{ $Id$ Copyright (c) 1998-2002 by Florian Klaempfl This unit implements the base class for the register allocator 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. **************************************************************************** } {$i fpcdefs.inc} { Allow duplicate allocations, can be used to get the .s file written } { $define ALLOWDUPREG} {# @abstract(Abstract register allocator unit) This unit contains services to allocate, free references and registers which are used by the code generator. } {******************************************************************************* (applies to new register allocator) Register allocator introduction. Free Pascal uses a Chaitin style register allocator. We use a variant similair to the one described in the book "Modern compiler implementation in C" by Andrew W. Appel., published by Cambridge University Press. The register allocator that is described by Appel uses a much improved way of register coalescing, called "iterated register coalescing". Instead of doing coalescing as a prepass to the register allocation, the coalescing is done inside the register allocator. This has the advantage that the register allocator can coalesce very aggresively without introducing spills. Reading this book is recommended for a complete understanding. Here is a small introduction. The code generator thinks it has an infinite amount of registers. Our processor has a limited amount of registers. Therefore we must reduce the amount of registers until there are less enough to fit into the processors registers. Registers can interfere or not interfere. If two imaginary registers interfere they cannot be placed into the same psysical register. Reduction of registers is done by: - "coalescing" Two registers that do not interfere are combined into one register. - "spilling" A register is changed into a memory location and the generated code is modified to use the memory location instead of the register. Register allocation is a graph colouring problem. Each register is a colour, and if two registers interfere there is a connection between them in the graph. In addition to the imaginary registers in the code generator, the psysical CPU registers are also present in this graph. This allows us to make interferences between imaginary registers and cpu registers. This is very usefull for describing archtectural constraints, like for example that the div instruction modifies edx, so variables that are in use at that time cannot be stored into edx. This can be modelled by making edx interfere with those variables. Graph colouring is an NP complete problem. Therefore we use an approximation that pushes registers to colour on to a stack. This is done in the "simplify" procedure. The register allocator first checks which registers are a candidate for coalescing. *******************************************************************************} unit rgobj; interface uses {$ifdef delphi} dmisc, {$endif} cutils,cclasses, globtype, cpubase,cpuinfo,cgbase, aasmbase,aasmtai,aasmcpu, node ; const ALL_OTHERREGISTERS=[low(tregisterindex)..high(tregisterindex)]; type regvarother_longintarray = array[tregisterindex] of longint; regvarother_booleanarray = array[tregisterindex] of boolean; regvarint_longintarray = array[first_int_supreg..last_int_supreg] of longint; regvarint_ptreearray = array[first_int_supreg..last_int_supreg] of tnode; tpushedsavedloc = record case byte of 0: (pushed: boolean); 1: (ofs: longint); end; tpushedsavedother = array[tregisterindex] of tpushedsavedloc; Tinterferencebitmap=array[Tsuperregister] of set of Tsuperregister; Tinterferenceadjlist=array[Tsuperregister] of Pstring; Tinterferencegraph=record bitmap:Tinterferencebitmap; adjlist:Tinterferenceadjlist; end; Pinterferencegraph=^Tinterferencegraph; Tmovelist=record count:cardinal; data:array[0..$ffff] of Tlinkedlistitem; end; Pmovelist=^Tmovelist; {In the register allocator we keep track of move instructions. These instructions are moved between five linked lists. There is also a linked list per register to keep track about the moves it is associated with. Because we need to determine quickly in which of the five lists it is we add anu enumeradtion to each move instruction.} Tmoveset=(ms_coalesced_moves,ms_constrained_moves,ms_frozen_moves, ms_worklist_moves,ms_active_moves); Tmoveins=class(Tlinkedlistitem) moveset:Tmoveset; { $ifdef ra_debug} x,y:Tsuperregister; { $endif} instruction:Taicpu; end; {# This class implements the abstract register allocator It is used by the code generator to allocate and free registers which might be valid across nodes. It also contains utility routines related to registers. Some of the methods in this class should be overriden by cpu-specific implementations. } trgobj = class { The "usableregsxxx" contain all registers of type "xxx" that } { aren't currently allocated to a regvar. The "unusedregsxxx" } { contain all registers of type "xxx" that aren't currently } { allocated } maxintreg:Tsuperregister; usable_registers:string[32]; unusedregsint,usableregsint:Tsuperregisterset; unusedregsaddr,usableregsaddr:Tsuperregisterset; unusedregsfpu,usableregsfpu : Tsuperregisterset; unusedregsmm,usableregsmm : Tsuperregisterset; { these counters contain the number of elements in the } { unusedregsxxx/usableregsxxx sets } countunusedregsfpu, countunusedregsmm : byte; countusableregsint, countusableregsaddr, countusableregsfpu, countusableregsmm : byte; { Contains the registers which are really used by the proc itself. It doesn't take care of registers used by called procedures } preserved_by_proc_int, used_in_proc_int : Tsuperregisterset; used_in_proc_other : totherregisterset; reg_pushes_other : regvarother_longintarray; is_reg_var_other : regvarother_booleanarray; is_reg_var_int : Tsuperregisterset; regvar_loaded_other : regvarother_booleanarray; regvar_loaded_int : Tsuperregisterset; colour : array[Tsuperregister] of Tsuperregister; spillednodes : string; { tries to hold the amount of times which the current tree is processed } t_times: longint; constructor create(Acpu_registers:byte;const Ausable:string); destructor destroy;override; {# Allocate a general purpose register An internalerror will be generated if there is no more free registers which can be allocated } function getregisterint(list:Taasmoutput;size:Tcgsize):Tregister; procedure add_constraints(reg:Tregister);virtual; {# Allocate an ABT register An internalerror will be generated if there is no more free registers which can be allocated An explanantion of abt registers can be found near the implementation. } function getabtregisterint(list:Taasmoutput;size:Tcgsize):Tregister; {# Free a general purpose register @param(r register to free) } procedure ungetregisterint(list: taasmoutput; r : tregister); virtual; {# Allocate a floating point register An internalerror will be generated if there is no more free registers which can be allocated } function getregisterfpu(list: taasmoutput;size:Tcgsize) : tregister; virtual; {# Free a floating point register @param(r register to free) } procedure ungetregisterfpu(list: taasmoutput; r : tregister;size:TCGsize); virtual; function getregistermm(list: taasmoutput) : tregister; virtual; procedure ungetregistermm(list: taasmoutput; r : tregister); virtual; {# Allocate an address register. Address registers are the only registers which can be used as a base register in references (treference). On most cpu's this is the same as a general purpose register. An internalerror will be generated if there is no more free registers which can be allocated } function getaddressregister(list:Taasmoutput):Tregister;virtual; procedure ungetaddressregister(list: taasmoutput; r: tregister); virtual; {# Verify if the specified register is an address or general purpose register. Returns TRUE if @var(reg) is an adress register. This routine should only be used to check on general purpose or address register. It will not work on multimedia or floating point registers @param(reg register to verify) } function isaddressregister(reg: tregister): boolean; virtual; {# Tries to allocate the passed register, if possible @param(r specific register to allocate) } function getexplicitregisterint(list:Taasmoutput;r:Tregister):Tregister;virtual; {# Tries to allocate the passed fpu register, if possible @param(r specific register to allocate) } function getexplicitregisterfpu(list : taasmoutput; r : Tregister) : tregister;virtual; procedure allocexplicitregistersint(list:Taasmoutput;r:Tsuperregisterset); procedure deallocexplicitregistersint(list:Taasmoutput;r:Tsuperregisterset); {# Deallocate any kind of register } procedure ungetregister(list: taasmoutput; r : tregister); virtual; {# Deallocate all registers which are allocated in the specified reference. On most systems, this will free the base and index registers of the specified reference. @param(ref reference which must have its registers freed) } procedure ungetreference(list: taasmoutput; const ref : treference); virtual; {# Convert a register to a specified register size, and return that register size } function makeregsize(reg: tregister; size: tcgsize): tregister; virtual; {# saves register variables (restoring happens automatically) } procedure saveotherregvars(list:Taasmoutput;const s:Totherregisterset); {# Saves in temporary references (allocated via the temp. allocator) the registers defined in @var(s). The registers are only saved if they are currently in use, otherwise they are left as is. On processors which have instructions which manipulate the stack, this routine should be overriden for performance reasons. @param(list) List to add the instruction to @param(saved) Array of saved register information @param(s) Registers which might require saving } procedure saveusedotherregisters(list:Taasmoutput; var saved:Tpushedsavedother; const s:Totherregisterset);virtual; {# Restores the registers which were saved with a call to @var(saveusedregisters). On processors which have instructions which manipulate the stack, this routine should be overriden for performance reasons. } procedure restoreusedotherregisters(list:Taasmoutput; const saved:Tpushedsavedother);virtual; { used when deciding which registers to use for regvars } procedure incrementotherregisterpushed(const s: totherregisterset); procedure clearregistercount; procedure resetusableregisters;virtual; procedure makeregvarint(reg:Tsuperregister); procedure makeregvarother(reg:Tregister); procedure saveStateForInline(var state: pointer);virtual; procedure restoreStateAfterInline(var state: pointer);virtual; procedure saveUnusedState(var state: pointer);virtual; procedure restoreUnusedState(var state: pointer);virtual; {$ifdef EXTDEBUG} procedure writegraph(loopidx:longint); {$endif EXTDEBUG} procedure add_move_instruction(instr:Taicpu); procedure prepare_colouring; procedure epilogue_colouring; procedure colour_registers; function spill_registers(list:Taasmoutput;headertai:tai;const regs_to_spill:string):boolean; procedure add_edge(u,v:Tsuperregister); protected cpu_registers:byte; igraph:Tinterferencegraph; degree:array[0..255] of byte; alias:array[Tsuperregister] of Tsuperregister; simplifyworklist,freezeworklist,spillworklist:string; coalescednodes:string; selectstack:string; abtlist:string; movelist:array[Tsuperregister] of Pmovelist; worklist_moves,active_moves,frozen_moves, coalesced_moves,constrained_moves:Tlinkedlist; { the following two contain the common (generic) code for all } { get- and ungetregisterxxx functions/procedures } function getregistergenother(list: taasmoutput; const lowreg, highreg: tsuperregister; var unusedregs:Tsuperregisterset;var countunusedregs:byte): tregister; function getregistergenint(list:Taasmoutput;subreg:Tsubregister; const lowreg,highreg:Tsuperregister; var fusedinproc,unusedregs:Tsuperregisterset):Tregister; procedure ungetregistergen(list: taasmoutput; r: tregister; const usableregs:tsuperregisterset;var unusedregs: tsuperregisterset; var countunusedregs: byte); procedure ungetregistergenint(list:taasmoutput;r:Tregister; const usableregs:Tsuperregisterset; var unusedregs:Tsuperregisterset); procedure getregisterintinline(list:Taasmoutput;position:Tai;subreg:Tsubregister;var result:Tregister); procedure ungetregisterintinline(list:Taasmoutput;position:Tai;r:Tregister); procedure add_edges_used(u:Tsuperregister); procedure add_to_movelist(u:Tsuperregister;data:Tlinkedlistitem); function move_related(n:Tsuperregister):boolean; procedure make_work_list; procedure enable_moves(n:Tsuperregister); procedure