はじめに
Pascal-S という Pascal インタプリタを最新の Delphi でコンパイルできるように改変する記事を書きました。
本記事はその Pascal-S を ANSI 版 Delphi でコンパイルしてみようという趣旨です。実際に用いた Delphi コンパイラは Delphi 2007 R2 なのですが、特殊な事をやっていないので、Delphi 6 や 7 とかでも大丈夫なハズです。
修正
以降で修正を行いますので、前回同様まずはアーカイブを適当な場所に展開しておいてください。
プロジェクトを開く
Pascal-S は単一のソースファイル (pascals.pas) で構成されているので、これを Delphi で開けるように拡張子を *dpr に変更します。アーカイブでのパスは /source/pascals.pas
です。
[ファイル | プロジェクトを開く] で pascals.dpr を開きます。
コードの修正 (コンパイルエラーの除去)
まずはコンパイルエラーになる箇所をすべて潰します。
コンソールアプリケーションの指定
コンソールアプリケーションとして動作させるために、{$APPTYPE CONSOLE}
を追加します。
...
program Pascals(input{+ [sam]}, output, srcfil{ [sam]}); (* 1.6.75 *)
(* N. Wirth, E.T.H
CH-8092 Zurich *)
{$APPTYPE CONSOLE} // <-- 追加
label 99;
...
競合する識別子をリネーム
object
という識別子が競合するので objekt
にリネームします。キーボードショートカットの〔Ctrl〕+〔R〕、またはメインメニューの [検索 | 置換] で置換ダイアログが開きます。ワード検索にチェックを入れておくといいでしょう。
[すべて置換] ボタンを押して全置換します。
ラベル 99 を削除
ラベル 99
を使った大域ジャンプが行われているので、これを削除します。Borland 系 Pascal での goto は手続き内 goto (intraprocedural gotos) であり、手続き/関数の外側へジャンプする事はできません。
ラベル 99
はプログラムの最後に設定されているので、ここにジャンプしている goto 文は Halt
で置き換えます。
ラベルの定義を削除します。
...
{$APPTYPE CONSOLE}
// label 99; // 削除
const nkw = 27; (* no. of key words *)
...
goto 99
を Halt
で置き換えます。
procedure nextch; (* read next character; process line end *)
begin if cc = ll then
begin if eof(srcfil) {[sam]} then
begin writeln;
writeln(' program incomplete');
errormsg; // goto 99 // 削除
halt; // 追加
end;
if errpos <> 0 then
begin writeln; errpos := 0
end;
write(lc:5, ' ');
ll := 0; cc := 0;
while not eoln(srcfil) {[sam]} do
begin ll := ll+1; read(srcfil{[sam]}, ch); write(ch); line[ll] := ch
end;
writeln; ll := ll+1; read(srcfil{[sam]}, line[ll]);
end;
cc := cc+1; ch := line[cc];
end (* nextch *);
もう一か所あります。
procedure fatal(n: integer);
var msg: array [1..7] of alfa;
begin writeln; errormsg;
msg[ 1] := 'identifier'; msg[ 2] := 'procedures';
msg[ 3] := 'reals '; msg[ 4] := 'arrays ';
msg[ 5] := 'levels '; msg[ 6] := 'code ';
msg[ 7] := 'strings ';
writeln(' compiler table for ', msg[n], ' is too small');
// goto 99 (* terminate compilation *) // 削除
Halt; // 追加
end (* fatal *);
ラベルを削除します。
...
if errs = [] then
begin
if iflag then
begin
if eof then writeln(' input data missing') else
begin writeln(' (eor) '); (* copy input data *)
while not eof do
begin write(' ');
while not eoln do
begin read(ch); write(ch)
end;
writeln; read(ch)
end;
end
end;
writeln(' (eof) ');
interpret
end
else errormsg;
//99: // 削除
end.
変数 inum の型を変更
inum を使っている式の一部が必ず False と判定されるので、型を Int64
(符号つき 64bit 整数) へ変更します。
...
var sy: symbol; (* last symbol read by insymbol *)
id: alfa; (* identifier from insymbol *)
// inum: integer; (* integer from insymbol *) // 削除
inum: Int64; (* integer from insymbol *) // 追加
初期化されていない変数の初期化
forstatement() 内の変数 cvt
が初期化されていないので初期化しておきます。
procedure forstatement;
var cvt: types; x: item;
i, f, lc1, lc2: integer;
begin insymbol;
cvt := notyp; // 追加
if sy = ident then
begin i := loc(id); insymbol;
...
これでコンパイルエラーは取り除かれました。
コードの修正 (不具合の修正)
この時点ではまだ正しく動作しません。不具合を修正します。
※ 以後、ソースコードを見やすくするために、オリジナルコードとは一部改行位置が異なる箇所があります。ご注意ください。
入力ファイルを受け付けるようにする
pascals ファイル名
で実行できるようにしたいので、AssignFile() を追加します。
...
begin { main program }
{ [sam] Added sign-on }
writeln;
writeln('Pascal-S compiler/interpreter');
{ [sam] If you need to associate 'srcfil' with an external file in the
source, do that here }
AssignFile(srcfil, ParamStr(1)); // 追加
reset(srcfil);
...
簡易的には上記コードでも構わないのですが、以下のようにすると使い勝手がよくなるでしょう。
- 指定されたファイルが存在しない場合には即終了
- 拡張子が指定されなかった場合には *.pas とみなす
ファイル操作系の関数が SysUtils
で定義されているので uses に追加します。
program Pascals(input{+ [sam]}, output, srcfil{ [sam]}); (* 1.6.75 *)
(* N. Wirth, E.T.H
CH-8092 Zurich *)
{$APPTYPE CONSOLE}
uses // 追加
SysUtils; // 追加
...
処理を追加します。
...
stab: packed array [0..smax] of char; (* string table *)
rconst: array [1..c2max] of real;
code: array [0..cmax] of order;
srcfil: TextFile; { source input file [sam] }
filename: string; // 追加
...
begin { main program }
{ [sam] Added sign-on }
writeln;
writeln('Pascal-S compiler/interpreter');
{ [sam] If you need to associate 'srcfil' with an external file in the
source, do that here }
filename := ParamStr(1); // 追加
if (filename <> '') and (ExtractFileExt(filename) = '') then // 追加
filename := ChangeFileExt(filename, '.pas'); // 追加
if not FileExists(filename) then // 追加
begin // 追加
writeln('File not found.'); // 追加
Halt; // 追加
end; // 追加
AssignFile(srcfil, filename); // 追加
reset(srcfil);
...
変数 filename は上の方に定義しなくても、
var // 追加
filename: string; // 追加
begin { main program }
このようにメインプログラムの begin の直上に var ブロックを追加すれば定義できる (var ブロックは複数設置できる) のですが var ブロックが複数あるとゴチャゴチャするので個人的には 1 箇所にまとめておきたいです。
- System.AssignFile (DocWiki)
- System.ParamStr (DocWiki)
- System.SysUtils.ChangeFileExt (DocWiki)
- System.SysUtils.ExtractFileExt (DocWiki)
- System.SysUtils.FileExists (DocWiki)
制御文字のスキップ
Pascal-S のアーカイブに含まれる test.pas を実行しようとしても無限ループで止まってしまいます。これは改行文字 (0x0A) をスキップしない事が原因なので、制御文字と半角 SP をすべてスキップするように書き換えます。
...
begin (* insymbol *)
//1: while ch = ' ' do nextch; // 削除
1: while (ch in [#$00 .. #$20, #$7F]) do nextch; // 追加
...
無限ループ防止 (1)
大文字アルファベットやアンダーバーで始まる識別子も受け付けるようにします。
begin (* insymbol *)
//1: while ch = ' ' do nextch;
1: while (ch in [#$00 .. #$20, #$7F]) do nextch;
// if ch in ['a'..'z'] then // 削除
if (ch in ['_', 'A' .. 'Z', 'a' .. 'z']) then // 追加
begin (* word *)
k := 0;
id := ' ';
repeat
if k < alng then
begin
k := k + 1;
id[k] := ch
end;
nextch
// until not (ch in ['a' .. 'z', '0' .. '9']); // 削除
until not (ch in ['_', 'A' .. 'Z', 'a' .. 'z', '0' .. '9']); // 追加
...
無限ループ防止 (2)
受け付けない文字はすべてエラーにします。
...
'+', '-', '*', '/', ')', '=', ',', '[', ']', '#', '&', ';':
begin
sy := sps[ch];
nextch
end;
// '$', '%', '@', '\', '~', '{', '}', '^': // 削除
// begin // 削除
// error(24); // 削除
// nextch; // 削除
// goto 1 // 削除
// end // 削除
else // 追加
error(24); // 追加
nextch; // 追加
goto 1 // 追加
end
end (* insymbol *);
...
プログラムロケーションカウンタ
プログラムロケーションカウンタを正しく表示できるようにします。プログラムロケーションカウンタは内部で使用される行番号のようなものです。
...
procedure nextch; (* read next character; process line end *)
begin
if cc = ll then
begin
if eof(srcfil) { [sam] } then
begin
writeln;
writeln(' program incomplete');
errormsg;
Halt;
end;
if errpos <> 0 then
begin
writeln;
errpos := 0
end;
write(lc:5, ' ');
ll := 0;
cc := 0;
while not eoln(srcfil) { [sam] } do
begin
ll := ll + 1;
read(srcfil { [sam] } , ch);
// write(ch); // 削除
if (ch in [#$0A, #$0D]) then // 追加
ch := #$00 // 追加
else // 追加
write(ch); // 追加
line[ll] := ch
end;
writeln;
ll := ll + 1;
read(srcfil { [sam] } , line[ll]);
end;
cc := cc + 1;
ch := line[cc];
end (* nextch *);
...
実行
これで test.pas が実行できるようになりました!
アーカイブの /sample_programs
にある *.pas も実行できますヨ!
