the correct branch instruction for a given combination } { of asmcondflags and destination addressing mode } procedure a_jmp(list: taasmoutput; op: tasmop; c: tasmcondflag; crval: longint; l: tasmlabel); { returns the lowest numbered FP register in use, and the number of used FP registers for the current procedure } procedure calcFirstUsedFPR(out firstfpr : TSuperRegister; out fprcount : aint); { returns the lowest numbered GP register in use, and the number of used GP registers for the current procedure } procedure calcFirstUsedGPR(out firstgpr : TSuperRegister; out gprcount : aint); { returns true if the offset of the given reference can not be represented by a 16 bit immediate as required by some PowerPC instructions } function hasLargeOffset(const ref : TReference) : Boolean; inline; procedure a_call_name_direct(list: taasmoutput; s: string; prependDot : boolean; addNOP : boolean); { emits code to store the given value a into the TOC (if not already in there), and load it from there as well } procedure loadConstantPIC(list : taasmoutput; size : TCGSize; a : aint; reg : TRegister); end; const TShiftOpCG2AsmOpConst : array[boolean, OP_SAR..OP_SHR] of TAsmOp = ( (A_SRAWI, A_SLWI, A_SRWI), (A_SRADI, A_SLDI, A_SRDI) ); TOpCmp2AsmCond: array[topcmp] of TAsmCondFlag = (C_NONE, C_EQ, C_GT, C_LT, C_GE, C_LE, C_NE, C_LE, C_LT, C_GE, C_GT); implementation uses sysutils, globals, verbose, systems, cutils, symconst, symsym, fmodule, rgobj, tgobj, cpupi, procinfo, paramgr; function ref2string(const ref : treference) : string; begin result := 'base : ' + inttostr(ord(ref.base)) + ' index : ' + inttostr(ord(ref.index)) + ' refaddr : ' + inttostr(ord(ref.refaddr)) + ' offset : ' + inttostr(ref.offset) + ' symbol : '; if (assigned(ref.symbol)) then result := result + ref.symbol.name; end; { helper function which calculate "magic" values for replacement of unsigned division by constant operation by multiplication. See the PowerPC compiler developer manual for more information } procedure getmagic_unsignedN(const N : byte; const d : aWord; out magic_m : aWord; out magic_add : boolean; out magic_shift : byte); var p : aInt; nc, delta, q1, r1, q2, r2, two_N_minus_1 : aWord; begin assert(d > 0); two_N_minus_1 := aWord(1) shl (N-1); magic_add := false; nc := - 1 - (-d) mod d; p := N-1; { initialize p } q1 := two_N_minus_1 div nc; { initialize q1 = 2p/nc } r1 := two_N_minus_1 - q1*nc; { initialize r1 = rem(2p,nc) } q2 := (two_N_minus_1-1) div d; { initialize q2 = (2p-1)/d } r2 := (two_N_minus_1-1) - q2*d; { initialize r2 = rem((2p-1),d) } repeat inc(p); if (r1 >= (nc - r1)) then begin q1 := 2 * q1 + 1; { update q1 } r1 := 2*r1 - nc; { update r1 } end else begin q1 := 2*q1; { update q1 } r1 := 2*r1; { update r1 } end; if ((r2 + 1) >= (d - r2)) then begin if (q2 >= (two_N_minus_1-1)) then magic_add := true; q2 := 2*q2 + 1; { update q2 } r2 := 2*r2 + 1 - d; { update r2 } end else begin if (q2 >= two_N_minus_1) then magic_add := true; q2 := 2*q2; { update q2 } r2 := 2*r2 + 1; { update r2 } end; delta := d - 1 - r2; until not ((p < (2*N)) and ((q1 < delta) or ((q1 = delta) and (r1 = 0)))); magic_m := q2 + 1; { resulting magic number } magic_shift := p - N; { resulting shift } end; { helper function which calculate "magic" values for replacement of signed division by constant operation by multiplication. See the PowerPC compiler developer manual for more information } procedure getmagic_signedN(const N : byte; const d : aInt; out magic_m : aInt; out magic_s : aInt); var p : aInt; ad, anc, delta, q1, r1, q2, r2, t : aWord; two_N_minus_1 : aWord; begin assert((d < -1) or (d > 1)); two_N_minus_1 := aWord(1) shl (N-1); ad := abs(d); t := two_N_minus_1 + (aWord(d) shr (N-1)); anc := t - 1 - t mod ad; { absolute value of nc } p := (N-1); { initialize p } q1 := two_N_minus_1 div anc; { initialize q1 = 2p/abs(nc) } r1 := two_N_minus_1 - q1*anc; { initialize r1 = rem(2p,abs(nc)) } q2 := two_N_minus_1 div ad; { initialize q2 = 2p/abs(d) } r2 := two_N_minus_1 - q2*ad; { initialize r2 = rem(2p,abs(d)) } repeat inc(p); q1 := 2*q1; { update q1 = 2p/abs(nc) } r1 := 2*r1; { update r1 = rem(2p/abs(nc)) } if (r1 >= anc) then begin { must be unsigned comparison } inc(q1); dec(r1, anc); end; q2 := 2*q2; { update q2 = 2p/abs(d) } r2 := 2*r2; { update r2 = rem(2p/abs(d)) } if (r2 >= ad) then begin { must be unsigned comparison } inc(q2); dec(r2, ad); end; delta := ad - r2; until not ((q1 < delta) or ((q1 = delta) and (r1 = 0))); magic_m := q2 + 1; if (d < 0) then begin magic_m := -magic_m; { resulting magic number } end; magic_s := p - N; { resulting shift } end; { finds positive and negative powers of two of the given value, returning the power and whether it's a negative power or not in addition to the actual result of the function } function ispowerof2(value : aInt; out power : byte; out neg : boolean) : boolean; var i : longint; hl : aInt; begin neg := false; { also try to find negative power of two's by negating if the value is negative. low(aInt) is special because it can not be negated. Simply return the appropriate values for it } if (value < 0) then begin neg := true; if (value = low(aInt)) then begin power := sizeof(aInt)*8-1; result := true; exit; end; value := -value; end; if ((value and (value-1)) <> 0) then begin result := false; exit; end; hl := 1; for i := 0 to (sizeof(aInt)*8-1) do begin if (hl = value) then begin result := true; power := i; exit; end; hl := hl shl 1; end; end; { returns the number of instruction required to load the given integer into a register. This is basically a stripped down version of a_load_const_reg, increasing a counter instead of emitting instructions. } function getInstructionLength(a : aint) : longint; function get32bitlength(a : longint; var length : longint) : boolean; inline; var is_half_signed : byte; begin { if the lower 16 bits are zero, do a single LIS } if (smallint(a) = 0) and ((a shr 16) <> 0) then begin inc(length); get32bitlength := longint(a) < 0; end else begin is_half_signed := ord(smallint(lo(a)) < 0); inc(length); if smallint(hi(a) + is_half_signed) <> 0 then inc(length); get32bitlength := (smallint(a) < 0) or (a < 0); end; end; var extendssign : boolean; begin result := 0; if (lo(a) = 0) and (hi(a) <> 0) then begin get32bitlength(hi(a), result); inc(result); end else begin extendssign := get32bitlength(lo(a), result); if (extendssign) and (hi(a) = 0) then inc(result) else if (not ((extendssign and (longint(hi(a)) = -1)) or ((not extendssign) and (hi(a)=0))) ) then begin get32bitlength(hi(a), result); inc(result); end; end; end; procedure tcgppc.init_register_allocators; begin inherited init_register_allocators; rg[R_INTREGISTER] := trgcpu.create(R_INTREGISTER, R_SUBWHOLE, [RS_R3, RS_R4, RS_R5, RS_R6, RS_R7, RS_R8, RS_R9, RS_R10, RS_R11, RS_R12, RS_R31, RS_R30, RS_R29, RS_R28, RS_R27, RS_R26, RS_R25, RS_R24, RS_R23, RS_R22, RS_R21, RS_R20, RS_R19, RS_R18, RS_R17, RS_R16, RS_R15, RS_R14, RS_R13], first_int_imreg, []); rg[R_FPUREGISTER] := trgcpu.create(R_FPUREGISTER, R_SUBNONE, [RS_F0, RS_F1, RS_F2, RS_F3, RS_F4, RS_F5, RS_F6, RS_F7, RS_F8, RS_F9, RS_F10, RS_F11, RS_F12, RS_F13, RS_F31, RS_F30, RS_F29, RS_F28, RS_F27, RS_F26, RS_F25, RS_F24, RS_F23, RS_F22, RS_F21, RS_F20, RS_F19, RS_F18, RS_F17, RS_F16, RS_F15, RS_F14], first_fpu_imreg, []); {$WARNING FIX ME} rg[R_MMREGISTER] := trgcpu.create(R_MMREGISTER, R_SUBNONE, [RS_M0, RS_M1, RS_M2], first_mm_imreg, []); end; procedure tcgppc.done_register_allocators; begin rg[R_INTREGISTER].free; rg[R_FPUREGISTER].free; rg[R_MMREGISTER].free; inherited done_register_allocators; end; procedure tcgppc.a_param_const(list: taasmoutput; size: tcgsize; a: aint; const paraloc: tcgpara); var ref: treference; begin paraloc.check_simple_location; case paraloc.location^.loc of LOC_REGISTER, LOC_CREGISTER: a_load_const_reg(list, size, a, paraloc.location^.register); LOC_REFERENCE: begin reference_reset(ref); ref.base := paraloc.location^.reference.index; ref.offset := paraloc.location^.reference.offset; a_load_const_ref(list, size, a, ref); end; else internalerror(2002081101); end; end; procedure tcgppc.a_param_ref(list: taasmoutput; size: tcgsize; const r: treference; const paraloc: tcgpara); var tmpref, ref: treference; location: pcgparalocation; sizeleft: aint; adjusttail : boolean; begin location := paraloc.location; tmpref := r; sizeleft := paraloc.intsize; adjusttail := false; while assigned(location) do begin case location^.loc of LOC_REGISTER, LOC_CREGISTER: begin if (size <> OS_NO) then a_load_ref_reg(list, size, location^.size, tmpref, location^.register) else {$IFDEF extdebug} list.concat(tai_comment.create(strpnew('a_param_ref with OS_NO, sizeleft ' + inttostr(sizeleft)))); {$ENDIF extdebug} { load non-integral sized memory location into register. This memory location be 1-sizeleft byte sized. Always assume that this memory area is properly aligned, eg. start loading the larger quantities for "odd" quantities first } case sizeleft of 1,2,4,8 : a_load_ref_reg(list, int_cgsize(sizeleft), location^.size, tmpref, location^.register); 3 : begin a_reg_alloc(list, NR_R12); a_load_ref_reg(list, OS_16, location^.size, tmpref, NR_R12); inc(tmpref.offset, tcgsize2size[OS_16]); a_load_ref_reg(list, OS_8, location^.size, tmpref, location^.register); list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, location^.register, NR_R12, 8, 40)); a_reg_dealloc(list, NR_R12); end; 5 : begin a_reg_alloc(list, NR_R12); a_load_ref_reg(list, OS_32, location^.size, tmpref, NR_R12); inc(tmpref.offset, tcgsize2size[OS_32]); a_load_ref_reg(list, OS_8, location^.size, tmpref, location^.register); list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, location^.register, NR_R12, 8, 24)); a_reg_dealloc(list, NR_R12); end; 6 : begin a_reg_alloc(list, NR_R12); a_load_ref_reg(list, OS_32, location^.size, tmpref, NR_R12); inc(tmpref.offset, tcgsize2size[OS_32]); a_load_ref_reg(list, OS_16, location^.size, tmpref, location^.register); list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, location^.register, NR_R12, 16, 16)); a_reg_dealloc(list, NR_R12); end; 7 : begin a_reg_alloc(list, NR_R12); a_reg_alloc(list, NR_R0); a_load_ref_reg(list, OS_32, location^.size, tmpref, NR_R12); inc(tmpref.offset, tcgsize2size[OS_32]); a_load_ref_reg(list, OS_16, location^.size, tmpref, NR_R0); inc(tmpref.offset, tcgsize2size[OS_16]); a_load_ref_reg(list, OS_8, location^.size, tmpref, location^.register); list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, NR_R0, NR_R12, 16, 16)); list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, location^.register, NR_R0, 8, 8)); a_reg_dealloc(list, NR_R0); a_reg_dealloc(list, NR_R12); end; else { still > 8 bytes to load, so load data single register now } a_load_ref_reg(list, location^.size, location^.size, tmpref, location^.register); { the block is > 8 bytes, so we have to store any bytes not a multiple of the register size beginning with the MSB } adjusttail := true; end; if (adjusttail) and (sizeleft < tcgsize2size[OS_INT]) then a_op_const_reg(list, OP_SHL, OS_INT, (tcgsize2size[OS_INT] - sizeleft) * tcgsize2size[OS_INT], location^.register); end; LOC_REFERENCE: begin reference_reset_base(ref, location^.reference.index, location^.reference.offset); g_concatcopy(list, tmpref, ref, sizeleft); if assigned(location^.next) then internalerror(2005010710); end; LOC_FPUREGISTER, LOC_CFPUREGISTER: case location^.size of OS_F32, OS_F64: a_loadfpu_ref_reg(list, location^.size, tmpref, location^.register); else internalerror(2002072801); end; LOC_VOID: { nothing to do } ; else internalerror(2002081103); end; inc(tmpref.offset, tcgsize2size[location^.size]); dec(sizeleft, tcgsize2size[location^.size]); location := location^.next; end; end; procedure tcgppc.a_paramaddr_ref(list: taasmoutput; const r: treference; const paraloc: tcgpara); var ref: treference; tmpreg: tregister; begin paraloc.check_simple_location; case paraloc.location^.loc of LOC_REGISTER, LOC_CREGISTER: a_loadaddr_ref_reg(list, r, paraloc.location^.register); LOC_REFERENCE: begin reference_reset(ref); ref.base := paraloc.location^.reference.index; ref.offset := paraloc.location^.reference.offset; tmpreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_loadaddr_ref_reg(list, r, tmpreg); a_load_reg_ref(list, OS_ADDR, OS_ADDR, tmpreg, ref); end; else internalerror(2002080701); end; end; { calling a procedure by name } procedure tcgppc.a_call_name(list: taasmoutput; const s: string); begin a_call_name_direct(list, s, true, true); end; procedure tcgppc.a_call_name_direct(list: taasmoutput; s: string; prependDot : boolean; addNOP : boolean); begin if (prependDot) then s := '.' + s; list.concat(taicpu.op_sym(A_BL, objectlibrary.newasmsymbol(s, AB_EXTERNAL, AT_FUNCTION))); if (addNOP) then list.concat(taicpu.op_none(A_NOP)); { the compiler does not properly set this flag anymore in pass 1, and for now we only need it after pass 2 (I hope) (JM) } include(current_procinfo.flags, pi_do_call); end; { calling a procedure by address } procedure tcgppc.a_call_reg(list: taasmoutput; reg: tregister); var tmpref: treference; begin if (not (cs_littlesize in aktglobalswitches)) then begin { load actual function entry (reg contains the reference to the function descriptor) into R0 } reference_reset_base(tmpref, reg, 0); a_load_ref_reg(list, OS_ADDR, OS_ADDR, tmpref, NR_R0); { save TOC pointer in stackframe } reference_reset_base(tmpref, NR_STACK_POINTER_REG, LA_RTOC_ELF); a_load_reg_ref(list, OS_ADDR, OS_ADDR, NR_RTOC, tmpref); { move actual function pointer to CTR register } list.concat(taicpu.op_reg(A_MTCTR, NR_R0)); { load new TOC pointer from function descriptor into RTOC register } reference_reset_base(tmpref, reg, tcgsize2size[OS_ADDR]); a_load_ref_reg(list, OS_ADDR, OS_ADDR, tmpref, NR_RTOC); { load new environment pointer from function descriptor into R11 register } reference_reset_base(tmpref, reg, 2*tcgsize2size[OS_ADDR]); a_load_ref_reg(list, OS_ADDR, OS_ADDR, tmpref, NR_R11); { call function } list.concat(taicpu.op_none(A_BCTRL)); end else begin { call ptrgl helper routine which expects the pointer to the function descriptor in R11 } a_load_reg_reg(list, OS_ADDR, OS_ADDR, reg, NR_R11); a_call_name_direct(list, '.ptrgl', false, false); end; { we need to load the old RTOC from stackframe because we changed it} reference_reset_base(tmpref, NR_STACK_POINTER_REG, LA_RTOC_ELF); a_load_ref_reg(list, OS_ADDR, OS_ADDR, tmpref, NR_RTOC); include(current_procinfo.flags, pi_do_call); end; {********************** load instructions ********************} procedure tcgppc.a_load_const_reg(list: taasmoutput; size: TCGSize; a: aint; reg: TRegister); { loads a 32 bit constant into the given register, using an optimal instruction sequence. This is either LIS, LI or LI+ADDIS. Returns true if during these operations the upper 32 bits were filled with 1 bits (e.g. sign extension was performed) } function load32bitconstant(list : taasmoutput; size : TCGSize; a : longint; reg : TRegister) : boolean; var is_half_signed : byte; begin { if the lower 16 bits are zero, do a single LIS } if (smallint(a) = 0) and ((a shr 16) <> 0) then begin list.concat(taicpu.op_reg_const(A_LIS, reg, smallint(hi(a)))); load32bitconstant := longint(a) < 0; end else begin is_half_signed := ord(smallint(lo(a)) < 0); list.concat(taicpu.op_reg_const(A_LI, reg, smallint(a and $ffff))); if smallint(hi(a) + is_half_signed) <> 0 then begin list.concat(taicpu.op_reg_reg_const(A_ADDIS, reg, reg, smallint(hi(a) + is_half_signed))); end; load32bitconstant := (smallint(a) < 0) or (a < 0); end; end; { emits the code to load a constant by emitting various instructions