ORCA-C/Native.pas
Stephen Heumann a87aeef25b Ensure native peephole opt uses a jump table.
In ORCA/Pascal's code generation, a case statement may use a jump table or a sequence of comparisons depending on whether it is considered sparse. This one was just a little too sparse to use a jump table, but changing it to use one makes it considerably faster. To force generation of a jump table, this commit adds several more explicit cases (even though they don't do anything).
2022-12-20 20:31:24 -06:00

2670 lines
90 KiB
ObjectPascal

{$optimize 7}
{---------------------------------------------------------------}
{ }
{ ORCA Native Code Generation }
{ }
{ This module of the code generator is called to generate }
{ native code instructions. The native code is optimized }
{ and written to the object segment. }
{ }
{ Externally available procedures: }
{ }
{ EndSeg - close out the current segment }
{ GenNative - write a native code instruction to the output }
{ file }
{ GenImplied - short form of GenNative - reduces code size }
{ GenCall - short form of jsl to library subroutine - reduces }
{ code size }
{ GenLab - generate a label }
{ InitFile - Set up the object file }
{ InitNative - set up for a new segment }
{ RefName - handle a reference to a named label }
{ }
{---------------------------------------------------------------}
unit Native;
interface
{$LibPrefix '0/obj/'}
uses CCommon, CGI, CGC, ObjOut;
{$segment 'CODEGEN'}
type
labelptr = ^labelentry; {pointer to a forward ref node}
labelentry = record {forward ref node}
addr: longint;
next: labelptr;
end;
labelrec = record {label record}
defined: boolean; {Note: form used in objout.asm}
chain: labelptr;
case boolean of
true : (val: longint);
false: (ival,hval: integer);
end;
var
{current instruction info}
{------------------------}
pc: longint; {program counter}
{65816 native code generation}
{----------------------------}
didOne: boolean; {has an optimization been done?}
labeltab: array[0..maxlabel] of labelrec; {label table}
localLabel: array[0..maxLocalLabel] of integer; {local variable label table}
{---------------------------------------------------------------}
procedure EndSeg;
{ close out the current segment }
procedure GenNative (p_opcode: integer; p_mode: addressingMode;
p_operand: integer; p_name: stringPtr; p_flags: integer);
{ write a native code instruction to the output file }
{ }
{ parameters: }
{ p_opcode - native op code }
{ p_mode - addressing mode }
{ p_operand - integer operand }
{ p_name - named operand }
{ p_flags - operand modifier flags }
procedure GenImplied (p_opcode: integer);
{ short form of GenNative - reduces code size }
{ }
{ parameters: }
{ p_code - operation code }
procedure GenImpliedForFlags (p_opcode: integer);
{ Generate implied addressing instruction used for flags only. }
{ }
{ parameters: }
{ p_code - operation code (m_tax or m_tay) }
procedure GenCall (callNum: integer);
{ short form of jsl to library subroutine - reduces code size }
{ }
{ parameters: }
{ callNum - subroutine # to generate a call for }
procedure GenLab (lnum: integer);
{ generate a label }
{ }
{ parameters: }
{ lnum - label number }
procedure InitFile (keepName: gsosOutStringPtr; keepFlag: integer; partial: boolean);
{ Set up the object file }
{ }
{ parameters: }
{ keepName - name of the output file }
{ keepFlag - keep status: }
{ 0 - don't keep the output }
{ 1 - create a new object module }
{ 2 - a .root already exists }
{ 3 - at least on .letter file exists }
{ partial - is this a partial compile? }
{ }
{ Note: Declared as extern in CGI.pas }
procedure InitNative;
{ set up for a new segment }
procedure LabelSearch (lab: integer; len, shift, disp: integer);
{ resolve a label reference }
{ }
{ parameters: }
{ lab - label number }
{ len - # bytes for the generated code }
{ shift - shift factor }
{ disp - disp past the label }
{ }
{ Note 1: maxlabel is reserved for use as the start of the }
{ string space }
{ Note 2: negative length indicates relative branch }
{ Note 3: zero length indicates 2 byte addr -1 }
procedure RefName (lab: stringPtr; disp, len, shift: integer);
{ handle a reference to a named label }
{ }
{ parameters: }
{ lab - label name }
{ disp - displacement past the label }
{ len - number of bytes in the reference }
{ shift - shift factor }
{--------------------------------------------------------------------------}
implementation
const
npeepSize = 128; {native peephole optimizer window size}
nMaxPeep = 4; {max # instructions needed to opt.}
type
{65816 native code generation}
{----------------------------}
npeepRange = 1..npeepsize; {subrange for native code peephole opt.}
nativeType = record {native code instruction}
opcode: integer; {op code}
mode: addressingMode; {addressing mode}
operand: integer; {operand value}
name: stringPtr; {operand label}
flags: integer; {modifier flags}
end;
registerConditions = (regUnknown,regImmediate,regAbsolute,regLocal);
registerType = record {used to track register contents}
condition: registerConditions;
value: integer;
lab: stringPtr;
flags: integer;
end;
var
{register optimization}
{---------------------}
aRegister, {current register contents}
xRegister,
yRegister: registerType;
lastRegOpcode: integer; {opcode of last reg/flag-setting instr.}
{native peephole optimization}
{----------------------------}
nleadOpcodes: set of 0..max_opcode; {instructions that can start an opt.}
nstopOpcodes: set of 0..max_opcode; {instructions not involved in opt.}
nnextspot: npeepRange; {next empty spot in npeep}
npeep: array[npeepRange] of nativeType; {native peephole array}
{I/O files}
{---------}
fname1, fname2: gsosOutString; {file names}
nextSuffix: char; {next suffix character to use}
procedure GenSymbols (sym: ptr; doGlobals: integer); extern;
{ generate the symbol table }
{--------------------------------------------------------------------------}
procedure LabelSearch {lab: integer; len, shift, disp: integer};
{ resolve a label reference }
{ }
{ parameters: }
{ lab - label number }
{ len - # bytes for the generated code }
{ shift - shift factor }
{ disp - disp past the label }
{ }
{ Note 1: maxlabel is reserved for use as the start of the }
{ string space }
{ Note 2: negative length indicates relative branch }
{ Note 3: zero length indicates 2 byte addr -1 }
var
next: labelptr; {work pointer}
begin {LabelSearch}
if labeltab[lab].defined and (len < 0) and (shift = 0) and (disp = 0) then begin
{handle a relative branch to a known disp}
if len = -1 then
CnOut(labeltab[lab].ival - long(pc).lsw - cbufflen + len)
else
CnOut2(labeltab[lab].ival - long(pc).lsw - cbufflen + len);
end {if}
else begin
if lab <> maxlabel then begin
{handle a normal label reference}
Purge; {empty the constant buffer}
if len < 0 then begin
len := -len; {generate a RELEXPR}
Out(238);
Out(len);
Out2(len); Out2(0);
end {if}
else begin
if isJSL then {generate a standard EXPR}
Out(243)
else
Out(235);
if len = 0 then
Out(2)
else
Out(len);
end; {else}
end; {if}
Out(135); {generate a relative offset from the seg. start}
if not labeltab[lab].defined then begin
next := pointer(Malloc(sizeof(labelEntry))); {value unknown: create a reference}
next^.next := labeltab[lab].chain;
labeltab[lab].chain := next;
next^.addr := blkcnt;
Out2(0);
Out2(0);
end {if}
else {labeltab[lab].defined} begin
Out2(labeltab[lab].ival); {value known: write it}
Out2(labeltab[lab].hval);
end; {else}
if len = 0 then begin
Out(129); {subtract 1 from addr}
Out2(1); Out2(0);
Out(2);
len := 2;
end; {if}
if disp <> 0 then begin
Out(129); {add in the displacement}
Out2(disp);
if disp < 0 then
Out2(-1)
else
Out2(0);
Out(1);
end; {if}
if shift <> 0 then begin
Out(129); {shift the address}
Out2(-shift); if (shift > 0) then Out2(-1) else Out2(0);
Out(7);
end; {if}
