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Version:
3.2.0 ▾
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{
Copyright (c) 1998-2002 by Florian Klaempfl
Does the parsing of the statements
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
****************************************************************************
}
unit pstatmnt;
{$i fpcdefs.inc}
interface
uses
tokens,node;
function statement_block(starttoken : ttoken) : tnode;
{ reads an assembler block }
function assembler_block : tnode;
implementation
uses
{ common }
cutils,cclasses,
{ global }
globtype,globals,verbose,constexp,
systems,
{ aasm }
cpubase,aasmtai,aasmdata,
{ symtable }
symconst,symbase,symtype,symdef,symsym,symtable,defutil,defcmp,
paramgr,
{ pass 1 }
pass_1,htypechk,
nutils,ngenutil,nbas,ncal,nmem,nset,ncnv,ncon,nld,nflw,
{ parser }
scanner,
pbase,ptype,pexpr,
{ codegen }
procinfo,cgbase,
{ assembler reader }
rabase;
function statement : tnode;forward;
function if_statement : tnode;
var
ex,if_a,else_a : tnode;
begin
consume(_IF);
ex:=comp_expr([ef_accept_equal]);
consume(_THEN);
if not(token in endtokens) then
if_a:=statement
else
if_a:=nil;
if try_to_consume(_ELSE) then
else_a:=statement
else
else_a:=nil;
result:=cifnode.create(ex,if_a,else_a);
end;
{ creates a block (list) of statements, til the next END token }
function statements_til_end : tnode;
var
first,last : tstatementnode;
begin
first:=nil;
last:=nil;
while token<>_END do
begin
if first=nil then
begin
last:=cstatementnode.create(statement,nil);
first:=last;
end
else
begin
last.right:=cstatementnode.create(statement,nil);
last:=tstatementnode(last.right);
end;
if not try_to_consume(_SEMICOLON) then
break;
consume_emptystats;
end;
consume(_END);
statements_til_end:=cblocknode.create(first);
end;
function case_statement : tnode;
var
casedef : tdef;
caseexpr,p : tnode;
blockid : longint;
hl1,hl2 : TConstExprInt;
sl1,sl2 : tstringconstnode;
casedeferror, caseofstring : boolean;
casenode : tcasenode;
begin
consume(_CASE);
caseexpr:=comp_expr([ef_accept_equal]);
{ determines result type }
do_typecheckpass(caseexpr);
{ variants must be accepted, but first they must be converted to integer }
if caseexpr.resultdef.typ=variantdef then
begin
caseexpr:=ctypeconvnode.create_internal(caseexpr,sinttype);
do_typecheckpass(caseexpr);
end;
set_varstate(caseexpr,vs_read,[vsf_must_be_valid]);
casedeferror:=false;
casedef:=caseexpr.resultdef;
{ case of string must be rejected in delphi-, }
{ tp7/bp7-, mac-compatibility modes. }
caseofstring :=
([m_delphi, m_mac, m_tp7] * current_settings.modeswitches = []) and
is_string(casedef);
if (not assigned(casedef)) or
( not(is_ordinal(casedef)) and (not caseofstring) ) then
begin
CGMessage(type_e_ordinal_or_string_expr_expected);
{ create a correct tree }
caseexpr.free;
caseexpr:=cordconstnode.create(0,u32inttype,false);
{ set error flag so no rangechecks are done }
casedeferror:=true;
end;
{ Create casenode }
casenode:=ccasenode.create(caseexpr);
consume(_OF);
{ Parse all case blocks }
blockid:=0;
repeat
{ maybe an instruction has more case labels }
repeat
p:=expr(true);
if is_widechar(casedef) then
begin
if (p.nodetype=rangen) then
begin
trangenode(p).left:=ctypeconvnode.create(trangenode(p).left,cwidechartype);
trangenode(p).right:=ctypeconvnode.create(trangenode(p).right,cwidechartype);
do_typecheckpass(trangenode(p).left);
do_typecheckpass(trangenode(p).right);
end
else
begin
p:=ctypeconvnode.create(p,cwidechartype);
do_typecheckpass(p);
end;
end
else
begin
if is_char(casedef) and is_widechar(p.resultdef) then
begin
if (p.nodetype=ordconstn) then
begin
p:=ctypeconvnode.create(p,cansichartype);
do_typecheckpass(p);
end
else if (p.nodetype=rangen) then
begin
trangenode(p).left:=ctypeconvnode.create(trangenode(p).left,cansichartype);
trangenode(p).right:=ctypeconvnode.create(trangenode(p).right,cansichartype);
do_typecheckpass(trangenode(p).left);
do_typecheckpass(trangenode(p).right);
end;
end;
end;
hl1:=0;
hl2:=0;
sl1:=nil;
sl2:=nil;
if (p.nodetype=rangen) then
begin
{ type check for string case statements }
if caseofstring and
is_conststring_or_constcharnode(trangenode(p).left) and
is_conststring_or_constcharnode(trangenode(p).right) then
begin
{ we need stringconstnodes, even if expression contains single chars }
sl1 := get_string_value(trangenode(p).left, tstringdef(casedef));
sl2 := get_string_value(trangenode(p).right, tstringdef(casedef));
if sl1.fullcompare(sl2) > 0 then
CGMessage(parser_e_case_lower_less_than_upper_bound);
end
{ type checking for ordinal case statements }