into the output code} procedure loadConstantNormal(list: taasmoutput; size : TCgSize; a: aint; reg: TRegister); var extendssign : boolean; begin if (lo(a) = 0) and (hi(a) <> 0) then begin { load only upper 32 bits, and shift } load32bitconstant(list, size, hi(a), reg); list.concat(taicpu.op_reg_reg_const(A_SLDI, reg, reg, 32)); end else begin { load lower 32 bits } extendssign := load32bitconstant(list, size, lo(a), reg); if (extendssign) and (hi(a) = 0) then { if upper 32 bits are zero, but loading the lower 32 bit resulted in automatic sign extension, clear those bits } a_load_reg_reg(list, OS_32, OS_64, reg, reg) else if (not ((extendssign and (longint(hi(a)) = -1)) or ((not extendssign) and (hi(a)=0))) ) then begin { only load the upper 32 bits, if the automatic sign extension is not okay, that is, _not_ if - loading the lower 32 bits resulted in -1 in the upper 32 bits, and the upper 32 bits should contain -1 - loading the lower 32 bits resulted in 0 in the upper 32 bits, and the upper 32 bits should contain 0 } load32bitconstant(list, size, hi(a), NR_R12); { combine both registers } list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, reg, NR_R12, 32, 0)); end; end; end; {$IFDEF EXTDEBUG} var astring : string; {$ENDIF EXTDEBUG} begin {$IFDEF EXTDEBUG} astring := 'a_load_const reg ' + inttostr(hi(a)) + ' ' + inttostr(lo(a)) + ' ' + inttostr(ord(size)) + ' ' + inttostr(tcgsize2size[size]); list.concat(tai_comment.create(strpnew(astring))); {$ENDIF EXTDEBUG} if not (size in [OS_8, OS_S8, OS_16, OS_S16, OS_32, OS_S32, OS_64, OS_S64]) then internalerror(2002090902); { if PIC or basic optimizations are enabled, and the number of instructions which would be required to load the value is greater than 2, store (and later load) the value from there } if (((cs_fastoptimize in aktglobalswitches) or (cs_create_pic in aktmoduleswitches)) and (getInstructionLength(a) > 2)) then loadConstantPIC(list, size, a, reg) else loadConstantNormal(list, size, a, reg); end; procedure tcgppc.a_load_reg_ref(list: taasmoutput; fromsize, tosize: TCGSize; reg: tregister; const ref: treference); const StoreInstr: array[OS_8..OS_64, boolean, boolean] of TAsmOp = { indexed? updating?} (((A_STB, A_STBU), (A_STBX, A_STBUX)), ((A_STH, A_STHU), (A_STHX, A_STHUX)), ((A_STW, A_STWU), (A_STWX, A_STWUX)), ((A_STD, A_STDU), (A_STDX, A_STDUX)) ); var op: TAsmOp; ref2: TReference; begin ref2 := ref; fixref(list, ref2, tosize); if tosize in [OS_S8..OS_S64] then { storing is the same for signed and unsigned values } tosize := tcgsize(ord(tosize) - (ord(OS_S8) - ord(OS_8))); op := storeinstr[tcgsize2unsigned[tosize], ref2.index <> NR_NO, false]; a_load_store(list, op, reg, ref2); end; procedure tcgppc.a_load_ref_reg(list: taasmoutput; fromsize, tosize: tcgsize; const ref: treference; reg: tregister); const LoadInstr: array[OS_8..OS_S64, boolean, boolean] of TAsmOp = { indexed? updating? } (((A_LBZ, A_LBZU), (A_LBZX, A_LBZUX)), ((A_LHZ, A_LHZU), (A_LHZX, A_LHZUX)), ((A_LWZ, A_LWZU), (A_LWZX, A_LWZUX)), ((A_LD, A_LDU), (A_LDX, A_LDUX)), { 128bit stuff too } ((A_NONE, A_NONE), (A_NONE, A_NONE)), { there's no load-byte-with-sign-extend :( } ((A_LBZ, A_LBZU), (A_LBZX, A_LBZUX)), ((A_LHA, A_LHAU), (A_LHAX, A_LHAUX)), { there's no load-word-arithmetic-indexed with update, simulate it in code :( } ((A_LWA, A_NOP), (A_LWAX, A_LWAUX)), ((A_LD, A_LDU), (A_LDX, A_LDUX)) ); var op: tasmop; ref2: treference; begin {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('a_load_ref_reg ' + ref2string(ref)))); {$ENDIF EXTDEBUG} if not (fromsize in [OS_8, OS_S8, OS_16, OS_S16, OS_32, OS_S32, OS_64, OS_S64]) then internalerror(2002090902); ref2 := ref; fixref(list, ref2, tosize); { the caller is expected to have adjusted the reference already in this case } if (TCGSize2Size[fromsize] >= TCGSize2Size[tosize]) then fromsize := tosize; op := loadinstr[fromsize, ref2.index <> NR_NO, false]; { there is no LWAU instruction, simulate using ADDI and LWA } if (op = A_NOP) then begin list.concat(taicpu.op_reg_reg_const(A_ADDI, reg, reg, ref2.offset)); ref2.offset := 0; op := A_LWA; end; a_load_store(list, op, reg, ref2); { sign extend shortint if necessary, since there is no load instruction that does that automatically (JM) } if fromsize = OS_S8 then list.concat(taicpu.op_reg_reg(A_EXTSB, reg, reg)); end; procedure tcgppc.a_load_reg_reg(list: taasmoutput; fromsize, tosize: tcgsize; reg1, reg2: tregister); const movemap : array[OS_8..OS_S128, OS_8..OS_S128] of tasmop = ( { to -> OS_8 OS_16 OS_32 OS_64 OS_128 OS_S8 OS_S16 OS_S32 OS_S64 OS_S128 } { from } { OS_8 } (A_MR, A_RLDICL, A_RLDICL, A_RLDICL, A_NONE, A_RLDICL, A_RLDICL, A_RLDICL, A_RLDICL, A_NOP ), { OS_16 } (A_RLDICL, A_MR, A_RLDICL, A_RLDICL, A_NONE, A_RLDICL, A_RLDICL, A_RLDICL, A_RLDICL, A_NOP ), { OS_32 } (A_RLDICL, A_RLDICL, A_MR, A_RLDICL, A_NONE, A_RLDICL, A_RLDICL, A_RLDICL, A_RLDICL, A_NOP ), { OS_64 } (A_RLDICL, A_RLDICL, A_RLDICL, A_MR, A_NONE, A_RLDICL, A_RLDICL, A_RLDICL, A_RLDICL, A_NOP ), { OS_128 } (A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NOP ), { OS_S8 } (A_EXTSB, A_EXTSB, A_EXTSB, A_EXTSB, A_NONE, A_MR, A_EXTSB, A_EXTSB, A_EXTSB, A_NOP ), { OS_S16 } (A_RLDICL, A_EXTSH, A_EXTSH, A_EXTSH, A_NONE, A_EXTSB, A_MR, A_EXTSH, A_EXTSH, A_NOP ), { OS_S32 } (A_RLDICL, A_RLDICL, A_EXTSW, A_EXTSW, A_NONE, A_EXTSB, A_EXTSH, A_MR, A_EXTSW, A_NOP ), { OS_S64 } (A_RLDICL, A_RLDICL, A_RLDICL, A_MR, A_NONE, A_EXTSB, A_EXTSH, A_EXTSW, A_MR, A_NOP ), { OS_S128 } (A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE, A_NOP ) ); var instr: taicpu; op : tasmop; begin op := movemap[fromsize, tosize]; case op of A_MR, A_EXTSB, A_EXTSH, A_EXTSW : instr := taicpu.op_reg_reg(op, reg2, reg1); A_RLDICL : instr := taicpu.op_reg_reg_const_const(A_RLDICL, reg2, reg1, 0, (8-tcgsize2size[fromsize])*8); else internalerror(2002090901); end; list.concat(instr); rg[R_INTREGISTER].add_move_instruction(instr); end; procedure tcgppc.a_loadfpu_reg_reg(list: taasmoutput; size: tcgsize; reg1, reg2: tregister); var instr: taicpu; begin instr := taicpu.op_reg_reg(A_FMR, reg2, reg1); list.concat(instr); rg[R_FPUREGISTER].add_move_instruction(instr); end; procedure tcgppc.a_loadfpu_ref_reg(list: taasmoutput; size: tcgsize; const ref: treference; reg: tregister); const FpuLoadInstr: array[OS_F32..OS_F64, boolean, boolean] of TAsmOp = { indexed? updating?} (((A_LFS, A_LFSU), (A_LFSX, A_LFSUX)), ((A_LFD, A_LFDU), (A_LFDX, A_LFDUX))); var op: tasmop; ref2: treference; begin { several functions call this procedure with OS_32 or OS_64 so this makes life easier (FK) } case size of OS_32, OS_F32: size := OS_F32; OS_64, OS_F64, OS_C64: size := OS_F64; else internalerror(200201121); end; ref2 := ref; fixref(list, ref2, size); op := fpuloadinstr[size, ref2.index <> NR_NO, false]; a_load_store(list, op, reg, ref2); end; procedure tcgppc.a_loadfpu_reg_ref(list: taasmoutput; size: tcgsize; reg: tregister; const ref: treference); const FpuStoreInstr: array[OS_F32..OS_F64, boolean, boolean] of TAsmOp = { indexed? updating? } (((A_STFS, A_STFSU), (A_STFSX, A_STFSUX)), ((A_STFD, A_STFDU), (A_STFDX, A_STFDUX))); var op: tasmop; ref2: treference; begin if not (size in [OS_F32, OS_F64]) then internalerror(200201122); ref2 := ref; fixref(list, ref2, size); op := fpustoreinstr[size, ref2.index <> NR_NO, false]; a_load_store(list, op, reg, ref2); end; procedure tcgppc.a_op_const_reg(list: taasmoutput; Op: TOpCG; size: TCGSize; a: aint; reg: TRegister); begin a_op_const_reg_reg(list, op, size, a, reg, reg); end; procedure tcgppc.a_op_reg_reg(list: taasmoutput; Op: TOpCG; size: TCGSize; src, dst: TRegister); begin a_op_reg_reg_reg(list, op, size, src, dst, dst); end; procedure tcgppc.a_op_const_reg_reg(list: taasmoutput; op: TOpCg; size: tcgsize; a: aint; src, dst: tregister); var useReg : boolean; procedure