※プログラムファイルの改行コードは CRLF にしておいてください。
おわりに
ANSI 版の Delphi の方が修正項目が少なかったですよね。
伝統的な Pascal のソースコードを移植する場合には一旦、Turbo Pascal や ANSI 版 Delphi (Delphi 2007 以前) へ移植してから Unicode 版 Delphi (Delphi 2009 以降) へ移植すると、Unicode 特有の問題とそれ以外を切り分けられるので作業が捗るかと思います。
「ANSI 版 Delphi なんて売ってないじゃないか!」 と思われるかもしれませんが、最新版の Delphi を購入すれば、ANSI 版を含む古い Delphi が入手可能なのです。例えば Delphi 10.3 Rio を購入すると以下のバージョンの Delphi を入手できます。
- Delphi 7 (ANSI)
- Delphi 2007 (ANSI)
- Delphi 2009, 2010 (Unicode)
- Delphi XE ~ XE8 (Unicode)
- Delphi 10 Seattle (Unicode)
- Delphi 10.1 Berlin (Unicode)
- Delphi 10.2 Tokyo (Unicode)
※ 残念ながら Community Edition には古い Delphi は付いてきません。
※ Turbo Pascal 5.5 は現在でも合法的に無償で入手可能です。
改変ソースコード
ANSI 版も手動で整形したソースコードを置いておきます。
{******************************************************************************
* *
* Pascal-s entered from wirth's Pascal-s document and converted for *
* ISO 7185 use. *
* *
* The original environment of pascal (CDC computer) used a special access *
* method where the input file was split into "segments" and special methods *
* were used to access these segments. I have changed things to open the file *
* "input.pas", and compile the program from there. Input and output then *
* occur from the simulated program normally. Very few changes were made to *
* accomplish this. *
* *
* See the original document for more information. *
* *
* Changes were also made to bring the program into compliance with *
* ISO 7185 Pascal. *
* *
* S. A. Moore *
* samiam@moorecad.com *
* *
* A brief overview of what is subsetted in Pascal-S: *
* *
* 1. Curly bracket mode comments are not supported. They are recognized and *
* dealt with as an error, however (see "insymbol"). *
* *
* 2. Subrange types are not implemented (type a = 1..10). *
* *
* 3. Scalar types are not implemented (type a = (one, two, three). *
* *
* 4. Sets are not implemented. *
* *
* 5. Files other than the "input" or "output" files are not implemented. *
* *
* 6. Dynamic variables (pointers) are not implemented. *
* *
* 7. Variant records are not implemented. *
* *
* 8. Gotos are not implemented. *
* *
* 9. The predefined functions succ and pred only function on type char. *
* *
* 10. Packing, the "packed" keyword, and the "pack" and "unpack" procedures, *
* are not implemented. *
* *
* 11. "get", "put", and file buffer variable handling are not implemented. *
* *
* 12. Strings are unimplemented, except for literals as parameters to *
* write/writeln, and those cannot have field lengths applied to them. *
* *
* 13. The "forward" specifier, and forwarded procedures and functions, are *
* not implemented. *
* *
* For more details on what is or is not implemented in Pascal-s, see the *
* original documentation by N. Wirth. *
* *
* Changes made: *
* *
* 1. The "+" sign was removed from "input" in the header. This signaled to *
* The CDC 6400 compiler that the input file was segmented, and contained both *
* The program and its input. *
* *
* To complete the separation of the program file from the input file, the *
* program file was formalized as "srcfil", placed in the header, and all *
* source reads directed to that. The "getseg" call used to advance segmented *
* input to the next section was removed. This actually makes the program *
* closer to both the standard and [J&W] (non CDC methods). *
* *
* 2. "downto" and "do" were swapped in the key table. This is nessary because *
* the CDC 6400 character set places space above, not below the other *
* characters as in ASCII. *
* *
* 3. On the CDC 6400 computer, integers greater than 48 bits are not *
* garanteed to be valid, so the maximum for any number is set to that in *
* nmax. I set it to maxint, which should work anywhere. *
* *
* 4. I increased the sizes quite a bit to enable large program processing. *
* Included are the string table, the code table, and various others. Pascal-s *
* came from a time when memory was more precious. *
* *
* 5. I changed the exponent of real minimum and maximum to match IEEE 754 *
* standard 64 bit floating point numbers. The size of significant digits did *
* not need changing, since both IEEE 754 and CDC 6400 use a 48 bit mantissa. *
* *
* 6. Added a constant "inxmax" that indicates the maximum ordinal value of *
* the character set, and replaced the old, in source limit of 63, which was *
* the CDC 6400 character limit (0-63). Updated the constant value for ASCII. *
* *
* 7. The original Wirth convention of having the first character of each *
* output line be a print control character (' ', '0', '1', '+') is long gone. *
* These were removed, and replaced by their equivalent in modern Pascal. *
* *
* 8. "The instruction 36 mystery" in simpleexpression, a single negate *
* instruction is emitted for both integer and real, and indeed, the 36 *
* instruction in interpret performs an integer negate, regardless of the real *
* or integer status of the stack operand. It SEEMS like a bug, but its not. *
* To understand why not, you have to do some serious dumpster diving into the *
* CDC 6000 machine documentation. Seymore Cray was a very clever fellow, and *
* the CDC 6600 series floating point notation is "compatible" with its *
* integer notation, that is, has its sign in the same place, and essentially *
* appears as an integer with an embedded exponent. Among other interesting *
* effects, it means that a negate operation works on both integer and real, *
* regardless of which type is being done. Try to find THAT in the Pascal-s *
* documentation ! The fix for this is to stick a real/integer indicator in *
* the "y" field of an "order" record, this tells a non-CDC 6000 computer to *
* treat the negate differently for real and integer. *
* *
* 9. I added a sign-on for the program. *
* *
* I have marked all my changes to the original source with [sam] in a comment *
* (my initals). *
* *
* Notes on compiling and running: *
* *
* 1. Pascal-s does not tolerate upper case input. On most systems, this will *
* result in a "case select" error in the procedure "insymbol". *
* *
* 2. The file program header file "srcfil" is going to need to be connected *
* to an external file. If your Pascal does not have the ability to connect *
* header files to external files, then you need to do this manually. See the *
* comment shortly after the main program "begin". *
* *
* 3. You may need to change the emin, emax, and kmax parameters to match your *
* particular floating point implementation. *
* *
* 4. You may want to increase alng, the number of significant characters in *
* identifiers, to match your needs. This will allow programs with long *
* idenfitiers to run, but will increase the space requirements to run *
* Pascal-s, perhaps dramatically. *
* *
* 5. Pascal-s can, by option, dump all of its tables after program *
* compilation, including identifers, blocks, arrays, and internal execution *
* code. This option is invoked by naming the program "test0" (the name in the *
* "program" statement). *
* *
******************************************************************************}
program Pascals(input { + [sam] } , output, srcfil { [sam] } ); (* 1.6.75 *)
(* N. Wirth, E.T.H CH-8092 Zurich *)
{$APPTYPE CONSOLE}
uses
SysUtils;
const
nkw = 27; (* no. of key words *)
alng = 10; (* no. of significant chars in identifiers *)
llng = 250 {120 [sam]}; (* input line length *)
emax = 308 {322 [sam]}; (* max exponent of real numbers *)
emin = -308 {-292 [sam]}; (* min exponent *)
kmax = 15; (* max no. of significant digits *)
tmax = 10000 {100 [sam]}; (* size of table *)
bmax = 1000 {20 [sam]}; (* size of block-table *)
amax = 1000 {30 [sam]}; (* size of array-table *)
c2max = 1000 {20 [sam]}; (* size of real constant table *)
csmax = 1000 {30 [sam]}; (* max no. of cases *)
cmax = 100000 {850 [sam]}; (* size of code *)
lmax = 100 {7 [sam]}; (* maximum level *)