if lab <> maxlabel then {if not a string, end the expression}
Out(0);
pc := pc+len; {update the pc}
end; {else}
end; {LabelSearch}
procedure UpDate (lab: integer; labelValue: longint);
{ define a label }
{ }
{ parameters: }
{ lab - label number }
{ labelValue - displacement in seg where label is located }
var
next,temp: labelptr; {work pointers}
begin {UpDate}
if labeltab[lab].defined then
Error(cge1)
else begin
{define the label for future references}
with labeltab[lab] do begin
defined := true;
val := labelValue;
next := chain;
end; {with}
{resolve any forward references}
if next <> nil then begin
Purge;
while next <> nil do begin
segdisp := next^.addr;
Out2(long(labelvalue).lsw);
Out2(long(labelvalue).msw);
blkcnt := blkcnt-4;
temp := next;
next := next^.next;
end; {while}
segdisp := blkcnt;
end; {if}
end; {else}
end; {UpDate}
procedure WriteNative (opcode: integer; mode: addressingMode; operand: integer;
name: stringPtr; flags: integer);
{ write a native code instruction to the output file }
{ }
{ parameters: }
{ opcode - native op code }
{ mode - addressing mode }
{ operand - integer operand }
{ name - named operand }
{ flags - operand modifier flags }
label 1;
type
rkind = (k1,k2,k3,k4); {cnv record types}
var
bp: ^byte; {byte pointer}
ch: char; {temp storage for string constants}
cns: realRec; {for converting reals to bytes}
cnv: record {for converting double, real to bytes}
case rkind of
k1: (rval: real;);
k2: (dval: double;);
k3: (qval: longlong);
k4: (ival1,ival2,ival3,ival4: integer;);
end;
count: integer; {number of constants to repeat}
i,j,k: integer; {loop variables}
lsegDisp: longint; {for backtracking while writing the }
{ debugger's symbol table }
lval: longint; {temp storage for long constant}
nptr: stringPtr; {pointer to a name}
sptr: longstringPtr; {pointer to a string constant}
procedure GenImmediate1;
{ generate a one byte immediate operand }
begin {GenImmediate1}
if (flags & stringReference) <> 0 then begin
Purge;
Out(235); Out(1); {one byte expression}
Out(128); {current location ctr}
Out(129); Out2(-16); Out2(-1); {-16}
Out(7); {bit shift}
Out(0); {end of expr}
pc := pc+1;
end {if}
else if (flags & localLab) <> 0 then
LabelSearch(long(name).lsw, 1, ord(odd(flags div shift16))*16, operand)
else if (flags & shift16) <> 0 then
RefName(name, operand, 1, -16)
else
CnOut(operand);
end; {GenImmediate1}
procedure GenImmediate2;
{ generate a two byte immediate operand }
begin {GenImmediate2}
if (flags & stringReference) <> 0 then begin
Purge;
Out(235); Out(2);
LabelSearch(maxLabel, 2, 0, 0);
if operand <> 0 then begin
Out(129);
Out2(operand); if (operand < 0) then Out2(-1) else Out2(0);
Out(1);
end; {if}
if (flags & shift16) <> 0 then begin
Out(129);
Out2(-16); Out2(-1);
Out(7);
end; {if}
Out(0);
end {if}
else if (flags & shift8) <> 0 then
RefName(name, operand, 2, -8)
else if (flags & localLab) <> 0 then
LabelSearch(long(name).lsw, 2, ord(odd(flags div shift16))*16, operand)
else if (flags & shift16) <> 0 then
RefName(name, operand, 2, -16)
else if name = nil then
CnOut2(operand)
else
RefName(name, operand, 2, 0);
end; {GenImmediate2}
procedure DefGlobal (private: integer);
{ define a global label }
{ }
{ parameters: }
{ private - private flag }
var
i: integer; {loop variable}
begin {DefGlobal}
Purge;
Out(230); {global label definition}
Out(ord(name^[0])); {write label name}
for i := 1 to ord(name^[0]) do
Out(ord(name^[i]));
Out2(0); {length attribute}
Out(ord('N')); {type attribute: other directive}
Out(private); {private or global?}
end; {DefGlobal}
function ShiftSize (flags: integer): integer;
{ Determine the shift size specified by flags. }
{ (Positive means right shift, negative means left shift.) }
{ }
{ parameters: }
{ flags - the flags }
begin {ShiftSize}
if (flags & shift8) <> 0 then
ShiftSize := 8
else if (flags & shift16) <> 0 then
ShiftSize := 16
else if (flags & shiftLeft8) <> 0 then
ShiftSize := -8
else
ShiftSize := 0;
end; {ShiftSize}
begin {WriteNative}
{ writeln('WriteNative: ',opcode:4, ', mode=', ord(mode):1,
' operand=', operand:1); {debug}
case mode of
implied:
CnOut(opcode);
immediate: begin
if opcode = d_bmov then
GenImmediate1
else begin
if opcode = m_and_imm then
if not longA then
if operand = 255 then
goto 1;
opcode := opcode & ~asmFlag;
CnOut(opcode);
if opcode = m_pea then
GenImmediate2
else if opcode in
[m_adc_imm,m_and_imm,m_cmp_imm,m_eor_imm,m_lda_imm,m_ora_imm,
m_sbc_imm,m_bit_imm] then
if longA then
GenImmediate2
else
GenImmediate1
else if opcode in [m_rep,m_sep,m_cop] then begin
GenImmediate1;
if opcode = m_rep then begin
if odd(operand div 32) then longA := true;
if odd(operand div 16) then longI := true;
end {if}
else if opcode = m_sep then begin
if odd(operand div 32) then longA := false;
if odd(operand div 16) then longI := false;
end; {else}
end {else}
else
if longI then
GenImmediate2
else
GenImmediate1;
end; {else}
end;
longabs: begin
CnOut(opcode);
isJSL := (opcode & ~asmFlag) = m_jsl; {allow for dynamic segs}
if name = nil then
if odd(flags div toolcall) then begin
CnOut2(0);
CnOut(225);
end {if}
else
LabelSearch(operand, 3, 0, 0)
else
if odd(flags div toolcall) then begin
CnOut2(long(name).lsw);
CnOut(long(name).msw);
end {if}
else
RefName(name, operand, 3, 0);
isJSL := false;
end;
longabsolute: begin
if opcode <> d_dcl then begin
CnOut(opcode);
i := 3;
end {if}
else
i := 4;
if (flags & localLab) <> 0 then
LabelSearch(long(name).lsw, i, 0, operand)
else if (flags & constantOpnd) <> 0 then begin
lval := ord4(name);
CnOut2(long(lval).lsw);
if opcode = d_dcl then
CnOut2(long(lval).msw)
else
CnOut(long(lval).msw);
end {else if}
else if name <> nil then
RefName(name, operand, i, 0)
else begin
CnOut2(operand);
CnOut(0);
if opcode = d_dcl then
CnOut(0);
end; {else}
end;
absolute: begin
if opcode <> d_dcw then
CnOut(opcode);
if (flags & localLab) <> 0 then
LabelSearch(long(name).lsw, 2, 0, operand)
else if name <> nil then
RefName(name, operand, 2, 0)
else if (flags & constantOpnd) <> 0 then
CnOut2(operand)
else
LabelSearch(operand, 2, 0, 0);
end;
direct: begin
if opcode <> d_dcb then
CnOut(opcode);
if (flags & localLab) <> 0 then
LabelSearch(long(name).lsw, 1, 0, operand)
else if name <> nil then
RefName(name, operand, 1, 0)
else
CnOut(operand);
end;
longrelative: begin
CnOut(opcode);
LabelSearch(operand, -2, 0, 0);
end;
relative: begin
CnOut(opcode);
LabelSearch(operand, -1, 0, 0);
end;
gnrLabel:
if name = nil then
UpDate(operand, pc+cbufflen)
else begin
DefGlobal((flags >> 5) & 1);
if operand <> 0 then begin
Out(241);
Out2(operand);
Out2(0);
pc := pc+operand;
end; {if}
end; {else}
gnrSpace:
if operand <> 0 then begin
Out(241);
Out2(operand);
Out2(0);
pc := pc+operand;
end; {if}
gnrConstant: begin
if icptr(name)^.optype = cgString then
count := 1
else
count := icptr(name)^.q;
for i := 1 to count do
case icptr(name)^.optype of
cgByte,cgUByte : CnOut(icptr(name)^.r);
cgWord,cgUWord : CnOut2(icptr(name)^.r);
cgLong,cgULong : begin
lval := icptr(name)^.lval;
CnOut2(long(lval).lsw);
CnOut2(long(lval).msw);
end;
cgQuad,cgUQuad : begin
cnv.qval := icptr(name)^.qval;
CnOut2(cnv.ival1);
CnOut2(cnv.ival2);
CnOut2(cnv.ival3);
CnOut2(cnv.ival4);
end;
cgReal : begin
cnv.rval := icptr(name)^.rval;
CnOut2(cnv.ival1);
CnOut2(cnv.ival2);
end;
cgDouble : begin
cnv.dval := icptr(name)^.rval;
CnOut2(cnv.ival1);
CnOut2(cnv.ival2);
CnOut2(cnv.ival3);
CnOut2(cnv.ival4);
end;
cgComp : begin
cns.itsReal := icptr(name)^.rval;
CnvSC(cns);
for j := 1 to 8 do
CnOut(cns.inCOMP[j]);
end;
cgExtended : begin
cns.itsReal := icptr(name)^.rval;
CnvSX(cns);
for j := 1 to 10 do
CnOut(cns.inSANE[j]);
end;
cgString : begin
if not icptr(name)^.isByteSeq then begin
sptr := icptr(name)^.str;
for j := 1 to sptr^.length do
CnOut(ord(sPtr^.str[j]));
end {if}
else begin
lval := 0;
while lval < icptr(name)^.len do begin