decrement_degree(m:Tsuperregister); procedure simplify; function get_alias(n:Tsuperregister):Tsuperregister; procedure add_worklist(u:Tsuperregister); function adjacent_ok(u,v:Tsuperregister):boolean; function conservative(u,v:Tsuperregister):boolean; procedure combine(u,v:Tsuperregister); procedure coalesce; procedure freeze_moves(u:Tsuperregister); procedure freeze; procedure select_spill; procedure assign_colours; procedure clear_interferences(u:Tsuperregister); end; trgobjclass = class of trgobj; const {# This value is used in tsaved. If the array value is equal to this, then this means that this register is not used. } reg_not_saved = $7fffffff; var rg : trgobj; { trerefence handling } {# Clear to zero a treference } procedure reference_reset(var ref : treference); {# Clear to zero a treference, and set is base address to base register. } procedure reference_reset_base(var ref : treference;base : tregister;offset : longint); procedure reference_reset_symbol(var ref : treference;sym : tasmsymbol;offset : longint); procedure reference_release(list: taasmoutput; const ref : treference); { This routine verifies if two references are the same, and if so, returns TRUE, otherwise returns false. } function references_equal(sref : treference;dref : treference) : boolean; { tlocation handling } procedure location_reset(var l : tlocation;lt:TCGLoc;lsize:TCGSize); procedure location_release(list: taasmoutput; const l : tlocation); procedure location_freetemp(list: taasmoutput; const l : tlocation); procedure location_copy(var destloc:tlocation; const sourceloc : tlocation); procedure location_swap(var destloc,sourceloc : tlocation); type psavedstate = ^tsavedstate; tsavedstate = record unusedregsint,usableregsint : Tsuperregisterset; unusedregsaddr,usableregsaddr : Tsuperregisterset; unusedregsfpu,usableregsfpu : totherregisterset; unusedregsmm,usableregsmm : totherregisterset; countunusedregsfpu, countunusedregsmm : byte; countusableregsint, countusableregsfpu, countusableregsmm : byte; { contains the registers which are really used by the proc itself } used_in_proc_int : Tsuperregisterset; used_in_proc_other : totherregisterset; reg_pushes_other : regvarother_longintarray; reg_pushes_int : regvarint_longintarray; is_reg_var_other : regvarother_booleanarray; is_reg_var_int : Tsuperregisterset; regvar_loaded_other: regvarother_booleanarray; regvar_loaded_int: Tsuperregisterset; end; punusedstate = ^tunusedstate; tunusedstate = record unusedregsaddr : Tsuperregisterset; unusedregsfpu : totherregisterset; unusedregsmm : totherregisterset; countunusedregsfpu, countunusedregsmm : byte; end; implementation uses systems, globals,verbose, cgobj,tgobj, procinfo; constructor Trgobj.create(Acpu_registers:byte;const Ausable:string); var i:Tsuperregister; begin used_in_proc_int := []; used_in_proc_other:=[]; t_times := 0; resetusableregisters; maxintreg:=first_int_imreg; cpu_registers:=Acpu_registers; unusedregsint:=[0..254]; { 255 (RS_INVALID) can't be used } unusedregsfpu:=usableregsfpu; unusedregsmm:=usableregsmm; countunusedregsfpu:=countusableregsfpu; countunusedregsmm:=countusableregsmm; {$ifdef powerpc} preserved_by_proc_int:=[RS_R13..RS_R31]; {$else powerpc} preserved_by_proc_int:=[]; {$endif powerpc} fillchar(igraph,sizeof(igraph),0); fillchar(degree,sizeof(degree),0); {Precoloured nodes should have an infinite degree, which we can approach by 255.} for i:=first_int_supreg to last_int_supreg do degree[i]:=255; fillchar(movelist,sizeof(movelist),0); worklist_moves:=Tlinkedlist.create; usable_registers:=Ausable; abtlist:=''; fillchar(colour,sizeof(colour),RS_INVALID); end; destructor Trgobj.destroy; var i:Tsuperregister; begin for i:=low(Tsuperregister) to high(Tsuperregister) do begin if igraph.adjlist[i]<>nil then dispose(igraph.adjlist[i]); if movelist[i]<>nil then dispose(movelist[i]); end; worklist_moves.free; end; function trgobj.getregistergenother(list: taasmoutput; const lowreg, highreg: tsuperregister; var unusedregs: tsuperregisterset; var countunusedregs: byte): tregister; var i: tsuperregister; r: Tregister; begin for i:=lowreg to highreg do begin if i in unusedregs then begin exclude(unusedregs,i); include(used_in_proc_other,i); dec(countunusedregs); {$warning Only FPU Registers supported} r:=newreg(R_FPUREGISTER,i,R_SUBNONE); list.concat(tai_regalloc.alloc(r)); result := r; exit; end; end; internalerror(10); end; function Trgobj.getregistergenint(list:Taasmoutput; subreg:Tsubregister; const lowreg,highreg:Tsuperregister; var fusedinproc,unusedregs:Tsuperregisterset):Tregister; var i,p:Tsuperregister; r:Tregister; min : byte; adj : pstring; begin if maxintregNR_NO) and (ref.base<>NR_FRAME_POINTER_REG) then ungetregisterint(list,ref.base); if (ref.index<>NR_NO) and (ref.index<>NR_FRAME_POINTER_REG) then ungetregisterint(list,ref.index); end; procedure trgobj.saveotherregvars(list: taasmoutput; const s: totherregisterset); var r: Tregister; begin if not(cs_regvars in aktglobalswitches) then exit; {$warning TODO firstsavefpureg} { if firstsavefpureg <> NR_NO then for r.enum := firstsavefpureg to lastsavefpureg do if is_reg_var_other[r.enum] and (r.enum in s) then store_regvar(list,r); if firstsavemmreg <> R_NO then for r.enum := firstsavemmreg to lastsavemmreg do if is_reg_var_other[r.enum] and (r.enum in s) then store_regvar(list,r); } end; procedure trgobj.saveusedotherregisters(list: taasmoutput; var saved : tpushedsavedother; const s: totherregisterset); var r : tregister; hr : treference; begin used_in_proc_other:=used_in_proc_other + s; {$warning TODO firstsavefpureg} (* { don't try to save the fpu registers if not desired (e.g. for } { the 80x86) } if firstsavefpureg <> R_NO then for r.enum:=firstsavefpureg to lastsavefpureg do begin saved[r.enum].ofs:=reg_not_saved; { if the register is used by the calling subroutine and if } { it's not a regvar (those are handled separately) } if not is_reg_var_other[r.enum] and (r.enum in s) and { and is present in use } not(r.enum in unusedregsfpu) then begin { then save it } tg.GetTemp(list,extended_size,tt_persistent,hr); saved[r.enum].ofs:=hr.offset; cg.a_loadfpu_reg_ref(list,OS_FLOAT,r,hr); cg.a_reg_dealloc(list,r); include(unusedregsfpu,r.enum); inc(countunusedregsfpu); end; end; { don't save the vector registers if there's no support for them } if firstsavemmreg <> R_NO then for r.enum:=firstsavemmreg to lastsavemmreg do begin saved[r.enum].ofs:=reg_not_saved; { if the register is in use and if it's not a regvar (those } { are handled separately), save it } if not is_reg_var_other[r.enum] and (r.enum in s) and { and is present in use } not(r.enum in unusedregsmm) then begin { then save it } tg.GetTemp(list,mmreg_size,tt_persistent,hr); saved[r.enum].ofs:=hr.offset; cg.a_loadmm_reg_ref(list,r,hr); cg.a_reg_dealloc(list,r); include(unusedregsmm,r.enum); inc(countunusedregsmm); end; end; *) end; procedure trgobj.restoreusedotherregisters(list : taasmoutput; const saved : tpushedsavedother); var r,r2 : tregister; hr : treference; begin {$warning TODO firstsavefpureg} (* if firstsavemmreg <> R_NO then for r.enum:=lastsavemmreg downto firstsavemmreg do begin if saved[r.enum].ofs <> reg_not_saved then begin r2.enum:=R_INTREGISTER; r2.number:=NR_FRAME_POINTER_REG; reference_reset_base(hr,r2,saved[r.enum].ofs); cg.a_reg_alloc(list,r); cg.a_loadmm_ref_reg(list,hr,r); if not (r.enum in unusedregsmm) then { internalerror(10) in n386cal we always save/restore the reg *state* using save/restoreunusedstate -> the current state may not be real (JM) } else begin dec(countunusedregsmm); exclude(unusedregsmm,r.enum); end; tg.UnGetTemp(list,hr); end; end; if firstsavefpureg <> R_NO then for r.enum:=lastsavefpureg downto firstsavefpureg do begin if saved[r.enum].ofs <> reg_not_saved then begin r2.enum:=R_INTREGISTER; r2.number:=NR_FRAME_POINTER_REG; reference_reset_base(hr,r2,saved[r.enum].ofs); cg.a_reg_alloc(list,r); cg.a_loadfpu_ref_reg(list,OS_FLOAT,hr,r); if not (r.enum in unusedregsfpu) then { internalerror(10) in n386cal we always save/restore the reg *state* using save/restoreunusedstate -> the current state may not be real (JM) } else begin dec(countunusedregsfpu); exclude(unusedregsfpu,r.enum); end; tg.UnGetTemp(list,hr); end; end; *) end; procedure trgobj.incrementotherregisterpushed(const s:Totherregisterset); {$ifdef i386} var regi : Tregister; {$endif i386} begin {$warning TODO firstsavefpureg} (* {$ifdef i386} if firstsavefpureg <> R_NO then for regi:=firstsavefpureg to lastsavefpureg do begin if (regi in s) then inc(reg_pushes_other[regi],t_times*2); end; if firstsavemmreg <> R_NO then for regi:=firstsavemmreg to lastsavemmreg do begin if (regi in s) then inc(reg_pushes_other[regi],t_times*2); end; {$endif i386} *) end; procedure trgobj.clearregistercount; begin fillchar(reg_pushes_other,sizeof(reg_pushes_other),0); {ifndef i386} { all used registers will have to be saved at the start and restored } { at the end, but otoh regpara's do not have to be saved to memory } { at the start (there is a move from regpara to regvar most of the } { time though) -> set cost to 100+20 } {$warning TODO firstsavefpureg} (* filldword(reg_pushes_other[firstsavefpureg],ord(lastsavefpureg)-ord(firstsavefpureg)+1,120); *) {endif not i386} fillchar(is_reg_var_other,sizeof(is_reg_var_other),false); is_reg_var_int:=[]; fillchar(regvar_loaded_other,sizeof(regvar_loaded_other),false); regvar_loaded_int:=[]; end; procedure trgobj.resetusableregisters; begin { initialize fields with constant values from cpubase } countusableregsint := cpubase.c_countusableregsint; countusableregsfpu := cpubase.c_countusableregsfpu; countusableregsmm := cpubase.c_countusableregsmm; usableregsint := cpubase.usableregsint; usableregsfpu := cpubase.usableregsfpu; usableregsmm := cpubase.usableregsmm; clearregistercount; end; procedure trgobj.makeregvarint(reg:Tsuperregister); begin dec(countusableregsint); include(is_reg_var_int,reg); end; procedure trgobj.makeregvarother(reg: tregister); begin (* if reg.enum>lastreg then internalerror(200301081); if reg.enum in intregs then internalerror(200301151) else if reg.enum in fpuregs then begin dec(countusableregsfpu); dec(countunusedregsfpu); exclude(usableregsfpu,reg.enum); exclude(unusedregsfpu,reg.enum); include(used_in_proc_other,reg.enum); end else if reg.enum in mmregs then begin dec(countusableregsmm); dec(countunusedregsmm); exclude(usableregsmm,reg.enum); exclude(unusedregsmm,reg.enum); include(used_in_proc_other,reg.enum); end; is_reg_var_other[reg.enum]:=true; *) end; procedure trgobj.saveStateForInline(var state: pointer); begin new(psavedstate(state)); psavedstate(state)^.unusedregsint := unusedregsint; psavedstate(state)^.usableregsint := usableregsint; psavedstate(state)^.unusedregsfpu := unusedregsfpu; psavedstate(state)^.usableregsfpu := usableregsfpu; psavedstate(state)^.unusedregsmm := unusedregsmm; psavedstate(state)^.usableregsmm := usableregsmm; psavedstate(state)^.countunusedregsfpu := countunusedregsfpu; psavedstate(state)^.countunusedregsmm := countunusedregsmm; psavedstate(state)^.countusableregsint := countusableregsint; psavedstate(state)^.countusableregsfpu := countusableregsfpu; psavedstate(state)^.countusableregsmm := countusableregsmm; psavedstate(state)^.used_in_proc_int := used_in_proc_int; psavedstate(state)^.used_in_proc_other := used_in_proc_other; psavedstate(state)^.reg_pushes_other := reg_pushes_other; psavedstate(state)^.is_reg_var_int := is_reg_var_int; psavedstate(state)^.is_reg_var_other := is_reg_var_other; psavedstate(state)^.regvar_loaded_int := regvar_loaded_int; psavedstate(state)^.regvar_loaded_other := regvar_loaded_other; end; procedure trgobj.restoreStateAfterInline(var state: pointer); begin unusedregsint := psavedstate(state)^.unusedregsint; usableregsint := psavedstate(state)^.usableregsint; unusedregsfpu := psavedstate(state)^.unusedregsfpu; usableregsfpu := psavedstate(state)^.usableregsfpu; unusedregsmm := psavedstate(state)^.unusedregsmm; usableregsmm := psavedstate(state)^.usableregsmm; countunusedregsfpu := psavedstate(state)^.countunusedregsfpu; countunusedregsmm := psavedstate(state)^.countunusedregsmm; countusableregsint := psavedstate(state)^.countusableregsint; countusableregsfpu := psavedstate(state)^.countusableregsfpu; countusableregsmm := psavedstate(state)^.countusableregsmm; used_in_proc_int := psavedstate(state)^.used_in_proc_int; used_in_proc_other := psavedstate(state)^.used_in_proc_other; reg_pushes_other := psavedstate(state)^.reg_pushes_other; is_reg_var_int := psavedstate(state)^.is_reg_var_int; is_reg_var_other := psavedstate(state)^.is_reg_var_other; regvar_loaded_other := psavedstate(state)^.regvar_loaded_other; regvar_loaded_int := psavedstate(state)^.regvar_loaded_int; dispose(psavedstate(state)); state := nil; end; procedure trgobj.saveUnusedState(var state: pointer); begin new(punusedstate(state)); punusedstate(state)^.unusedregsfpu := unusedregsfpu; punusedstate(state)^.unusedregsmm := unusedregsmm; punusedstate(state)^.countunusedregsfpu := countunusedregsfpu; punusedstate(state)^.countunusedregsmm := countunusedregsmm; end; procedure trgobj.restoreUnusedState(var state: pointer); begin unusedregsfpu := punusedstate(state)^.unusedregsfpu; unusedregsmm := punusedstate(state)^.unusedregsmm; countunusedregsfpu := punusedstate(state)^.countunusedregsfpu; countunusedregsmm := punusedstate(state)^.countunusedregsmm; dispose(punusedstate(state)); state := nil; end; procedure Trgobj.add_edge(u,v:Tsuperregister); {This procedure will add an edge to the virtual interference graph.} procedure addadj(u,v:Tsuperregister); begin if igraph.adjlist[u]=nil then begin getmem(igraph.adjlist[u],16); igraph.adjlist[u]^:=''; end else if (length(igraph.adjlist[u]^) and 15)=15 then reallocmem(igraph.adjlist[u],length(igraph.adjlist[u]^)+16); igraph.adjlist[u]^:=igraph.adjlist[u]^+char(v); end; begin if (u<>v) and not(v in igraph.bitmap[u]) then begin include(igraph.bitmap[u],v); include(igraph.bitmap[v],u); {Precoloured nodes are not stored in the interference graph.} if not(u in [first_int_supreg..last_int_supreg]) then begin addadj(u,v); inc(degree[u]); end; if not(v in [first_int_supreg..last_int_supreg]) then begin addadj(v,u); inc(degree[v]); end; end; end; procedure Trgobj.add_edges_used(u:Tsuperregister); var i:Tsuperregister; begin for i:=0 to maxintreg do if not(i in unusedregsint) then add_edge(u,i); end; {$ifdef EXTDEBUG} procedure Trgobj.writegraph(loopidx:longint); {This procedure writes out the current interference graph in the register allocator.} var f:text; i,j:Tsuperregister; begin assign(f,'igraph'+tostr(loopidx)); rewrite(f); writeln(f,'Interference graph'); writeln(f); write(f,' '); for i:=0 to 15 do for j:=0 to 15 do write(f,hexstr(i,1)); writeln(f); write(f,' '); for i:=0 to 15 do write(f,'0123456789ABCDEF'); writeln(f); for i:=0 to 255 do begin write(f,hexstr(i,2):4); for j:=0 to 255 do if j in igraph.bitmap[i] then write(f,'*') else write(f,'-'); writeln(f); end; close(f); end; {$endif EXTDEBUG} procedure Trgobj.add_to_movelist(u:Tsuperregister;data:Tlinkedlistitem); begin if movelist[u]=nil then begin getmem(movelist[u],64); movelist[u]^.count:=0; end else if (movelist[u]^.count and 15)=15 then reallocmem(movelist[u],(movelist[u]^.count+1)*4+64); movelist[u]^.data[movelist[u]^.count]:=data; inc(movelist[u]^.count); end; procedure Trgobj.add_move_instruction(instr:Taicpu); {This procedure notifies a certain as a move instruction so the register allocator can try to eliminate it.} var i:Tmoveins; ssupreg,dsupreg:Tsuperregister; begin i:=Tmoveins.create; i.moveset:=ms_worklist_moves; i.instruction:=instr; worklist_moves.insert(i); ssupreg:=getsupreg(instr.oper[O_MOV_SOURCE].reg); add_to_movelist(ssupreg,i); dsupreg:=getsupreg(instr.oper[O_MOV_DEST].reg); if ssupreg<>dsupreg then {Avoid adding the same move instruction twice to a single register.} add_to_movelist(dsupreg,i); i.x:=ssupreg; i.y:=dsupreg; end; function Trgobj.move_related(n:Tsuperregister):boolean; var i:cardinal; begin move_related:=false; if movelist[n]<>nil then begin for i:=0 to movelist[n]^.count-1 do if Tmoveins(movelist[n]^.data[i]).moveset in [ms_worklist_moves,ms_active_moves] then begin move_related:=true; break; end; end; end; procedure Trgobj.make_work_list; var n:Tsuperregister; begin {If we have 7 cpu registers, and the degree of a node is 7, we cannot assign it to any of the registers, thus it is significant.} for n:=first_int_imreg to maxintreg do if degree[n]>=cpu_registers then spillworklist:=spillworklist+char(n) else if move_related(n) then freezeworklist:=freezeworklist+char(n) else simplifyworklist:=simplifyworklist+char(n); end; procedure Trgobj.prepare_colouring; begin make_work_list; active_moves:=Tlinkedlist.create; frozen_moves:=Tlinkedlist.create; coalesced_moves:=Tlinkedlist.create; constrained_moves:=Tlinkedlist.create; fillchar(alias,sizeof(alias),0); coalescednodes:=''; selectstack:=''; end; procedure Trgobj.enable_moves(n:Tsuperregister); var m:Tlinkedlistitem; i:cardinal; begin if movelist[n]<>nil then for i:=0 to movelist[n]^.count-1 do begin m:=movelist[n]^.data[i]; if Tmoveins(m).moveset in [ms_worklist_moves,ms_active_moves] then begin if Tmoveins(m).moveset=ms_active_moves then begin {Move m from the set active_moves to the set worklist_moves.} active_moves.remove(m); Tmoveins(m).moveset:=ms_worklist_moves; worklist_moves.concat(m); end; end; end; end; procedure Trgobj.decrement_degree(m:Tsuperregister); var adj:Pstring; d:byte; i,p:byte; n:char; begin {$ifdef ALLOWDUPREG} if m=RS_INVALID then exit; {$endif} d:=degree[m]; if degree[m]>0 then dec(degree[m]); if d=cpu_registers then begin {Enable moves for m.} enable_moves(m); {Enable moves for adjacent.} adj:=igraph.adjlist[m]; if adj<>nil then for i:=1 to length(adj^) do begin n:=adj^[i]; if (pos(n,selectstack) or pos(n,coalescednodes))=0 then enable_moves(Tsuperregister(n)); end; {Remove the node from the spillworklist.} p:=pos(char(m),spillworklist); if p=0 then internalerror(200305301); {must be found} if length(spillworklist)>1 then spillworklist[p]:=spillworklist[length(spillworklist)]; dec(spillworklist[0]); if move_related(m) then freezeworklist:=freezeworklist+char(m) else simplifyworklist:=simplifyworklist+char(m); end; end; procedure Trgobj.simplify; var adj:Pstring; i,min,p:byte; m:char; n:Tsuperregister; begin {We the element with the least interferences out of the simplifyworklist.} min:=$ff; p:=1; for i:=1 to length(simplifyworklist) do begin adj:=igraph.adjlist[Tsuperregister(simplifyworklist[i])]; if adj=nil then begin min:=0; break; {We won't find smaller ones.} end else if length(adj^)1 then simplifyworklist[p]:=simplifyworklist[length(simplifyworklist)]; dec(simplifyworklist[0]); {Push it on the selectstack.