ORCA-C/Printf.pas

1020 lines
27 KiB
ObjectPascal

{$optimize 7}
{---------------------------------------------------------------}
{ }
{ Printf }
{ }
{ Analyzes printf/scanf format and arguments to check for }
{ potential problems. }
{ Called from FunctionParms (Expression.pas) }
{ Enabled via #pragma lint 16 }
{---------------------------------------------------------------}
unit Printf;
interface
{$LibPrefix '0/obj/'}
uses CCommon, Scanner;
{$segment 'PRINTF'}
type
fmtArgPtr = ^fmtArgRecord;
fmtArgRecord = record
next: fmtArgPtr;
ty: typePtr;
tk: tokenPtr;
end;
{
format arg1: printf
format arg2: fprintf, sprintf, asprintf, dprintf
format arg3: snprintf
format arg1: scanf
format arg2: fscanf, sscanf
}
fmt_type = (fmt_none, fmt_printf1, fmt_printf2, fmt_printf3, fmt_scanf1, fmt_scanf2);
function FormatClassify(fname: stringPtr): fmt_type;
procedure FormatCheck(fmt: fmt_type; args: fmtArgPtr);
implementation
const
feature_hh = true;
feature_ll = true;
feature_s_long = false;
feature_n_size = true;
feature_scanf_ld = true;
type
length_modifier = (default, h, hh, l, ll, j, z, t, ld);
state_enum = (st_text, st_flag, st_width,
st_precision_dot, st_precision, st_precision_number,
st_length, st_length_h, st_length_l, st_format,
{ scanf }
st_suppress, st_set, st_set_1, st_set_2,
st_error);
types = set of baseTypeEnum;
function KeyPress: boolean; extern; {in Scanner.asm}
function FormatClassify {fname: stringPtr): fmt_type};
{
Check if a function name is printf/scanf. Caller must check if
it otherwise matches (variadic, direct call)
}
var
l: integer;
begin {FormatClassify}
FormatClassify := fmt_none;
l := length(fname^);
if (l >= 5) and (l <= 8) then case fname^[1] of
'a': if fname^ = 'asprintf' then FormatClassify := fmt_printf2;
'd': if fname^ = 'dprintf' then FormatClassify := fmt_printf2;
'p': if fname^ = 'printf' then FormatClassify := fmt_printf1;
'f':
if fname^ = 'fprintf' then FormatClassify := fmt_printf2
else if fname^ = 'fscanf' then FormatClassify := fmt_scanf2;
's':
if fname^ = 'scanf' then FormatClassify := fmt_scanf1
else if fname^ = 'snprintf' then FormatClassify := fmt_printf3
else if fname^ = 'sprintf' then FormatClassify := fmt_printf2
else if fname^ = 'sscanf' then FormatClassify := fmt_scanf2;
otherwise: ;
end; {case}
end; {FormatClassify}
procedure FormatCheck{fmt: fmt_type; args: fmtArgPtr};
var
head: fmtArgPtr;
s: longstringPtr;
state: state_enum;
has_length: length_modifier;
error_count: integer;
expected: integer;
offset: integer;
number_set : set of char;
flag_set : set of char;
length_set : set of char;
format_set : set of char;
procedure Warning(msg: stringPtr);
{
Pretty Print a warning.
offset is the location of the current % character within s.