else if (not caseofstring) and
is_subequal(casedef, trangenode(p).left.resultdef) and
is_subequal(casedef, trangenode(p).right.resultdef) then
begin
hl1:=get_ordinal_value(trangenode(p).left);
hl2:=get_ordinal_value(trangenode(p).right);
if hl1>hl2 then
CGMessage(parser_e_case_lower_less_than_upper_bound);
if not casedeferror then
begin
adaptrange(casedef,hl1,false,false,cs_check_range in current_settings.localswitches);
adaptrange(casedef,hl2,false,false,cs_check_range in current_settings.localswitches);
end;
end
else
CGMessage(parser_e_case_mismatch);
if caseofstring then
casenode.addlabel(blockid,sl1,sl2)
else
casenode.addlabel(blockid,hl1,hl2);
end
else
begin
{ type check for string case statements }
if (caseofstring and (not is_conststring_or_constcharnode(p))) or
{ type checking for ordinal case statements }
((not caseofstring) and (not is_subequal(casedef, p.resultdef))) then
CGMessage(parser_e_case_mismatch);
if caseofstring then
begin
sl1:=get_string_value(p, tstringdef(casedef));
casenode.addlabel(blockid,sl1,sl1);
end
else
begin
hl1:=get_ordinal_value(p);
if not casedeferror then
adaptrange(casedef,hl1,false,false,cs_check_range in current_settings.localswitches);
casenode.addlabel(blockid,hl1,hl1);
end;
end;
p.free;
sl1.free;
sl2.free;
if token=_COMMA then
consume(_COMMA)
else
break;
until false;
consume(_COLON);
{ add instruction block }
casenode.addblock(blockid,statement);
{ next block }
inc(blockid);
if not(token in [_ELSE,_OTHERWISE,_END]) then
consume(_SEMICOLON);
until (token in [_ELSE,_OTHERWISE,_END]);
if (token in [_ELSE,_OTHERWISE]) then
begin
if not try_to_consume(_ELSE) then
consume(_OTHERWISE);
casenode.addelseblock(statements_til_end);
end
else
consume(_END);
result:=casenode;
end;
function repeat_statement : tnode;
var
first,last,p_e : tnode;
begin
consume(_REPEAT);
first:=nil;
last:=nil;
while token<>_UNTIL do
begin
if first=nil then
begin
last:=cstatementnode.create(statement,nil);
first:=last;
end
else
begin
tstatementnode(last).right:=cstatementnode.create(statement,nil);
last:=tstatementnode(last).right;
end;
if not try_to_consume(_SEMICOLON) then
break;
consume_emptystats;
end;
consume(_UNTIL);
first:=cblocknode.create(first);
p_e:=comp_expr([ef_accept_equal]);
result:=cwhilerepeatnode.create(p_e,first,false,true);
end;
function while_statement : tnode;
var
p_e,p_a : tnode;
begin
consume(_WHILE);
p_e:=comp_expr([ef_accept_equal]);
consume(_DO);
p_a:=statement;
result:=cwhilerepeatnode.create(p_e,p_a,true,false);
end;
{ a helper function which is used both by "with" and "for-in loop" nodes }
function skip_nodes_before_load(p: tnode): tnode;
begin
{ ignore nodes that don't add instructions in the tree }
while assigned(p) and
{ equal type conversions }
(
(p.nodetype=typeconvn) and
(ttypeconvnode(p).convtype=tc_equal)
) or
{ constant array index }
(
(p.nodetype=vecn) and
(tvecnode(p).right.nodetype=ordconstn)
) do
p:=tunarynode(p).left;
result:=p;
end;
function for_statement : tnode;
procedure check_range(hp:tnode; fordef: tdef);
begin
if (hp.nodetype=ordconstn) and
(fordef.typ<>errordef) then
adaptrange(fordef,tordconstnode(hp).value,false,false,true);
end;
function for_loop_create(hloopvar: tnode): tnode;
var
hp,
hblock,
hto,hfrom : tnode;
backward : boolean;
loopvarsym : tabstractvarsym;
begin
{ Check loop variable }
loopvarsym:=nil;
{ variable must be an ordinal, int64 is not allowed for 32bit targets }
if (
not(is_ordinal(hloopvar.resultdef))
{$ifndef cpu64bitaddr}
or is_64bitint(hloopvar.resultdef)
{$endif not cpu64bitaddr}
) and
(hloopvar.resultdef.typ<>undefineddef)
then
MessagePos(hloopvar.fileinfo,type_e_ordinal_expr_expected);
hp:=hloopvar;
while assigned(hp) and
(
{ record/object fields and array elements are allowed }
{ in tp7 mode only }
(
(m_tp7 in current_settings.modeswitches) and
(
((hp.nodetype=subscriptn) and
((tsubscriptnode(hp).left.resultdef.typ=recorddef) or
is_object(tsubscriptnode(hp).left.resultdef))
) or
{ constant array index }
(
(hp.nodetype=vecn) and
is_constintnode(tvecnode(hp).right)
)
)
) or
{ equal typeconversions }
(
(hp.nodetype=typeconvn) and
(ttypeconvnode(hp).convtype=tc_equal)
)
) do
begin
{ Use the recordfield for loopvarsym }
if not assigned(loopvarsym) and
(hp.nodetype=subscriptn) then
loopvarsym:=tsubscriptnode(hp).vs;
hp:=tunarynode(hp).left;
end;
if assigned(hp) and
(hp.nodetype=loadn) then
begin
case tloadnode(hp).symtableentry.typ of
staticvarsym,
localvarsym,
paravarsym :
begin
{ we need a simple loadn:
1. The load must be in a global symtable or
in the same level as the para of the current proc.