do_lo_hi(loOp, hiOp : TAsmOp); begin { Optimization for logical ops (excluding AND), trying to do this as efficiently as possible by only generating code for the affected halfwords. Note that all the instructions handled here must have "X op 0 = X" for every halfword. } usereg := false; if (aword(a) > high(dword)) then begin usereg := true; end else begin if (word(a) <> 0) then begin list.concat(taicpu.op_reg_reg_const(loOp, dst, src, word(a))); if (word(a shr 16) <> 0) then list.concat(taicpu.op_reg_reg_const(hiOp, dst, dst, word(a shr 16))); end else if (word(a shr 16) <> 0) then list.concat(taicpu.op_reg_reg_const(hiOp, dst, src, word(a shr 16))); end; end; procedure do_lo_hi_and; begin { optimization logical and with immediate: only use "andi." for 16 bit ands, otherwise use register method. Doing this for 32 bit constants would not give any advantage to the register method (via useReg := true), requiring a scratch register and three instructions. } usereg := false; if (aword(a) > high(word)) then usereg := true else list.concat(taicpu.op_reg_reg_const(A_ANDI_, dst, src, word(a))); end; procedure do_constant_div(list : taasmoutput; size : TCgSize; a : aint; src, dst : TRegister; signed : boolean); const negops : array[boolean] of tasmop = (A_NEG, A_NEGO); var magic, shift : int64; u_magic : qword; u_shift : byte; u_add : boolean; power : byte; isNegPower : boolean; divreg : tregister; begin if (a = 0) then begin internalerror(2005061701); end else if (a = 1) then begin cg.a_load_reg_reg(exprasmlist, OS_INT, OS_INT, src, dst); end else if (a = -1) and (signed) then begin { note: only in the signed case possible..., may overflow } exprasmlist.concat(taicpu.op_reg_reg(negops[cs_check_overflow in aktlocalswitches], dst, src)); end else if (ispowerof2(a, power, isNegPower)) then begin if (signed) then begin { From "The PowerPC Compiler Writer's Guide", pg. 52ff } cg.a_op_const_reg_reg(exprasmlist, OP_SAR, OS_INT, power, src, dst); exprasmlist.concat(taicpu.op_reg_reg(A_ADDZE, dst, dst)); if (isNegPower) then exprasmlist.concat(taicpu.op_reg_reg(A_NEG, dst, dst)); end else begin cg.a_op_const_reg_reg(exprasmlist, OP_SHR, OS_INT, power, src, dst) end; end else begin { replace division by multiplication, both implementations } { from "The PowerPC Compiler Writer's Guide" pg. 53ff } divreg := cg.getintregister(exprasmlist, OS_INT); if (signed) then begin getmagic_signedN(sizeof(aInt)*8, a, magic, shift); { load magic value } cg.a_load_const_reg(exprasmlist, OS_INT, magic, divreg); { multiply } exprasmlist.concat(taicpu.op_reg_reg_reg(A_MULHD, dst, src, divreg)); { add/subtract numerator } if (a > 0) and (magic < 0) then begin cg.a_op_reg_reg_reg(exprasmlist, OP_ADD, OS_INT, src, dst, dst); end else if (a < 0) and (magic > 0) then begin cg.a_op_reg_reg_reg(exprasmlist, OP_SUB, OS_INT, src, dst, dst); end; { shift shift places to the right (arithmetic) } cg.a_op_const_reg_reg(exprasmlist, OP_SAR, OS_INT, shift, dst, dst); { extract and add sign bit } if (a >= 0) then begin cg.a_op_const_reg_reg(exprasmlist, OP_SHR, OS_INT, 63, src, divreg); end else begin cg.a_op_const_reg_reg(exprasmlist, OP_SHR, OS_INT, 63, dst, divreg); end; cg.a_op_reg_reg_reg(exprasmlist, OP_ADD, OS_INT, dst, divreg, dst); end else begin getmagic_unsignedN(sizeof(aWord)*8, a, u_magic, u_add, u_shift); { load magic in divreg } cg.a_load_const_reg(exprasmlist, OS_INT, u_magic, divreg); exprasmlist.concat(taicpu.op_reg_reg_reg(A_MULHDU, dst, src, divreg)); if (u_add) then begin cg.a_op_reg_reg_reg(exprasmlist, OP_SUB, OS_INT, dst, src, divreg); cg.a_op_const_reg_reg(exprasmlist, OP_SHR, OS_INT, 1, divreg, divreg); cg.a_op_reg_reg_reg(exprasmlist, OP_ADD, OS_INT, divreg, dst, divreg); cg.a_op_const_reg_reg(exprasmlist, OP_SHR, OS_INT, u_shift-1, divreg, dst); end else begin cg.a_op_const_reg_reg(exprasmlist, OP_SHR, OS_INT, u_shift, dst, dst); end; end; end; end; var scratchreg: tregister; shift : byte; shiftmask : longint; isneg : boolean; begin { subtraction is the same as addition with negative constant } if op = OP_SUB then begin a_op_const_reg_reg(list, OP_ADD, size, -a, src, dst); exit; end; { This case includes some peephole optimizations for the various operations, (e.g. AND, OR, XOR, ..) - can't this be done at some higher level, independent of architecture? } { assume that we do not need a scratch register for the operation } useReg := false; case (op) of OP_DIV, OP_IDIV: if (cs_optimize in aktglobalswitches) then do_constant_div(list, size, a, src, dst, op = OP_IDIV) else usereg := true; OP_IMUL, OP_MUL: { idea: factorize constant multiplicands and use adds/shifts with few factors; however, even a 64 bit multiply is already quite fast on PPC64 } if (a = 0) then a_load_const_reg(list, size, 0, dst) else if (a = -1) then list.concat(taicpu.op_reg_reg(A_NEG, dst, dst)) else if (a = 1) then a_load_reg_reg(list, OS_INT, OS_INT, src, dst) else if ispowerof2(a, shift, isneg) then begin list.concat(taicpu.op_reg_reg_const(A_SLDI, dst, src, shift)); if (isneg) then exprasmlist.concat(taicpu.op_reg_reg(A_NEG, dst, dst)); end else if (a >= low(smallint)) and (a <= high(smallint)) then list.concat(taicpu.op_reg_reg_const(A_MULLI, dst, src, smallint(a))) else usereg := true; OP_ADD: if (a = 0) then a_load_reg_reg(list, size, size, src, dst) else if (a >= low(smallint)) and (a <= high(smallint)) then list.concat(taicpu.op_reg_reg_const(A_ADDI, dst, src, smallint(a))) else useReg := true; OP_OR: if (a = 0) then a_load_reg_reg(list, size, size, src, dst) else if (a = -1) then a_load_const_reg(list, size, -1, dst) else do_lo_hi(A_ORI, A_ORIS); OP_AND: if (a = 0) then a_load_const_reg(list, size, 0, dst) else if (a = -1) then a_load_reg_reg(list, size, size, src, dst) else do_lo_hi_and; OP_XOR: if (a = 0) then a_load_reg_reg(list, size, size, src, dst) else if (a = -1) then list.concat(taicpu.op_reg_reg(A_NOT, dst, src)) else do_lo_hi(A_XORI, A_XORIS); OP_SHL, OP_SHR, OP_SAR: begin if (size in [OS_64, OS_S64]) then shift := 6 else shift := 5; shiftmask := (1 shl shift)-1; if (a and shiftmask) <> 0 then list.concat(taicpu.op_reg_reg_const( TShiftOpCG2AsmOpConst[size in [OS_64, OS_S64], op], dst, src, a and shiftmask)) else a_load_reg_reg(list, size, size, src, dst); if ((a shr shift) <> 0) then internalError(68991); end else internalerror(200109091); end; { if all else failed, load the constant in a register and then perform the operation } if (useReg) then begin scratchreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_load_const_reg(list, size, a, scratchreg); a_op_reg_reg_reg(list, op, size, scratchreg, src, dst); end; end; procedure tcgppc.a_op_reg_reg_reg(list: taasmoutput; op: TOpCg; size: tcgsize; src1, src2, dst: tregister); const op_reg_reg_opcg2asmop32: array[TOpCG] of tasmop = (A_NONE, A_ADD, A_AND, A_DIVWU, A_DIVW, A_MULLW, A_MULLW, A_NEG, A_NOT, A_OR, A_SRAW, A_SLW, A_SRW, A_SUB, A_XOR); op_reg_reg_opcg2asmop64: array[TOpCG] of tasmop = (A_NONE, A_ADD, A_AND, A_DIVDU, A_DIVD, A_MULLD, A_MULLD, A_NEG, A_NOT, A_OR, A_SRAD, A_SLD, A_SRD, A_SUB, A_XOR); begin case op of OP_NEG, OP_NOT: begin list.concat(taicpu.op_reg_reg(op_reg_reg_opcg2asmop64[op], dst, src1)); if (op = OP_NOT) and not (size in [OS_64, OS_S64]) then { zero/sign extend result again, fromsize is not important here } a_load_reg_reg(list, OS_S64, size, dst, dst) end; else if (size in [OS_64, OS_S64]) then begin list.concat(taicpu.op_reg_reg_reg(op_reg_reg_opcg2asmop64[op], dst, src2, src1)); end else begin list.concat(taicpu.op_reg_reg_reg(op_reg_reg_opcg2asmop32[op], dst, src2, src1)); end; end; end; {*************** compare instructructions ****************} procedure tcgppc.a_cmp_const_reg_label(list: taasmoutput; size: tcgsize; cmp_op: topcmp; a: aint; reg: tregister; l: tasmlabel); var scratch_register: TRegister; signed: boolean; begin