}
var
i: integer;
ch: char;
begin {Warning}
if error_count = 0 then begin
WriteLine;
Error(124);
WriteLine;
if s <> nil then begin
Write(' > "');
for i := 1 to s^.length-1 do begin
ch := s^.str[i];
if ch in [' '..'~'] then begin
if ch in ['"','\','?'] then
write('\');
write(ch);
end {if}
else
case ord(ch) of
7: write('\a');
8: write('\b');
9: write('\t');
10: write('\n');
11: write('\v');
12: write('\f');
13: write('\r');
otherwise: begin
write('\');
write((ord(ch)>>6):1);
write(((ord(ch)>>3) & $0007):1);
write((ord(ch) & $0007):1);
end;
end; {case}
end; {for}
WriteLn('"');
end; {if}
end; {if}
error_count := error_count + 1;
Write(' ');
if offset = 0 then
if s <> nil then begin
offset := s^.length-1;
write(' ');
end; {if}
if s <> nil then begin
if offset > 0 then begin
if offset > s^.length-1 then
offset := s^.length-1;
for i := 1 to offset do begin
ch := s^.str[i];
if ch in [' '..'~'] then begin
if ch in ['"','\','?'] then
write(' ');
write(' ');
end {if}
else
case ord(ch) of
7,8,9,10,11,12,13: write(' ');
otherwise: write(' ');
end; {case}
end; {for}
end; {if}
Write('^ ');
end; {if}
WriteLn(msg^);
end; {Warning}
procedure WarningConversionChar(c: char);
{ Warn that a conversion character is invalid, eg %z }
var
msg: stringPtr;
begin {WarningConversionChar}
if (ord(c) >= $20) and (ord(c) < $7f) then begin
new(msg);
msg^ := concat('unknown conversion type character ''', c, ''' in format');
Warning(msg);
dispose(msg);
end {if}
else Warning(@'unknown conversion type character in format');
end; {WarningConversionChar}
procedure WarningExtraArgs(i: integer);
{ Warn that too many arguments were provided }
var
msg: stringPtr;
begin {WarningExtraArgs}
new(msg);
msg^ := concat('extra argument(s) provided (', cnvis(i), ' expected)');
Warning(msg);
dispose(msg);
end; {WarningExtraArgs}
function popType: typePtr;
{ Return the token type and advance the linked list. }
begin {popType}
expected := expected + 1;
popType := nil;
if args <> nil then begin
popType := args^.ty;
args := args^.next;
end; {if}
end; {popType}
procedure expect_long;
{ Verify the current argument is a long int.}
var
ty: typePtr;
begin {expect_long}
ty := popType;
if ty <> nil then begin
if (ty^.kind <> scalarType) or (not (ty^.baseType in [cgLong, cgULong])) then begin
Warning(@'expected long int');
end; {if}
end {if}
else begin
Warning(@'argument missing; expected long int');
end; {else}
end; {expect_long}
procedure expect_long_long;
{ Verify the current argument is a long long int.}
var
ty: typePtr;
begin {expect_long_long}
ty := popType;
if ty <> nil then begin
if (ty^.kind <> scalarType) or (not (ty^.baseType in [cgQuad, cgUQuad])) then begin
Warning(@'expected long long int');
end; {if}
end {if}
else begin
Warning(@'argument missing; expected long long int');
end; {else}
end; {expect_long_long}
procedure expect_int;
var
ty: typePtr;
begin {expect_int}
ty := popType;
if ty <> nil then begin
if (ty^.kind <> scalarType) or
not (ty^.baseType in [cgWord, cgUWord, cgByte, cgUByte]) then begin
Warning(@'expected int');
end; {if}
end {if}
else begin
Warning(@'argument missing; expected int');
end; {else}
end; {expect_int}
procedure expect_char;
var
ty: typePtr;
begin {expect_char}
ty := popType;
if ty <> nil then begin
if (ty^.kind <> scalarType) or
not (ty^.baseType in [cgWord, cgUWord, cgByte, cgUByte]) then begin
Warning(@'expected char');
end; {if}
end {if}
else begin
Warning(@'argument missing; expected char');
end; {else}
end; {expect_char}
procedure expect_extended;
{ Verify the current argument is an extended*. }
{ * or float or double or comp since they're all passed as extended }
var
ty: typePtr;
begin {expect_extended}
ty := popType;
if ty <> nil then begin
if (ty^.kind <> scalarType) or
not (ty^.baseType in [cgExtended, cgReal, cgDouble, cgComp]) then begin
Warning(@'expected a floating-point value');
end; {if}
end {if}
else begin
Warning(@'argument missing; expected a floating-point value');
end; {else}
end; {expect_extended}
procedure expect_pointer;
{ Verify the current argument is a pointer of some sort. }
var
ty: typePtr;
begin {expect_pointer}
ty := popType;
if ty <> nil then begin
if not (ty^.kind in [pointerType,arrayType]) then begin
Warning(@'expected pointer');
end; {if}
end {if}
else begin