smax = 100000 {600 [sam]}; (* size of string table *)
ermax = 58; (* max error no. *)
omax = 63; (* highest order code *)
xmax = 131071; (* 2**17 - 1 *)
nmax = maxint {281474976710655 [sam]}; (* 2**48 - 1 *)
lineleng = 250 {136 [sam] }; (* output line length *)
linelimit = 100000 {200 [sam]};
stacksize = 100000 {1500 [sam]};
inxmax = 127; { maximum index for character (ASCII) [sam] }
type
symbol = (intcon, realcon, charcon, stringt, notsy, plus, minus, times, idiv,
rdiv, imod, andsy, orsy, egl, neg, gtr, geg, lss, leg, lparent, rparent,
lbrack, rbrack, comma, semicolon, period, colon, becomes, constsy, typesy,
varsy, functionsy, proceduresy, arraysy, recordsy, programsy, ident,
beginsy, ifsy, casesy, repeatsy, whilesy, forsy, endsy, elsesy, untilsy,
ofsy, dosy, tosy, downtosy, thensy);
index = -xmax..+xmax;
alfa = packed array [1..alng] of char;
objekt = (konstant, variable, typel, prozedure, funktion);
types = (notyp, ints, reals, bools, chars, arrays, records);
symset = set of symbol;
typset = set of types;
item = record
typ: types;
ref: index;
end;
order = packed record
f: - omax..+omax;
x: - lmax..+lmax;
y: - nmax..+nmax;
end;
var
sy: symbol; (* last symbol read by insymbol *)
id: alfa; (* identifier from insymbol *)
inum: Int64; (* integer from insymbol *)
rnum: real; (* real number from insymbol *)
sleng: integer; (* string length *)
ch: char; (* last character read from source program *)
line: array [1..llng] of char;
cc: integer; (* character counter *)
lc: integer; (* program location counter *)
ll: integer; (* length of current line *)
errs: set of 0..ermax;
errpos: integer;
progname: alfa;
iflag, oflag: boolean;
constbegsys, typebegsys, blockbegsys, facbegsys, statbegsys: symset;
key: array [1..nkw] of alfa;
ksy: array [1..nkw] of symbol;
sps: array [char] of symbol; (* special symbols *)
t, a, b, sx, c1, c2: integer; (* indicies to tables *)
stantyps: typset;
display: array [0..lmax] of integer;
tab: array [0..tmax] of (* identifier table *)
packed record name: alfa;
link: index;
obj: objekt;
typ: types;
ref: index;
normal: boolean;
lev: 0..lmax;
adr: integer;
end;
atab: array [1..amax] of (* array-tabvle *)
packed record inxtyp, eltyp: types;
elref, low, high, elsize, size: index;
end;
btab: array [1..bmax] of (* block table *)
packed record
last, lastpar, psize, vsize: index
end;
stab: packed array [0..smax] of char; (* string table *)
rconst: array [1..c2max] of real;
code: array [0..cmax] of order;
srcfil: TextFile; { source input file [sam] }
filename: string;
procedure errormsg;
var
k: integer;
msg: array [0..ermax] of alfa;
begin
msg[ 0] := 'undef id '; msg[ 1] := 'multi def ';
msg[ 2] := 'identifier'; msg[ 3] := 'program ';
msg[ 4] := ') '; msg[ 5] := ': ';
msg[ 6] := 'syntax '; msg[ 7] := 'ident, var';
msg[ 8] := 'of '; msg[ 9] := '( ';
msg[10] := 'id, array '; msg[11] := '[ ';
msg[12] := '] '; msg[13] := '.. ';
msg[14] := '; '; msg[15] := 'func. type';
msg[16] := '= '; msg[17] := 'boolean ';
msg[18] := 'convar typ'; msg[19] := 'type ';
msg[20] := 'prog.param'; msg[21] := 'too big ';
msg[22] := '. '; msg[23] := 'typ (case)';
msg[24] := 'character '; msg[25] := 'const id ';
msg[26] := 'index type'; msg[27] := 'indexbound';
msg[28] := 'no array '; msg[29] := 'type id ';
msg[30] := 'undef type'; msg[31] := 'no record ';
msg[32] := 'boole type'; msg[33] := 'arith type';
msg[34] := 'integer '; msg[35] := 'types ';
msg[36] := 'param type'; msg[37] := 'variab id ';
msg[38] := 'string '; msg[39] := 'no.of pars';
msg[40] := 'type '; msg[41] := 'type ';
msg[42] := 'real type '; msg[43] := 'integer ';
msg[44] := 'var, const'; msg[45] := 'var, proc ';
msg[46] := 'types (:=)'; msg[47] := 'typ (case)';
msg[48] := 'type '; msg[49] := 'store ovfl';
msg[50] := 'constant '; msg[51] := ':= ';
msg[52] := 'then '; msg[53] := 'until ';
msg[54] := 'do '; msg[55] := 'to downto ';
msg[56] := 'begin '; msg[57] := 'end ';
msg[58] := 'factor ';
k := 0;
writeln;
writeln(' key words');
while errs <> [] do
begin
while not(k in errs) do
k := k + 1;
writeln(k, ' ', msg[k]);
errs := errs - [k]
end
end (* errormsg *);
procedure nextch; (* read next character; process line end *)
begin
if cc = ll then
begin
if eof(srcfil) { [sam] } then
begin
writeln;
writeln(' program incomplete');
errormsg;
Halt;
end;
if errpos <> 0 then
begin
writeln;
errpos := 0
end;
write(lc:5, ' ');
ll := 0;
cc := 0;
while not Eoln(srcfil) { [sam] } do
begin
ll := ll + 1;
read(srcfil { [sam] } , ch);
if (ch in [#$0A, #$0D]) then
ch := #$00
else
write(ch);
line[ll] := ch
end;
writeln;
ll := ll + 1;
read(srcfil { [sam] } , line[ll]);
end;
cc := cc + 1;
ch := line[cc];
end (* nextch *);
procedure error(n: integer);
begin
if errpos = 0 then
write(' ****');
if cc > errpos then
begin
write(' ':cc - errpos, '^', n:2);
errpos := cc + 3;
errs := errs + [n]
end;
end (* error *);
procedure fatal(n: integer);
var
msg: array [1..7] of alfa;
begin
writeln;
errormsg;
msg[1] := 'identifier';
msg[2] := 'procedures';
msg[3] := 'reals ';
msg[4] := 'arrays ';
msg[5] := 'levels ';
msg[6] := 'code ';
msg[7] := 'strings ';
writeln(' compiler table for ', msg[n], ' is too small');
Halt; (* terminate compilation *)
end (* fatal *);
procedure insymbol; (* reads next symbol *)
label
1, 2, 3;
var
i, j, k, e: integer;
procedure readscale;
var
s, sign: integer;
begin
nextch;
sign := 1;
s := 0;
if ch = '+' then
nextch
else if ch = '-' then
begin
nextch;
sign := -1
end;
while (ch in ['0'..'9']) do
begin
s := 10 * s + ord(ch) - ord('0');
nextch
end;
e := s * sign + e
end (* readscale *);
procedure adjustscale;
var
s: integer;
d, t: real;
begin
if k + e > emax then
error(21)
else if k + e < emin then
rnum := 0
else
begin
s := abs(e);
t := 1.0;
d := 10.0;
repeat
while not odd(s) do
begin
s := s div 2;
d := sqr(d)
end;
s := s - 1;
t := d * t
until s = 0;
if e >= 0 then
rnum := rnum * t
else
rnum := rnum / t
end
end (* adjustscale *);
begin (* insymbol *)
1: // label 1
while (ch in [#$00..#$20, #$7F]) do
nextch;
if (ch in ['_', 'A'..'Z', 'a'..'z']) then
begin (* word *)
k := 0;
id := ' ';
repeat
if k < alng then
begin
k := k + 1;
id[k] := ch
end;
nextch
until not (ch in ['_', 'A'..'Z', 'a'..'z', '0'..'9']);
i := 1;
j := nkw; (* binary search *)
repeat
k := (i + j) div 2;
if id <= key[k] then
j := k - 1;
if id >= key[k] then
i := k + 1
until i > j;
if i - 1 > j then
sy := ksy[k]
else
sy := ident
end
else if (ch in ['0'..'9']) then
begin (* number *)
k := 0;
inum := 0;
sy := intcon;
repeat
inum := inum * 10 + ord(ch) - ord('0');
k := k + 1;
nextch
until not (ch in ['0'..'9']);
if (k > kmax) or (inum > nmax) then
begin
error(21);
inum := 0;
k := 0
end;
if ch = '.' then
begin
nextch;
if ch = '.' then
ch := ':'
else
begin
sy := realcon;
rnum := inum;
e := 0;
while (ch in ['0'..'9']) do
begin
e := e - 1;
rnum := 10.0 * rnum + (ord(ch) - ord('0'));
nextch
end;
if ch = 'e' then
readscale;
if e <> 0 then
adjustscale
end
end
else if ch = 'e' then
begin
sy := realcon;
rnum := inum;
e := 0;
readscale;
if e <> 0 then
adjustscale
end;
end
else
case ch of
':':
begin
nextch;
if ch = '=' then
begin
sy := becomes;
nextch
end
else
sy := colon
end;
'<':
begin
nextch;
if ch = '=' then
begin
sy := leg;
nextch
end
else if ch = '>' then
begin
sy := neg;
nextch
end
else
sy := lss
end;
'>':
begin
nextch;
if ch = '=' then
begin
sy := geg;
nextch
end
else
sy := gtr
end;
'.':
begin
nextch;
if ch = '.' then
begin
sy := colon;
nextch
end
else
sy := period
end;
'''':
begin
k := 0;
2: // label 2
nextch;
if ch = '''' then
begin
nextch;
if ch <> '''' then
goto 3
end;
if sx + k = smax then
fatal(7);
stab[sx + k] := ch;
k := k + 1;
if cc = 1 then
begin (* end of line *)
k := 0;
end
else
goto 2;
3: // label 3
if k = 1 then
begin
sy := charcon;
inum := ord(stab[sx])
end
else if k = 0 then
begin
error(38);
sy := charcon;
inum := 0
end
else
begin
sy := stringt;
inum := sx;