} selectstack:=selectstack+char(n); adj:=igraph.adjlist[n]; if adj<>nil then for i:=1 to length(adj^) do begin m:=adj^[i]; if ((pos(m,selectstack) or pos(m,coalescednodes))=0) and not (Tsuperregister(m) in [first_int_supreg..last_int_supreg]) then decrement_degree(Tsuperregister(m)); end; end; function Trgobj.get_alias(n:Tsuperregister):Tsuperregister; begin while pos(char(n),coalescednodes)<>0 do n:=alias[n]; get_alias:=n; end; procedure Trgobj.add_worklist(u:Tsuperregister); var p:byte; begin if not(u in [first_int_supreg..last_int_supreg]) and not move_related(u) and (degree[u]1 then freezeworklist[p]:=freezeworklist[length(freezeworklist)]; dec(freezeworklist[0]); simplifyworklist:=simplifyworklist+char(u); end; end; function Trgobj.adjacent_ok(u,v:Tsuperregister):boolean; {Check wether u and v should be coalesced. u is precoloured.} function ok(t,r:Tsuperregister):boolean; begin ok:=(degree[t]nil then for i:=1 to length(adj^) do begin t:=adj^[i]; if (pos(t,selectstack) or pos(t,coalescednodes))=0 then if not ok(Tsuperregister(t),u) then begin adjacent_ok:=false; break; end; end; end; function Trgobj.conservative(u,v:Tsuperregister):boolean; var adj:Pstring; done:set of char; {To prevent that we count nodes twice.} i,k:byte; n:char; begin k:=0; done:=[]; adj:=igraph.adjlist[u]; if adj<>nil then for i:=1 to length(adj^) do begin n:=adj^[i]; if (pos(n,selectstack) or pos(n,coalescednodes))=0 then begin include(done,n); if degree[Tsuperregister(n)]>=cpu_registers then inc(k); end; end; adj:=igraph.adjlist[v]; if adj<>nil then for i:=1 to length(adj^) do begin n:=adj^[i]; if ((pos(n,selectstack) or pos(n,coalescednodes))=0) and not (n in done) and (degree[Tsuperregister(n)]>=cpu_registers) then inc(k); end; conservative:=(k0 then delete(freezeworklist,p,1) else delete(spillworklist,pos(char(v),spillworklist),1); coalescednodes:=coalescednodes+char(v); alias[v]:=u; {Combine both movelists. Since the movelists are sets, only add elements that are not already present.} if assigned(movelist[v]) then begin for n:=0 to movelist[v]^.count-1 do begin add:=true; for o:=0 to movelist[u]^.count-1 do if movelist[u]^.data[o]=movelist[v]^.data[n] then begin add:=false; break; end; if add then add_to_movelist(u,movelist[v]^.data[n]); end; enable_moves(v); end; adj:=igraph.adjlist[v]; if adj<>nil then for i:=1 to length(adj^) do begin t:=adj^[i]; if (pos(t,selectstack) or pos(t,coalescednodes))=0 then begin decrement:=(Tsuperregister(t)<>u) and not(u in igraph.bitmap[Tsuperregister(t)]); add_edge(Tsuperregister(t),u); {Do not call decrement_degree because it might move nodes between lists while the degree does not change (add_edge will increase it). Instead, we will decrement manually. (Only if the degree has been increased.)} if decrement and not (Tsuperregister(t) in [first_int_supreg..last_int_supreg]) and (degree[Tsuperregister(t)]>0) then dec(degree[Tsuperregister(t)]); end; end; p:=pos(char(u),freezeworklist); if (degree[u]>=cpu_registers) and (p<>0) then begin delete(freezeworklist,p,1); spillworklist:=spillworklist+char(u); end; end; procedure Trgobj.coalesce; var m:Tmoveins; x,y,u,v:Tsuperregister; begin m:=Tmoveins(worklist_moves.getfirst); x:=get_alias(getsupreg(m.instruction.oper[0].reg)); y:=get_alias(getsupreg(m.instruction.oper[1].reg)); if y in [first_int_supreg..last_int_supreg] then begin u:=y; v:=x; end else begin u:=x; v:=y; end; if (u=v) then begin m.moveset:=ms_coalesced_moves; {Already coalesced.} coalesced_moves.insert(m); add_worklist(u); end {Do u and v interfere? In that case the move is constrained. Two precoloured nodes interfere allways. If v is precoloured, by the above code u is precoloured, thus interference...} else if (v in [first_int_supreg..last_int_supreg]) or (u in igraph.bitmap[v]) then begin m.moveset:=ms_constrained_moves; {Cannot coalesce yet...} constrained_moves.insert(m); add_worklist(u); add_worklist(v); end {Next test: is it possible and a good idea to coalesce??} else if ((u in [first_int_supreg..last_int_supreg]) and adjacent_ok(u,v)) or (not(u in [first_int_supreg..last_int_supreg]) and conservative(u,v)) then begin m.moveset:=ms_coalesced_moves; {Move coalesced!} coalesced_moves.insert(m); combine(u,v); add_worklist(u); end else begin m.moveset:=ms_active_moves; active_moves.insert(m); end; end; procedure Trgobj.freeze_moves(u:Tsuperregister); var i:cardinal; m:Tlinkedlistitem; v,x,y:Tsuperregister; begin if movelist[u]<>nil then for i:=0 to movelist[u]^.count-1 do begin m:=movelist[u]^.data[i]; if Tmoveins(m).moveset in [ms_worklist_moves,ms_active_moves] then begin x:=getsupreg(Tmoveins(m).instruction.oper[0].reg); y:=getsupreg(Tmoveins(m).instruction.oper[1].reg); if get_alias(y)=get_alias(u) then v:=get_alias(x) else v:=get_alias(y); {Move m from active_moves/worklist_moves to frozen_moves.} if Tmoveins(m).moveset=ms_active_moves then active_moves.remove(m) else worklist_moves.remove(m); Tmoveins(m).moveset:=ms_frozen_moves; frozen_moves.insert(m); if not(v in [first_int_supreg..last_int_supreg]) and not(move_related(v)) and (degree[v]nil then for j:=1 to length(adj^) do begin w:=adj^[j]; a:=get_alias(Tsuperregister(w)); if a in colourednodes then include(adj_colours,colour[a]); end; include(adj_colours,RS_STACK_POINTER_REG); {Assume a spill by default...} spillednodes:=spillednodes+char(n); {Search for a colour not in this list.} for k:=1 to length(usable_registers) do begin c:=Tsuperregister(usable_registers[k]); if not(c in adj_colours) then begin colour[n]:=c; dec(spillednodes[0]); {Colour found: no spill.} include(colourednodes,n); if n in used_in_proc_int then include(used_in_proc_int,c); break; end; end; end; {Finally colour the nodes that were coalesced.} for i:=1 to length(coalescednodes) do begin n:=Tsuperregister(coalescednodes[i]); k:=get_alias(n); colour[n]:=colour[k]; if n in used_in_proc_int then include(used_in_proc_int,colour[k]); end; {$ifdef ra_debug} if aktfilepos.line=-1 then begin writeln('colourlist ',length(freezeworklist)); for i:=0 to maxintreg do writeln(i:4,' ',colour[i]:4) end; {$endif ra_debug} end; procedure Trgobj.colour_registers; begin repeat if length(simplifyworklist)<>0 then simplify else if not(worklist_moves.empty) then coalesce else if length(freezeworklist)<>0 then freeze else if length(spillworklist)<>0 then select_spill; until (length(simplifyworklist)=0) and worklist_moves.empty and (length(freezeworklist)=0) and (length(spillworklist)=0); assign_colours; end; procedure Trgobj.epilogue_colouring; { procedure move_to_worklist_moves(list:Tlinkedlist); var p:Tlinkedlistitem; begin p:=list.first; while p<>nil do begin Tmoveins(p).moveset:=ms_worklist_moves; p:=p.next; end; worklist_moves.concatlist(list); end; } var i:Tsuperregister; begin worklist_moves.clear; {$ifdef Principle_wrong_by_definition} {Move everything back to worklist_moves.