2. value variables (no const,out or var)
3. No threadvar, readonly or typedconst
}
if (
(tloadnode(hp).symtable.symtablelevel=main_program_level) or
(tloadnode(hp).symtable.symtablelevel=current_procinfo.procdef.parast.symtablelevel)
) and
(tabstractvarsym(tloadnode(hp).symtableentry).varspez=vs_value) and
([vo_is_thread_var,vo_is_typed_const] * tabstractvarsym(tloadnode(hp).symtableentry).varoptions=[]) then
begin
{ Assigning for-loop variable is only allowed in tp7 and macpas }
if ([m_tp7,m_mac] * current_settings.modeswitches = []) then
begin
if not assigned(loopvarsym) then
loopvarsym:=tabstractvarsym(tloadnode(hp).symtableentry);
include(loopvarsym.varoptions,vo_is_loop_counter);
end;
end
else
begin
{ Typed const is allowed in tp7 }
if not(m_tp7 in current_settings.modeswitches) or
not(vo_is_typed_const in tabstractvarsym(tloadnode(hp).symtableentry).varoptions) then
MessagePos(hp.fileinfo,type_e_illegal_count_var);
end;
end;
else
MessagePos(hp.fileinfo,type_e_illegal_count_var);
end;
end
else
MessagePos(hloopvar.fileinfo,type_e_illegal_count_var);
hfrom:=comp_expr([ef_accept_equal]);
if try_to_consume(_DOWNTO) then
backward:=true
else
begin
consume(_TO);
backward:=false;
end;
hto:=comp_expr([ef_accept_equal]);
consume(_DO);
{ Check if the constants fit in the range }
check_range(hfrom,hloopvar.resultdef);
check_range(hto,hloopvar.resultdef);
{ first set the varstate for from and to, so
uses of loopvar in those expressions will also
trigger a warning when it is not used yet. This
needs to be done before the instruction block is
parsed to have a valid hloopvar }
typecheckpass(hfrom);
set_varstate(hfrom,vs_read,[vsf_must_be_valid]);
typecheckpass(hto);
set_varstate(hto,vs_read,[vsf_must_be_valid]);
typecheckpass(hloopvar);
{ in two steps, because vs_readwritten may turn on vsf_must_be_valid }
{ for some subnodes }
set_varstate(hloopvar,vs_written,[]);
set_varstate(hloopvar,vs_read,[vsf_must_be_valid]);
{ ... now the instruction block }
hblock:=statement;
{ variable is not used for loop counter anymore }
if assigned(loopvarsym) then
exclude(loopvarsym.varoptions,vo_is_loop_counter);
result:=cfornode.create(hloopvar,hfrom,hto,hblock,backward);
end;
function for_in_loop_create(hloopvar: tnode): tnode;
var
expr,hloopbody,hp: tnode;
loopvarsym: tabstractvarsym;
begin
hp:=skip_nodes_before_load(hloopvar);
if assigned(hp)and(hp.nodetype=loadn) then
begin
loopvarsym:=tabstractvarsym(tloadnode(hp).symtableentry);
include(loopvarsym.varoptions,vo_is_loop_counter);
end
else
loopvarsym:=nil;
expr:=comp_expr([ef_accept_equal]);
consume(_DO);
set_varstate(hloopvar,vs_written,[]);
set_varstate(hloopvar,vs_read,[vsf_must_be_valid]);
hloopbody:=statement;
if assigned(loopvarsym) then
exclude(loopvarsym.varoptions,vo_is_loop_counter);
result:=create_for_in_loop(hloopvar,hloopbody,expr);
expr.free;
end;
var
hloopvar: tnode;
begin
{ parse loop header }
consume(_FOR);
hloopvar:=factor(false,[]);
valid_for_loopvar(hloopvar,true);
if try_to_consume(_ASSIGNMENT) then
result:=for_loop_create(hloopvar)
else if try_to_consume(_IN) then
result:=for_in_loop_create(hloopvar)
else
begin
consume(_ASSIGNMENT); // fail
result:=cerrornode.create;
end;
end;
function _with_statement : tnode;
var
p : tnode;
i : longint;
st : TSymtable;
newblock : tblocknode;
newstatement : tstatementnode;
calltempnode,
tempnode : ttempcreatenode;
valuenode,
hp,
refnode : tnode;
hdef : tdef;
helperdef : tobjectdef;
hasimplicitderef : boolean;
withsymtablelist : TFPObjectList;
procedure pushobjchild(withdef,obj:tobjectdef);
var
parenthelperdef : tobjectdef;
begin
if not assigned(obj) then
exit;
pushobjchild(withdef,obj.childof);
{ we need to look for helpers that were defined for the parent
class as well }
search_last_objectpascal_helper(obj,current_structdef,parenthelperdef);
{ push the symtables of the helper's parents in reverse order }
if assigned(parenthelperdef) then
pushobjchild(withdef,parenthelperdef.childof);
{ keep the original tobjectdef as owner, because that is used for
visibility of the symtable }
st:=twithsymtable.create(withdef,obj.symtable.SymList,refnode.getcopy);
symtablestack.push(st);
withsymtablelist.add(st);
{ push the symtable of the helper }
if assigned(parenthelperdef) then
begin
st:=twithsymtable.create(withdef,parenthelperdef.symtable.SymList,refnode.getcopy);
symtablestack.push(st);
withsymtablelist.add(st);
end;
end;
begin
calltempnode:=nil;
p:=comp_expr([ef_accept_equal]);