sleng := k;
sx := sx + k
end
end;
'(':
begin
nextch;
if ch <> '*' then
sy := lparent
else
begin (* comment *)
nextch;
repeat
while ch <> '*' do
nextch;
nextch
until ch = ')';
nextch;
goto 1
end
end;
'+', '-', '*', '/', ')', '=', ',', '[', ']', '#', '&', ';':
begin
sy := sps[ch];
nextch
end;
else
error(24);
nextch;
goto 1
end
end (* insymbol *);
procedure enter(x0: alfa; x1: objekt; x2: types; x3: integer);
begin
t := t + 1; (* enter standard identifier *)
with tab[t] do
begin
name := x0;
link := t - 1;
obj := x1;
typ := x2;
ref := 0;
normal := true;
lev := 0;
adr := x3
end
end (* enter *);
procedure enterarray(tp: types; l, h: integer);
begin
if l > h then
error(27);
if (abs(l) > xmax) or (abs(h) > xmax) then
begin
error(27);
l := 0;
h := 0;
end;
if a = amax then
fatal(4)
else
begin
a := a + 1;
with atab[a] do
begin
inxtyp := tp;
low := l;
high := h
end
end
end (* enterarray *);
procedure enterblock;
begin
if b = bmax then
fatal(2)
else
begin
b := b + 1;
btab[b].last := 0;
btab[b].lastpar := 0
end
end (* enterblock *);
procedure enterreal(x: real);
begin
if c2 = c2max - 1 then
fatal(3)
else
begin
rconst[c2 + 1] := x;
c1 := 1;
while rconst[c1] <> x do
c1 := c1 + 1;
if c1 > c2 then
c2 := c1
end
end (* enterreal *);
procedure emit(fct: integer);
begin
if lc = cmax then
fatal(6);
code[lc].f := fct;
lc := lc + 1
end (* emit *);
procedure emit1(fct, b: integer);
begin
if lc = cmax then
fatal(6);
with code[lc] do
begin
f := fct;
y := b
end;
lc := lc + 1
end (* emit1 *);
procedure emit2(fct, a, b: integer);
begin
if lc = cmax then
fatal(6);
with code[lc] do
begin
f := fct;
x := a;
y := b
end;
lc := lc + 1
end (* emit2 *);
procedure printtables;
var
i: integer;
o: order;
begin
{ Changed to double spacing [sam] }
writeln('identifiers link obj typ ref nrm lev adr');
writeln;
for i := btab[1].last + 1 to t do
with tab[i] do
writeln(i, ' ', name, link:5, ord(obj):5, ord(typ):5, ref:5,
ord(normal):5, lev:5, adr:5);
{ Changed to double spacing [sam] }
writeln('blocks last lpar psze vsze');
writeln;
for i := 1 to b do
with btab[i] do
writeln(i, last:5, lastpar:5, psize:5, vsize:5);
{ Changed to double spacing [sam] }
writeln('arrays xtyp etyp eref low high elsz size');
writeln;
for i := 1 to a do
with atab[i] do
writeln(i, ord(inxtyp):5, ord(eltyp):5, elref:5, low:5, high:5,
elsize:5, size:5);
{ Changed to double spacing [sam] }
writeln('code:');
writeln;
for i := 0 to lc - 1 do
begin
if i mod 5 = 0 then
begin
writeln;
write(i:5)
end;
o := code[i];
write(o.f:5);
{ Changed 36 to have a parameter, see notes in header [sam] }
if (o.f < 31) or (o.f = 36) then
if o.f < 4 then
write(o.x:2, o.y:5)
else
write(o.y:7)
else
write(' ');
write(',')
end;
writeln
end (* printtables *);
procedure block(fsys: symset; isfun: boolean; level: integer);
type
conrec = record
case tp: types of
ints, chars, bools:
(i: integer);
reals:
(r: real);
notyp, arrays, records:
();
end;
var
dx: integer; (* data allocation index *)
prt: integer; (* t-index of this procedure *)
prb: integer; (* b-index of this procedure *)
x: integer;
procedure skip(fsys: symset; n: integer);
begin
error(n);
while not(sy in fsys) do
insymbol
end (* skip *);
procedure test(s1, s2: symset; n: integer);
begin
if not(sy in s1) then
skip(s1 + s2, n)
end (* test *);
procedure testsemicolon;
begin
if sy = semicolon then
insymbol
else
begin
error(14);
if sy in [comma, colon] then
insymbol
end;
test([ident] + blockbegsys, fsys, 6)
end (* testsemicolon *);
procedure enter(id: alfa; k: objekt);
var
j, l: integer;
begin
if t = tmax then
fatal(1)
else
begin
tab[0].name := id;
j := btab[display[level]].last;
l := j;
while tab[j].name <> id do
j := tab[j].link;
if j <> 0 then
error(1)
else
begin
t := t + 1;
with tab[t] do
begin
name := id;
link := l;
obj := k;
typ := notyp;
ref := 0;
lev := level;
adr := 0
end;
btab[display[level]].last := t
end
end
end (* enter *);
function loc(id: alfa): integer;
var
i, j: integer; (* locate id in table *)
begin
i := level;
tab[0].name := id; (* sentinel *)
repeat
j := btab[display[i]].last;
while tab[j].name <> id do
j := tab[j].link;
i := i - 1;
until (i < 0) or (j <> 0);
if j = 0 then
error(0);
loc := j
end (* loc *);
procedure entervariable;
begin
if sy = ident then
begin
enter(id, variable);
insymbol
end
else
error(2)
end (* entervariable *);
procedure constant(fsys: symset; var c: conrec);
var
x, sign: integer;
begin
c.tp := notyp;
c.i := 0;
test(constbegsys, fsys, 50);
if sy in constbegsys then
begin
if sy = charcon then
begin
c.tp := chars;
c.i := inum;
insymbol
end
else
begin
sign := 1;
if sy in [plus, minus] then
begin
if sy = minus then
sign := -1;
insymbol
end;
if sy = ident then
begin
x := loc(id);
if x <> 0 then
if tab[x].obj <> konstant then
error(25)
else
begin
c.tp := tab[x].typ;
if c.tp = reals then
c.r := sign * rconst[tab[x].adr]
else
c.i := sign * tab[x].adr
end;
insymbol
end
else if sy = intcon then
begin
c.tp := ints;
c.i := sign * inum;
insymbol
end
else if sy = realcon then
begin
c.tp := reals;
c.r := sign * rnum;
insymbol
end
else
skip(fsys, 50)
end;
test(fsys, [], 6)
end
end (* constant *);
procedure typ(fsys: symset; var tp: types; var rf, sz: integer);
var
x: integer;
eltp: types;
elrf: integer;
elsz, offset, t0, t1: integer;
procedure arraytyp(var aref, arsz: integer);
var
eltp: types;
low, high: conrec;
elrf, elsz: integer;
begin
constant([colon, rbrack, rparent, ofsy] + fsys, low);
if low.tp = reals then
begin
error(27);
low.tp := ints;
low.i := 0
end;
if sy = colon then
insymbol
else
error(13);
constant([rbrack, comma, rparent, ofsy] + fsys, high);
if high.tp <> low.tp then
begin
error(27);
high.i := low.i
end;
enterarray(low.tp, low.i, high.i);
aref := a;
if sy = comma then
begin
insymbol;
eltp := arrays;
arraytyp(elrf, elsz)
end
else
begin
if sy = rbrack then
insymbol
else
begin
error(12);
if sy = rparent then
insymbol
end;
if sy = ofsy then
insymbol
else
error(8);
typ(fsys, eltp, elrf, elsz)
end;
with atab[aref] do
begin
arsz := (high - low + 1) * elsz;
size := arsz;
eltyp := eltp;
elref := elrf;
elsize := elsz
end;
end (* arraytyp *);
begin (* typ *)
tp := notyp;
rf := 0;
sz := 0;
test(typebegsys, fsys, 10);
if sy in typebegsys then
begin
if sy = ident then
begin
x := loc(id);
if x <> 0 then
with tab[x] do
if obj <> typel then
error(29)
else
begin
tp := typ;
rf := ref;
sz := adr;
if tp = notyp then
error(30)
end;
insymbol
end
else if sy = arraysy then
begin
insymbol;
if sy = lbrack then
insymbol
else
begin
error(11);
if sy = lparent then
insymbol
end;
tp := arrays;
arraytyp(rf, sz)
end
else
begin (* records *)
insymbol;
enterblock;
tp := records;
rf := b;
if level = lmax then
fatal(5);
level := level + 1;
display[level] := b;
offset := 0;
while sy <> endsy do
begin (* field section *)
if sy = ident then
begin
t0 := t;
entervariable;
while sy = comma do
begin
insymbol;
entervariable
end;
if sy = colon then
insymbol
else
error(5);
t1 := t;
typ(fsys + [semicolon, endsy, comma, ident], eltp, elrf, elsz);
while t0 < t1 do
begin
t0 := t0 + 1;
with tab[t0] do
begin
typ := eltp;
ref := elrf;
normal := true;
adr := offset;
offset := offset + elsz
end
end
end;
if sy <> endsy then
begin
if sy = semicolon then
insymbol
else
begin
error(14);
if sy = comma then
insymbol
end;
test([ident, endsy, semicolon], fsys, 6)
end
end;
btab[rf].vsize := offset;
sz := offset;
btab[rf].psize := 0;
insymbol;
level := level - 1
end;
test(fsys, [], 6)
end
end (* typ *);
procedure parameterlist; (* formal parameter list *)
var
tp: types;
rf, sz, x, t0: integer;
valpar: boolean;
begin
insymbol;
tp := notyp;
rf := 0;
sz := 0;
test([ident, varsy], fsys + [rparent], 7);
while sy in [ident, varsy] do
begin
if sy <> varsy then
valpar := true
else
begin
insymbol;
valpar := false
end;
t0 := t;
entervariable;
while sy = comma do
begin
insymbol;
entervariable;
end;
if sy = colon then
begin
insymbol;
if sy <> ident then