signed := cmp_op in [OC_GT, OC_LT, OC_GTE, OC_LTE]; { in the following case, we generate more efficient code when } { signed is true } if (cmp_op in [OC_EQ, OC_NE]) and (aword(a) > $FFFF) then signed := true; if signed then if (a >= low(smallint)) and (a <= high(smallint)) then list.concat(taicpu.op_reg_reg_const(A_CMPDI, NR_CR0, reg, a)) else begin scratch_register := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_load_const_reg(list, OS_64, a, scratch_register); list.concat(taicpu.op_reg_reg_reg(A_CMPD, NR_CR0, reg, scratch_register)); end else if (aword(a) <= $FFFF) then list.concat(taicpu.op_reg_reg_const(A_CMPLDI, NR_CR0, reg, aword(a))) else begin scratch_register := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_load_const_reg(list, OS_64, a, scratch_register); list.concat(taicpu.op_reg_reg_reg(A_CMPLD, NR_CR0, reg, scratch_register)); end; a_jmp(list, A_BC, TOpCmp2AsmCond[cmp_op], 0, l); end; procedure tcgppc.a_cmp_reg_reg_label(list: taasmoutput; size: tcgsize; cmp_op: topcmp; reg1, reg2: tregister; l: tasmlabel); var op: tasmop; begin if cmp_op in [OC_GT, OC_LT, OC_GTE, OC_LTE] then if (size in [OS_64, OS_S64]) then op := A_CMPD else op := A_CMPW else if (size in [OS_64, OS_S64]) then op := A_CMPLD else op := A_CMPLW; list.concat(taicpu.op_reg_reg_reg(op, NR_CR0, reg2, reg1)); a_jmp(list, A_BC, TOpCmp2AsmCond[cmp_op], 0, l); end; procedure tcgppc.a_jmp_cond(list: taasmoutput; cond: TOpCmp; l: tasmlabel); begin a_jmp(list, A_BC, TOpCmp2AsmCond[cond], 0, l); end; procedure tcgppc.a_jmp_name(list: taasmoutput; const s: string); var p: taicpu; begin p := taicpu.op_sym(A_B, objectlibrary.newasmsymbol(s, AB_EXTERNAL, AT_LABEL)); p.is_jmp := true; list.concat(p) end; procedure tcgppc.a_jmp_always(list: taasmoutput; l: tasmlabel); begin a_jmp(list, A_B, C_None, 0, l); end; procedure tcgppc.a_jmp_flags(list: taasmoutput; const f: TResFlags; l: tasmlabel); var c: tasmcond; begin c := flags_to_cond(f); a_jmp(list, A_BC, c.cond, c.cr - RS_CR0, l); end; procedure tcgppc.g_flags2reg(list: taasmoutput; size: TCgSize; const f: TResFlags; reg: TRegister); var testbit: byte; bitvalue: boolean; begin { get the bit to extract from the conditional register + its requested value (0 or 1) } testbit := ((f.cr - RS_CR0) * 4); case f.flag of F_EQ, F_NE: begin inc(testbit, 2); bitvalue := f.flag = F_EQ; end; F_LT, F_GE: begin bitvalue := f.flag = F_LT; end; F_GT, F_LE: begin inc(testbit); bitvalue := f.flag = F_GT; end; else internalerror(200112261); end; { load the conditional register in the destination reg } list.concat(taicpu.op_reg(A_MFCR, reg)); { we will move the bit that has to be tested to bit 0 by rotating left } testbit := (testbit + 1) and 31; { extract bit } list.concat(taicpu.op_reg_reg_const_const_const( A_RLWINM,reg,reg,testbit,31,31)); { if we need the inverse, xor with 1 } if not bitvalue then list.concat(taicpu.op_reg_reg_const(A_XORI, reg, reg, 1)); end; { *********** entry/exit code and address loading ************ } procedure tcgppc.g_save_standard_registers(list: Taasmoutput); begin { this work is done in g_proc_entry; additionally it is not safe to use it because it is called at some weird time } end; procedure tcgppc.g_restore_standard_registers(list: Taasmoutput); begin { this work is done in g_proc_exit; mainly because it is not safe to put the register restore code here because it is called at some weird time } end; procedure tcgppc.calcFirstUsedFPR(out firstfpr : TSuperRegister; out fprcount : aint); var reg : TSuperRegister; begin fprcount := 0; firstfpr := RS_F31; if not (po_assembler in current_procinfo.procdef.procoptions) then for reg := RS_F14 to RS_F31 do if reg in rg[R_FPUREGISTER].used_in_proc then begin fprcount := ord(RS_F31)-ord(reg)+1; firstfpr := reg; break; end; end; procedure tcgppc.calcFirstUsedGPR(out firstgpr : TSuperRegister; out gprcount : aint); var reg : TSuperRegister; begin gprcount := 0; firstgpr := RS_R31; if not (po_assembler in current_procinfo.procdef.procoptions) then for reg := RS_R14 to RS_R31 do if reg in rg[R_INTREGISTER].used_in_proc then begin gprcount := ord(RS_R31)-ord(reg)+1; firstgpr := reg; break; end; end; { Generates the entry code of a procedure/function. This procedure may be called before, as well as after g_return_from_proc is called. localsize is the sum of the size necessary for local variables and the maximum possible combined size of ALL the parameters of a procedure called by the current one IMPORTANT: registers are not to be allocated through the register allocator here, because the register colouring has already occured !! } procedure tcgppc.g_proc_entry(list: taasmoutput; localsize: longint; nostackframe: boolean); var firstregfpu, firstreggpr: TSuperRegister; needslinkreg: boolean; fprcount, gprcount : aint; { Save standard registers, both FPR and GPR; does not support VMX/Altivec } procedure save_standard_registers; var regcount : TSuperRegister; href : TReference; mayNeedLRStore : boolean; begin { there are two ways to do this: manually, by generating a few "std" instructions, or via the restore helper functions. The latter are selected by the -Og switch, i.e. "optimize for size" } if (cs_littlesize in aktglobalswitches) then begin mayNeedLRStore := false; if ((fprcount > 0) and (gprcount > 0)) then begin a_op_const_reg_reg(list, OP_SUB, OS_INT, 8 * fprcount, NR_R1, NR_R12); a_call_name_direct(list, '_savegpr1_' + intToStr(32-gprcount), false, false); a_call_name_direct(list, '_savefpr_' + intToStr(32-fprcount), false, false); end else if (gprcount > 0) then a_call_name_direct(list, '_savegpr0_' + intToStr(32-gprcount), false, false) else if (fprcount > 0) then a_call_name_direct(list, '_savefpr_' + intToStr(32-fprcount), false, false) else mayNeedLRStore := true; end else begin { save registers, FPU first, then GPR } reference_reset_base(href, NR_STACK_POINTER_REG, -8); if (fprcount > 0) then for regcount := RS_F31 downto firstregfpu do begin a_loadfpu_reg_ref(list, OS_FLOAT, newreg(R_FPUREGISTER, regcount, R_SUBNONE), href); dec(href.offset, tcgsize2size[OS_FLOAT]); end; if (gprcount > 0) then for regcount := RS_R31 downto firstreggpr do begin a_load_reg_ref(list, OS_INT, OS_INT, newreg(R_INTREGISTER, regcount, R_SUBNONE), href); dec(href.offset, tcgsize2size[OS_INT]); end; { VMX registers not supported by FPC atm } { in this branch we may always need to store LR ourselves} mayNeedLRStore := true; end; { we may need to store R0 (=LR) ourselves } if (mayNeedLRStore) and (needslinkreg) then begin reference_reset_base(href, NR_STACK_POINTER_REG, LA_LR_ELF); list.concat(taicpu.op_reg_ref(A_STD, NR_R0, href)); end; end; var href: treference; begin calcFirstUsedFPR(firstregfpu, fprcount); calcFirstUsedGPR(firstreggpr, gprcount); { calculate real stack frame size } localsize := tppcprocinfo(current_procinfo).calc_stackframe_size( gprcount, fprcount); { determine whether we need to save the link register } needslinkreg := ((not (po_assembler in current_procinfo.procdef.procoptions)) and (pi_do_call in current_procinfo.flags)) or ((cs_littlesize in aktglobalswitches) and ((fprcount > 0) or (gprcount > 0))) or ([cs_lineinfo, cs_debuginfo] * aktmoduleswitches <> []); a_reg_alloc(list, NR_STACK_POINTER_REG); a_reg_alloc(list, NR_R0); { move link register to r0 } if (needslinkreg) then list.concat(taicpu.op_reg(A_MFLR, NR_R0)); save_standard_registers; { save old stack frame pointer } if (tppcprocinfo(current_procinfo).needs_frame_pointer) then begin a_reg_alloc(list, NR_OLD_STACK_POINTER_REG); list.concat(taicpu.op_reg_reg(A_MR, NR_OLD_STACK_POINTER_REG, NR_STACK_POINTER_REG)); end; { create stack frame } if (not nostackframe) and (localsize > 0) then begin if (localsize <= high(smallint)) then begin reference_reset_base(href, NR_STACK_POINTER_REG, -localsize); a_load_store(list, A_STDU, NR_STACK_POINTER_REG, href); end