do_typecheckpass(p);
if (p.nodetype=vecn) and
(nf_memseg in p.flags) then
CGMessage(parser_e_no_with_for_variable_in_other_segments);
{ "with procvar" can never mean anything, so always try
to call it in case it returns a record/object/... }
maybe_call_procvar(p,false);
if (p.resultdef.typ in [objectdef,recorddef,classrefdef]) or
((p.resultdef.typ=undefineddef) and (df_generic in current_procinfo.procdef.defoptions)) then
begin
newblock:=nil;
valuenode:=nil;
tempnode:=nil;
hp:=skip_nodes_before_load(p);
if (hp.nodetype=loadn) and
(
(tloadnode(hp).symtable=current_procinfo.procdef.localst) or
(tloadnode(hp).symtable=current_procinfo.procdef.parast) or
(tloadnode(hp).symtable.symtabletype in [staticsymtable,globalsymtable])
) and
{ MacPas objects are mapped to classes, and the MacPas compilers
interpret with-statements with MacPas objects the same way
as records (the object referenced by the with-statement
must remain constant)
}
not(is_class(hp.resultdef) and
(m_mac in current_settings.modeswitches)) then
begin
{ simple load, we can reference direct }
refnode:=p;
end
else
begin
{ complex load, load in temp first }
newblock:=internalstatements(newstatement);
{ when we can't take the address of p, load it in a temp }
{ since we may need its address later on }
if not valid_for_addr(p,false) then
begin
calltempnode:=ctempcreatenode.create(p.resultdef,p.resultdef.size,tt_persistent,true);
addstatement(newstatement,calltempnode);
addstatement(newstatement,cassignmentnode.create(
ctemprefnode.create(calltempnode),
p));
p:=ctemprefnode.create(calltempnode);
typecheckpass(p);
end;
{ several object types have implicit dereferencing }
{ is_implicit_pointer_object_type() returns true for records
on the JVM target because they are implemented as classes
there, but we definitely have to take their address here
since otherwise a deep copy is made and changes are made to
this copy rather than to the original one }
hasimplicitderef:=
(is_implicit_pointer_object_type(p.resultdef) or
(p.resultdef.typ=classrefdef)) and
not((target_info.system in systems_jvm) and
((p.resultdef.typ=recorddef) or
is_object(p.resultdef)));
if hasimplicitderef then
hdef:=p.resultdef
else
hdef:=cpointerdef.create(p.resultdef);
{ load address of the value in a temp }
tempnode:=ctempcreatenode.create_withnode(hdef,sizeof(pint),tt_persistent,true,p);
typecheckpass(tnode(tempnode));
valuenode:=p;
refnode:=ctemprefnode.create(tempnode);
fillchar(refnode.fileinfo,sizeof(tfileposinfo),0);
{ add address call for valuenode and deref for refnode if this
is not done implicitly }
if not hasimplicitderef then
begin
valuenode:=caddrnode.create_internal_nomark(valuenode);
include(taddrnode(valuenode).addrnodeflags,anf_typedaddr);
refnode:=cderefnode.create(refnode);
fillchar(refnode.fileinfo,sizeof(tfileposinfo),0);
end;
addstatement(newstatement,tempnode);
addstatement(newstatement,cassignmentnode.create(
ctemprefnode.create(tempnode),
valuenode));
typecheckpass(refnode);
end;
{ Note: the symtable of the helper is pushed after the following
"case", the symtables of the helper's parents are passed in
the "case" branches }
withsymtablelist:=TFPObjectList.create(true);
case p.resultdef.typ of
objectdef :
begin
{ do we have a helper for this type? }
search_last_objectpascal_helper(tabstractrecorddef(p.resultdef),current_structdef,helperdef);
{ push symtables of all parents in reverse order }
pushobjchild(tobjectdef(p.resultdef),tobjectdef(p.resultdef).childof);
{ push symtables of all parents of the helper in reverse order }
if assigned(helperdef) then
pushobjchild(helperdef,helperdef.childof);
{ push object symtable }
st:=twithsymtable.Create(tobjectdef(p.resultdef),tobjectdef(p.resultdef).symtable.SymList,refnode);
symtablestack.push(st);
withsymtablelist.add(st);
end;
classrefdef :
begin
{ do we have a helper for this type? }
search_last_objectpascal_helper(tobjectdef(tclassrefdef(p.resultdef).pointeddef),current_structdef,helperdef);
{ push symtables of all parents in reverse order }
pushobjchild(tobjectdef(tclassrefdef(p.resultdef).pointeddef),tobjectdef(tclassrefdef(p.resultdef).pointeddef).childof);
{ push symtables of all parents of the helper in reverse order }
if assigned(helperdef) then
pushobjchild(helperdef,helperdef.childof);
{ push object symtable }
st:=twithsymtable.Create(tobjectdef(tclassrefdef(p.resultdef).pointeddef),tobjectdef(tclassrefdef(p.resultdef).pointeddef).symtable.SymList,refnode);