error(2)
else
begin
x := loc(id);
insymbol;
if x <> 0 then
with tab[x] do
if obj <> typel then
error(29)
else
begin
tp := typ;
rf := ref;
if valpar then
sz := adr
else
sz := 1
end;
end;
test([semicolon, rparent], [comma, ident] + fsys, 14)
end
else
error(5);
while t0 < t do
begin
t0 := t0 + 1;
with tab[t0] do
begin
typ := tp;
ref := rf;
normal := valpar;
adr := dx;
lev := level;
dx := dx + sz
end
end;
if sy <> rparent then
begin
if sy = semicolon then
insymbol
else
begin
error(14);
if sy = comma then
insymbol
end;
test([ident, varsy], [rparent] + fsys, 6)
end
end (* while *);
if sy = rparent then
begin
insymbol;
test([semicolon, colon], fsys, 6)
end
else
error(4)
end (* parameter list *);
procedure constantdeclaration;
var
c: conrec;
begin
insymbol;
test([ident], blockbegsys, 2);
while sy = ident do
begin
enter(id, konstant);
insymbol;
if sy = egl then
insymbol
else
begin
error(16);
if sy = becomes then
insymbol
end;
constant([semicolon, comma, ident] + fsys, c);
tab[t].typ := c.tp;
tab[t].ref := 0;
if c.tp = reals then
begin
enterreal(c.r);
tab[t].adr := c1
end
else
tab[t].adr := c.i;
testsemicolon
end
end (* constantdeclaration *);
procedure typedeclaration;
var
tp: types;
rf, sz, t1: integer;
begin
insymbol;
test([ident], blockbegsys, 2);
while sy = ident do
begin
enter(id, typel);
t1 := t;
insymbol;
if sy = egl then
insymbol
else
begin
error(16);
if sy = becomes then
insymbol
end;
typ([semicolon, comma, ident] + fsys, tp, rf, sz);
with tab[t1] do
begin
typ := tp;
ref := rf;
adr := sz
end;
testsemicolon
end
end (* typedeclaration *);
procedure variabledeclaration;
var
t0, t1, rf, sz: integer;
tp: types;
begin
insymbol;
while sy = ident do
begin
t0 := t;
entervariable;
while sy = comma do
begin
insymbol;
entervariable;
end;
if sy = colon then
insymbol
else
error(5);
t1 := t;
typ([semicolon, comma, ident] + fsys, tp, rf, sz);
while t0 < t1 do
begin
t0 := t0 + 1;
with tab[t0] do
begin
typ := tp;
ref := rf;
lev := level;
adr := dx;
normal := true;
dx := dx + sz
end
end;
testsemicolon
end
end (* variabledeclaration *);
procedure procdeclaration;
var
isfun: boolean;
begin
isfun := sy = functionsy;
insymbol;
if sy <> ident then
begin
error(2);
id := ' ';
end;
if isfun then
enter(id, funktion)
else
enter(id, prozedure);
tab[t].normal := true;
insymbol;
block([semicolon] + fsys, isfun, level + 1);
if sy = semicolon then
insymbol
else
error(14);
emit(32 + ord(isfun)) (* exit *)
end (* proceduredeclaration *);
procedure statement(fsys: symset);
var
i: integer;
procedure expression(fsys: symset; var x: item); forward;
procedure selector(fsys: symset; var v: item);
var
x: item;
a, j: integer;
begin (* sy in [lparent, lbrack, period] *)
repeat
if sy = period then
begin
insymbol; (* field selector *)
if sy <> ident then
error(2)
else
begin
if v.typ <> records then
error(31)
else
begin (* search field identifier *)
j := btab[v.ref].last;
tab[0].name := id;
while tab[j].name <> id do
j := tab[j].link;
if j = 0 then
error(0);
v.typ := tab[j].typ;
v.ref := tab[j].ref;
a := tab[j].adr;
if a <> 0 then
emit1(9, a)
end;
insymbol
end
end
else
begin (* array selector *)
if sy <> lbrack then
error(11);
repeat
insymbol;
expression(fsys + [comma, rbrack], x);
if v.typ <> arrays then
error(28)
else
begin
a := v.ref;
if atab[a].inxtyp <> x.typ then
error(26)
else if atab[a].elsize = 1 then
emit1(20, a)
else
emit1(21, a);
v.typ := atab[a].eltyp;
v.ref := atab[a].elref
end
until sy <> comma;
if sy = rbrack then
insymbol
else
begin
error(12);
if sy = rparent then
insymbol
end
end
until not(sy in [lbrack, lparent, period]);
test(fsys, [], 6)
end (* selector *);
procedure call(fsys: symset; i: integer);
var
x: item;
lastp, cp, k: integer;
begin
emit1(18, i); (* mark stack *)
lastp := btab[tab[i].ref].lastpar;
cp := i;
if sy = lparent then
begin (* actual parameter list *)
repeat
insymbol;
if cp >= lastp then
error(39)
else
begin
cp := cp + 1;
if tab[cp].normal then
begin (* value parameter *)
expression(fsys + [comma, colon, rparent], x);
if x.typ = tab[cp].typ then
begin
if x.ref <> tab[cp].ref then
error(36)
else if x.typ = arrays then
emit1(22, atab[x.ref].size)
else if x.typ = records then
emit1(22, btab[x.ref].vsize)
end
else if (x.typ = ints) and (tab[cp].typ = reals) then
emit1(26, 0)
else if x.typ <> notyp then
error(36);
end
else
begin (* variable parameter *)
if sy <> ident then
error(2)
else
begin
k := loc(id);
insymbol;
if k <> 0 then
begin
if tab[k].obj <> variable then
error(37);
x.typ := tab[k].typ;
x.ref := tab[k].ref;
if tab[k].normal then
emit2(0, tab[k].lev, tab[k].adr)
else
emit2(1, tab[k].lev, tab[k].adr);
if sy in [lbrack, lparent, period] then
selector(fsys + [comma, colon, rparent], x);
if (x.typ <> tab[cp].typ) or (x.ref <> tab[cp].ref) then
error(36)
end
end
end
end;
test([comma, rparent], fsys, 6)
until sy <> comma;
if sy = rparent then
insymbol
else
error(4)
end;
if cp < lastp then
error(39); (* too few actual parameters *)
emit1(19, btab[tab[i].ref].psize - 1);
if tab[i].lev < level then
emit2(3, tab[i].lev, level)
end (* call *);
function resulttype(a, b: types): types;
begin
if (a > reals) or (b > reals) then
begin
error(33);
resulttype := notyp
end
else if (a = notyp) or (b = notyp) then
resulttype := notyp
else if a = ints then
if b = ints then
resulttype := ints
else
begin
resulttype := reals;
emit1(26, 1)
end
else
begin
resulttype := reals;
if b = ints then
emit1(26, 0)
end
end (* resulttype *);
procedure expression;
var
y: item;
op: symbol;
procedure simpleexpression(fsys: symset; var x: item);
var
y: item;
op: symbol;
procedure term(fsys: symset; var x: item);
var
y: item;
op: symbol;
procedure factor(fsys: symset; var x: item);
var
i, f: integer;
procedure standfct(n: integer);
var
ts: typset;
begin (* standard function no. n *)
if sy = lparent then
insymbol
else
error(9);
if n < 17 then
begin
expression(fsys + [rparent], x);
case n of
(* abs, sqr *) 0, 2:
begin
ts := [ints, reals];
tab[i].typ := x.typ;
if x.typ = reals then
n := n + 1
end;
(* odd, chr *) 4, 5:
ts := [ints];
(* ord *) 6:
ts := [ints, bools, chars];
(* succ, pred *) 7, 8:
ts := [chars];
(* round, trunc sin, cos... *) 9, 10, 11, 12, 13, 14, 15, 16:
begin
ts := [ints, reals];
if x.typ = ints then
emit1(26, 0)
end;
end;
if x.typ in ts then
emit1(8, n)
else if x.typ <> notyp then
error(48)
end
else
(* eof, eoln *) begin (* n in [17, 18] *)
if sy <> ident then
error(2)
else if id <> 'input ' then
error(0)
else
insymbol;
emit1(8, n);
end;
x.typ := tab[i].typ;
if sy = rparent then
insymbol
else
error(4)
end (* standfct *);
begin (* factor *)
x.typ := notyp;
x.ref := 0;
test(facbegsys, fsys, 58);
while sy in facbegsys do
begin
if sy = ident then
begin
i := loc(id);
insymbol;
with tab[i] do
case obj of
konstant:
begin
x.typ := typ;
x.ref := 0;
if x.typ = reals then
emit1(25, adr)
else
emit1(24, adr)
end;
variable:
begin
x.typ := typ;
x.ref := ref;
if sy in [lbrack, lparent, period] then
begin
if normal then
f := 0
else
f := 1;
emit2(f, lev, adr);
selector(fsys, x);
if x.typ in stantyps then
emit(34)
end
else
begin
if x.typ in stantyps then
if normal then
f := 1
else
f := 2
else if normal then
f := 0
else
f := 1;
emit2(f, lev, adr)
end
end;
typel, prozedure:
error(44);
funktion:
begin
x.typ := typ;
if lev <> 0 then
call(fsys, i)
else
standfct(adr)
end
end (* case, with *)
end
else if sy in [charcon, intcon, realcon] then
begin
if sy = realcon then
begin
x.typ := reals;
enterreal(rnum);
emit1(25, c1)
end
else
begin
if sy = charcon then
x.typ := chars
else
x.typ := ints;
emit1(24, inum)
end;
x.ref := 0;
insymbol
end
else if sy = lparent then
begin
insymbol;
expression(fsys + [rparent], x);
if sy = rparent then
insymbol
else
error(4)
end
else if sy = notsy then
begin
insymbol;
factor(fsys, x);
if x.typ = bools then
emit(35)
else if x.typ <> notyp then
error(32)
end;
test(fsys, facbegsys, 6)