else begin reference_reset_base(href, NR_NO, -localsize); { Use R0 for loading the constant (which is definitely > 32k when entering this branch). Inlined at this position because it must not use temp registers because register allocations have already been done } { Code template: lis r0,ofs@highest ori r0,r0,ofs@higher sldi r0,r0,32 oris r0,r0,ofs@h ori r0,r0,ofs@l } list.concat(taicpu.op_reg_const(A_LIS, NR_R0, word(href.offset shr 48))); list.concat(taicpu.op_reg_reg_const(A_ORI, NR_R0, NR_R0, word(href.offset shr 32))); list.concat(taicpu.op_reg_reg_const(A_SLDI, NR_R0, NR_R0, 32)); list.concat(taicpu.op_reg_reg_const(A_ORIS, NR_R0, NR_R0, word(href.offset shr 16))); list.concat(taicpu.op_reg_reg_const(A_ORI, NR_R0, NR_R0, word(href.offset))); list.concat(taicpu.op_reg_reg_reg(A_STDUX, NR_R1, NR_R1, NR_R0)); end; end; { CR register not used by FPC atm } { keep R1 allocated??? } a_reg_dealloc(list, NR_R0); end; { Generates the exit code for a method. This procedure may be called before, as well as after g_stackframe_entry is called. IMPORTANT: registers are not to be allocated through the register allocator here, because the register colouring has already occured !! } procedure tcgppc.g_proc_exit(list: taasmoutput; parasize: longint; nostackframe: boolean); var firstregfpu, firstreggpr: TSuperRegister; needslinkreg : boolean; fprcount, gprcount: aint; { Restore standard registers, both FPR and GPR; does not support VMX/Altivec } procedure restore_standard_registers; var { flag indicating whether we need to manually add the exit code (e.g. blr instruction) or not } needsExitCode : Boolean; href : treference; regcount : TSuperRegister; begin { there are two ways to do this: manually, by generating a few "ld" instructions, or via the restore helper functions. The latter are selected by the -Og switch, i.e. "optimize for size" } if (cs_littlesize in aktglobalswitches) then begin needsExitCode := false; if ((fprcount > 0) and (gprcount > 0)) then begin a_op_const_reg_reg(list, OP_SUB, OS_INT, 8 * fprcount, NR_R1, NR_R12); a_call_name_direct(list, '_restgpr1_' + intToStr(32-gprcount), false, false); a_jmp_name(list, '_restfpr_' + intToStr(32-fprcount)); end else if (gprcount > 0) then a_jmp_name(list, '_restgpr0_' + intToStr(32-gprcount)) else if (fprcount > 0) then a_jmp_name(list, '_restfpr_' + intToStr(32-fprcount)) else needsExitCode := true; end else begin needsExitCode := true; { restore registers, FPU first, GPR next } reference_reset_base(href, NR_STACK_POINTER_REG, -tcgsize2size[OS_FLOAT]); if (fprcount > 0) then for regcount := RS_F31 downto firstregfpu do begin a_loadfpu_ref_reg(list, OS_FLOAT, href, newreg(R_FPUREGISTER, regcount, R_SUBNONE)); dec(href.offset, tcgsize2size[OS_FLOAT]); end; if (gprcount > 0) then for regcount := RS_R31 downto firstreggpr do begin a_load_ref_reg(list, OS_INT, OS_INT, href, newreg(R_INTREGISTER, regcount, R_SUBNONE)); dec(href.offset, tcgsize2size[OS_INT]); end; { VMX not supported by FPC atm } end; if (needsExitCode) then begin { restore LR (if needed) } if (needslinkreg) then begin reference_reset_base(href, NR_STACK_POINTER_REG, LA_LR_ELF); list.concat(taicpu.op_reg_ref(A_LD, NR_R0, href)); list.concat(taicpu.op_reg(A_MTLR, NR_R0)); end; { generate return instruction } list.concat(taicpu.op_none(A_BLR)); end; end; var href: treference; localsize : aint; begin calcFirstUsedFPR(firstregfpu, fprcount); calcFirstUsedGPR(firstreggpr, gprcount); { determine whether we need to restore the link register } needslinkreg := ((not (po_assembler in current_procinfo.procdef.procoptions)) and (pi_do_call in current_procinfo.flags)) or ((cs_littlesize in aktglobalswitches) and ((fprcount > 0) or (gprcount > 0))) or ([cs_lineinfo, cs_debuginfo] * aktmoduleswitches <> []); { calculate stack frame } localsize := tppcprocinfo(current_procinfo).calc_stackframe_size( gprcount, fprcount); { CR register not supported } { restore stack pointer } if (not nostackframe) and (localsize > 0) then begin if (localsize <= high(smallint)) then begin list.concat(taicpu.op_reg_reg_const(A_ADDI, NR_STACK_POINTER_REG, NR_STACK_POINTER_REG, localsize)); end else begin reference_reset_base(href, NR_NO, localsize); { use R0 for loading the constant (which is definitely > 32k when entering this branch) Inlined because it must not use temp registers because register allocations have already been done } { Code template: lis r0,ofs@highest ori r0,ofs@higher sldi r0,r0,32 oris r0,r0,ofs@h ori r0,r0,ofs@l } list.concat(taicpu.op_reg_const(A_LIS, NR_R0, word(href.offset shr 48))); list.concat(taicpu.op_reg_reg_const(A_ORI, NR_R0, NR_R0, word(href.offset shr 32))); list.concat(taicpu.op_reg_reg_const(A_SLDI, NR_R0, NR_R0, 32)); list.concat(taicpu.op_reg_reg_const(A_ORIS, NR_R0, NR_R0, word(href.offset shr 16))); list.concat(taicpu.op_reg_reg_const(A_ORI, NR_R0, NR_R0, word(href.offset))); list.concat(taicpu.op_reg_reg_reg(A_ADD, NR_R1, NR_R1, NR_R0)); end; end; restore_standard_registers; end; procedure tcgppc.a_loadaddr_ref_reg(list: taasmoutput; const ref: treference; r: tregister); var ref2, tmpref: treference; { register used to construct address } tempreg : TRegister; begin ref2 := ref; fixref(list, ref2, OS_64); { load a symbol } if (assigned(ref2.symbol) or (hasLargeOffset(ref2))) then begin { add the symbol's value to the base of the reference, and if the } { reference doesn't have a base, create one } reference_reset(tmpref); tmpref.offset := ref2.offset; tmpref.symbol := ref2.symbol; tmpref.relsymbol := ref2.relsymbol; { load 64 bit reference into r. If the reference already has a base register, first load the 64 bit value into a temp register, then add it to the result register rD } if (ref2.base <> NR_NO) then begin { already have a base register, so allocate a new one } tempreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); end else begin tempreg := r; end; { code for loading a reference from a symbol into a register rD } (* lis rX,SYM@highest ori rX,SYM@higher sldi rX,rX,32 oris rX,rX,SYM@h ori rX,rX,SYM@l *) {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('loadaddr_ref_reg '))); {$ENDIF EXTDEBUG} if (assigned(tmpref.symbol)) then begin tmpref.refaddr := addr_highest; list.concat(taicpu.op_reg_ref(A_LIS, tempreg, tmpref)); tmpref.refaddr := addr_higher; list.concat(taicpu.op_reg_reg_ref(A_ORI, tempreg, tempreg, tmpref)); list.concat(taicpu.op_reg_reg_const(A_SLDI, tempreg, tempreg, 32)); tmpref.refaddr := addr_high; list.concat(taicpu.op_reg_reg_ref(A_ORIS, tempreg, tempreg, tmpref)); tmpref.refaddr := addr_low; list.concat(taicpu.op_reg_reg_ref(A_ORI, tempreg, tempreg, tmpref)); end else a_load_const_reg(list, OS_ADDR, tmpref.offset, tempreg); { if there's already a base register, add the temp register contents to the base register } if (ref2.base <> NR_NO) then begin list.concat(taicpu.op_reg_reg_reg(A_ADD, r, tempreg, ref2.base)); end; end else if (ref2.offset <> 0) then begin { no symbol, but offset <> 0 } if (ref2.base <> NR_NO) then begin a_op_const_reg_reg(list, OP_ADD, OS_64, ref2.offset, ref2.base, r) { FixRef makes sure that "(ref.index <> R_NO) and (ref.offset <> 0)" never occurs, so now only ref.offset has to be loaded } end else begin a_load_const_reg(list, OS_64, ref2.offset, r); end; end else if (ref2.index <> NR_NO) then begin list.concat(taicpu.op_reg_reg_reg(A_ADD, r, ref2.base, ref2.index)) end else if (ref2.base <> NR_NO) and (r <> ref2.base) then begin a_load_reg_reg(list, OS_ADDR, OS_ADDR, ref2.base, r) //list.concat(taicpu.op_reg_reg(A_MR, ref2.base, r)); end else begin list.concat(taicpu.op_reg_const(A_LI, r, 0)); end; end; { ************* concatcopy ************ } const maxmoveunit = 8; procedure tcgppc.g_concatcopy(list: taasmoutput; const source, dest: treference; len: aint); var