/*
* Copyright 2001-2006 Adrian Thurston <thurston@complang.org>
* 2004 Erich Ocean <eric.ocean@ampede.com>
* 2005 Alan West <alan@alanz.com>
*/
/* This file is part of Ragel.
*
* Ragel 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.
*
* Ragel 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 Ragel; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include "cdcodegen.h"
#include "ragel.h"
#include "redfsm.h"
#include "gendata.h"
#include <sstream>
#include <string>
#include <assert.h>
using std::ostream;
using std::ostringstream;
using std::string;
using std::cerr;
using std::endl;
using std::istream;
using std::ifstream;
using std::ostream;
using std::ios;
using std::cin;
using std::cout;
using std::cerr;
using std::endl;
extern int numSplitPartitions;
extern bool noLineDirectives;
void cdLineDirective( ostream &out, const char *fileName, int line )
{
if ( noLineDirectives )
out << "/* ";
/* Write the preprocessor line info for to the input file. */
out << "#line " << line << " \"";
for ( const char *pc = fileName; *pc != 0; pc++ ) {
if ( *pc == '\\' )
out << "\\\\";
else
out << *pc;
}
out << '"';
if ( noLineDirectives )
out << " */";
out << '\n';
}
void FsmCodeGen::genLineDirective( ostream &out )
{
std::streambuf *sbuf = out.rdbuf();
output_filter *filter = static_cast<output_filter*>(sbuf);
cdLineDirective( out, filter->fileName, filter->line + 1 );
}
/* Init code gen with in parameters. */
FsmCodeGen::FsmCodeGen( ostream &out )
:
CodeGenData(out)
{
}
unsigned int FsmCodeGen::arrayTypeSize( unsigned long maxVal )
{
long long maxValLL = (long long) maxVal;
HostType *arrayType = keyOps->typeSubsumes( maxValLL );
assert( arrayType != 0 );
return arrayType->size;
}
string FsmCodeGen::ARRAY_TYPE( unsigned long maxVal )
{
long long maxValLL = (long long) maxVal;
HostType *arrayType = keyOps->typeSubsumes( maxValLL );
assert( arrayType != 0 );
string ret = arrayType->data1;
if ( arrayType->data2 != 0 ) {
ret += " ";
ret += arrayType->data2;
}
return ret;
}
/* Write out the fsm name. */
string FsmCodeGen::FSM_NAME()
{
return fsmName;
}
/* Emit the offset of the start state as a decimal integer. */
string FsmCodeGen::START_STATE_ID()
{
ostringstream ret;
ret << redFsm->startState->id;
return ret.str();
};
/* Write out the array of actions. */
std::ostream &FsmCodeGen::ACTIONS_ARRAY()
{
out << "\t0, ";
int totalActions = 1;
for ( GenActionTableMap::Iter act = redFsm->actionMap; act.lte(); act++ ) {
/* Write out the length, which will never be the last character. */
out << act->key.length() << ", ";
/* Put in a line break every 8 */
if ( totalActions++ % 8 == 7 )
out << "\n\t";
for ( GenActionTable::Iter item = act->key; item.lte(); item++ ) {
out << item->value->actionId;
if ( ! (act.last() && item.last()) )
out << ", ";
/* Put in a line break every 8 */
if ( totalActions++ % 8 == 7 )
out << "\n\t";
}
}
out << "\n";
return out;
}
string FsmCodeGen::ACCESS()
{
ostringstream ret;
if ( accessExpr != 0 )
INLINE_LIST( ret, accessExpr, 0, false, false );
return ret.str();
}
string FsmCodeGen::P()
{
ostringstream ret;
if ( pExpr == 0 )
ret << "p";
else {
ret << "(";
INLINE_LIST( ret, pExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::PE()
{
ostringstream ret;
if ( peExpr == 0 )
ret << "pe";
else {
ret << "(";
INLINE_LIST( ret, peExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::vEOF()
{
ostringstream ret;
if ( eofExpr == 0 )
ret << "eof";
else {