bp := pointer(
ord4(icptr(name)^.data) + lval);
CnOut(bp^);
lval := lval + 1;
end;
end; {else}
end;
ccPointer : begin
if icptr(name)^.lab <> nil then begin
Purge;
Out(235);
Out(4);
Out(131);
pc := pc+4;
nptr := icptr(name)^.lab;
for j := 0 to ord(nptr^[0]) do
Out(ord(nptr^[j]));
lval := icptr(name)^.pVal;
if lval <> 0 then begin
Out(129);
Out2(long(lval).lsw);
Out2(long(lval).msw);
Out(2-icptr(name)^.r);
end; {if}
Out(0);
end {if}
else begin
lval := icptr(name)^.pVal;
if icptr(name)^.r = 1 then
operand := stringSize+long(lval).lsw
else
operand := stringSize-long(lval).lsw;
flags := stringReference;
GenImmediate2;
flags := stringReference+shift16;
GenImmediate2;
sptr := icptr(name)^.pStr;
j := sptr^.length;
if maxString-stringSize >= j then begin
for k := 1 to j do
stringSpace^[k+stringSize] :=
sptr^.str[k];
stringSize := stringSize+j;
end {if}
else
Error(cge3);
end; {else}
end;
otherwise : Error(cge1);
end; {case}
end;
genAddress: begin
if opcode < 256 then {includes opcodes with asmFlag}
CnOut(opcode);
if (flags & stringReference) <> 0 then begin
Purge;
Out(235);
Out(2);
LabelSearch(maxLabel,2,0,0);
if operand <> 0 then begin
Out(129);
Out2(operand);
Out2(0);
Out(1);
end; {if}
if (flags & shift16) <> 0 then begin
Out(129);
Out2(-16);
Out2(-1);
Out(7);
end; {if}
Out(0);
end {if}
else if operand = 0 then begin
CnOut(0);
CnOut(0);
end {else if}
else if (flags & shift16) <> 0 then
if longA then
LabelSearch(operand, 2, 16, 0)
else
LabelSearch(operand, 1, 16, 0)
else if (flags & subtract1) <> 0 then
LabelSearch(operand, 0, ShiftSize(flags), 0)
else
LabelSearch(operand, 2, 0, 0);
end;
special:
if opcode = d_pin then begin
segDisp := 36;
out2(long(pc).lsw+cBuffLen);
blkCnt := blkCnt-2;
segDisp := blkCnt;
end {if}
else if opcode = d_sym then begin
CnOut(m_cop);
CnOut(5);
Purge;
lsegDisp := segDisp+1;
CnOut2(0);
symLength := 0;
GenSymbols(pointer(name), operand);
segDisp := lSegDisp;
out2(symLength);
blkCnt := blkCnt-2;
segDisp := blkCnt;
end {else if}
else {d_wrd}
CnOut2(operand);
otherwise: Error(cge1);
end; {case}
1:
end; {WriteNative}
procedure CheckRegisters(p_opcode: integer; p_mode: addressingMode;
p_operand: integer; p_name: stringPtr; p_flags: integer);
{ write a native code instruction to the output file }
{ }
{ parameters: }
{ p_opcode - native op code }
{ p_mode - addressing mode }
{ p_operand - integer operand }
{ p_name - named operand }
{ p_flags - operand modifier flags }
label 1,2,3;
function NZMatchA: boolean;
{ Are the N and Z flags known to match the value in A? }
{ }
{ Note: Assumes long registers }
begin {NZMatchA}
NZMatchA := lastRegOpcode in
[m_adc_abs,m_adc_dir,m_adc_imm,m_adc_s,m_adc_indl,m_adc_indly,
m_and_abs,m_and_dir,m_and_imm,m_and_s,m_and_indl,m_and_indly,m_asl_a,
m_dea,m_eor_abs,m_eor_dir,m_eor_imm,m_eor_s,m_eor_indl,m_eor_indly,
m_ina,m_lda_abs,m_lda_absx,m_lda_dir,m_lda_dirx,m_lda_imm,m_lda_indl,
m_lda_indly,m_lda_long,m_lda_longx,m_lda_s,m_lsr_a,m_ora_abs,m_ora_dir,
m_ora_dirX,m_ora_imm,m_ora_long,m_ora_longX,m_ora_s,m_ora_indl,
m_ora_indly,m_pla,m_rol_a,m_ror_a,m_sbc_abs,m_sbc_dir,m_sbc_imm,m_sbc_s,
m_sbc_indl,m_sbc_indly,m_tax,m_tay,m_tcd,m_tdc,m_txa,m_tya];
end; {NZMatchA}
begin {CheckRegisters}
case p_opcode of
m_adc_abs,m_adc_dir,m_adc_imm,m_adc_s,m_and_abs,m_and_dir,m_and_imm,
m_and_s,m_asl_a,m_dea,m_eor_abs,m_eor_dir,m_eor_imm,m_eor_s,m_lda_absx,
m_lda_dirx,m_lda_indl,m_lda_indly,m_lda_longx,m_lda_s,m_lsr_a,m_ora_abs,
m_ora_dir,m_ora_dirX,m_ora_imm,m_ora_long,m_ora_longX,m_ora_s,m_pla,
m_sbc_abs,m_sbc_dir,m_sbc_imm,m_sbc_s,m_tdc,m_tsc,m_adc_indl,m_adc_indly,
m_and_indl,m_and_indly,m_ora_indl,m_ora_indly,m_sbc_indl,m_sbc_indly,
m_eor_indl,m_eor_indly,m_rol_a,m_ror_a:
aRegister.condition := regUnknown;
m_ldy_absX,m_ldy_dirX,m_ply:
yRegister.condition := regUnknown;
m_plx:
xRegister.condition := regUnknown;
m_bcc,m_bcs,m_beq,m_bmi,m_bne,m_bpl,m_bvs,
m_pha,m_phb,m_phd,m_php,m_phx,m_phy,m_pei_dir,m_tcs:
goto 3;
m_bra,m_brl,m_clc,m_cmp_abs,m_cmp_dir,m_cmp_imm,m_cmp_s,m_cmp_indl,
m_cmp_indly,m_cpx_imm,m_jml,m_jmp_indX,m_plb,m_rtl,m_rts,m_sec,d_add,d_pin,
m_cpx_abs,m_cpx_dir,m_cmp_dirx,m_plp,m_cop,d_wrd: ;
m_pea: begin
if aRegister.condition = regImmediate then
if aRegister.value = p_operand then
if aRegister.lab = p_name then
if aRegister.flags = p_flags then
if longA then begin
p_opcode := m_pha;
p_mode := implied;
goto 2;
end; {if}
if longI then begin
if xRegister.condition = regImmediate then
if xRegister.value = p_operand then
if xRegister.lab = p_name then
if xRegister.flags = p_flags then begin
p_opcode := m_phx;
p_mode := implied;
goto 2;
end; {if}
if yRegister.condition = regImmediate then
if yRegister.value = p_operand then
if yRegister.lab = p_name then
if yRegister.flags = p_flags then begin
p_opcode := m_phy;
p_mode := implied;
goto 2;
end; {if}
end; {if}
goto 3;
end;
m_sta_s: begin
if aRegister.condition = regLocal then
aRegister.condition := regUnknown;
if xRegister.condition = regLocal then
xRegister.condition := regUnknown;
if yRegister.condition = regLocal then
yRegister.condition := regUnknown;
goto 3;
end;
m_pld,m_tcd: begin
if aRegister.condition = regLocal then
aRegister.condition := regUnknown;
if xRegister.condition = regLocal then
xRegister.condition := regUnknown;
if yRegister.condition = regLocal then
yRegister.condition := regUnknown;
end;
m_sta_indl,m_sta_indlY: begin
if aRegister.condition <> regImmediate then
aRegister.condition := regUnknown;
if xRegister.condition <> regImmediate then
xRegister.condition := regUnknown;
if yRegister.condition <> regImmediate then
yRegister.condition := regUnknown;
goto 3;
end;
m_sta_absX,m_stz_absX,m_sta_longX: begin
if aRegister.condition = regAbsolute then
if aRegister.lab = p_name then
aRegister.condition := regUnknown;
if xRegister.condition = regAbsolute then
if xRegister.lab = p_name then
xRegister.condition := regUnknown;
if yRegister.condition = regAbsolute then
if yRegister.lab = p_name then
yRegister.condition := regUnknown;
goto 3;
end;
m_dec_abs,m_inc_abs,m_tsb_abs: begin
if aRegister.condition = regAbsolute then
if aRegister.lab = p_name then
if aRegister.value = p_operand then
aRegister.condition := regUnknown;
if xRegister.condition = regAbsolute then
if xRegister.lab = p_name then
if xRegister.value = p_operand then
xRegister.condition := regUnknown;
if yRegister.condition = regAbsolute then
if yRegister.lab = p_name then
if yRegister.value = p_operand then
yRegister.condition := regUnknown;
end;
m_sta_abs,m_stx_abs,m_sty_abs,m_sta_long,m_stz_abs: begin
if aRegister.condition = regAbsolute then
if aRegister.lab = p_name then
if aRegister.value = p_operand then
if not (p_opcode in [m_sta_abs,m_sta_long]) then
aRegister.condition := regUnknown;
if xRegister.condition = regAbsolute then
if xRegister.lab = p_name then
if xRegister.value = p_operand then
if p_opcode <> m_stx_abs then
xRegister.condition := regUnknown;
if yRegister.condition = regAbsolute then
if yRegister.lab = p_name then
if yRegister.value = p_operand then
if p_opcode <> m_sty_abs then
yRegister.condition := regUnknown;
goto 3;
end;
m_dec_dir,m_inc_dir,m_tsb_dir: begin
if aRegister.condition = regLocal then
if aRegister.value = p_operand then
aRegister.condition := regUnknown;
if xRegister.condition = regLocal then
if xRegister.value = p_operand then
xRegister.condition := regUnknown;
if yRegister.condition = regLocal then
if yRegister.value = p_operand then
yRegister.condition := regUnknown;
end;
m_sta_dir,m_stx_dir,m_sty_dir,m_stz_dir: begin
if aRegister.condition = regLocal then
if aRegister.value = p_operand then
if p_opcode <> m_sta_dir then
aRegister.condition := regUnknown;
if xRegister.condition = regLocal then
if xRegister.value = p_operand then
if p_opcode <> m_stx_dir then
xRegister.condition := regUnknown;