symtablestack.push(st);
withsymtablelist.add(st);
end;
recorddef :
begin
{ do we have a helper for this type? }
search_last_objectpascal_helper(tabstractrecorddef(p.resultdef),current_structdef,helperdef);
{ push symtables of all parents of the helper in reverse order }
if assigned(helperdef) then
pushobjchild(helperdef,helperdef.childof);
{ push record symtable }
st:=twithsymtable.create(trecorddef(p.resultdef),trecorddef(p.resultdef).symtable.SymList,refnode);
symtablestack.push(st);
withsymtablelist.add(st);
end;
undefineddef :
begin
if not(df_generic in current_procinfo.procdef.defoptions) then
internalerror(2012122802);
helperdef:=nil;
{ push record symtable }
st:=twithsymtable.create(p.resultdef,nil,refnode);
symtablestack.push(st);
withsymtablelist.add(st);
end;
else
internalerror(200601271);
end;
{ push helper symtable }
if assigned(helperdef) then
begin
st:=twithsymtable.Create(helperdef,helperdef.symtable.SymList,refnode.getcopy);
symtablestack.push(st);
withsymtablelist.add(st);
end;
if try_to_consume(_COMMA) then
p:=_with_statement()
else
begin
consume(_DO);
if token<>_SEMICOLON then
p:=statement
else
p:=cnothingnode.create;
end;
{ remove symtables in reverse order from the stack }
for i:=withsymtablelist.count-1 downto 0 do
symtablestack.pop(TSymtable(withsymtablelist[i]));
withsymtablelist.free;
{ Finalize complex withnode with destroy of temp }
if assigned(newblock) then
begin
addstatement(newstatement,p);
if assigned(tempnode) then
addstatement(newstatement,ctempdeletenode.create(tempnode));
if assigned(calltempnode) then
addstatement(newstatement,ctempdeletenode.create(calltempnode));
p:=newblock;
end;
result:=p;
end
else
begin
p.free;
Message1(parser_e_false_with_expr,p.resultdef.GetTypeName);
{ try to recover from error }
if try_to_consume(_COMMA) then
begin
hp:=_with_statement();
if (hp=nil) then; { remove warning about unused }
end
else
begin
consume(_DO);
{ ignore all }
if token<>_SEMICOLON then
statement;
end;
result:=nil;
end;
end;
function with_statement : tnode;
begin
consume(_WITH);
with_statement:=_with_statement();
end;
function raise_statement : tnode;
var
p,pobj,paddr,pframe : tnode;
begin
pobj:=nil;
paddr:=nil;
pframe:=nil;
consume(_RAISE);
if not(token in endtokens) then
begin
{ object }
pobj:=comp_expr([ef_accept_equal]);
if try_to_consume(_AT) then
begin
paddr:=comp_expr([ef_accept_equal]);
if try_to_consume(_COMMA) then
pframe:=comp_expr([ef_accept_equal]);
end;
end
else
begin
if (block_type<>bt_except) then
Message(parser_e_no_reraise_possible);
end;
p:=craisenode.create(pobj,paddr,pframe);
raise_statement:=p;
end;
function try_statement : tnode;
procedure check_type_valid(var def: tdef);
begin
if not (is_class(def) or is_javaclass(def) or
{ skip showing error message the second time }
(def.typ=errordef)) then
begin
Message1(type_e_class_type_expected,def.typename);
def:=generrordef;
end;
end;
var
p_try_block,p_finally_block,first,last,
p_default,p_specific,hp : tnode;
ot : tDef;
sym : tlocalvarsym;
old_block_type : tblock_type;
excepTSymtable : TSymtable;
objname,objrealname : TIDString;
srsym : tsym;
srsymtable : TSymtable;
t:ttoken;
unit_found:boolean;
oldcurrent_exceptblock: integer;
begin
p_default:=nil;
p_specific:=nil;
excepTSymtable:=nil;
last:=nil;
{ read statements to try }
consume(_TRY);
first:=nil;
inc(exceptblockcounter);
oldcurrent_exceptblock := current_exceptblock;
current_exceptblock := exceptblockcounter;
old_block_type := block_type;
block_type := bt_body;
while (token<>_FINALLY) and (token<>_EXCEPT) do
begin
if first=nil then
begin
last:=cstatementnode.create(statement,nil);
first:=last;
end
else
begin
tstatementnode(last).right:=cstatementnode.create(statement,nil);
last:=tstatementnode(last).right;
end;
if not try_to_consume(_SEMICOLON) then
break;
consume_emptystats;
end;
p_try_block:=cblocknode.create(first);
if try_to_consume(_FINALLY) then
begin
inc(exceptblockcounter);
current_exceptblock := exceptblockcounter;
p_finally_block:=statements_til_end;
try_statement:=ctryfinallynode.create(p_try_block,p_finally_block);
end
else
begin
consume(_EXCEPT);
block_type:=bt_except;
inc(exceptblockcounter);
current_exceptblock := exceptblockcounter;
ot:=generrordef;
p_specific:=nil;
if (idtoken=_ON) then
{ catch specific exceptions }
begin
repeat
consume(_ON);
if token=_ID then
begin
objname:=pattern;
objrealname:=orgpattern;
{ can't use consume_sym here, because we need already
to check for the colon }