Warning(@'argument missing; expected pointer');
end; {else}
end; {expect_pointer}
procedure expect_pointer_to_pointer;
{ Verify the current argument is a pointer to a pointer.}
var
ty: typePtr;
ok: boolean;
begin {expect_pointer_to_pointer}
ok := false;
ty := popType;
if ty <> nil then
if (ty^.kind = pointerType) or (ty^.kind = arrayType) then
if ty^.pType <> nil then
if ty^.pType^.kind = pointerType then
ok := true;
if not ok then begin
if ty = nil then
Warning(@'argument missing; expected pointer to a pointer')
else Warning(@'expected pointer to a pointer');
end; {if}
end; {expect_pointer_to_pointer}
procedure expect_pointer_to(expected: types; name: stringPtr);
{ Verify the current argument is a pointer to the expected set.}
var
ty: typePtr;
baseTy: typePtr;
ok: boolean;
procedure error(prefix: stringPtr);
var
msg: stringPtr;
begin
new(msg);
msg^ := concat(prefix^, name^);
Warning(msg);
dispose(msg);
end; {error}
begin {expect_pointer_to}
ok := false;
ty := popType;
baseTy := nil;
if ty <> nil then
if (ty^.kind = pointerType) or (ty^.kind = arrayType) then begin
baseTy := ty^.pType;
if (baseTy <> nil)
and (baseTy^.kind = scalarType)
and (baseTy^.baseType in expected)
then ok := true;
end; {if}
if not ok then begin
if ty = nil then
error(@'argument missing; expected pointer to ')
else error(@'expected pointer to ');
end; {if}
end; {expect_pointer_to}
procedure do_length(c: char);
{ helper to process the length modifier }
begin {do_length}
state := st_format;
case c of
'h': begin
has_length := h;
state := st_length_h;
end;
'l': begin
has_length := l;
state := st_length_l;
end;
'j': has_length := j;
'z': has_length := z;
't': has_length := t;
'L': has_length := ld;
end; {case}
end; {do_length}
procedure FormatScanf;
{ Check the scanf string and arguments. }
label 1;
var
i: integer;
c: char;
has_suppress: boolean;
procedure do_scanf_format;
{ check an individual scanf argument. }
{
(current) ORCALib limitations, wrt size modifiers:
- ignored for string types
- hh not supported
- L not supported
- ignored for 'n'
}
var
expected: types;
name: stringPtr;
begin {do_scanf_format}
name := nil;
state := st_text;
if c in format_set then begin
case c of
'%': begin
if has_suppress or (has_length <> default) then
Warning(@'invalid element in %% conversion specification');
has_suppress := true;
end;
'b', 'P': begin
if has_length <> default then
Warning(@'length modifier may not be used with %b or %P');
expected := [cgByte, cgUByte];
name := @'char';
end;
'c', 's', '[' : begin
{ %ls, etc is a wchar_t *}
expected := [cgByte, cgUByte];
name := @'char';
if has_length = l then begin
expected := [cgWord, cgUWord];
name := @'wchar_t';
if not feature_s_long then
Warning(@'%ls, %lc, or %l[ is not currently supported');
end {if}
else if has_length <> default then
Warning(@'invalid length modifier');
if c = '[' then state := st_set_1;
end;
'd', 'i', 'u', 'o', 'x', 'X': begin
case has_length of
hh: begin
expected := [cgByte, cgUByte];
name := @'char';
end;
l, z, t: begin
expected := [cgLong, cgULong];
name := @'long';
end;
ll, j: begin
expected := [cgQuad, cgUQuad];
name := @'long long';
end;
h: begin
expected := [cgWord, cgUWord];
name := @'short';
end;
default: begin
expected := [cgWord, cgUWord];
name := @'int';
end;
otherwise: begin
Warning(@'invalid length modifier');
expected := [cgWord, cgUWord];
name := @'int';
end;
end; {case}
end;
'n': begin
{ n.b. - *n is undefined; orcalib pops a parm but doesn't store.}
{ C99 - support for length modifiers }
if has_suppress then Warning(@'behavior of %*n is undefined');
has_suppress := false;
if (not feature_n_size) and (has_length <> default) then
Warning(@'size modifier for %n is not currently supported');
case has_length of
hh: begin
expected := [cgByte, cgUByte];
name := @'char';
end;
l, z, t: begin
expected := [cgLong, cgULong];
name := @'long';
end;
ll, j: begin
expected := [cgQuad, cgUQuad];
name := @'long long';
end;
h: begin
expected := [cgWord, cgUWord];
name := @'short';
end;
default: begin
expected := [cgWord, cgUWord];
name := @'int';
end;
otherwise: begin
Warning(@'invalid length modifier');
expected := [cgWord, cgUWord];
name := @'int';
end;
end; {case}
end;
'p': begin
if has_length <> default then
Warning(@'length modifier may not be used with %p');