if yRegister.condition = regLocal then
if yRegister.value = p_operand then
if p_opcode <> m_sty_dir then
yRegister.condition := regUnknown;
goto 3;
end;
m_dec_dirX,m_inc_dirX: begin
if aRegister.condition = regLocal then
if aRegister.value >= p_operand-1 then
aRegister.condition := regUnknown;
if xRegister.condition = regLocal then
if xRegister.value >= p_operand-1 then
xRegister.condition := regUnknown;
if yRegister.condition = regLocal then
if yRegister.value >= p_operand-1 then
yRegister.condition := regUnknown;
end;
m_sta_dirX,m_sty_dirX,m_stz_dirX: begin
if aRegister.condition = regLocal then
if aRegister.value >= p_operand-1 then
aRegister.condition := regUnknown;
if xRegister.condition = regLocal then
if xRegister.value >= p_operand-1 then
xRegister.condition := regUnknown;
if yRegister.condition = regLocal then
if yRegister.value >= p_operand-1 then
yRegister.condition := regUnknown;
goto 3;
end;
m_dex:
if xRegister.condition = regImmediate then
xRegister.value := xRegister.value-1
else
xRegister.condition := regUnknown;
m_dey:
if yRegister.condition = regImmediate then
yRegister.value := yRegister.value-1
else
yRegister.condition := regUnknown;
m_ina:
if aRegister.condition = regImmediate then
aRegister.value := aRegister.value+1
else
aRegister.condition := regUnknown;
m_inx:
if xRegister.condition = regImmediate then
xRegister.value := xRegister.value+1
else
xRegister.condition := regUnknown;
m_iny:
if yRegister.condition = regImmediate then
yRegister.value := yRegister.value+1
else
yRegister.condition := regUnknown;
otherwise,
m_jsl,m_mvn,m_rep,m_sep,d_lab,d_end,d_bmov,d_cns: begin
aRegister.condition := regUnknown;
xRegister.condition := regUnknown;
yRegister.condition := regUnknown;
end;
m_lda_abs,m_lda_long: begin
if (aRegister.condition = regAbsolute) and
(aRegister.value = p_operand) and
(aRegister.lab = p_name) then
goto 1
else if longA = longI then begin
if (xRegister.condition = regAbsolute) and
(xRegister.value = p_operand) and
(xRegister.lab = p_name) then begin
p_opcode := m_txa;
p_mode := implied;
aRegister := xRegister;
goto 2;
end {if}
else if (yRegister.condition = regAbsolute) and
(yRegister.value = p_operand) and
(yRegister.lab = p_name) then begin
p_opcode := m_tya;
p_mode := implied;
aRegister := yRegister;
goto 2;
end; {else if}
end;
aRegister.condition := regAbsolute;
aRegister.value := p_operand;
aRegister.lab := p_name;
aRegister.flags := p_flags;
end;
m_lda_dir: begin
if (aRegister.condition = regLocal) and
(aRegister.value = p_operand) then
goto 1
else if longA = longI then begin
if (xRegister.condition = regLocal) and
(xRegister.value = p_operand) then begin
p_opcode := m_txa;
p_mode := implied;
aRegister := xRegister;
goto 2;
end {if}
else if (yRegister.condition = regLocal) and
(yRegister.value = p_operand) then begin
p_opcode := m_tya;
p_mode := implied;
aRegister := yRegister;
goto 2;
end; {else if}
end; {else if}
aRegister.condition := regLocal;
aRegister.value := p_operand;
aRegister.flags := p_flags;
end;
m_lda_imm: begin
if (aRegister.condition = regImmediate) and
(aRegister.value = p_operand) and
(aRegister.lab = p_name) and
(aRegister.flags = p_flags) then
goto 1
else if longA = longI then begin
if (xRegister.condition = regImmediate) and
(xRegister.value = p_operand) and
(xRegister.lab = p_name) and
(xRegister.flags = p_flags) then begin
p_opcode := m_txa;
p_mode := implied;
aRegister := xRegister;
goto 2;
end {if}
else if (yRegister.condition = regImmediate) and
(yRegister.value = p_operand) and
(yRegister.lab = p_name) and
(yRegister.flags = p_flags) then begin
p_opcode := m_tya;
p_mode := implied;
aRegister := yRegister;
goto 2;
end; {else if}
end; {else if}
if (aRegister.condition = regImmediate) and
(aRegister.lab = p_name) and
(aRegister.flags = p_flags) then
if aRegister.value = (p_operand + 1) then begin
p_opcode := m_dea;
p_mode := implied;
aRegister.value := p_operand;
goto 2;
end {if}
else if aRegister.value = (p_operand - 1) then begin
p_opcode := m_ina;
p_mode := implied;
aRegister.value := p_operand;
goto 2;
end; {else if}
aRegister.condition := regImmediate;
aRegister.value := p_operand;
aRegister.flags := p_flags;
aRegister.lab := p_name;
end;
m_ldx_abs: begin
if (xRegister.condition = regAbsolute) and
(xRegister.value = p_operand) and
(xRegister.lab = p_name) then
goto 1
else if (aRegister.condition = regAbsolute) and
(aRegister.value = p_operand) and
(aRegister.lab = p_name) and
(longA = longI) then begin
p_opcode := m_tax;
p_mode := implied;
xRegister := aRegister;
end {else if}
else if (yRegister.condition = regAbsolute) and
(yRegister.value = p_operand) and
(yRegister.lab = p_name) then begin
p_opcode := m_tyx;
p_mode := implied;
xRegister := yRegister;
end {else if}
else begin
xRegister.condition := regAbsolute;
xRegister.value := p_operand;
xRegister.lab := p_name;
xRegister.flags := p_flags;
end; {else}
end;
m_ldx_dir: begin
if (xRegister.condition = regLocal) and
(xRegister.value = p_operand) then
goto 1
else if (aRegister.condition = regLocal) and
(aRegister.value = p_operand) and
(longA = longI) then begin
p_opcode := m_tax;
p_mode := implied;
xRegister := aRegister;
end {else if}
else if (yRegister.condition = regLocal) and
(yRegister.value = p_operand) then begin
p_opcode := m_tyx;
p_mode := implied;
xRegister := yRegister;
end {else if}
else begin
xRegister.condition := regLocal;
xRegister.value := p_operand;
xRegister.flags := p_flags;
end; {else}
end;
m_ldx_imm: begin
if (xRegister.condition = regImmediate) and
(xRegister.value = p_operand) and
(xRegister.lab = p_name) and
(xRegister.flags = p_flags) then
goto 1
else if (aRegister.condition = regImmediate) and
(aRegister.value = p_operand) and
(longA = longI) and
(aRegister.lab = p_name) and
(aRegister.flags = p_flags) then begin
p_opcode := m_tax;
p_mode := implied;
xRegister := aRegister;
end {else}
else if (yRegister.condition = regImmediate) and
(yRegister.value = p_operand) and
(yRegister.lab = p_name) and
(yRegister.flags = p_flags) then begin
p_opcode := m_tyx;
p_mode := implied;
xRegister := yRegister;
end {else if}
else begin
if (xRegister.condition = regImmediate) and
(xRegister.lab = p_name) and
(xRegister.flags = p_flags) then
if xRegister.value = (p_operand + 1) then begin
p_opcode := m_dex;
p_mode := implied;
xRegister.value := p_operand;
goto 2;
end {if}
else if xRegister.value = (p_operand - 1) then begin
p_opcode := m_inx;
p_mode := implied;
xRegister.value := p_operand;
goto 2;
end; {else if}
xRegister.condition := regImmediate;
xRegister.value := p_operand;
xRegister.flags := p_flags;
xRegister.lab := p_name;
end; {else}
end;
m_ldy_abs: begin
if (yRegister.condition = regAbsolute) and
(yRegister.value = p_operand) and
(yRegister.lab = p_name) then
goto 1
else if (aRegister.condition = regAbsolute) and
(aRegister.value = p_operand) and
(aRegister.lab = p_name) and
(longA = longI) then begin
p_opcode := m_tay;
p_mode := implied;
yRegister := aRegister;
end {else if}
else if (xRegister.condition = regAbsolute) and
(xRegister.value = p_operand) and
(xRegister.lab = p_name) then begin
p_opcode := m_txy;
p_mode := implied;
yRegister := xRegister;
end {else if}
else begin
yRegister.condition := regAbsolute;
yRegister.value := p_operand;
yRegister.lab := p_name;
yRegister.flags := p_flags;
end; {else}
end;
m_ldy_dir: begin
if (yRegister.condition = regLocal) and
(yRegister.value = p_operand) then
goto 1
else if (aRegister.condition = regLocal) and
(aRegister.value = p_operand) and
(longA = longI) then begin
p_opcode := m_tay;
p_mode := implied;
yRegister := aRegister;
end {else if}
else if (xRegister.condition = regLocal) and
(xRegister.value = p_operand) then begin
p_opcode := m_txy;
p_mode := implied;
yRegister := xRegister;
end {else if}
else begin