end (* while *)
end (* factor *);
begin (* term *)
factor(fsys + [times, rdiv, idiv, imod, andsy], x);
while sy in [times, rdiv, idiv, imod, andsy] do
begin
op := sy;
insymbol;
factor(fsys + [times, rdiv, idiv, imod, andsy], y);
if op = times then
begin
x.typ := resulttype(x.typ, y.typ);
case x.typ of
notyp:
;
ints:
emit(57);
reals:
emit(60);
end
end
else if op = rdiv then
begin
if x.typ = ints then
begin
emit1(26, 1);
x.typ := reals
end;
if y.typ = ints then
begin
emit1(26, 0);
y.typ := reals
end;
if (x.typ = reals) and (y.typ = reals) then
emit(61)
else
begin
if (x.typ <> notyp) and (y.typ <> notyp) then
error(32);
x.typ := notyp
end
end
else if op = andsy then
begin
if (x.typ = bools) and (y.typ = bools) then
emit(56)
else
begin
if (x.typ <> notyp) and (y.typ <> notyp) then
error(32);
x.typ := notyp
end
end
else
begin (* op in [idiv, imod] *)
if (x.typ = ints) and (y.typ = ints) then
if op = idiv then
emit(58)
else
emit(59)
else
begin
if (x.typ <> notyp) and (y.typ <> notyp) then
error(34);
x.typ := notyp
end
end
end
end (* term *);
begin (* simpleexpression *)
if sy in [plus, minus] then
begin
op := sy;
insymbol;
term(fsys + [plus, minus], x);
if x.typ > reals then
error(33)
else
{ Changed the negate instruction 36 to also emit a parameter that
says if the operand is real or integer. See comments at top. [sam] }
if op = minus then
emit1(36, ord(x.typ = reals))
end
else
term(fsys + [plus, minus, orsy], x);
while sy in [plus, minus, orsy] do
begin
op := sy;
insymbol;
term(fsys + [plus, minus, orsy], y);
if op = orsy then
begin
if (x.typ = bools) and (y.typ = bools) then
emit(51)
else
begin
if (x.typ <> notyp) and (y.typ <> notyp) then
error(32);
x.typ := notyp
end
end
else
begin
x.typ := resulttype(x.typ, y.typ);
case x.typ of
notyp:
;
ints:
if op = plus then
emit(52)
else
emit(53);
reals:
if op = plus then
emit(54)
else
emit(55)
end
end
end
end (* simpleexpression *);
begin (* expression *)
simpleexpression(fsys + [egl, neg, lss, leg, gtr, geg], x);
if sy in [egl, neg, lss, leg, gtr, geg] then
begin
op := sy;
insymbol;
simpleexpression(fsys, y);
if (x.typ in [notyp, ints, bools, chars]) and (x.typ = y.typ) then
case op of
egl:
emit(45);
neg:
emit(46);
lss:
emit(47);
leg:
emit(48);
gtr:
emit(49);
geg:
emit(50);
end
else
begin
if x.typ = ints then
begin
x.typ := reals;
emit1(26, 1)
end
else if y.typ = ints then
begin
y.typ := reals;
emit1(26, 0)
end;
if (x.typ = reals) and (y.typ = reals) then
case op of
egl:
emit(39);
neg:
emit(40);
lss:
emit(41);
leg:
emit(42);
gtr:
emit(43);
geg:
emit(44);
end
else
error(35)
end;
x.typ := bools
end
end (* expression *);
procedure assignment(lv, ad: integer);
var
x, y: item;
f: integer;
(* tab[i].obj in [variable, prozedure] *)
begin
x.typ := tab[i].typ;
x.ref := tab[i].ref;
if tab[i].normal then
f := 0
else
f := 1;
emit2(f, lv, ad);
if sy in [lbrack, lparent, period] then
selector([becomes, egl] + fsys, x);
if sy = becomes then
insymbol
else
begin
error(51);
if sy = egl then
insymbol
end;
expression(fsys, y);
if x.typ = y.typ then
if x.typ in stantyps then
emit(38)
else if x.ref <> y.ref then
error(46)
else if x.typ = arrays then
emit1(23, atab[x.ref].size)
else
emit1(23, btab[x.ref].vsize)
else if (x.typ = reals) and (y.typ = ints) then
begin
emit1(26, 0);
emit(38)
end
else if (x.typ <> notyp) and (y.typ <> notyp) then
error(46)
end (* assignment *);
procedure compoundstatement;
begin
insymbol;
statement([semicolon, endsy] + fsys);
while sy in [semicolon] + statbegsys do
begin
if sy = semicolon then
insymbol
else
error(14);
statement([semicolon, endsy] + fsys)
end;
if sy = endsy then
insymbol
else
error(57)
end (* compoundstatement *);
procedure ifstatement;
var
x: item;
lc1, lc2: integer;
begin
insymbol;
expression(fsys + [thensy, dosy], x);
if not(x.typ in [bools, notyp]) then
error(17);
lc1 := lc;
emit(11); (* jmpc *)
if sy = thensy then
insymbol
else
begin
error(52);
if sy = dosy then
insymbol
end;
statement(fsys + [elsesy]);
if sy = elsesy then
begin
insymbol;
lc2 := lc;
emit(10);
code[lc1].y := lc;
statement(fsys);
code[lc2].y := lc
end
else
code[lc1].y := lc
end (* if statment *);
procedure casestatement;
var
x: item;
i, j, k, lc1: integer;
casetab: array [1..csmax] of
packed record
val, lc: index
end;
exittab: array [1..csmax] of integer;
procedure caselabel;
var
lab: conrec;
k: integer;
begin
constant(fsys + [comma, colon], lab);
if lab.tp <> x.typ then
error(47)
else if i = csmax then
fatal(6)
else
begin
i := i + 1;
k := 0;
casetab[i].val := lab.i;
casetab[i].lc := lc;
repeat
k := k + 1
until casetab[k].val = lab.i;
if k < i then
error(1); (* multiple definition *)
end
end (* caselabel *);
procedure onecase;
begin
if sy in constbegsys then
begin
caselabel;
while sy = comma do
begin
insymbol;
caselabel
end;
if sy = colon then
insymbol
else
error(5);
statement([semicolon, endsy] + fsys);
j := j + 1;
exittab[j] := lc;
emit(10)
end
end (* onecase *);
begin
insymbol;
i := 0;
j := 0;
expression(fsys + [ofsy, comma, colon], x);
if not(x.typ in [ints, bools, chars, notyp]) then
error(23);
lc1 := lc;
emit(12); (* jmpx *)
if sy = ofsy then
insymbol
else
error(8);
onecase;
while sy = semicolon do
begin
insymbol;
onecase
end;
code[lc1].y := lc;
for k := 1 to i do
begin
emit1(13, casetab[k].val);
emit1(13, casetab[k].lc)
end;
emit1(10, 0);
for k := 1 to j do
code[exittab[k]].y := lc;
if sy = endsy then
insymbol
else
error(57)
end (* casestement *);
procedure repeatstatement;
var
x: item;
lc1: integer;
begin
lc1 := lc;
insymbol;
statement([semicolon, untilsy] + fsys);
while sy in [semicolon] + statbegsys do
begin
if sy = semicolon then
insymbol
else
error(14);
statement([semicolon, untilsy] + fsys)
end;
if sy = untilsy then
begin
insymbol;
expression(fsys, x);
if not(x.typ in [bools, notyp]) then
error(17);
emit1(11, lc1)
end
else
error(53)
end (* repeatstement *);
procedure whilestatement;
var
x: item;
lc1, lc2: integer;
begin
insymbol;
lc1 := lc;
expression(fsys + [dosy], x);
if not(x.typ in [bools, notyp]) then
error(17);
lc2 := lc;
emit(11);
if sy = dosy then
insymbol
else
error(54);
statement(fsys);
emit1(10, lc1);
code[lc2].y := lc
end (* whilestatement *);
procedure forstatement;
var
cvt: types;
x: item;
i, f, lc1, lc2: integer;
begin
insymbol;
cvt := notyp;
if sy = ident then
begin
i := loc(id);
insymbol;
if i = 0 then
cvt := ints
else if tab[i].obj = variable then
begin
cvt := tab[i].typ;
emit2(0, tab[i].lev, tab[i].adr);
if not(cvt in [notyp, ints, bools, chars]) then
error(18)
end
else
begin
error(37);
cvt := ints
end
end
else
skip([becomes, tosy, downtosy, dosy] + fsys, 2);
if sy = becomes then
begin
insymbol;
expression([tosy, downtosy, dosy] + fsys, x);
if x.typ <> cvt then
error(19);
end
else
skip([tosy, downtosy, dosy] + fsys, 51);
f := 14;
if sy in [tosy, downtosy] then
begin
if sy = downtosy then
f := 16;
insymbol;
expression([dosy] + fsys, x);
if x.typ <> cvt then
error(19)
end
else
skip([dosy] + fsys, 55);
lc1 := lc;
emit(f);
if sy = dosy then
insymbol
else
error(54);
lc2 := lc;
statement(fsys);
emit1(f + 1, lc2);
code[lc1].y := lc
end (* forstatement *);
procedure standproc(n: integer);
var
i, f: integer;
x, y: item;
begin
case n of
1, 2:
begin (* read *)
if not iflag then
begin
error(20);
iflag := true
end;
if sy = lparent then
begin
repeat
insymbol;
if sy <> ident then
error(2)
else
begin
i := loc(id);
insymbol;
if i <> 0 then
if tab[i].obj <> variable then
error(37)
else
begin
x.typ := tab[i].typ;
x.ref := tab[i].ref;
if tab[i].normal then
f := 0
else
f := 1;
emit2(f, tab[i].lev, tab[i].adr);
if sy in [lbrack, lparent, period] then
selector(fsys + [comma, rparent], x);
if x.typ in [ints, reals, chars, notyp] then
emit1(27, ord(x.typ))
else
error(40)
end
end;
test([comma, rparent], fsys, 6);
until sy <> comma;
if sy = rparent then
insymbol
else
error(4)
end;
if n = 2 then
emit(62)
end;
3, 4:
begin (* write *)