ret << "(";
INLINE_LIST( ret, eofExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::vCS()
{
ostringstream ret;
if ( csExpr == 0 )
ret << ACCESS() << "cs";
else {
/* Emit the user supplied method of retrieving the key. */
ret << "(";
INLINE_LIST( ret, csExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::TOP()
{
ostringstream ret;
if ( topExpr == 0 )
ret << ACCESS() + "top";
else {
ret << "(";
INLINE_LIST( ret, topExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::STACK()
{
ostringstream ret;
if ( stackExpr == 0 )
ret << ACCESS() + "stack";
else {
ret << "(";
INLINE_LIST( ret, stackExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::ACT()
{
ostringstream ret;
if ( actExpr == 0 )
ret << ACCESS() + "act";
else {
ret << "(";
INLINE_LIST( ret, actExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::TOKSTART()
{
ostringstream ret;
if ( tokstartExpr == 0 )
ret << ACCESS() + "ts";
else {
ret << "(";
INLINE_LIST( ret, tokstartExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::TOKEND()
{
ostringstream ret;
if ( tokendExpr == 0 )
ret << ACCESS() + "te";
else {
ret << "(";
INLINE_LIST( ret, tokendExpr, 0, false, false );
ret << ")";
}
return ret.str();
}
string FsmCodeGen::GET_WIDE_KEY()
{
if ( redFsm->anyConditions() )
return "_widec";
else
return GET_KEY();
}
string FsmCodeGen::GET_WIDE_KEY( RedStateAp *state )
{
if ( state->stateCondList.length() > 0 )
return "_widec";
else
return GET_KEY();
}
string FsmCodeGen::GET_KEY()
{
ostringstream ret;
if ( getKeyExpr != 0 ) {
/* Emit the user supplied method of retrieving the key. */
ret << "(";
INLINE_LIST( ret, getKeyExpr, 0, false, false );
ret << ")";
}
else {
/* Expression for retrieving the key, use simple dereference. */
ret << "(*" << P() << ")";
}
return ret.str();
}
/* Write out level number of tabs. Makes the nested binary search nice
* looking. */
string FsmCodeGen::TABS( int level )
{
string result;
while ( level-- > 0 )
result += "\t";
return result;
}
/* Write out a key from the fsm code gen. Depends on wether or not the key is
* signed. */
string FsmCodeGen::KEY( Key key )
{
ostringstream ret;
if ( keyOps->isSigned || !hostLang->explicitUnsigned )
ret << key.getVal();
else
ret << (unsigned long) key.getVal() << 'u';
return ret.str();
}
bool FsmCodeGen::isAlphTypeSigned()
{
return keyOps->isSigned;
}
bool FsmCodeGen::isWideAlphTypeSigned()
{
string ret;
if ( redFsm->maxKey <= keyOps->maxKey )
return isAlphTypeSigned();
else {
long long maxKeyVal = redFsm->maxKey.getLongLong();
HostType *wideType = keyOps->typeSubsumes( keyOps->isSigned, maxKeyVal );
return wideType->isSigned;
}
}
string FsmCodeGen::WIDE_KEY( RedStateAp *state, Key key )
{
if ( state->stateCondList.length() > 0 ) {
ostringstream ret;
if ( isWideAlphTypeSigned() )
ret << key.getVal();
else
ret << (unsigned long) key.getVal() << 'u';
return ret.str();
}
else {
return KEY( key );
}
}
void FsmCodeGen::EOF_CHECK( ostream &ret )
{
ret <<
" if ( " << P() << " == " << PE() << " )\n"
" goto _test_eof;\n";
testEofUsed = true;
}
void FsmCodeGen::EXEC( ostream &ret, GenInlineItem *item, int targState, int inFinish )
{
/* The parser gives fexec two children. The double brackets are for D
* code. If the inline list is a single word it will get interpreted as a
* C-style cast by the D compiler. */
ret << "{" << P() << " = ((";
INLINE_LIST( ret, item->children, targState, inFinish, false );
ret << "))-1;}";
}