yRegister.condition := regLocal;
yRegister.value := p_operand;
yRegister.flags := p_flags;
end; {else}
end;
m_ldy_imm: begin
if (yRegister.condition = regImmediate) and
(yRegister.value = p_operand) and
(yRegister.lab = p_name) and
(yRegister.flags = p_flags) then
goto 1
else if (aRegister.condition = regImmediate) and
(aRegister.value = p_operand) and
(aRegister.flags = p_flags) and
(aRegister.lab = p_name) and
(longA = longI) then begin
p_opcode := m_tay;
p_mode := implied;
yRegister := aRegister;
end {else if}
else if (xRegister.condition = regImmediate) and
(xRegister.value = p_operand) and
(xRegister.lab = p_name) and
(xRegister.flags = p_flags) then begin
p_opcode := m_txy;
p_mode := implied;
yRegister := xRegister;
end {else if}
else begin
if (yRegister.condition = regImmediate) and
(yRegister.lab = p_name) and
(yRegister.flags = p_flags) then
if yRegister.value = (p_operand + 1) then begin
p_opcode := m_dey;
p_mode := implied;
yRegister.value := p_operand;
goto 2;
end {if}
else if yRegister.value = (p_operand - 1) then begin
p_opcode := m_iny;
p_mode := implied;
yRegister.value := p_operand;
goto 2;
end; {else if}
yRegister.condition := regImmediate;
yRegister.value := p_operand;
yRegister.flags := p_flags;
yRegister.lab := p_name;
end; {else}
end;
m_tax: begin
if (p_flags & forFlags) <> 0 then begin
if longA then
if longI then
if NZMatchA then
goto 1;
end {if}
else if aRegister.condition <> regUnknown then
if aRegister.condition = xRegister.condition then
if aRegister.value = xRegister.value then
if aRegister.flags = xRegister.flags then
if aRegister.condition <> regAbsolute then
goto 1
else if aRegister.lab = xRegister.lab then
goto 1;
xRegister := aRegister;
end;
m_tay: begin
if (p_flags & forFlags) <> 0 then begin
if longA then
if longI then
if NZMatchA then
goto 1;
end {if}
else if aRegister.condition <> regUnknown then
if aRegister.condition = yRegister.condition then
if aRegister.value = yRegister.value then
if aRegister.flags = yRegister.flags then
if aRegister.condition <> regAbsolute then
goto 1
else if aRegister.lab = yRegister.lab then
goto 1;
yRegister := aRegister;
end;
m_txa: begin
if xRegister.condition <> regUnknown then
if xRegister.condition = aRegister.condition then
if xRegister.value = aRegister.value then
if xRegister.flags = aRegister.flags then
if xRegister.condition <> regAbsolute then
goto 1
else if xRegister.lab = aRegister.lab then
goto 1;
aRegister := xRegister;
end;
m_txy: begin
if xRegister.condition <> regUnknown then
if xRegister.condition = yRegister.condition then
if xRegister.value = yRegister.value then
if xRegister.flags = yRegister.flags then
if xRegister.condition <> regAbsolute then
goto 1
else if xRegister.lab = yRegister.lab then
goto 1;
yRegister := xRegister;
end;
m_tya: begin
if yRegister.condition <> regUnknown then
if yRegister.condition = aRegister.condition then
if yRegister.value = aRegister.value then
if yRegister.flags = aRegister.flags then
if yRegister.condition <> regAbsolute then
goto 1
else if yRegister.lab = aRegister.lab then
goto 1;
aRegister := yRegister;
end;
m_tyx: begin
if yRegister.condition <> regUnknown then
if yRegister.condition = xRegister.condition then
if yRegister.value = xRegister.value then
if yRegister.flags = xRegister.flags then
if yRegister.condition <> regAbsolute then
goto 1
else if yRegister.lab = xRegister.lab then
goto 1;
xRegister := yRegister;
end;
end; {case}
2: {emit the instruction normally}
lastRegOpcode := p_opcode;
3: {branch here for instructions that}
{do not modify A/X/Y or flags }
WriteNative(p_opcode, p_mode, p_operand, p_name, p_flags);
1: {branch here to skip the instruction}
end; {CheckRegisters}
procedure Remove (ns: integer); extern;
{ Remove the instruction ns from the peephole array }
{ }
{ parameters: }
{ ns - index of the instruction to remove }
function Short (n, lab: integer): boolean; extern;
{ see if a label is within range of a one-byte relative branch }
{ }
{ parameters: }
{ n - index to branch instruction }
{ lab - label number }
{--------------------------------------------------------------------------}
procedure EndSeg;
{ close out the current segment }
var
i: integer;
begin {EndSeg}
Purge; {dump constant buffer}
if stringsize <> 0 then begin {define string space}
UpDate(maxLabel, pc); {define the local label for the string space}
for i := 1 to stringsize do
CnOut(ord(stringspace^[i]));
Purge;
end; {if}
Out(0); {end the segment}
segDisp := 8; {update header}
Out2(long(pc).lsw);
Out2(long(pc).msw);
if pc > $00010000 then
if currentSegment <> '~ARRAYS ' then
Error(184);
blkcnt := blkcnt-4; {purge the segment to disk}
segDisp := blkcnt;
CloseSeg;
end; {EndSeg}
procedure GenNative {p_opcode: integer; p_mode: addressingMode;
p_operand: integer; p_name: stringPtr; p_flags: integer};
{ write a native code instruction to the output file }
{ }
{ parameters: }
{ p_opcode - native op code }
{ p_mode - addressing mode }
{ p_operand - integer operand }
{ p_name - named operand }
{ p_flags - operand modifier flags }
var
done: boolean; {loop termination}
llongA: boolean; {for tracking A size during opt.}
i: integer; {index}
op: integer; {temp storage for opcode}
procedure Purge;
{ Empty the peephole array }
begin {Purge}
while nnextSpot > 1 do begin
if registers then
CheckRegisters(npeep[1].opcode, npeep[1].mode, npeep[1].operand,
npeep[1].name, npeep[1].flags)
else
WriteNative(npeep[1].opcode, npeep[1].mode, npeep[1].operand,
npeep[1].name, npeep[1].flags);
Remove(1);
end; {while}
end; {Purge}
procedure Optimize(ns: integer; longA: boolean);
{ Optimize the instruction starting at ns }
{ }
{ parameters: }
{ ns - index of instruction to check for optimization }
{ longA - is the accumulator long? }
label 1;
var
tn: nativeType; {temp operation}
function ASafe (ns: integer): boolean;
{ See if it is safe to skip loading the A register }
{ }
{ parameters: }
{ ns - starting index }
label 1;
var
i: integer; {loop variable}
opcode: integer; {copy of current op code}
begin {ASafe}
ASafe := false;
for i := ns to nnextSpot-1 do begin
opcode := npeep[i].opcode;
if opcode in
[m_bcc,m_bcs,m_beq,m_bmi,m_bne,m_bpl,m_bra,m_brl,m_bvs,m_jml,
m_jmp_indX,m_jsl,m_lda_abs,m_lda_absx,m_lda_dir,m_lda_dirx,
m_lda_imm,m_lda_indl,m_lda_indly,m_lda_long,m_lda_longx,m_lda_s,
m_pla,m_rtl,m_rts,m_tdc,m_txa,m_tya,m_tsc,d_end,d_bmov,
d_add,d_pin,d_wrd,d_sym,d_cns] then begin
ASafe := true;
goto 1;
end {if}
else if not (opcode in
[m_clc,m_cop,m_cpx_abs,m_cpx_dir,m_cpx_imm,m_dec_abs,m_dec_absX,
m_dec_dir,m_dec_dirX,m_dex,m_dey,m_inc_abs,m_inc_absX,m_inc_dir,
m_inc_dirX,m_inx,m_iny,m_ldx_abs,m_ldx_dir,m_ldx_imm,m_ldy_abs,
m_ldy_absX,m_ldy_dir,m_ldy_dirX,m_ldy_imm,m_pea,m_pei_dir,m_phb,
m_phd,m_phx,m_phy,m_php,m_plb,m_pld,m_plx,m_ply,m_plp,m_rep,
m_sec,m_sep,m_stx_dir,m_stx_abs,m_sty_abs,m_sty_dir,m_sty_dirX,
m_stz_abs,m_stz_absX,m_stz_dir,m_stz_dirX,m_tsx,m_txs,m_txy,
m_tyx,d_lab]) then
goto 1;
end; {for}
1:
end; {ASafe}
function SignExtension (ns: integer): boolean;
{ See if the pattern is a sign extension }
{ }
{ Parameters: }
{ ns - start of suspected pattern }
{ }
{ Returns: true for a sign extension, else false }
begin {SignExtension}
SignExtension := false;
if npeep[ns].opcode = m_ldx_imm then
if npeep[ns].operand = 0 then
if npeep[ns+1].opcode = m_tay then
if npeep[ns+2].opcode = m_bpl then
if npeep[ns+3].opcode = m_dex then
SignExtension := true;
end; {SignExtension}
begin {Optimize}
with npeep[ns] do
case opcode of
m_and_imm:
if npeep[ns+1].opcode = m_and_imm then begin
operand := operand & npeep[ns+1].operand;
Remove(ns+1);
end; {if}
m_eor_imm:
if npeep[ns+1].opcode = m_eor_imm then begin
operand := operand ! npeep[ns+1].operand;
Remove(ns+1);
end; {if}
m_ora_imm:
if npeep[ns+1].opcode = m_ora_imm then begin