searchsym(objname,srsym,srsymtable);
consume(_ID);
{ is a explicit name for the exception given ? }
if try_to_consume(_COLON) then
begin
single_type(ot,[]);
check_type_valid(ot);
sym:=clocalvarsym.create(objrealname,vs_value,ot,[]);
end
else
begin
{ check if type is valid, must be done here because
with "e: Exception" the e is not necessary }
{ support unit.identifier }
unit_found:=try_consume_unitsym_no_specialize(srsym,srsymtable,t,false,objname);
if srsym=nil then
begin
identifier_not_found(orgpattern);
srsym:=generrorsym;
end;
if unit_found then
consume(t);
{ check if type is valid, must be done here because
with "e: Exception" the e is not necessary }
if (srsym.typ=typesym) then
begin
ot:=ttypesym(srsym).typedef;
parse_nested_types(ot,false,false,nil);
check_type_valid(ot);
end
else
begin
Message(type_e_type_id_expected);
ot:=generrordef;
end;
{ create dummy symbol so we don't need a special
case in ncgflw, and so that we always know the
type }
sym:=clocalvarsym.create('$exceptsym',vs_value,ot,[]);
end;
excepTSymtable:=tstt_excepTSymtable.create;
excepTSymtable.insert(sym);
symtablestack.push(excepTSymtable);
end
else
consume(_ID);
consume(_DO);
hp:=connode.create(nil,statement);
if ot.typ=errordef then
begin
hp.free;
hp:=cerrornode.create;
end;
if p_specific=nil then
begin
last:=hp;
p_specific:=last;
end
else
begin
tonnode(last).left:=hp;
last:=tonnode(last).left;
end;
{ set the informations }
{ only if the creation of the onnode was succesful, it's possible }
{ that last and hp are errornodes (JM) }
if last.nodetype = onn then
begin
tonnode(last).excepttype:=tobjectdef(ot);
tonnode(last).excepTSymtable:=excepTSymtable;
end;
{ remove exception symtable }
if assigned(excepTSymtable) then
begin
symtablestack.pop(excepTSymtable);
if last.nodetype <> onn then
excepTSymtable.free;
end;
if not try_to_consume(_SEMICOLON) then
break;
consume_emptystats;
until (token in [_END,_ELSE]);
if try_to_consume(_ELSE) then
begin
{ catch the other exceptions }
p_default:=statements_til_end;
end
else
consume(_END);
end
else
begin
{ catch all exceptions }
p_default:=statements_til_end;
end;
try_statement:=ctryexceptnode.create(p_try_block,p_specific,p_default);
end;
block_type:=old_block_type;
current_exceptblock := oldcurrent_exceptblock;
end;
function _asm_statement : tnode;
var
asmstat : tasmnode;
reg : tregister;
asmreader : tbaseasmreader;
entrypos : tfileposinfo;
hl : TAsmList;
begin
Inside_asm_statement:=true;
asmstat:=nil;
hl:=nil;
if assigned(asmmodeinfos[current_settings.asmmode]) then
begin
asmreader:=asmmodeinfos[current_settings.asmmode]^.casmreader.create;
entrypos:=current_filepos;
hl:=asmreader.assemble as TAsmList;
if (not hl.empty) then
begin
{ mark boundaries of assembler block, this is necessary for optimizer }
hl.insert(tai_marker.create(mark_asmblockstart));
hl.concat(tai_marker.create(mark_asmblockend));
end;
asmstat:=casmnode.create(hl);
asmstat.fileinfo:=entrypos;
asmreader.free;
end
else
Message(parser_f_assembler_reader_not_supported);
{ Mark procedure that it has assembler blocks }
include(current_procinfo.flags,pi_has_assembler_block);
{ Read first the _ASM statement }
consume(_ASM);
{ Force an empty register list for pure assembler routines,
so that pass2 won't allocate volatile registers for them. }
asmstat.has_registerlist:=(po_assembler in current_procinfo.procdef.procoptions);
{ END is read, got a list of changed registers? }
if try_to_consume(_LECKKLAMMER) then
begin
if token<>_RECKKLAMMER then
begin
if po_assembler in current_procinfo.procdef.procoptions then
Message(parser_w_register_list_ignored);
repeat
{ it's possible to specify the modified registers }
reg:=std_regnum_search(lower(cstringpattern));
if reg<>NR_NO then
begin
if not(po_assembler in current_procinfo.procdef.procoptions) and assigned(hl) then
begin
hl.Insert(tai_regalloc.alloc(reg,nil));
hl.Insert(tai_regalloc.markused(reg));
hl.Concat(tai_regalloc.dealloc(reg,nil));
end;
end
else
Message(asmr_e_invalid_register);
consume(_CSTRING);
if not try_to_consume(_COMMA) then
break;
until false;
asmstat.has_registerlist:=true;
end;
consume(_RECKKLAMMER);
end;
Inside_asm_statement:=false;
_asm_statement:=asmstat;
end;
function statement : tnode;
var
p,
code : tnode;
filepos : tfileposinfo;
srsym : tsym;
srsymtable : TSymtable;
s : TIDString;
begin
filepos:=current_tokenpos;
code:=nil;
case token of
_GOTO :
begin
if not(cs_support_goto in current_settings.moduleswitches) then