if not has_suppress then expect_pointer_to_pointer;
has_suppress := true;
end;
'a', 'A', 'f', 'F', 'g', 'G', 'e', 'E': begin
case has_length of
ld: begin
if not feature_scanf_ld then
if not has_suppress then
Warning(@'L length modifier is not currently supported');
expected := [cgExtended];
name := @'long double';
end;
l: begin
expected := [cgDouble];
name := @'double';
end;
default: begin
expected := [cgReal];
name := @'float';
end;
otherwise: begin
Warning(@'invalid length modifier');
expected := [cgReal];
name := @'float';
end;
end; {case}
end;
end; { case }
if not has_suppress then begin
expect_pointer_to(expected, name);
end; {if}
end {if}
else WarningConversionChar(c);
end; {do_scanf_format}
begin {FormatScanf}
{
'%'
'*'? - assignment suppression
\d* - maximum field width
(h|hh|l|ll|j|z|t|L)? - length modifier
[%bcsdiuoxXnaAeEfFgGp] | set - format
set: '[[' [^]]* ']'
set: '[^[' [^]]* ']'
set: '[' [^]]+ ']'
}
state := st_text;
expected := 0;
offset := 0;
number_set := ['0' .. '9'];
length_set := ['h', 'l', 'j', 't', 'z', 'L'];
flag_set := ['#', '0', '-', '+', ' '];
format_set := ['%', '[', 'b', 'c', 's', 'd', 'i', 'o', 'x', 'X', 'u',
'f', 'F', 'e', 'E', 'a', 'A', 'g', 'G', 'n', 'p', 'P'];
for i := 1 to s^.length do begin
c := s^.str[i];
case state of
st_text: if c = '%' then begin
state := st_suppress;
offset := i;
has_length := default;
has_suppress := false;
end; {if}
st_suppress: { suppress? width? length? format }
if c = '*' then begin
state := st_width;
has_suppress := true;
end {if}
else if c in number_set then state := st_width
else if c in length_set then do_length(c)
else do_scanf_format;
st_width: {width? length? format }
if c in number_set then state := st_width
else if c in length_set then do_length(c)
else do_scanf_format;
st_length_h: { h? format }
if c = 'h' then begin
has_length := hh;
state := st_format;
if not feature_hh then
Warning(@'hh modifier is not currently supported');
end {if}
else do_scanf_format;
st_length_l: { l? format }
if c = 'l' then begin
has_length := ll;
state := st_format;
if not feature_ll then
Warning(@'ll modifier is not currently supported');
end {if}
else do_scanf_format;
st_format: { format }
do_scanf_format;
{ first char of a [set]. ']' does not end the set. }
st_set_1:
if c = '^' then state := st_set_2
else state := st_set;
st_set_2:
state := st_set;
st_set:
if c = ']' then state := st_text;
st_error: goto 1;
end; { case }
end; { for }
if state <> st_text then
Warning(@'incomplete format specifier');
if args <> nil then begin
offset := 0;
WarningExtraArgs(expected);
end;
1:
end; {FormatScanf}
procedure FormatPrintf;
{ Check the printf string and arguments. }
label 1;
var
i : integer;
c : char;
has_flag : boolean;
has_width: boolean;
has_precision : boolean;
procedure do_printf_format;
{ check an individual printf argument. }
begin {do_printf_format}
state := st_text;
if c in format_set then begin
case c of
'p': begin
if has_length <> default then
Warning(@'length modifier may not be used with %p');
expect_pointer;
end;
{ %b: orca-specific - pascal string }
'b', 'P': begin
if has_length <> default then
Warning(@'length modifier may not be used with %b or %P');
expect_pointer_to([cgByte, cgUByte], @'char');
end;
's':
if has_length = l then begin
if not feature_s_long then
Warning(@'%ls is not currently supported');
expect_pointer_to([cgWord, cgUWord], @'wchar_t')
end {if}
else begin
if has_length <> default then
Warning(@'invalid length modifier');
expect_pointer_to([cgByte, cgUByte], @'char');
end; {else}
'n': begin
if (not feature_n_size) and (has_length <> default) then
Warning(@'length modifier for %n is not currently supported');
case has_length of
hh:
expect_pointer_to([cgByte, cgUByte], @'char');
l, z, t:
expect_pointer_to([cgLong, cgULong], @'long');
ll, j:
expect_pointer_to([cgQuad, cgUQuad], @'long long');
otherwise: begin
if feature_n_size and (has_length = ld) then
Warning(@'invalid length modifier');
expect_pointer_to([cgWord, cgUWord], @'int');
end;
end; {case}
end;
'c':
if has_length = l then begin
if not feature_s_long then
Warning(@'%lc is not currently supported');
expect_int;
end
else if has_length <> default then begin
Warning(@'invalid length modifier');
expect_char;
end
else begin
expect_char;
end;