void FsmCodeGen::LM_SWITCH( ostream &ret, GenInlineItem *item,
int targState, int inFinish, bool csForced )
{
ret <<
" switch( " << ACT() << " ) {\n";
bool haveDefault = false;
for ( GenInlineList::Iter lma = *item->children; lma.lte(); lma++ ) {
/* Write the case label, the action and the case break. */
if ( lma->lmId < 0 ) {
ret << " default:\n";
haveDefault = true;
}
else
ret << " case " << lma->lmId << ":\n";
/* Write the block and close it off. */
ret << " {";
INLINE_LIST( ret, lma->children, targState, inFinish, csForced );
ret << "}\n";
ret << " break;\n";
}
if ( (hostLang->lang == HostLang::D || hostLang->lang == HostLang::D2) && !haveDefault )
ret << " default: break;";
ret <<
" }\n"
"\t";
}
void FsmCodeGen::SET_ACT( ostream &ret, GenInlineItem *item )
{
ret << ACT() << " = " << item->lmId << ";";
}
void FsmCodeGen::SET_TOKEND( ostream &ret, GenInlineItem *item )
{
/* The tokend action sets tokend. */
ret << TOKEND() << " = " << P();
if ( item->offset != 0 )
out << "+" << item->offset;
out << ";";
}
void FsmCodeGen::GET_TOKEND( ostream &ret, GenInlineItem *item )
{
ret << TOKEND();
}
void FsmCodeGen::INIT_TOKSTART( ostream &ret, GenInlineItem *item )
{
ret << TOKSTART() << " = " << NULL_ITEM() << ";";
}
void FsmCodeGen::INIT_ACT( ostream &ret, GenInlineItem *item )
{
ret << ACT() << " = 0;";
}
void FsmCodeGen::SET_TOKSTART( ostream &ret, GenInlineItem *item )
{
ret << TOKSTART() << " = " << P() << ";";
}
void FsmCodeGen::SUB_ACTION( ostream &ret, GenInlineItem *item,
int targState, bool inFinish, bool csForced )
{
if ( item->children->length() > 0 ) {
/* Write the block and close it off. */
ret << "{";
INLINE_LIST( ret, item->children, targState, inFinish, csForced );
ret << "}";
}
}
/* Write out an inline tree structure. Walks the list and possibly calls out
* to virtual functions than handle language specific items in the tree. */
void FsmCodeGen::INLINE_LIST( ostream &ret, GenInlineList *inlineList,
int targState, bool inFinish, bool csForced )
{
for ( GenInlineList::Iter item = *inlineList; item.lte(); item++ ) {
switch ( item->type ) {
case GenInlineItem::Text:
ret << item->data;
break;
case GenInlineItem::Goto:
GOTO( ret, item->targState->id, inFinish );
break;
case GenInlineItem::Call:
CALL( ret, item->targState->id, targState, inFinish );
break;
case GenInlineItem::Next:
NEXT( ret, item->targState->id, inFinish );
break;
case GenInlineItem::Ret:
RET( ret, inFinish );
break;
case GenInlineItem::PChar:
ret << P();
break;
case GenInlineItem::Char:
ret << GET_KEY();
break;
case GenInlineItem::Hold:
ret << P() << "--;";
break;
case GenInlineItem::Exec:
EXEC( ret, item, targState, inFinish );
break;
case GenInlineItem::Curs:
CURS( ret, inFinish );
break;
case GenInlineItem::Targs:
TARGS( ret, inFinish, targState );
break;
case GenInlineItem::Entry:
ret << item->targState->id;
break;
case GenInlineItem::GotoExpr:
GOTO_EXPR( ret, item, inFinish );
break;
case GenInlineItem::CallExpr:
CALL_EXPR( ret, item, targState, inFinish );
break;
case GenInlineItem::NextExpr:
NEXT_EXPR( ret, item, inFinish );
break;
case GenInlineItem::LmSwitch:
LM_SWITCH( ret, item, targState, inFinish, csForced );
break;
case GenInlineItem::LmSetActId:
SET_ACT( ret, item );
break;
case GenInlineItem::LmSetTokEnd:
SET_TOKEND( ret, item );
break;
case GenInlineItem::LmGetTokEnd:
GET_TOKEND( ret, item );
break;
case GenInlineItem::LmInitTokStart:
INIT_TOKSTART( ret, item );
break;
case GenInlineItem::LmInitAct:
INIT_ACT( ret, item );
break;
case GenInlineItem::LmSetTokStart:
SET_TOKSTART( ret, item );
break;
case GenInlineItem::SubAction:
SUB_ACTION( ret, item, targState, inFinish, csForced );
break;
case GenInlineItem::Break:
BREAK( ret, targState, csForced );
break;
}
}
}
/* Write out paths in line directives. Escapes any special characters. */
string FsmCodeGen::LDIR_PATH( char *path )
{
ostringstream ret;
for ( char *pc = path; *pc != 0; pc++ ) {
if ( *pc == '\\' )
ret << "\\\\";
else
ret << *pc;
}
return ret.str();
}
void FsmCodeGen::ACTION( ostream &ret, GenAction *action, int targState,
bool inFinish, bool csForced )
{
/* Write the preprocessor line info for going into the source file. */
cdLineDirective( ret, action->loc.fileName, action->loc.line );
/* Write the block and close it off. */
ret << "\t{";
INLINE_LIST( ret, action->inlineList, targState, inFinish, csForced );
ret << "}\n";
}
void FsmCodeGen::CONDITION( ostream &ret, GenAction *condition )
{
ret << "\n";
cdLineDirective( ret, condition->loc.fileName, condition->loc.line );
INLINE_LIST( ret, condition->inlineList, 0, false, false );
}
string FsmCodeGen::ERROR_STATE()
{
ostringstream ret;
if ( redFsm->errState != 0 )
ret << redFsm->errState->id;
else
ret << "-1";
return ret.str();
}
string FsmCodeGen::FIRST_FINAL_STATE()
{
ostringstream ret;
if ( redFsm->firstFinState != 0 )
ret << redFsm->firstFinState->id;
else
ret << redFsm->nextStateId;
return ret.str();
}
void FsmCodeGen::writeInit()
{
out << " {\n";
if ( !noCS )
out << "\t" << vCS() << " = " << START() << ";\n";
/* If there are any calls, then the stack top needs initialization. */
if ( redFsm->anyActionCalls() || redFsm->anyActionRets() )
out << "\t" << TOP() << " = 0;\n";
if ( hasLongestMatch ) {
out <<
" " << TOKSTART() << " = " << NULL_ITEM() << ";\n"
" " << TOKEND() << " = " << NULL_ITEM() << ";\n"
" " << ACT() << " = 0;\n";
}
out << " }\n";
}
string FsmCodeGen::DATA_PREFIX()
{
if ( !noPrefix )
return FSM_NAME() + "_";
return "";
}
/* Emit the alphabet data type. */
string FsmCodeGen::ALPH_TYPE()
{
string ret = keyOps->alphType->data1;
if ( keyOps->alphType->data2 != 0 ) {
ret += " ";
ret += + keyOps->alphType->data2;
}
return ret;
}
/* Emit the alphabet data type. */
string FsmCodeGen::WIDE_ALPH_TYPE()
{
string ret;
if ( redFsm->maxKey <= keyOps->maxKey )
ret = ALPH_TYPE();
else {
long long maxKeyVal = redFsm->maxKey.getLongLong();
HostType *wideType = keyOps->typeSubsumes( keyOps->isSigned, maxKeyVal );
assert( wideType != 0 );
ret = wideType->data1;
if ( wideType->data2 != 0 ) {
ret += " ";
ret += wideType->data2;
}
}
return ret;
}
void FsmCodeGen::STATE_IDS()
{
if ( redFsm->startState != 0 )
STATIC_VAR( "int", START() ) << " = " << START_STATE_ID() << "};\n";
if ( !noFinal )
STATIC_VAR( "int" , FIRST_FINAL() ) << " = " << FIRST_FINAL_STATE() << "};\n";
if ( !noError )
STATIC_VAR( "int", ERROR() ) << " = " << ERROR_STATE() << "};\n";
out << "\n";
if ( !noEntry && entryPointNames.length() > 0 ) {
for ( EntryNameVect::Iter en = entryPointNames; en.lte(); en++ ) {
STATIC_VAR( "int", DATA_PREFIX() + "en_" + *en ) <<
" = " << entryPointIds[en.pos()] << "};\n";
}
out << "\n";
}
}
void FsmCodeGen::writeStart()
{
out << START_STATE_ID();
}
void FsmCodeGen::writeFirstFinal()
{
out << FIRST_FINAL_STATE();
}
void FsmCodeGen::writeError()
{
out << ERROR_STATE();
}
/*
* Language specific, but style independent code generators functions.