countreg, tempreg: TRegister; src, dst: TReference; lab: tasmlabel; count, count2: longint; size: tcgsize; begin {$IFDEF extdebug} if len > high(aint) then internalerror(2002072704); list.concat(tai_comment.create(strpnew('g_concatcopy1 ' + inttostr(len) + ' bytes left '))); {$ENDIF extdebug} { make sure short loads are handled as optimally as possible; note that the data here never overlaps, so we can do a forward copy at all times. NOTE: maybe use some scratch registers to pair load/store instructions } if (len <= maxmoveunit) then begin src := source; dst := dest; list.concat(tai_comment.create(strpnew('g_concatcopy3 ' + inttostr(src.offset) + ' ' + inttostr(dst.offset)))); while (len <> 0) do begin if (len = 8) then begin a_load_ref_ref(list, OS_64, OS_64, src, dst); dec(len, 8); end else if (len >= 4) then begin a_load_ref_ref(list, OS_32, OS_32, src, dst); inc(src.offset, 4); inc(dst.offset, 4); dec(len, 4); end else if (len >= 2) then begin a_load_ref_ref(list, OS_16, OS_16, src, dst); inc(src.offset, 2); inc(dst.offset, 2); dec(len, 2); end else begin a_load_ref_ref(list, OS_8, OS_8, src, dst); inc(src.offset, 1); inc(dst.offset, 1); dec(len, 1); end; end; exit; end; {$IFDEF extdebug} list.concat(tai_comment.create(strpnew('g_concatcopy2 ' + inttostr(len) + ' bytes left '))); {$ENDIF extdebug} count := len div maxmoveunit; reference_reset(src); reference_reset(dst); { load the address of source into src.base } if (count > 4) or not issimpleref(source) or ((source.index <> NR_NO) and ((source.offset + len) > high(smallint))) then begin src.base := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_loadaddr_ref_reg(list, source, src.base); end else begin src := source; end; { load the address of dest into dst.base } if (count > 4) or not issimpleref(dest) or ((dest.index <> NR_NO) and ((dest.offset + len) > high(smallint))) then begin dst.base := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_loadaddr_ref_reg(list, dest, dst.base); end else begin dst := dest; end; { generate a loop } if count > 4 then begin { the offsets are zero after the a_loadaddress_ref_reg and just have to be set to 8. I put an Inc there so debugging may be easier (should offset be different from zero here, it will be easy to notice in the generated assembler } inc(dst.offset, 8); inc(src.offset, 8); list.concat(taicpu.op_reg_reg_const(A_SUBI, src.base, src.base, 8)); list.concat(taicpu.op_reg_reg_const(A_SUBI, dst.base, dst.base, 8)); countreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_load_const_reg(list, OS_64, count, countreg); { explicitely allocate F0 since it can be used safely here (for holding date that's being copied) } a_reg_alloc(list, NR_F0); objectlibrary.getjumplabel(lab); a_label(list, lab); list.concat(taicpu.op_reg_reg_const(A_SUBIC_, countreg, countreg, 1)); list.concat(taicpu.op_reg_ref(A_LFDU, NR_F0, src)); list.concat(taicpu.op_reg_ref(A_STFDU, NR_F0, dst)); a_jmp(list, A_BC, C_NE, 0, lab); a_reg_dealloc(list, NR_F0); len := len mod 8; end; count := len div 8; { unrolled loop } if count > 0 then begin a_reg_alloc(list, NR_F0); for count2 := 1 to count do begin a_loadfpu_ref_reg(list, OS_F64, src, NR_F0); a_loadfpu_reg_ref(list, OS_F64, NR_F0, dst); inc(src.offset, 8); inc(dst.offset, 8); end; a_reg_dealloc(list, NR_F0); len := len mod 8; end; if (len and 4) <> 0 then begin a_reg_alloc(list, NR_R0); a_load_ref_reg(list, OS_32, OS_32, src, NR_R0); a_load_reg_ref(list, OS_32, OS_32, NR_R0, dst); inc(src.offset, 4); inc(dst.offset, 4); a_reg_dealloc(list, NR_R0); end; { copy the leftovers } if (len and 2) <> 0 then begin a_reg_alloc(list, NR_R0); a_load_ref_reg(list, OS_16, OS_16, src, NR_R0); a_load_reg_ref(list, OS_16, OS_16, NR_R0, dst); inc(src.offset, 2); inc(dst.offset, 2); a_reg_dealloc(list, NR_R0); end; if (len and 1) <> 0 then begin a_reg_alloc(list, NR_R0); a_load_ref_reg(list, OS_8, OS_8, src, NR_R0); a_load_reg_ref(list, OS_8, OS_8, NR_R0, dst); a_reg_dealloc(list, NR_R0); end; end; procedure tcgppc.g_overflowcheck(list: taasmoutput; const l: tlocation; def: tdef); var hl: tasmlabel; flags : TResFlags; begin if not (cs_check_overflow in aktlocalswitches) then exit; objectlibrary.getjumplabel(hl); if not ((def.deftype = pointerdef) or ((def.deftype = orddef) and (torddef(def).typ in [u64bit, u16bit, u32bit, u8bit, uchar, bool8bit, bool16bit, bool32bit]))) then begin { ... instructions setting overflow flag ... mfxerf R0 mtcrf 128, R0 ble cr0, label } list.concat(taicpu.op_reg(A_MFXER, NR_R0)); list.concat(taicpu.op_const_reg(A_MTCRF, 128, NR_R0)); flags.cr := RS_CR0; flags.flag := F_LE; a_jmp_flags(list, flags, hl); end else a_jmp_cond(list, OC_AE, hl); a_call_name(list, 'FPC_OVERFLOW'); a_label(list, hl); end; procedure tcgppc.g_intf_wrapper(list: TAAsmoutput; procdef: tprocdef; const labelname: string; ioffset: longint); procedure loadvmttor11; var href: treference; begin reference_reset_base(href, NR_R3, 0); cg.a_load_ref_reg(list, OS_ADDR, OS_ADDR, href, NR_R11); end; procedure op_onr11methodaddr; var href: treference; begin if (procdef.extnumber = $FFFF) then Internalerror(200006139); { call/jmp vmtoffs(%eax) ; method offs } reference_reset_base(href, NR_R11, procdef._class.vmtmethodoffset(procdef.extnumber)); if not (hasLargeOffset(href)) then begin list.concat(taicpu.op_reg_reg_const(A_ADDIS, NR_R11, NR_R11, smallint((href.offset shr 16) + ord(smallint(href.offset and $FFFF) < 0)))); href.offset := smallint(href.offset and $FFFF); end else { add support for offsets > 16 bit } internalerror(200510201); list.concat(taicpu.op_reg_ref(A_LD, NR_R11, href)); { the loaded reference is a function descriptor reference, so deref again (at ofs 0 there's the real pointer) } {$warning ts:TODO: update GOT reference} reference_reset_base(href, NR_R11, 0); list.concat(taicpu.op_reg_ref(A_LD, NR_R11, href)); list.concat(taicpu.op_reg(A_MTCTR, NR_R11)); list.concat(taicpu.op_none(A_BCTR)); { NOP needed for the linker...? } list.concat(taicpu.op_none(A_NOP)); end; var make_global: boolean; begin if (not (procdef.proctypeoption in [potype_function, potype_procedure])) then Internalerror(200006137); if not assigned(procdef._class) or (procdef.procoptions * [po_classmethod, po_staticmethod, po_methodpointer, po_interrupt, po_iocheck] <> []) then Internalerror(200006138); if procdef.owner.symtabletype <> objectsymtable then Internalerror(200109191); make_global := false; if (not current_module.is_unit) or (cs_create_smart in aktmoduleswitches) or (procdef.owner.defowner.owner.symtabletype = globalsymtable) then make_global := true; if make_global then List.concat(Tai_symbol.Createname_global(labelname, AT_FUNCTION, 0)) else List.concat(Tai_symbol.Createname(labelname, AT_FUNCTION, 0)); { set param1 interface to self } g_adjust_self_value(list, procdef, ioffset); if po_virtualmethod in procdef.procoptions then begin loadvmttor11; op_onr11methodaddr; end else {$note ts:todo add GOT change?? - think not needed :) } list.concat(taicpu.op_sym(A_B, objectlibrary.newasmsymbol('.' + procdef.mangledname, AB_EXTERNAL, AT_FUNCTION))); List.concat(Tai_symbol_end.Createname(labelname)); end; {***************** This is private property, keep out! :) *****************} function tcgppc.issimpleref(const ref: treference): boolean; begin if (ref.base = NR_NO) and (ref.index <> NR_NO) then internalerror(200208101); result := not (assigned(ref.symbol)) and (((ref.index = NR_NO) and (ref.offset >= low(smallint)) and (ref.offset <= high(smallint))) or ((ref.index <> NR_NO) and (ref.offset = 0))); end; function tcgppc.load_got_symbol(list: taasmoutput; symbol : string) : tregister; var l: tasmsymbol; ref: treference; begin l:=objectlibrary.getasmsymbol(symbol+'$got'); if not(assigned(l)) then begin l:=objectlibrary.newasmsymbol(symbol+'$got',AB_LOCAL, AT_LABEL); asmlist[al_picdata].concat(tai_section.create(sec_toc, '.toc', 