Message(sym_e_goto_and_label_not_supported);
consume(_GOTO);
if (token<>_INTCONST) and (token<>_ID) then
begin
Message(sym_e_label_not_found);
code:=cerrornode.create;
end
else
begin
if token=_ID then
consume_sym(srsym,srsymtable)
else
begin
if token<>_INTCONST then
internalerror(201008021);
{ strip leading 0's in iso mode }
if (([m_iso,m_extpas]*current_settings.modeswitches)<>[]) then
while pattern[1]='0' do
delete(pattern,1,1);
searchsym(pattern,srsym,srsymtable);
if srsym=nil then
begin
identifier_not_found(pattern);
srsym:=generrorsym;
srsymtable:=nil;
end;
consume(token);
end;
if srsym.typ<>labelsym then
begin
Message(sym_e_id_is_no_label_id);
code:=cerrornode.create;
end
else
begin
{ goto outside the current scope? }
if srsym.owner<>current_procinfo.procdef.localst then
begin
{ allowed? }
if not(m_non_local_goto in current_settings.modeswitches) then
Message(parser_e_goto_outside_proc);
include(current_procinfo.flags,pi_has_global_goto);
end;
code:=cgotonode.create(tlabelsym(srsym));
tgotonode(code).labelsym:=tlabelsym(srsym);
{ set flag that this label is used }
tlabelsym(srsym).used:=true;
end;
end;
end;
_BEGIN :
code:=statement_block(_BEGIN);
_IF :
code:=if_statement;
_CASE :
code:=case_statement;
_REPEAT :
code:=repeat_statement;
_WHILE :
code:=while_statement;
_FOR :
code:=for_statement;
_WITH :
code:=with_statement;
_TRY :
code:=try_statement;
_RAISE :
code:=raise_statement;
{ semicolons,else until and end are ignored }
_SEMICOLON,
_ELSE,
_UNTIL,
_END:
code:=cnothingnode.create;
_FAIL :
begin
if (current_procinfo.procdef.proctypeoption<>potype_constructor) then
Message(parser_e_fail_only_in_constructor);
consume(_FAIL);
code:=cnodeutils.call_fail_node;
end;
_ASM :
begin
if parse_generic then
Message(parser_e_no_assembler_in_generic);
code:=_asm_statement;
end;
_EOF :
Message(scan_f_end_of_file);
else
begin
{ don't typecheck yet, because that will also simplify, which may
result in not detecting certain kinds of syntax errors --
see mantis #15594 }
p:=expr(false);
{ save the pattern here for latter usage, the label could be "000",
even if we read an expression, the pattern is still valid if it's really
a label (FK)
if you want to mess here, take care of
tests/webtbs/tw3546.pp
}
s:=pattern;
{ When a colon follows a intconst then transform it into a label }
if (p.nodetype=ordconstn) and
try_to_consume(_COLON) then
begin
{ in iso mode, 0003: is equal to 3: }
if (([m_iso,m_extpas]*current_settings.modeswitches)<>[]) then
searchsym(tostr(tordconstnode(p).value),srsym,srsymtable)
else
searchsym(s,srsym,srsymtable);
p.free;
if assigned(srsym) and
(srsym.typ=labelsym) then
begin
if tlabelsym(srsym).defined then
Message(sym_e_label_already_defined);
if symtablestack.top.symtablelevel<>srsymtable.symtablelevel then
begin
tlabelsym(srsym).nonlocal:=true;
exclude(current_procinfo.procdef.procoptions,po_inline);
end;
if tlabelsym(srsym).nonlocal and
(current_procinfo.procdef.proctypeoption in [potype_unitinit,potype_unitfinalize]) then
Message(sym_e_interprocgoto_into_init_final_code_not_allowed);
tlabelsym(srsym).defined:=true;
p:=clabelnode.create(nil,tlabelsym(srsym));
tlabelsym(srsym).code:=p;
end
else
begin
Message1(sym_e_label_used_and_not_defined,s);
p:=cnothingnode.create;
end;
end;
if p.nodetype=labeln then
begin
{ the pointer to the following instruction }
{ isn't a very clean way }
if token in endtokens then
tlabelnode(p).left:=cnothingnode.create
else
tlabelnode(p).left:=statement();
{ be sure to have left also typecheckpass }
typecheckpass(tlabelnode(p).left);
end
else
{ change a load of a procvar to a call. this is also
supported in fpc mode }
if p.nodetype in [vecn,derefn,typeconvn,subscriptn,loadn] then
maybe_call_procvar(p,false);
{ blockn support because a read/write is changed into a blocknode
with a separate statement for each read/write operation (JM)
the same is true for val() if the third parameter is not 32 bit
goto nodes are created by the compiler for non local exit statements, so
include them as well
}
if not(p.nodetype in [nothingn,errorn,calln,ifn,assignn,breakn,inlinen,
continuen,labeln,blockn,exitn,goton]) or
((p.nodetype=inlinen) and
not is_void(p.resultdef)) or
((p.nodetype=calln) and
(assigned(tcallnode(p).procdefinition)) and
(tcallnode(p).procdefinition.proctypeoption=potype_operator)) then
Message(parser_e_illegal_expression);
if not assigned(p.resultdef) then
do_typecheckpass(p);
{ Specify that we don't use the value returned by the call.