operand := operand | npeep[ns+1].operand;
Remove(ns+1);
end; {if}
m_asl_a:
if npeep[ns+1].opcode = m_tay then
if npeep[ns+2].opcode = m_iny then
if npeep[ns+3].opcode = m_iny then begin
opcode := m_ina;
npeep[ns+1].opcode := m_asl_a;
npeep[ns+2].opcode := m_tay;
Remove(ns+3);
end; {if}
m_bcs,m_beq,m_bne,m_bmi,m_bpl,m_bcc:
if npeep[ns+2].opcode = d_lab then
if npeep[ns+2].operand = operand then
if npeep[ns+1].opcode = m_brl then begin
if Short(ns,npeep[ns+1].operand) then begin
operand := npeep[ns+1].operand;
Remove(ns+1);
if opcode = m_bcs then
opcode := m_bcc
else if opcode = m_beq then
opcode := m_bne
else if opcode = m_bne then
opcode := m_beq
else if opcode = m_bmi then
opcode := m_bpl
else if opcode = m_bcc then
opcode := m_bcs
else
opcode := m_bmi;
end; {if}
end {if m_brl}
else if npeep[ns+1].opcode = m_bra then begin
operand := npeep[ns+1].operand;
Remove(ns+1); Remove(ns+1);
if opcode = m_bcs then
opcode := m_bcc
else if opcode = m_beq then
opcode := m_bne
else if opcode = m_bne then
opcode := m_beq
else if opcode = m_bmi then
opcode := m_bpl
else if opcode = m_bcc then
opcode := m_bcs
else
opcode := m_bmi;
end; {else if m_bra}
m_brl:
if Short(ns,operand) then begin
opcode := m_bra;
mode := relative;
didOne := true;
end; {if}
m_bvs:
if npeep[ns+2].opcode = d_lab then
if npeep[ns+2].operand = operand then
if npeep[ns+1].opcode = m_bmi then
if npeep[ns+4].opcode = d_lab then
if npeep[ns+1].operand = npeep[ns+4].operand then
if npeep[ns+3].opcode = m_brl then
if Short(ns,npeep[ns+3].operand) then
if Short(ns+1,npeep[ns+3].operand) then begin
operand := npeep[ns+3].operand;
npeep[ns+1].operand := npeep[ns+3].operand;
npeep[ns+1].opcode := m_bpl;
Remove(ns+3);
end; {if}
m_dec_abs:
if npeep[ns+1].opcode = m_lda_abs then
if name^ = npeep[ns+1].name^ then
if npeep[ns+2].opcode = m_beq then
Remove(ns+1);
m_lda_abs:
if npeep[ns+1].opcode = m_clc then begin
if npeep[ns+2].opcode = m_adc_abs then
if operand = npeep[ns+2].operand then
if name = npeep[ns+2].name then
if not rangeCheck then begin
npeep[ns+1].opcode := m_asl_a;
Remove(ns+2);
end; {if}
end {if}
else if npeep[ns+1].opcode = m_dea then begin
if npeep[ns+2].opcode = m_tax then begin
opcode := m_ldx_abs;
npeep[ns+1].opcode := m_dex;
Remove(ns+2);
end; {if}
end {else if}
else if npeep[ns+2].opcode = m_sta_abs then begin
if npeep[ns+1].opcode in [m_ora_dir,m_ora_abs,m_ora_dirX,
m_ora_imm,m_ora_longX,m_ora_s] then
if operand = npeep[ns+2].operand then
if name = npeep[ns+2].name then begin
npeep[ns+1].opcode := npeep[ns+1].opcode + $00A0;
npeep[ns+2].opcode := m_tsb_abs;
Remove(ns);
end; {if}
end {else if}
else if SignExtension(ns+1) then begin
npeep[ns+2] := npeep[ns];
Remove(ns);
end {else if}
else if npeep[ns+1].opcode = m_xba then
if npeep[ns+2].opcode = m_and_imm then
if npeep[ns+2].operand = $00FF then begin
operand := operand+1;
Remove(ns+1);
end; {if}
m_lda_dir:
if npeep[ns+1].opcode = m_clc then begin
if npeep[ns+2].opcode = m_adc_dir then
if operand = npeep[ns+2].operand then
if not rangeCheck then begin
npeep[ns+1].opcode := m_asl_a;
Remove(ns+2);
end; {if}
end
else if npeep[ns+1].opcode = m_dea then begin
if npeep[ns+2].opcode = m_tax then begin
opcode := m_ldx_dir;
npeep[ns+1].opcode := m_dex;
Remove(ns+2);
end; {if}
end {else if}
else if npeep[ns+1].opcode = m_pha then begin
if longA then begin
opcode := m_pei_dir;
Remove(ns+1);
end {if}
end {else if}
else if npeep[ns+2].opcode = m_sta_dir then begin
if npeep[ns+1].opcode in [m_ora_dir,m_ora_abs,m_ora_dirX,
m_ora_imm,m_ora_longX,m_ora_s] then
if operand = npeep[ns+2].operand then begin
npeep[ns+1].opcode := npeep[ns+1].opcode + $00A0;
npeep[ns+2].opcode := m_tsb_dir;
Remove(ns);
end {if}
end {else if}
else if SignExtension(ns+1) then begin
npeep[ns+2] := npeep[ns];
Remove(ns);
end {else if}
else if npeep[ns+1].opcode = m_xba then begin
if npeep[ns+2].opcode = m_and_imm then
if npeep[ns+2].operand = $00FF then begin
operand := operand+1;
Remove(ns+1);
end {if}
end {else if}
else if npeep[ns+1].opcode = m_tay then
if npeep[ns+2].opcode = m_lda_dir then begin
opcode := m_ldy_dir;
Remove(ns+1);
end {if}
else if npeep[ns+2].opcode = m_pld then
if npeep[ns+3].opcode = m_tsc then begin
opcode := m_ldy_dir;
Remove(ns+1);
end; {if}
m_ldx_dir:
if npeep[ns+1].opcode = m_txs then {optimize stack repair code}
if npeep[ns+2].opcode = m_tsx then begin
if npeep[ns+3].opcode = m_stx_dir then
if npeep[ns+3].operand = npeep[ns].operand then begin
Remove(ns+2);
Remove(ns+2);
end; {if}
end {if}
else if npeep[ns+2].opcode in
[m_sta_dir,m_sta_abs,m_sta_long,m_sta_indl,m_tyx] then begin
if (npeep[ns+2].opcode <> m_sta_dir)
or (npeep[ns+2].operand <> npeep[ns].operand) then
if npeep[ns+3].opcode = m_tsx then
if npeep[ns+4].opcode = m_stx_dir then
if npeep[ns+4].operand = npeep[ns].operand then begin
Remove(ns+3);
Remove(ns+3);
if npeep[ns+2].opcode = m_tyx then
Remove(ns+2);
end; {if}
end {else if}
else if npeep[ns+2].opcode = m_tsc then begin
npeep[ns].opcode := m_lda_dir;
npeep[ns+1].opcode := m_tcs;
Remove(ns+2);
end; {else if}
m_pei_dir:
if npeep[ns+1].opcode = m_pla then begin
opcode := m_lda_dir;
Remove(ns+1);
end; {if}
m_lda_imm:
if npeep[ns+1].opcode = m_pha then
if ASafe(ns+2) then
if longA then begin
opcode := m_pea;
Remove(ns+1);
end; {if}
m_ldx_imm:
if npeep[ns+1].opcode = m_lda_imm then
if npeep[ns+2].opcode = m_phx then
if npeep[ns+3].opcode = m_pha then begin
opcode := m_pea;
npeep[ns+1].opcode := m_pea;
Remove(ns+2);
Remove(ns+2);
end; {if}
m_ldy_imm:
if npeep[ns+1].opcode = m_sep then
if npeep[ns+1].operand = 32 then begin
didOne := true;
tn := npeep[ns];
npeep[ns] := npeep[ns+1];
npeep[ns+1] := tn;
end; {if}
m_ora_abs:
if npeep[ns+1].opcode = m_sta_abs then
if operand = npeep[ns+1].operand then
if name = npeep[ns+1].name then begin
opcode := m_tsb_abs;
Remove(ns+1);
end; {if}
m_ora_dir:
if npeep[ns+1].opcode = m_sta_dir then
if operand = npeep[ns+1].operand then begin
opcode := m_tsb_dir;
Remove(ns+1);
end; {if}
m_pea:
if npeep[ns+1].opcode = m_pla then begin
opcode := m_lda_imm;
Remove(ns+1);
end; {if}
m_sta_abs:
if npeep[ns+1].opcode = m_lda_abs then
if operand = npeep[ns+1].operand then
if name = npeep[ns+1].name then
if not (npeep[ns+2].opcode in
[m_bcc,m_bcs,m_beq,m_bmi,m_bne,m_bpl,m_bvs]) then
Remove(ns+1);
m_sta_dir:
if npeep[ns+1].opcode = m_lda_dir then
if operand = npeep[ns+1].operand then
if not (npeep[ns+2].opcode in
[m_bcc,m_bcs,m_beq,m_bmi,m_bne,m_bpl,m_bvs]) then
Remove(ns+1);
m_plb:
if npeep[ns+1].opcode = m_phb then begin
Remove(ns);
Remove(ns);
end; {if}
{disabled - can generate bad code if the x value is used}
{m_plx:
if npeep[ns+1].opcode = m_pha then begin
opcode := m_sta_s;
mode := direct;
operand := 1;
Remove(ns+1);
end; {if}
m_tax:
if npeep[ns+1].opcode = m_phx then begin
Remove(ns+1);
opcode := m_pha;
end {if}
else if npeep[ns+1].opcode = m_txa then begin
if not (npeep[ns+2].opcode in
[m_bcc,m_bcs,m_beq,m_bmi,m_bne,m_bpl,m_bvs]) then begin
Remove(ns);
Remove(ns);
end; {if}
end {else if}
else if npeep[ns+1].opcode = m_dey then
if npeep[ns+2].opcode = m_dey then
if npeep[ns+3].opcode = m_lda_indly then
if npeep[ns+4].opcode = m_stx_dir then
if (npeep[ns+4].operand - npeep[ns+3].operand < -1)
or (npeep[ns+4].operand - npeep[ns+3].operand > 2)
then begin
npeep[ns] := npeep[ns+4];
opcode := m_sta_dir;
Remove(ns+4);
end; {if}
m_tya:
if npeep[ns+1].opcode = m_sta_dir then begin
if ASafe(ns+2) then begin
npeep[ns+1].opcode := m_sty_dir;
Remove(ns);
end; {if}
end {if}
else if npeep[ns+1].opcode = m_sta_abs then begin
if ASafe(ns+2) then begin
npeep[ns+1].opcode := m_sty_abs;
Remove(ns);
end; {if}
end; {else if}
m_tyx:
if npeep[ns+1].opcode = m_phx then begin
Remove(ns+1);
opcode := m_phy;
end; {if}
m_pha:
if npeep[ns+1].opcode = m_pla then begin
Remove(ns);
Remove(ns);
end {if}