} move_to_worklist_moves(active_moves); move_to_worklist_moves(frozen_moves); move_to_worklist_moves(coalesced_moves); move_to_worklist_moves(constrained_moves); {$endif Principle_wrong_by_definition} active_moves.destroy; active_moves:=nil; frozen_moves.destroy; frozen_moves:=nil; coalesced_moves.destroy; coalesced_moves:=nil; constrained_moves.destroy; constrained_moves:=nil; for i:=0 to 255 do if movelist[i]<>nil then begin dispose(movelist[i]); movelist[i]:=0; end; end; procedure Trgobj.clear_interferences(u:Tsuperregister); {Remove node u from the interference graph and remove all collected move instructions it is associated with.} var i:byte; j,k,count:cardinal; v:Tsuperregister; m,n:Tmoveins; begin if igraph.adjlist[u]<>nil then begin for i:=1 to length(igraph.adjlist[u]^) do begin v:=Tsuperregister(igraph.adjlist[u]^[i]); {Remove (u,v) and (v,u) from bitmap.} exclude(igraph.bitmap[u],v); exclude(igraph.bitmap[v],u); {Remove (v,u) from adjacency list.} if igraph.adjlist[v]<>nil then begin delete(igraph.adjlist[v]^,pos(char(v),igraph.adjlist[v]^),1); if length(igraph.adjlist[v]^)=0 then begin dispose(igraph.adjlist[v]); igraph.adjlist[v]:=nil; end; end; end; {Remove ( u,* ) from adjacency list.} dispose(igraph.adjlist[u]); igraph.adjlist[u]:=nil; end; {$ifdef Principle_wrong_by_definition} {Now remove the moves.} if movelist[u]<>nil then begin for j:=0 to movelist[u]^.count-1 do begin m:=Tmoveins(movelist[u]^.data[j]); {Get the other register of the move instruction.} v:=m.instruction.oper[0].reg.number shr 8; if v=u then v:=m.instruction.oper[1].reg.number shr 8; repeat repeat if (u<>v) and (movelist[v]<>nil) then begin {Remove the move from it's movelist.} count:=movelist[v]^.count-1; for k:=0 to count do if m=movelist[v]^.data[k] then begin if k<>count then movelist[v]^.data[k]:=movelist[v]^.data[count]; dec(movelist[v]^.count); if count=0 then begin dispose(movelist[v]); movelist[v]:=nil; end; break; end; end; {The complexity is enourmous: the register might have been coalesced. In that case it's movelists have been added to it's coalescing alias. (DM)} v:=alias[v]; until v=0; {And also register u might have been coalesced.} u:=alias[u]; until u=0; case m.moveset of ms_coalesced_moves: coalesced_moves.remove(m); ms_constrained_moves: constrained_moves.remove(m); ms_frozen_moves: frozen_moves.remove(m); ms_worklist_moves: worklist_moves.remove(m); ms_active_moves: active_moves.remove(m); end; end; dispose(movelist[u]); movelist[u]:=nil; end; {$endif Principle_wrong_by_definition} end; procedure Trgobj.getregisterintinline(list:Taasmoutput;position:Tai;subreg:Tsubregister;var result:Tregister); var min,p,i:Tsuperregister; r:Tregister; adj:Pstring; begin if maxintreg0 then begin if maxintreg" Revision 1.60 2003/07/06 15:31:21 daniel * Fixed register allocator. *Lots* of fixes. Revision 1.59 2003/07/06 15:00:47 jonas * fixed my previous completely broken commit. It's not perfect though, registers > last_int_supreg and < max_intreg may still be "translated" Revision 1.58 2003/07/06 14:45:05 jonas * support integer registers that are not managed by newra (ie. don't translate register numbers that fall outside the range first_int_supreg..last_int_supreg) Revision 1.57 2003/07/02 22:18:04 peter * paraloc splitted in callerparaloc,calleeparaloc * sparc calling convention updates Revision 1.56 2003/06/17 16:34:44 jonas * lots of newra fixes (need getfuncretparaloc implementation for i386)! * renamed all_intregisters to volatile_intregisters and made it processor dependent Revision 1.55 2003/06/14 14:53:50 jonas * fixed newra cycle for x86 * added constants for indicating source and destination operands of the "move reg,reg" instruction to aasmcpu (and use those in rgobj) Revision 1.54 2003/06/13 21:19:31 peter * current_procdef removed, use current_procinfo.procdef instead Revision 1.53 2003/06/12 21:11:10 peter * ungetregisterfpu gets size parameter Revision 1.52 2003/06/12 16:43:07 peter * newra compiles for sparc Revision 1.51 2003/06/09 14:54:26 jonas * (de)allocation of registers for parameters is now performed properly (and checked on the ppc) - removed obsolete allocation of all parameter registers at the start of a procedure (and deallocation at the end) Revision 1.50 2003/06/03 21:11:09 peter * cg.a_load_* get a from and to size specifier * makeregsize only accepts newregister * i386 uses generic tcgnotnode,tcgunaryminus Revision 1.49 2003/06/03 13:01:59 daniel * Register allocator finished Revision 1.48 2003/06/01 21:38:06 peter * getregisterfpu size parameter added * op_const_reg size parameter added * sparc updates Revision 1.47 2003/05/31 20:31:11 jonas * set inital costs of assigning a variable to a register to 120 for non-i386, because the used register must be store to memory at the start and loaded again at the end Revision 1.46 2003/05/30 18:55:21 jonas * fixed several regvar related bugs for non-i386. make cycle with -Or now works for ppc Revision 1.45 2003/05/30 12:36:13 jonas * use as little different registers on the ppc until newra is released, since every used register must be saved Revision 1.44 2003/05/17 13:30:08 jonas * changed tt_persistant to tt_persistent :) * tempcreatenode now doesn't accept a boolean anymore for persistent temps, but a ttemptype, so you can also create ansistring temps etc Revision 1.43 2003/05/16 14:33:31 peter * regvar fixes Revision 1.42 2003/04/26 20:03:49 daniel * Bug fix in simplify Revision 1.41 2003/04/25 20:59:35 peter * removed funcretn,funcretsym, function result is now in varsym and aliases for result and function name are added using absolutesym * vs_hidden parameter for funcret passed in parameter * vs_hidden fixes * writenode changed to printnode and released from extdebug * -vp option added to generate a tree.log with the nodetree * nicer printnode for statements, callnode Revision 1.40 2003/04/25 08:25:26 