This is used for :
- dispose of temp stack space
- dispose on FPU stack
- extended syntax checking }
if (p.nodetype=calln) then
begin
exclude(tcallnode(p).callnodeflags,cnf_return_value_used);
{ in $x- state, the function result must not be ignored }
if not(cs_extsyntax in current_settings.moduleswitches) and
not(is_void(p.resultdef)) and
{ can be nil in case there was an error in the expression }
assigned(tcallnode(p).procdefinition) and
{ allow constructor calls to drop the result if they are
called as instance methods instead of class methods }
not(
(tcallnode(p).procdefinition.proctypeoption=potype_constructor) and
is_class_or_object(tprocdef(tcallnode(p).procdefinition).struct) and
assigned(tcallnode(p).methodpointer) and
(tnode(tcallnode(p).methodpointer).resultdef.typ=objectdef)
) then
Message(parser_e_illegal_expression);
end;
code:=p;
end;
end;
if assigned(code) then
begin
typecheckpass(code);
code.fileinfo:=filepos;
end;
statement:=code;
end;
function statement_block(starttoken : ttoken) : tnode;
var
first,last : tnode;
filepos : tfileposinfo;
begin
first:=nil;
last:=nil;
filepos:=current_tokenpos;
consume(starttoken);
while not((token=_END) or (token=_FINALIZATION)) do
begin
if first=nil then
begin
last:=cstatementnode.create(statement,nil);
first:=last;
end
else
begin
tstatementnode(last).right:=cstatementnode.create(statement,nil);
last:=tstatementnode(last).right;
end;
if ((token=_END) or (token=_FINALIZATION)) then
break
else
begin
{ if no semicolon, then error and go on }
if token<>_SEMICOLON then
begin
consume(_SEMICOLON);
consume_all_until(_SEMICOLON);
end;
consume(_SEMICOLON);
end;
consume_emptystats;
end;
{ don't consume the finalization token, it is consumed when
reading the finalization block, but allow it only after
an initalization ! }
if (starttoken<>_INITIALIZATION) or (token<>_FINALIZATION) then
consume(_END);
last:=cblocknode.create(first);
last.fileinfo:=filepos;
statement_block:=last;
end;
function assembler_block : tnode;
var
p : tnode;
{$if not(defined(sparcgen)) and not(defined(arm)) and not(defined(avr)) and not(defined(mips))}
locals : longint;
{$endif not(defined(sparcgen)) and not(defined(arm)) and not(defined(avr)) and not(defined(mips))}
srsym : tsym;
begin
if parse_generic then
message(parser_e_no_assembler_in_generic);
{ Rename the funcret so that recursive calls are possible }
if not is_void(current_procinfo.procdef.returndef) then
begin
srsym:=TSym(current_procinfo.procdef.localst.Find(current_procinfo.procdef.procsym.name));
if assigned(srsym) then
srsym.realname:='$hiddenresult';
end;
{ delphi uses register calling for assembler methods }
if (m_delphi in current_settings.modeswitches) and
(po_assembler in current_procinfo.procdef.procoptions) and
not(po_hascallingconvention in current_procinfo.procdef.procoptions) then
current_procinfo.procdef.proccalloption:=pocall_register;
{ force the asm statement }
if token<>_ASM then
consume(_ASM);
include(current_procinfo.flags,pi_is_assembler);
p:=_asm_statement;
{$if not(defined(sparcgen)) and not(defined(arm)) and not(defined(avr)) and not(defined(mips))}
if (po_assembler in current_procinfo.procdef.procoptions) then
begin
{ set the framepointer to esp for assembler functions when the
following conditions are met:
- if the are no local variables and parameters (except the allocated result)
- no reference to the result variable (refcount<=1)
- result is not stored as parameter
- target processor has optional frame pointer save
(vm, i386, vm only currently)
}
locals:=tabstractlocalsymtable(current_procinfo.procdef.parast).count_locals;
if (current_procinfo.procdef.localst.symtabletype=localsymtable) then
inc(locals,tabstractlocalsymtable(current_procinfo.procdef.localst).count_locals);
if (locals=0) and
not (current_procinfo.procdef.owner.symtabletype in [ObjectSymtable,recordsymtable]) and
(not assigned(current_procinfo.procdef.funcretsym) or
(tabstractvarsym(current_procinfo.procdef.funcretsym).refs<=1)) and
not (df_generic in current_procinfo.procdef.defoptions) and
not(paramanager.ret_in_param(current_procinfo.procdef.returndef,current_procinfo.procdef)) then
begin
{ Only need to set the framepointer, the locals will
be inserted with the correct reference in tcgasmnode.pass_generate_code }
current_procinfo.framepointer:=NR_STACK_POINTER_REG;
end;
end;
{$endif not(defined(sparcgen)) and not(defined(arm)) and not(defined(avr)) not(defined(mipsel))}
{ Flag the result as assigned when it is returned in a
register.
}
if assigned(current_procinfo.procdef.funcretsym) and
not (df_generic in current_procinfo.procdef.defoptions) and
(not paramanager.ret_in_param(current_procinfo.procdef.returndef,current_procinfo.procdef)) then
tabstractvarsym(current_procinfo.procdef.funcretsym).varstate:=vs_initialised;
{ because the END is already read we need to get the
last_endtoken_filepos here (PFV) }
last_endtoken_filepos:=current_tokenpos;
assembler_block:=p;
end;
end.