8)); asmlist[al_picdata].concat(tai_symbol.create(l,0)); asmlist[al_picdata].concat(tai_directive.create(asd_toc_entry, symbol + '[TC], ' + symbol)); end; reference_reset_symbol(ref,l,0); ref.base := NR_R2; ref.refaddr := addr_pic; result := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('loading got reference for ' + symbol))); {$ENDIF EXTDEBUG} // cg.a_load_ref_reg(list,OS_ADDR,OS_ADDR,ref,result); list.concat(taicpu.op_reg_ref(A_LD, result, ref)); end; function tcgppc.fixref(list: taasmoutput; var ref: treference; const size : TCgsize): boolean; var tmpreg: tregister; name : string; begin result := false; { Avoids recursion. } if (ref.refaddr = addr_pic) then exit; {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('fixref0 ' + ref2string(ref)))); {$ENDIF EXTDEBUG} { if we have to create PIC, add the symbol to the TOC/GOT } if (cs_create_pic in aktmoduleswitches) and (assigned(ref.symbol)) then begin tmpreg := load_got_symbol(list, ref.symbol.name); if (ref.base = NR_NO) then ref.base := tmpreg else if (ref.index = NR_NO) then ref.index := tmpreg else begin a_op_reg_reg_reg(list, OP_ADD, OS_ADDR, ref.base, tmpreg, tmpreg); ref.base := tmpreg; end; ref.symbol := nil; {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('fixref-pic ' + ref2string(ref)))); {$ENDIF EXTDEBUG} end; if (ref.base = NR_NO) then begin ref.base := ref.index; ref.index := NR_NO; end; if (ref.base <> NR_NO) and (ref.index <> NR_NO) and ((ref.offset <> 0) or assigned(ref.symbol)) then begin result := true; tmpreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_op_reg_reg_reg(list, OP_ADD, size, ref.base, ref.index, tmpreg); ref.base := tmpreg; ref.index := NR_NO; end; if (ref.index <> NR_NO) and (assigned(ref.symbol) or (ref.offset <> 0)) then internalerror(2006010506); {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('fixref1 ' + ref2string(ref)))); {$ENDIF EXTDEBUG} end; procedure tcgppc.a_load_store(list: taasmoutput; op: tasmop; reg: tregister; ref: treference); var tmpreg, tmpreg2: tregister; tmpref: treference; largeOffset: Boolean; begin { at this point there must not be a combination of values in the ref treference which is not possible to directly map to instructions of the PowerPC architecture } if (ref.index <> NR_NO) and ((ref.offset <> 0) or (assigned(ref.symbol))) then internalerror(200310131); { if this is a PIC'ed address, handle it and exit } if (ref.refaddr = addr_pic) then begin if (ref.offset <> 0) then internalerror(2006010501); if (ref.index <> NR_NO) then internalerror(2006010502); if (not assigned(ref.symbol)) then internalerror(200601050); list.concat(taicpu.op_reg_ref(op, reg, ref)); exit; end; { for some instructions we need to check that the offset is divisible by at least four. If not, add the bytes which are "off" to the base register and adjust the offset accordingly } case op of A_LD, A_LDU, A_STD, A_STDU, A_LWA : if ((ref.offset mod 4) <> 0) then begin tmpreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); if (ref.base <> NR_NO) then begin a_op_const_reg_reg(list, OP_ADD, OS_ADDR, ref.offset mod 4, ref.base, tmpreg); ref.base := tmpreg; end else begin list.concat(taicpu.op_reg_const(A_LI, tmpreg, ref.offset mod 4)); ref.base := tmpreg; end; ref.offset := (ref.offset div 4) * 4; end; end; {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('a_load_store1 ' + BoolToStr(ref.refaddr = addr_pic)))); {$ENDIF EXTDEBUG} { if we have to load/store from a symbol or large addresses, use a temporary register containing the address } if (assigned(ref.symbol) or (hasLargeOffset(ref))) then begin tmpreg := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); if (hasLargeOffset(ref) and (ref.base = NR_NO)) then begin ref.base := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); a_load_const_reg(list, OS_ADDR, ref.offset, ref.base); ref.offset := 0; end; reference_reset(tmpref); tmpref.symbol := ref.symbol; tmpref.relsymbol := ref.relsymbol; tmpref.offset := ref.offset; if (ref.base <> NR_NO) then begin { As long as the TOC isn't working we try to achieve highest speed (in this case by allowing instructions execute in parallel) as possible at the cost of using another temporary register. So the code template when there is a base register and an offset is the following: lis rT1, SYM+offs@highest ori rT1, rT1, SYM+offs@higher lis rT2, SYM+offs@hi ori rT2, SYM+offs@lo rldimi rT2, rT1, 32 X reg, base, rT2 } tmpreg2 := rg[R_INTREGISTER].getregister(list, R_SUBWHOLE); if (assigned(tmpref.symbol)) then begin tmpref.refaddr := addr_highest; list.concat(taicpu.op_reg_ref(A_LIS, tmpreg, tmpref)); tmpref.refaddr := addr_higher; list.concat(taicpu.op_reg_reg_ref(A_ORI, tmpreg, tmpreg, tmpref)); tmpref.refaddr := addr_high; list.concat(taicpu.op_reg_ref(A_LIS, tmpreg2, tmpref)); tmpref.refaddr := addr_low; list.concat(taicpu.op_reg_reg_ref(A_ORI, tmpreg2, tmpreg2, tmpref)); list.concat(taicpu.op_reg_reg_const_const(A_RLDIMI, tmpreg2, tmpreg, 32, 0)); end else a_load_const_reg(list, OS_ADDR, tmpref.offset, tmpreg2); reference_reset(tmpref); tmpref.base := ref.base; tmpref.index := tmpreg2; case op of { the code generator doesn't generate update instructions anyway, so error out on those instructions } A_LBZ : op := A_LBZX; A_LHZ : op := A_LHZX; A_LWZ : op := A_LWZX; A_LD : op := A_LDX; A_LHA : op := A_LHAX; A_LWA : op := A_LWAX; A_LFS : op := A_LFSX; A_LFD : op := A_LFDX; A_STB : op := A_STBX; A_STH : op := A_STHX; A_STW : op := A_STWX; A_STD : op := A_STDX; A_STFS : op := A_STFSX; A_STFD : op := A_STFDX; else { unknown load/store opcode } internalerror(2005101302); end; list.concat(taicpu.op_reg_ref(op, reg, tmpref)); end else begin { when accessing value from a reference without a base register, use the following code template: lis rT,SYM+offs@highesta ori rT,SYM+offs@highera sldi rT,rT,32 oris rT,rT,SYM+offs@ha ld rD,SYM+offs@l(rT) } tmpref.refaddr := addr_highesta; list.concat(taicpu.op_reg_ref(A_LIS, tmpreg, tmpref)); tmpref.refaddr := addr_highera; list.concat(taicpu.op_reg_reg_ref(A_ORI, tmpreg, tmpreg, tmpref)); list.concat(taicpu.op_reg_reg_const(A_SLDI, tmpreg, tmpreg, 32)); tmpref.refaddr := addr_higha; list.concat(taicpu.op_reg_reg_ref(A_ORIS, tmpreg, tmpreg, tmpref)); tmpref.base := tmpreg; tmpref.refaddr := addr_low; list.concat(taicpu.op_reg_ref(op, reg, tmpref)); end; end else begin list.concat(taicpu.op_reg_ref(op, reg, ref)); end; end; procedure tcgppc.a_jmp(list: taasmoutput; op: tasmop; c: tasmcondflag; crval: longint; l: tasmlabel); var p: taicpu; begin p := taicpu.op_sym(op, objectlibrary.newasmsymbol(l.name, AB_EXTERNAL, AT_LABEL)); if op <> A_B then create_cond_norm(c, crval, p.condition); p.is_jmp := true; list.concat(p) end; function tcgppc.hasLargeOffset(const ref : TReference) : Boolean; begin { this rather strange calculation is required because offsets of TReferences are unsigned } result := aword(ref.offset-low(smallint)) > high(smallint)-low(smallint); end; procedure tcgppc.loadConstantPIC(list : taasmoutput; size : TCGSize; a : aint; reg : TRegister); var l: tasmsymbol; ref: treference; symbol : string; begin symbol := 'toc$' + hexstr(a, sizeof(a)*2); l:=objectlibrary.getasmsymbol(symbol); if not(assigned(l)) then begin l:=objectlibrary.newasmsymbol(symbol,AB_LOCAL, AT_LABEL); asmlist[al_picdata].concat(tai_section.create(sec_toc, '.toc', 8)); asmlist[al_picdata].concat(tai_symbol.create(l,0)); asmlist[al_picdata].concat(tai_directive.create(asd_toc_entry, symbol + '[TC], ' + inttostr(a))); end; reference_reset_symbol(ref,l,0); ref.base := NR_R2; ref.refaddr := addr_pic; {$IFDEF EXTDEBUG} list.concat(tai_comment.create(strpnew('loading value from TOC reference for ' + symbol))); {$ENDIF EXTDEBUG} cg.a_load_ref_reg(list, OS_INT, OS_INT, ref, reg); end; begin cg := tcgppc.create; end.