if sy = lparent then
begin
repeat
insymbol;
if sy = stringt then
begin
emit1(24, sleng);
emit1(28, inum);
insymbol
end
else
begin
expression(fsys + [comma, colon, rparent], x);
if not(x.typ in stantyps) then
error(41);
if sy = colon then
begin
insymbol;
expression(fsys + [comma, colon, rparent], y);
if y.typ <> ints then
error(43);
if sy = colon then
begin
if x.typ <> reals then
error(42);
insymbol;
expression(fsys + [comma, rparent], y);
if y.typ <> ints then
error(43);
emit(37)
end
else
emit1(30, ord(x.typ))
end
else
emit1(29, ord(x.typ))
end
until sy <> comma;
if sy = rparent then
insymbol
else
error(4)
end;
if n = 4 then
emit(63)
end;
end (* case *)
end (* standproc *);
begin (* statement *)
if sy in statbegsys + [ident] then
case sy of
ident:
begin
i := loc(id);
insymbol;
if i <> 0 then
case tab[i].obj of
konstant, typel:
error(45);
variable:
assignment(tab[i].lev, tab[i].adr);
prozedure:
if tab[i].lev <> 0 then
call(fsys, i)
else
standproc(tab[i].adr);
funktion:
if tab[i].ref = display[level] then
assignment(tab[i].lev + 1, 0)
else
error(45)
end
end;
beginsy:
compoundstatement;
ifsy:
ifstatement;
casesy:
casestatement;
whilesy:
whilestatement;
repeatsy:
repeatstatement;
forsy:
forstatement;
end;
test(fsys, [], 14)
end (* statement *);
begin (* block *)
dx := 5;
prt := t;
if level > lmax then
fatal(5);
test([lparent, colon, semicolon], fsys, 7);
enterblock;
display[level] := b;
prb := b;
tab[prt].typ := notyp;
tab[prt].ref := prb;
if sy = lparent then
parameterlist;
btab[prb].lastpar := t;
btab[prb].psize := dx;
if isfun then
if sy = colon then
begin
insymbol; (* function type *)
if sy = ident then
begin
x := loc(id);
insymbol;
if x <> 0 then
if tab[x].obj <> typel then
error(29)
else if tab[x].typ in stantyps then
tab[prt].typ := tab[x].typ
else
error(15)
end
else
skip([semicolon] + fsys, 2)
end
else
error(5);
if sy = semicolon then
insymbol
else
error(14);
repeat
if sy = constsy then
constantdeclaration;
if sy = typesy then
typedeclaration;
if sy = varsy then
variabledeclaration;
btab[prb].vsize := dx;
while sy in [proceduresy, functionsy] do
procdeclaration;
test([beginsy], blockbegsys + statbegsys, 56)
until sy in statbegsys;
tab[prt].adr := lc;
insymbol;
statement([semicolon, endsy] + fsys);
while sy in [semicolon] + statbegsys do
begin
if sy = semicolon then
insymbol
else
error(14);
statement([semicolon, endsy] + fsys)
end;
if sy = endsy then
insymbol
else
error(57);
test(fsys + [period], [], 6)
end (* block *);
procedure interpret;
(* global code, tab, btab *)
var
ir: order; (* instruction buffer *)
pc: integer; (* program counter *)
ps: (run, fin, caschk, divchk, inxchk, stkchk, linchk, lngchk, redchk);
t: integer; (* top stack index *)
b: integer; (* base index *)
lncnt, ocnt, blkcnt, chrcnt: integer; (* counters *)
h1, h2, h3, h4: integer;
fld: array [1..4] of integer; (* default field widths *)
display: array [1..lmax] of integer;
s: array [1..stacksize] of (* blockmark: *)
record (* *)
case types of (* s[b+0] = fct result *)
ints: (i: integer); (* s[b+1] = return adr *)
reals: (r: real); (* s[b+2] = static link *)
bools: (b: boolean); (* s[b+3] = dynamic link *)
chars: (c: char); (* s[b+4] = table index *)
notyp, arrays, records: ()
end;
begin (* interpret *)
s[1].i := 0;
s[2].i := 0;
s[3].i := -1;
s[4].i := btab[1].last;
b := 0;
display[1] := 0;
t := btab[2].vsize - 1;
pc := tab[s[4].i].adr;
ps := run;
lncnt := 0;
ocnt := 0;
chrcnt := 0;
fld[1] := 10;
fld[2] := 22;
fld[3] := 10;
fld[4] := 1;
repeat
ir := code[pc];
pc := pc + 1;
ocnt := ocnt + 1;
case ir.f of
0: begin (* load address *)
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t].i := display[ir.x] + ir.y
end;
1: begin (* load value *)
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t] := s[display[ir.x] + ir.y]
end;
2: begin (* load indirect *)
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t] := s[s[display[ir.x] + ir.y].i]
end;
3: begin (* update display *)
h1 := ir.y;
h2 := ir.x;
h3 := b;
repeat
display[h1] := h3;
h1 := h1 - 1;
h3 := s[h3 + 2].i
until h1 = h2
end;
8: case ir.y of
0: s[t].i := abs(s[t].i);
1: s[t].r := abs(s[t].r);
2: s[t].i := sqr(s[t].i);
3: s[t].r := sqr(s[t].r);
4: s[t].b := odd(s[t].i);
5: begin (* s[t].c := chr(s[t].i); *)
if (s[t].i < 0) or (s[t].i > inxmax { [sam] } ) then
ps := inxchk
end;
6: (* s[t].i := ord(s[t].c) *);
7: s[t].c := succ(s[t].c);
8: s[t].c := pred(s[t].c);
9: s[t].i := round(s[t].r);
10: s[t].i := trunc(s[t].r);
11: s[t].r := sin(s[t].r);
12: s[t].r := cos(s[t].r);
13: s[t].r := exp(s[t].r);
14: s[t].r := ln(s[t].r);
15: s[t].r := sqrt(s[t].r);
16: s[t].r := arctan(s[t].r);
17: begin
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t].b := eof(input)
end;
18: begin
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t].b := eoln(input)
end;
end;
9: s[t].i := s[t].i + ir.y; (* offset *)
10: pc := ir.y; (* jump *)
11: begin (* conditional jump *)
if not s[t].b then
pc := ir.y;
t := t - 1
end;
12: begin (* switch *)
h1 := s[t].i;
t := t - 1;
h2 := ir.y;
h3 := 0;
repeat
if code[h2].f <> 13 then
begin
h3 := 1;
ps := caschk
end
else if code[h2].y = h1 then
begin
h3 := 1;
pc := code[h2 + 1].y
end
else
h2 := h2 + 2
until h3 <> 0
end;
14: begin (* forlup *)
h1 := s[t - 1].i;
if h1 <= s[t].i then
s[s[t - 2].i].i := h1
else
begin
t := t - 3;
pc := ir.y
end
end;
15: begin (* for2up *)
h2 := s[t - 2].i;
h1 := s[h2].i + 1;
if h1 <= s[t].i then
begin
s[h2].i := h1;
pc := ir.y
end
else
t := t - 3;
end;
16: begin (* for1down *)
h1 := s[t - 1].i;
if h1 >= s[t].i then
s[s[t - 2].i].i := h1
else
begin
pc := ir.y;
t := t - 3
end
end;
17: begin (* for2down *)
h2 := s[t - 2].i;
h1 := s[h2].i - 1;
if h1 >= s[t].i then
begin
s[h2].i := h1;
pc := ir.y
end
else
t := t - 3;
end;
18: begin (* mark stack *)
h1 := btab[tab[ir.y].ref].vsize;
if t + h1 > stacksize then
ps := stkchk
else
begin
t := t + 5;
s[t - 1].i := h1 - 1;
s[t].i := ir.y
end
end;
19: begin (* call *)
h1 := t - ir.y; (* h1 points top base *)
h2 := s[h1 + 4].i;
h3 := tab[h2].lev;
display[h3 + 1] := h1;
h4 := s[h1 + 3].i + h1;
s[h1 + 1].i := pc;
s[h1 + 2].i := display[h3];
s[h1 + 3].i := b;
for h3 := t + 1 to h4 do
s[h3].i := 0;
b := h1;
t := h4;
pc := tab[h2].adr
end;
20: begin (* index *)
h1 := ir.y; (* h1 points to atab *)
h2 := atab[h1].low;
h3 := s[t].i;
if h3 < h2 then
ps := inxchk
else if h3 > atab[h1].high then
ps := inxchk
else
begin
t := t - 1;
s[t].i := s[t].i + (h3 - h2)
end
end;
21: begin (* index *)
h1 := ir.y; (* h1 points to atab *)
h2 := atab[h1].low;
h3 := s[t].i;
if h3 < h2 then
ps := inxchk
else if h3 > atab[h1].high then
ps := inxchk
else
begin
t := t - 1;
s[t].i := s[t].i + (h3 - h2) * atab[h1].elsize
end
end;
22: begin (* load block *)
h1 := s[t].i;
t := t - 1;
h2 := ir.y + t;
if h2 > stacksize then
ps := stkchk
else
while t < h2 do
begin
t := t + 1;
s[t] := s[h1];
h1 := h1 + 1
end
end;
23: begin (* copy block *)
h1 := s[t - 1].i;
h2 := s[t].i;
h3 := h1 + ir.y;
while h1 < h3 do
begin
s[h1] := s[h2];
h1 := h1 + 1;
h2 := h2 + 1
end;
t := t - 2
end;
24: begin (* literal *)
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t].i := ir.y
end;
25: begin (* load real *)
t := t + 1;
if t > stacksize then
ps := stkchk
else
s[t].r := rconst[ir.y]
end;
26: begin (* float *)
h1 := t - ir.y;
s[h1].r := s[h1].i
end;
27: begin (* read *)
if eof(input) then
ps := redchk
else
case ir.y of
1: read(s[s[t].i].i);
2: read(s[s[t].i].r);
4: read(s[s[t].i].c)
end;
t := t - 1
end;
28: begin (* write string *)
h1 := s[t].i;
h2 := ir.y;
t := t - 1;
chrcnt := chrcnt + h1;
if chrcnt > lineleng then
ps := lngchk;
repeat
write(stab[h2]);
h1 := h1 - 1;
h2 := h2 + 1
until h1 = 0
end;
29: begin (* write1 *)
chrcnt := chrcnt + fld[ir.y];
if chrcnt > lineleng then
ps := lngchk
else
case ir.y of
1: write(s[t].i:fld[1]);
2: write(s[t].r:fld[2]);
3: write(s[t].b:fld[3]);
4: write(s[t].c);