else if npeep[ns+1].opcode in [m_ldx_abs,m_ldx_dir] then
if npeep[ns+2].opcode = m_pla then begin
Remove(ns+2);
Remove(ns);
end; {if}
m_phy:
if npeep[ns+1].opcode = m_ply then begin
Remove(ns);
Remove(ns);
end; {if}
m_rep:
if npeep[ns+1].opcode = m_sep then
if npeep[ns].operand = npeep[ns+1].operand then begin
Remove(ns);
Remove(ns);
end; {if}
{ kws }
{ stz $xx, stz $xx }
m_stz_abs, m_stz_absX:
if npeep[ns].opcode = npeep[ns+1].opcode then
if npeep[ns].operand = npeep[ns+1].operand then
if npeep[ns].name = npeep[ns+1].name then
if not volatile then
Remove(ns+1);
m_stz_dir, m_stz_dirX:
if npeep[ns].opcode = npeep[ns+1].opcode then
if npeep[ns].operand = npeep[ns+1].operand then
if not volatile then
Remove(ns+1);
m_tcd:
if npeep[ns+1].opcode = m_tdc then
Remove(ns+1)
else if npeep[ns+1].opcode in [m_pea,m_stz_dir,m_stz_abs] then
if npeep[ns+2].opcode = m_tdc then
Remove(ns+2);
m_tcs:
if npeep[ns+1].opcode = m_tsx then
if npeep[ns+2].opcode = m_stx_dir then begin
npeep[ns+2].opcode := m_sta_dir;
Remove(ns+1);
end; {if}
m_tsx:
if npeep[ns+1].opcode = m_stx_dir then
if npeep[ns+2].opcode = m_pei_dir then
if npeep[ns+3].opcode = m_tsx then
if npeep[ns+4].opcode = m_stx_dir then
if npeep[ns+1].operand = npeep[ns+2].operand then
if npeep[ns+1].operand = npeep[ns+4].operand then
begin
npeep[ns+1].opcode := m_phx;
npeep[ns+1].mode := implied;
Remove(ns+2);
end; {if}
{extra explicit cases to ensure this case statement uses a jump table}
m_rtl,m_rts,m_jml,m_jsl,m_mvn,m_plp,m_pld,m_txs,
otherwise: ;
end; {case}
1:
end; {Optimize}
begin {GenNative}
{ writeln('GenNative: ',p_opcode:4, ', mode=', ord(p_mode):1,
' operand=', p_operand:1); {debug}
if npeephole then begin
if (nnextspot = 1) and not (p_opcode in nleadOpcodes) then begin
if p_opcode <> d_end then
if registers then
CheckRegisters(p_opcode, p_mode, p_operand, p_name, p_flags)
else
WriteNative(p_opcode, p_mode, p_operand, p_name, p_flags);
end {if}
else if p_opcode in nstopOpcodes then begin
repeat
didOne := false;
i := 1;
llongA := longA;
while i < nnextSpot-nMaxPeep do begin
op := npeep[i].opcode;
if op = m_sep then begin
if npeep[i].operand & $20 <> 0 then
llongA := false;
end {if}
else if op = m_rep then begin
if npeep[i].operand & $20 <> 0 then
llongA := true;
end; {else}
Optimize(i,llongA);
i := i+1;
end; {while}
until not didone;
Purge;
if p_opcode <> d_end then
if registers then
CheckRegisters(p_opcode, p_mode, p_operand, p_name, p_flags)
else
WriteNative(p_opcode, p_mode, p_operand, p_name, p_flags);
end {else if}
else if nnextSpot = npeepSize then begin
repeat
didOne := false;
i := 1;
llongA := longA;
while i < nnextSpot-nMaxPeep do begin
op := npeep[i].opcode;
if op = m_sep then begin
if npeep[i].operand & $20 <> 0 then
llongA := false;
end {if}
else if op = m_rep then begin
if npeep[i].operand & $20 <> 0 then
llongA := true;
end; {else}
Optimize(i,llongA);
i := i+1;
end; {while}
until not didone;
done := false;
repeat
if nnextSpot = 1 then
done := true
else begin
if npeep[1].opcode in nleadOpcodes then
done := true
else begin
if registers then
CheckRegisters(nPeep[1].opcode, nPeep[1].mode,
nPeep[1].operand, nPeep[1].name, nPeep[1].flags)
else
WriteNative(nPeep[1].opcode, nPeep[1].mode, nPeep[1].operand,
nPeep[1].name,nPeep[1].flags);
Remove(1);
end; {else}
end; {else}
until done;
if nnextSpot = nPeepSize then begin
if registers then
CheckRegisters(nPeep[1].opcode, nPeep[1].mode, nPeep[1].operand,
nPeep[1].name, nPeep[1].flags)
else
WriteNative(nPeep[1].opcode, nPeep[1].mode, nPeep[1].operand,
nPeep[1].name, nPeep[1].flags);
Remove(1);
end; {if}
with npeep[nnextSpot] do begin
opcode := p_opcode;
mode := p_mode;
operand := p_operand;
name := p_name;
flags := p_flags;
end; {with}
nnextSpot := nnextSpot+1;
if not (npeep[1].opcode in nleadOpcodes) then begin
if registers then
CheckRegisters(nPeep[1].opcode, nPeep[1].mode, nPeep[1].operand,
nPeep[1].name, nPeep[1].flags)
else
WriteNative(nPeep[1].opcode, nPeep[1].mode, nPeep[1].operand,
nPeep[1].name, nPeep[1].flags);
Remove(1);
end; {if}
end {else if}
else begin
with npeep[nnextSpot] do begin
opcode := p_opcode;
mode := p_mode;
operand := p_operand;
name := p_name;
flags := p_flags;
end; {with}
nnextSpot := nnextSpot+1;
end; {else}
end {if}
else if p_opcode <> d_end then
if registers then
CheckRegisters(p_opcode, p_mode, p_operand, p_name, p_flags)
else
WriteNative(p_opcode, p_mode, p_operand, p_name, p_flags);
end; {GenNative}
procedure GenImplied {p_opcode: integer};
{ short form of GenNative - reduces code size }
{ }
{ parameters: }
{ p_code - operation code }
begin {GenImplied}
GenNative(p_opcode, implied, 0, nil, 0);
end; {GenImplied}
procedure GenImpliedForFlags {p_opcode: integer};
{ Generate implied addressing instruction used for flags only. }
{ }
{ parameters: }
{ p_code - operation code (m_tax or m_tay) }
begin {GenImpliedForFlags}
GenNative(p_opcode, implied, 0, nil, forFlags);
end; {GenImpliedForFlags}
procedure GenCall {callNum: integer};
{ short form of jsl to library subroutine - reduces code size }
{ }
{ parameters: }
{ callNum - subroutine # to generate a call for }
var
sp: stringPtr; {work string}
begin {GenCall}
case callNum of
1: sp := @'~CHECKSTACK';
2: sp := @'~RESETNAME';
3: sp := @'~CREALRET';
4: sp := @'~CDOUBLERET';
5: sp := @'~SETNAME';
6: sp := @'~SETLINENUMBER';
7: sp := @'~REALFN';
8: sp := @'~DOUBLEFN';
9: sp := @'~SAVEREAL';
10: sp := @'~SAVEDOUBLE';
11: sp := @'~CNVINTREAL';
12: sp := @'~CNVLONGREAL';
13: sp := @'~CNVULONGREAL';
14: sp := @'~CNVREALINT';
15: sp := @'~CNVREALUINT';
16: sp := @'~CNVREALLONG';
17: sp := @'~CNVREALULONG';
18: sp := @'~CNVL2'; {PASCAL}
19: sp := @'~SAVESET';
20: sp := @'~LOADSET'; {PASCAL}
21: sp := @'~LOADREAL';
22: sp := @'~LOADDOUBLE';
23: sp := @'~SHIFTLEFT';
24: sp := @'~SSHIFTRIGHT';
25: sp := @'~INTCHKC';
26: sp := @'~DIV2';
27: sp := @'~MOD2';
28: sp := @'~MUL2';
29: sp := @'~GRTL';
30: sp := @'~GEQL';
31: sp := @'~GRTE';
32: sp := @'~GEQE';
33: sp := @'~SETINCLUSION';
34: sp := @'~GRTSTRING';
35: sp := @'~GEQSTRING';
36: sp := @'~EQUE';
37: sp := @'~SETEQU';
38: sp := @'~EQUSTRING';
39: sp := @'~UMUL2';
40: sp := @'~UDIV2';
41: sp := @'~USHIFTRIGHT';
42: sp := @'~MUL4';
43: sp := @'~PDIV4';
44: sp := @'~MOD4';
45: sp := @'~SHL4';
46: sp := @'~LSHR4';
47: sp := @'~ASHR4'; {CC}
48: sp := @'~UMUL4'; {CC}
49: sp := @'~UDIV4'; {CC}
50: sp := @'~UMOD4'; {CC}
51: sp := @'~COPYREAL';
52: sp := @'~COPYDOUBLE';
53: sp := @'~XJPERROR';
54: sp := @'~MOVE';
55: sp := @'~MOVE2';
56: sp := @'~ADDE';
57: sp := @'~DIVE';
58: sp := @'~MULE';
59: sp := @'~SUBE';
60: sp := @'~POWER';
61: sp := @'~ARCTAN2E';
62: sp := @'~LONGMOVE';
63: sp := @'~LONGMOVE2';
64: sp := @'~CCOMPRET';
65: sp := @'~CEXTENDEDRET';
66: sp := @'~SAVECOMP';
67: sp := @'~SAVEEXTENDED';
68: sp := @'~COPYCOMP';
69: sp := @'~COPYEXTENDED';
70: sp := @'~LOADCOMP';
71: sp := @'~LOADEXTENDED';
72: sp := @'~LOADUBF';
73: sp := @'~LOADBF';
74: sp := @'~SAVEBF';
75: sp := @'~COPYBF';
76: sp := @'~STACKERR'; {CC}
77: sp := @'~LOADSTRUCT'; {CC}
78: sp := @'~DIV4'; {CC}
79: sp := @'~MUL8';
80: sp := @'~UMUL8';
81: sp := @'~CDIV8';
82: sp := @'~UDIV8';
83: sp := @'~CNVLONGLONGREAL';
84: sp := @'~CNVULONGLONGREAL';
85: sp := @'~SHL8';
86: sp := @'~ASHR8';
87: sp := @'~LSHR8';
88: sp := @'~SCMP8';
89: sp := @'~CNVREALLONGLONG';
90: sp := @'~CNVREALULONGLONG';
91: sp := @'~SINGLEPRECISION';
92: sp := @'~DOUBLEPRECISION';
93: sp := @'~COMPPRECISION';
94: sp := @'~CUMUL2';
95: sp := @'~REALFIX';
96: sp := @'~DOUBLEFIX';
97: sp := @'~COMPFIX';
otherwise:
Error(cge1);
end; {case}
GenNative(m_jsl, longabs, 0, sp, 0);
end; {GenCall}
procedure GenLab {lnum: integer};
{ generate a label }
{ }
{ parameters: }
{ lnum - label number }
begin {GenLab}
GenNative(d_lab, gnrlabel, lnum, nil, 0);