daniel * Ifdefs around a lot of calls to cleartempgen * Fixed registers that are allocated but not freed in several nodes * Tweak to register allocator to cause less spills * 8-bit registers now interfere with esi,edi and ebp Compiler can now compile rtl successfully when using new register allocator Revision 1.39 2003/04/23 20:23:06 peter * compile fix for no-newra Revision 1.38 2003/04/23 14:42:07 daniel * Further register allocator work. Compiler now smaller with new allocator than without. * Somebody forgot to adjust ppu version number Revision 1.37 2003/04/22 23:50:23 peter * firstpass uses expectloc * checks if there are differences between the expectloc and location.loc from secondpass in EXTDEBUG Revision 1.36 2003/04/22 10:09:35 daniel + Implemented the actual register allocator + Scratch registers unavailable when new register allocator used + maybe_save/maybe_restore unavailable when new register allocator used Revision 1.35 2003/04/21 19:16:49 peter * count address regs separate Revision 1.34 2003/04/17 16:48:21 daniel * Added some code to keep track of move instructions in register allocator Revision 1.33 2003/04/17 07:50:24 daniel * Some work on interference graph construction Revision 1.32 2003/03/28 19:16:57 peter * generic constructor working for i386 * remove fixed self register * esi added as address register for i386 Revision 1.31 2003/03/11 21:46:24 jonas * lots of new regallocator fixes, both in generic and ppc-specific code (ppc compiler still can't compile the linux system unit though) Revision 1.30 2003/03/09 21:18:59 olle + added cutils to the uses clause Revision 1.29 2003/03/08 20:36:41 daniel + Added newra version of Ti386shlshrnode + Added interference graph construction code Revision 1.28 2003/03/08 13:59:16 daniel * Work to handle new register notation in ag386nsm + Added newra version of Ti386moddivnode Revision 1.27 2003/03/08 10:53:48 daniel * Created newra version of secondmul in n386add.pas Revision 1.26 2003/03/08 08:59:07 daniel + $define newra will enable new register allocator + getregisterint will return imaginary registers with $newra + -sr switch added, will skip register allocation so you can see the direct output of the code generator before register allocation Revision 1.25 2003/02/26 20:50:45 daniel * Fixed ungetreference Revision 1.24 2003/02/19 22:39:56 daniel * Fixed a few issues Revision 1.23 2003/02/19 22:00:14 daniel * Code generator converted to new register notation - Horribily outdated todo.txt removed Revision 1.22 2003/02/02 19:25:54 carl * Several bugfixes for m68k target (register alloc., opcode emission) + VIS target + Generic add more complete (still not verified) Revision 1.21 2003/01/08 18:43:57 daniel * Tregister changed into a record Revision 1.20 2002/10/05 12:43:28 carl * fixes for Delphi 6 compilation (warning : Some features do not work under Delphi) Revision 1.19 2002/08/23 16:14:49 peter * tempgen cleanup * tt_noreuse temp type added that will be used in genentrycode Revision 1.18 2002/08/17 22:09:47 florian * result type handling in tcgcal.pass_2 overhauled * better tnode.dowrite * some ppc stuff fixed Revision 1.17 2002/08/17 09:23:42 florian * first part of procinfo rewrite Revision 1.16 2002/08/06 20:55:23 florian * first part of ppc calling conventions fix Revision 1.15 2002/08/05 18:27:48 carl + more more more documentation + first version include/exclude (can't test though, not enough scratch for i386 :()... Revision 1.14 2002/08/04 19:06:41 carl + added generic exception support (still does not work!) + more documentation Revision 1.13 2002/07/07 09:52:32 florian * powerpc target fixed, very simple units can be compiled * some basic stuff for better callparanode handling, far from being finished Revision 1.12 2002/07/01 18:46:26 peter * internal linker * reorganized aasm layer Revision 1.11 2002/05/18 13:34:17 peter * readded missing revisions Revision 1.10 2002/05/16 19:46:44 carl + defines.inc -> fpcdefs.inc to avoid conflicts if compiling by hand + try to fix temp allocation (still in ifdef) + generic constructor calls + start of tassembler / tmodulebase class cleanup Revision 1.8 2002/04/21 15:23:03 carl + makeregsize + changeregsize is now a local routine Revision 1.7 2002/04/20 21:32:25 carl + generic FPC_CHECKPOINTER + first parameter offset in stack now portable * rename some constants + move some cpu stuff to other units - remove unused constents * fix stacksize for some targets * fix generic size problems which depend now on EXTEND_SIZE constant Revision 1.6 2002/04/15 19:03:31 carl + reg2str -> std_reg2str() Revision 1.5 2002/04/06 18:13:01 jonas * several powerpc-related additions and fixes Revision 1.4 2002/04/04 19:06:04 peter * removed unused units * use tlocation.size in cg.a_*loc*() routines Revision 1.3 2002/04/02 17:11:29 peter * tlocation,treference update * LOC_CONSTANT added for better constant handling * secondadd splitted in multiple routines * location_force_reg added for loading a location to a register of a specified size * secondassignment parses now first the right and then the left node (this is compatible with Kylix). This saves a lot of push/pop especially with string operations * adapted some routines to use the new cg methods Revision 1.2 2002/04/01 19:24:25 jonas * fixed different parameter name in interface and implementation declaration of a method (only 1.0.x detected this) Revision 1.1 2002/03/31 20:26:36 jonas + a_loadfpu_* and a_loadmm_* methods in tcg * register allocation is now handled by a class and is mostly processor independent (+rgobj.pas and i386/rgcpu.pas) * temp allocation is now handled by a class (+tgobj.pas, -i386\tgcpu.pas) * some small improvements and fixes to the optimizer * some register allocation fixes * some fpuvaroffset fixes in the unary minus node * push/popusedregisters is now called rg.save/restoreusedregisters and (for i386) uses temps instead of push/pop's when using -Op3 (that code is also better optimizable) * fixed and optimized register saving/restoring for new/dispose nodes * LOC_FPU locations now also require their "register" field to be set to R_ST, not R_ST0 (the latter is used for LOC_CFPUREGISTER locations only) - list field removed of the tnode class because it's not used currently and can cause hard-to-find bugs }