{ chars are passed as ints so %hhx can be ignored here. }
'd', 'i', 'o', 'x', 'X', 'u':
if has_length in [l, z, t] then begin
expect_long;
end
else if has_length in [ll, j] then begin
expect_long_long;
end
else if has_length = ld then begin
Warning(@'invalid length modifier');
expect_int;
end
else begin
expect_int;
end;
'f', 'F', 'e', 'E', 'a', 'A', 'g', 'G': begin
if not (has_length in [l, ld, default]) then
Warning(@'invalid length modifier');
expect_extended;
end;
'%':
if has_flag or has_width or has_precision
or (has_length <> default) then
Warning(@'invalid element in %% conversion specification');
end; {case}
end {if}
else WarningConversionChar(c);
end; {do_printf_format}
begin {FormatPrintf}
state := st_text;
expected := 0;
offset := 0;
number_set := ['0' .. '9'];
length_set := ['h', 'l', 'j', 't', 'z', 'L'];
flag_set := ['#', '0', '-', '+', ' '];
format_set := ['%', 'b', 'c', 's', 'd', 'i', 'o', 'x', 'X', 'u',
'f', 'F', 'e', 'E', 'a', 'A', 'g', 'G', 'n', 'p', 'P'];
for i := 1 to s^.length do begin
c := s^.str[i];
case state of
st_text:
if c = '%' then begin
state := st_flag;
offset := i;
has_length := default;
has_flag := false;
has_width := false;
has_precision := false;
end;
st_flag: { flags* width? precision? length? format }
if c in flag_set then begin
state := st_flag;
has_flag := true;
end
else if c in number_set then begin
state := st_width;
has_width := true;
end
else if c = '*' then begin
{ * for the width }
has_width := true;
expect_int;
state := st_precision;
end
else if c = '.' then state := st_precision_dot
else if c in length_set then do_length(c)
else do_printf_format;
st_width: { width? precision? length? format }
if c in number_set then state := st_width
else if c = '.' then state := st_precision_dot
else if c in length_set then do_length(c)
else do_printf_format;
st_precision: { (. precision)? length? format }
if c = '.' then state := st_precision_dot
else if c in length_set then do_length(c)
else do_printf_format;
st_precision_dot: begin { * | [0-9]+ }
has_precision := true;
if c = '*' then begin
expect_int;
state := st_length;
end
else if c in number_set then state := st_precision_number
else state := st_error;
end;
st_precision_number: { [0-9]* length? format }
if c in number_set then state := st_precision_number
else if c in length_set then do_length(c)
else do_printf_format;
st_length: { length? format }
if c in length_set then do_length(c)
else do_printf_format;
st_length_h: { h? format }
if c = 'h' then begin
has_length := hh;
state := st_format;
if not feature_hh then
Warning(@'hh modifier is not currently supported');
end
else do_printf_format;
st_length_l: { l? format}
if c = 'l' then begin
has_length := ll;
state := st_format;
if not feature_ll then
Warning(@'ll modifier is not currently supported');
end
else do_printf_format;
st_format: do_printf_format;
st_error: { error }
goto 1;
end; { case }
end; { for i }
if state <> st_text then
Warning(@'incomplete format specifier');
if args <> nil then begin
offset := 0;
WarningExtraArgs(expected);
end;
1:
end; {FormatPrintf}
function get_format_string(pos: integer): longstringPtr;
{ get the format string from the pos'th argument. }
var
tk: tokenPtr;
begin {get_format_string}
get_format_string := nil;
while (args <> nil) and (pos > 1) do begin
args := args^.next;
pos := pos - 1;
end; {while}
if (pos = 1) and (args <> nil) then begin
tk := args^.tk;
args := args^.next;
if (tk <> nil) and (tk^.token.kind = stringconst) then
get_format_string := tk^.token.sval
else
{Error(125) - disabled for now};
end; {if}
{ no format string -> Error(85) }
end; {get_format_string}
begin {FormatCheck}
head := args;
error_count := 0;
offset := 0;
case fmt of
fmt_printf1, fmt_scanf1:
s := get_format_string(1);
fmt_printf2, fmt_scanf2:
s := get_format_string(2);
fmt_printf3:
s := get_format_string(3);
otherwise: s := nil;
end; {case}
if (s <> nil) then case fmt of
fmt_printf1, fmt_printf2, fmt_printf3:
FormatPrintf;
fmt_scanf1, fmt_scanf2:
FormatScanf;
end; {case}
{ clean up linked list }
while head <> nil do begin
args := head^.next;
dispose(head);
head := args;
end;
{handle pauses}
if ((error_count <> 0) and wait) or KeyPress then begin
DrawHourglass;
while not KeyPress do {nothing};
ClearHourglass;
end; {if}
end; {FormatCheck}
end.