end; {GenLab}
procedure InitFile {keepName: gsosOutStringPtr; keepFlag: integer; partial: boolean};
{ Set up the object file }
{ }
{ parameters: }
{ keepName - name of the output file }
{ keepFlag - keep status: }
{ 0 - don't keep the output }
{ 1 - create a new object module }
{ 2 - a .root already exists }
{ 3 - at least on .letter file exists }
{ partial - is this a partial compile? }
{ }
{ Note: Declared as extern in CGI.pas }
procedure RootFile;
{ Create and write the initial entry segment }
const
dispToOpen = 21; {disps to glue routines for NDAs}
dispToClose = 38;
dispToAction = 50;
dispToInit = 65;
dispToCDAOpen = 9; {disps to glue routines for CDAs}
dispToCDAClose = 36;
var
i: integer; {loop index}
lab: stringPtr; {for holding names var pointers}
menuLen: integer; {length of the menu name string}
procedure SetDataBank;
{ set up the data bank register }
var
lisJSL: boolean; {saved copy of isJSL}
begin {SetDataBank}
lisJSL := isJSL;
isJSL := false;
CnOut(m_pea);
RefName(@'~GLOBALS', 0, 2, -8);
CnOut(m_plb);
CnOut(m_plb);
isJSL := lisJSL;
end; {SetDataBank}
begin {RootFile}
{open the initial object module}
fname2.theString.theString := concat(fname1.theString.theString, '.root');
fname2.theString.size := length(fname2.theString.theString);
OpenObj(fname2);
{force this to be a static segment}
if (segmentKind & $8000) <> 0 then begin
currentSegment := ' ';
segmentKind := 0;
end; {if}
{write the header}
InitNative;
Header(@'~_ROOT', $4000, 0);
{new desk accessory initialization}
if isNewDeskAcc then begin
{set up the initial jump table}
lab := @'~_ROOT';
menuLen := length(menuLine);
RefName(lab, menuLen + dispToOpen, 4, 0);
RefName(lab, menuLen + dispToClose, 4, 0);
RefName(lab, menuLen + dispToAction, 4, 0);
RefName(lab, menuLen + dispToInit, 4, 0);
CnOut2(refreshPeriod);
CnOut2(eventMask);
for i := 1 to menuLen do
CnOut(ord(menuLine[i]));
CnOut(0);
{glue code for calling open routine}
isJSL := true;
CnOut(m_phb);
SetDataBank;
CnOut(m_jsl);
RefName(openName, 0, 3, 0);
CnOut(m_plb);
CnOut(m_sta_s); CnOut(4);
CnOut(m_txa);
CnOut(m_sta_s); CnOut(6);
CnOut(m_rtl);
{glue code for calling close routine}
CnOut(m_phb);
SetDataBank;
CnOut(m_jsl);
RefName(closeName, 0, 3, 0);
CnOut(m_plb);
CnOut(m_rtl);
{glue code for calling action routine}
CnOut(m_phb);
SetDataBank;
CnOut(m_pha);
CnOut(m_phy);
CnOut(m_phx);
CnOut(m_jsl);
RefName(actionName, 0, 3, 0);
CnOut(m_plb);
CnOut(m_rtl);
{glue code for calling init routine}
CnOut(m_pha);
CnOut(m_jsl);
RefName(@'~DAID', 0, 3, 0);
CnOut(m_phb);
SetDataBank;
CnOut(m_pha);
CnOut(m_jsl);
RefName(initName, 0, 3, 0);
CnOut(m_plb);
CnOut(m_rtl);
isJSL := false;
end
{classic desk accessory initialization}
else if isClassicDeskAcc then begin
{write the name}
menuLen := length(menuLine);
CnOut(menuLen);
for i := 1 to menuLen do
CnOut(ord(menuLine[i]));
{set up the initial jump table}
lab := @'~_ROOT';
RefName(lab, menuLen + dispToCDAOpen, 4, 0);
RefName(lab, menuLen + dispToCDAClose, 4, 0);
{glue code for calling open routine}
isJSL := true;
CnOut(m_pea);
CnOut2(1);
CnOut(m_jsl);
RefName(@'~DAID', 0, 3, 0);
CnOut(m_phb);
SetDataBank;
CnOut(m_jsl);
RefName(@'~CDASTART', 0, 3, 0);
CnOut(m_jsl);
RefName(openName,0,3,0);
CnOut(m_jsl);
RefName(@'~CDASHUTDOWN', 0, 3, 0);
CnOut(m_plb);
CnOut(m_rtl);
{glue code for calling close routine}
CnOut(m_phb);
SetDataBank;
CnOut(m_jsl);
RefName(closeName, 0, 3, 0);
CnOut(m_pea);
CnOut2(0);
CnOut(m_jsl);
RefName(@'~DAID', 0, 3, 0);
CnOut(m_plb);
CnOut(m_rtl);
isJSL := false;
end
{control panel device initialization}
else if isCDev then begin
CnOut(m_phb); {save data bank}
SetDataBank; {set data bank}
CnOut(m_plx); {get RTL address & original data bank}
CnOut(m_ply);
CnOut(m_lda_s); CnOut(3); {move CDev parameters}
CnOut(m_pha);
CnOut(m_lda_s); CnOut(3);
CnOut(m_pha);
CnOut(m_lda_s); CnOut(9);
CnOut(m_sta_s); CnOut(5);
CnOut(m_lda_s); CnOut(11);
CnOut(m_sta_s); CnOut(7);
CnOut(m_lda_s); CnOut(13);
CnOut(m_sta_s); CnOut(9);
CnOut(m_sta_s); CnOut(15); {store message in result space}
CnOut(m_lda_long); {store original user ID in result space}
RefName(@'~USER_ID',0,3,0);
CnOut(m_sta_s); CnOut(17);
CnOut(m_txa); {save RTL address & original data bank}
CnOut(m_sta_s); CnOut(11);
CnOut(m_tya);
CnOut(m_sta_s); CnOut(13);
CnOut(m_pea); CnOut2(1); {get user ID}
CnOut(m_jsl);
RefName(@'~DAID', 0, 3, 0);
CnOut(m_jsl); {call CDev main routine}
RefName(openName,0,3,0);
CnOut(m_jml); {clean up and return to caller}
RefName(@'~CDEVCLEANUP', 0, 3, 0);
end
{NBA initialization}
else if isNBA then begin
CnOut(m_jsl);
RefName(@'~NBASTARTUP', 0, 3, 0);
CnOut(m_phx);
CnOut(m_phy);
CnOut(m_jsl);
RefName(openName,0,3,0);
CnOut(m_jsl);
RefName(@'~NBASHUTDOWN', 0, 3, 0);
CnOut(m_rtl);
end
{XCMD initialization}
else if isXCMD then begin
CnOut(m_jsl);
RefName(@'~XCMDSTARTUP', 0, 3, 0);
CnOut(m_jsl);
RefName(openName,0,3,0);
CnOut(m_jsl);
RefName(@'~XCMDSHUTDOWN', 0, 3, 0);
CnOut(m_rtl);
end
{normal program initialization}
else begin
{write the initial JSL}
isJSL := true;
CnOut(m_jsl);
if rtl then
RefName(@'~_BWSTARTUP4', 0, 3, 0)
else
RefName(@'~_BWSTARTUP3', 0, 3, 0);
{set the data bank register}
SetDataBank;
{write JSL to main entry point}
CnOut(m_jsl);
if rtl then
RefName(@'~C_STARTUP2', 0, 3, 0)
else
RefName(@'~C_STARTUP', 0, 3, 0);
CnOut(m_jsl);
RefName(@'main', 0, 3, 0);
isJSL := false;
CnOut(m_jml);
if rtl then
RefName(@'~C_SHUTDOWN2', 0, 3, 0)
else
RefName(@'~C_SHUTDOWN', 0, 3, 0);
end;
{finish the current segment}
EndSeg;
end; {RootFile}
procedure SetStack;
{ Set up a stack frame }
begin {SetStack}
if stackSize <> 0 then begin
currentSegment := '~_STACK '; {write the header}
segmentKind := 0;
Header(@'~_STACK', $4012, 0);
Out($F1); {write the DS record to reserve space}
Out2(stackSize);
Out2(0);
EndSeg; {finish the current segment}
end; {if}
end; {SetStack}
begin {InitFile}
fname1 := keepname^;
if partial or (keepFlag = 3) then
FindSuffix(fname1, nextSuffix)
else begin
if (keepFlag = 1) and (not noroot) then begin
RootFile;
SetStack;
CloseObj;
end; {if}
DestroySuffixes(fname1);
nextSuffix := 'a';
end; {else}
fname2.theString.theString := concat(fname1.theString.theString, '.', nextSuffix);
fname2.theString.size := length(fname2.theString.theString);
OpenObj(fname2);
end; {InitFile}
procedure InitNative;
{ set up for a new segment }
begin {InitNative}
aRegister.condition := regUnknown; {set up the peephole optimizer}
xRegister.condition := regUnknown;
yRegister.condition := regUnknown;
lastRegOpcode := 0; {BRK}
nnextspot := 1;
nleadOpcodes := [m_asl_a,m_bcs,m_beq,m_bmi,m_bne,m_bpl,m_brl,m_bvs,m_bcc,
m_dec_abs,m_lda_abs,m_lda_dir,m_lda_imm,m_ldx_imm,m_sta_abs,m_sta_dir,
m_pha,m_plb,m_plx,m_tax,m_tya,m_tyx,m_phy,m_pei_dir,m_ldy_imm,m_rep,
m_ora_dir,m_ora_abs,m_and_imm,m_pea,m_tcd];
nstopOpcodes := [d_end,d_pin];
stringSize := 0; {initialize scalars for a new segment}
pc := 0;
cbufflen := 0;
longA := true;
longI := true;
end; {InitNative}
procedure RefName {lab: stringPtr; disp, len, shift: integer};
{ handle a reference to a named label }
{ }
{ parameters: }
{ lab - label name }
{ disp - displacement past the label }
{ len - number of bytes in the reference }
{ shift - shift factor }
var
i: integer; {loop var}
slen: integer; {length of string}
begin {RefName}
Purge; {clear any constant bytes}
if isJSL then {expression header}
Out(243)
else
Out(235);
Out(len);
Out(131);
pc := pc+len;
slen := length(lab^);
Out(slen);
for i := 1 to slen do
Out(ord(lab^[i]));
if disp <> 0 then begin {if there is a disp, add it in}
Out(129);
Out2(disp);
Out2(0);
Out(1);
end; {end}
if shift <> 0 then begin {if there is a shift, add it in}
Out(129);
Out2(shift);
if shift < 0 then
Out2(-1)
else
Out2(0);
Out(7);
end; {if}
Out(0); {end of expression}
end; {RefName}
end.
{$append 'native.asm'}