end;
t := t - 1
end;
30: begin (* write2 *)
chrcnt := chrcnt + s[t].i;
if chrcnt > lineleng then
ps := lngchk
else
case ir.y of
1: write(s[t - 1].i:s[t].i);
2: write(s[t - 1].r:s[t].i);
3: write(s[t - 1].b:s[t].i);
4: write(s[t - 1].c:s[t].i);
end;
t := t - 2
end;
31: ps := fin;
32: begin (* exit procedure *)
t := b - 1;
pc := s[b + 1].i;
b := s[b + 3].i
end;
33: begin (* exit function *)
t := b;
pc := s[b + 1].i;
b := s[b + 3].i
end;
34: s[t] := s[s[t].i];
35: s[t].b := not s[t].b;
{ Changed the negate instruction to work according to the type of the
operand. See the header comments. [sam] }
36: begin
if ir.y = 0 then
s[t].i := -s[t].i
else
s[t].r := -s[t].r
end;
37: begin
chrcnt := chrcnt + s[t - 1].i;
if chrcnt > lineleng then
ps := lngchk
else
write(s[t - 2].r:s[t - 1].i:s[t].i);
t := t - 3
end;
38: begin (* store *)
s[s[t - 1].i] := s[t];
t := t - 2;
end;
39: begin
t := t - 1;
s[t].b := s[t].r = s[t + 1].r
end;
40: begin
t := t - 1;
s[t].b := s[t].r <> s[t + 1].r
end;
41: begin
t := t - 1;
s[t].b := s[t].r < s[t + 1].r
end;
42: begin
t := t - 1;
s[t].b := s[t].r <= s[t + 1].r
end;
43: begin
t := t - 1;
s[t].b := s[t].r > s[t + 1].r
end;
44: begin
t := t - 1;
s[t].b := s[t].r >= s[t + 1].r
end;
45: begin
t := t - 1;
s[t].b := s[t].i = s[t + 1].i
end;
46: begin
t := t - 1;
s[t].b := s[t].i <> s[t + 1].i
end;
47: begin
t := t - 1;
s[t].b := s[t].i < s[t + 1].i
end;
48: begin
t := t - 1;
s[t].b := s[t].i <= s[t + 1].i
end;
49: begin
t := t - 1;
s[t].b := s[t].i > s[t + 1].i
end;
50: begin
t := t - 1;
s[t].b := s[t].i >= s[t + 1].i
end;
51: begin
t := t - 1;
s[t].b := s[t].b or s[t + 1].b
end;
52: begin
t := t - 1;
s[t].i := s[t].i + s[t + 1].i
end;
53: begin
t := t - 1;
s[t].i := s[t].i - s[t + 1].i
end;
54: begin
t := t - 1;
s[t].r := s[t].r + s[t + 1].r;
end;
55: begin
t := t - 1;
s[t].r := s[t].r - s[t + 1].r;
end;
56: begin
t := t - 1;
s[t].b := s[t].b and s[t + 1].b;
end;
57: begin
t := t - 1;
s[t].i := s[t].i * s[t + 1].i
end;
58: begin
t := t - 1;
if s[t + 1].i = 0 then
ps := divchk
else
s[t].i := s[t].i div s[t + 1].i
end;
59: begin
t := t - 1;
if s[t + 1].i = 0 then
ps := divchk
else
s[t].i := s[t].i mod s[t + 1].i
end;
60: begin
t := t - 1;
s[t].r := s[t].r * s[t + 1].r;
end;
61: begin
t := t - 1;
s[t].r := s[t].r / s[t + 1].r;
end;
62: if eof(input) then
ps := redchk
else
readln;
63: begin
writeln;
lncnt := lncnt + 1;
chrcnt := 0;
if lncnt > linelimit then
ps := linchk
end
end (* case *);
until ps <> run;
if ps <> fin then
begin
writeln;
{ Changed to double spacing [sam] }
write('halt at', pc:5, ' because of ');
writeln;
case ps of
caschk:
writeln('undefined case');
divchk:
writeln('division by 0');
inxchk:
writeln('invalid index');
stkchk:
writeln('storage overflow');
linchk:
writeln('too much output');
lngchk:
writeln('line too long');
redchk:
writeln('reading past end of file');
end;
h1 := b;
blkcnt := 10; (* post mortem dump *)
repeat
writeln;
blkcnt := blkcnt - 1;
if blkcnt = 0 then
h1 := 0;
h2 := s[h1 + 4].i;
if h1 <> 0 then
writeln(' ', tab[h2].name, ' called at',
s[h1 + 1].i:5);
h2 := btab[tab[h2].ref].last;
while h2 <> 0 do
with tab[h2] do
begin
if obj = variable then
if typ in stantyps then
begin
write(' ', name, ' = ');
if normal then
h3 := h1 + adr
else
h3 := s[h1 + adr].i;
case typ of
ints:
writeln(s[h3].i);
reals:
writeln(s[h3].r);
bools:
writeln(s[h3].b);
chars:
writeln(s[h3].c);
end
end;
h2 := link
end;
h1 := s[h1 + 3].i
until h1 < 0;
end;
writeln;
writeln(ocnt, ' steps')
end (* interpret *);
begin { main program }
{ [sam] Added sign-on }
writeln;
writeln('Pascal-S compiler/interpreter');
{ [sam] If you need to associate 'srcfil' with an external file in the
source, do that here }
filename := ParamStr(1);
if (filename <> '') and (ExtractFileExt(filename) = '') then
filename := ChangeFileExt(filename, '.pas');
if not FileExists(filename) then
begin
writeln('File not found.');
Halt;
end;
AssignFile(srcfil, filename);
reset(srcfil);
key[ 1] := 'and '; key[ 2] := 'array ';
key[ 3] := 'begin '; key[ 4] := 'case ';
key[ 5] := 'const '; key[ 6] := 'div ';
key[ 7] := 'do '; key[ 8] := 'downto ';
key[ 9] := 'else '; key[10] := 'end ';
key[11] := 'for '; key[12] := 'function ';
key[13] := 'if '; key[14] := 'mod ';
key[15] := 'not '; key[16] := 'of ';
key[17] := 'or '; key[18] := 'procedure ';
key[19] := 'program '; key[20] := 'record ';
key[21] := 'repeat '; key[22] := 'then ';
key[23] := 'to '; key[24] := 'type ';
key[25] := 'until '; key[26] := 'var ';
key[27] := 'while ';
ksy[ 1] := andsy; ksy[ 2] := arraysy;
ksy[ 3] := beginsy; ksy[ 4] := casesy;
ksy[ 5] := constsy; ksy[ 6] := idiv;
ksy[ 7] := dosy; ksy[ 8] := downtosy;
ksy[ 9] := elsesy; ksy[10] := endsy;
ksy[11] := forsy; ksy[12] := functionsy;
ksy[13] := ifsy; ksy[14] := imod;
ksy[15] := notsy; ksy[16] := ofsy;
ksy[17] := orsy; ksy[18] := proceduresy;
ksy[19] := programsy; ksy[20] := recordsy;
ksy[21] := repeatsy; ksy[22] := thensy;
ksy[23] := tosy; ksy[24] := typesy;
ksy[25] := untilsy; ksy[26] := varsy;
ksy[27] := whilesy;
sps['+'] := plus; sps['-'] := minus;
sps['*'] := times; sps['/'] := rdiv;
sps['('] := lparent; sps[')'] := rparent;
sps['='] := egl; sps[','] := comma;
sps['['] := lbrack; sps[']'] := rbrack;
sps['#'] := neg; sps['&'] := andsy;
sps[';'] := semicolon;
constbegsys := [plus, minus, intcon, realcon, charcon, ident];
typebegsys := [ident, arraysy, recordsy];
blockbegsys := [constsy, typesy, varsy, proceduresy, functionsy, beginsy];
facbegsys := [intcon, realcon, charcon, ident, lparent, notsy];
statbegsys := [beginsy, ifsy, whilesy, repeatsy, forsy, casesy];
stantyps := [notyp, ints, reals, bools, chars];
lc := 0;
ll := 0;
cc := 0;
ch := ' ';
errpos := 0;
errs := [];
insymbol;
t := -1;
a := 0;
b := 1;
sx := 0;
c2 := 0;
display[0] := 1;
iflag := false;
oflag := false;
if sy <> programsy then
error(3)
else
begin
insymbol;
if sy <> ident then
error(2)
else
begin
progname := id;
insymbol;
if sy <> lparent then
error(9)
else
repeat
insymbol;
if sy <> ident then
error(2)
else
begin
if id = 'input ' then
iflag := true
else if id = 'output ' then
oflag := true
else
error(0);
insymbol
end
until sy <> comma;
if sy = rparent then
insymbol
else
error(4);
if not oflag then
error(20)
end
end;
enter(' ', variable, notyp, 0); (* sentinel *)
enter('false ', konstant, bools, 0);
enter('true ', konstant, bools, 1);
enter('real ', typel, reals, 1);
enter('char ', typel, chars, 1);
enter('boolean ', typel, bools, 1);
enter('integer ', typel, ints , 1);
enter('abs ', funktion, reals, 0);
enter('sqr ', funktion, reals, 2);
enter('odd ', funktion, bools, 4);
enter('chr ', funktion, chars, 5);
enter('ord ', funktion, ints, 6);
enter('succ ', funktion, chars, 7);
enter('pred ', funktion, chars, 8);
enter('round ', funktion, ints, 9);
enter('trunc ', funktion, ints, 10);
enter('sin ', funktion, reals, 11);
enter('cos ', funktion, reals, 12);
enter('exp ', funktion, reals, 13);
enter('ln ', funktion, reals, 14);
enter('sqrt ', funktion, reals, 15);
enter('arctan ', funktion, reals, 16);
enter('eof ', funktion, bools, 17);
enter('eoln ', funktion, bools, 18);
enter('read ', prozedure, notyp, 1);
enter('readln ', prozedure, notyp, 2);
enter('write ', prozedure, notyp, 3);
enter('writeln ', prozedure, notyp, 4);
enter(' ', prozedure, notyp, 0);
with btab[1] do
begin
last := t;
lastpar := 1;
psize := 0;
vsize := 0
end;
block(blockbegsys + statbegsys, false, 1);
if sy <> period then
error(22);
emit(31); (* halt *)
if btab[2].vsize > stacksize then
error(49);
if progname = 'test0 ' then
printtables;
if errs = [] then
begin
if iflag then
begin
if eof then
writeln(' input data missing')
else
begin
writeln(' (eor) '); (* copy input data *)
while not eof do
begin
write(' ');
while not eoln do
begin
read(ch);
write(ch)
end;
writeln;
read(ch)
end;
end
end;
writeln(' (eof) ');
interpret
end
else
errormsg;
end.