*/
string CCodeGen::PTR_CONST()
{
return "const ";
}
string CCodeGen::PTR_CONST_END()
{
return "";
}
std::ostream &CCodeGen::OPEN_ARRAY( string type, string name )
{
out << "#if defined(__GNUC__)\n";
out << "static __attribute__((used)) const " << type << " " << name << "[] = {\n";
out << "#else\n";
out << "static const " << type << " " << name << "[] = {\n";
out << "#endif\n";
return out;
}
std::ostream &CCodeGen::CLOSE_ARRAY()
{
return out << "};\n";
}
std::ostream &CCodeGen::STATIC_VAR( string type, string name )
{
out << "enum {" << name;
return out;
}
string CCodeGen::UINT( )
{
return "unsigned int";
}
string CCodeGen::ARR_OFF( string ptr, string offset )
{
return ptr + " + " + offset;
}
string CCodeGen::CAST( string type )
{
return "(" + type + ")";
}
string CCodeGen::NULL_ITEM()
{
return "0";
}
string CCodeGen::POINTER()
{
return " *";
}
std::ostream &CCodeGen::SWITCH_DEFAULT()
{
return out;
}
string CCodeGen::CTRL_FLOW()
{
return "";
}
void CCodeGen::writeExports()
{
if ( exportList.length() > 0 ) {
for ( ExportList::Iter ex = exportList; ex.lte(); ex++ ) {
out << "#define " << DATA_PREFIX() << "ex_" << ex->name << " " <<
KEY(ex->key) << "\n";
}
out << "\n";
}
}
/*
* D Specific
*/
string DCodeGen::NULL_ITEM()
{
return "null";
}
string DCodeGen::POINTER()
{
// multiple items seperated by commas can also be pointer types.
return "* ";
}
string DCodeGen::PTR_CONST()
{
return "";
}
string DCodeGen::PTR_CONST_END()
{
return "";
}
std::ostream &DCodeGen::OPEN_ARRAY( string type, string name )
{
out << "static const " << type << "[] " << name << " = [\n";
return out;
}
std::ostream &DCodeGen::CLOSE_ARRAY()
{
return out << "];\n";
}
std::ostream &DCodeGen::STATIC_VAR( string type, string name )
{
out << "static const " << type << " " << name;
return out;
}
string DCodeGen::ARR_OFF( string ptr, string offset )
{
return "&" + ptr + "[" + offset + "]";
}
string DCodeGen::CAST( string type )
{
return "cast(" + type + ")";
}
string DCodeGen::UINT( )
{
return "uint";
}
std::ostream &DCodeGen::SWITCH_DEFAULT()
{
out << " default: break;\n";
return out;
}
string DCodeGen::CTRL_FLOW()
{
return "if (true) ";
}
void DCodeGen::writeExports()
{
if ( exportList.length() > 0 ) {
for ( ExportList::Iter ex = exportList; ex.lte(); ex++ ) {
out << "static const " << ALPH_TYPE() << " " << DATA_PREFIX() <<
"ex_" << ex->name << " = " << KEY(ex->key) << ";\n";
}
out << "\n";
}
}
/*
* End D-specific code.
*/
/*
* D2 Specific
*/
string D2CodeGen::NULL_ITEM()
{
return "null";
}
string D2CodeGen::POINTER()
{
// multiple items seperated by commas can also be pointer types.
return "* ";
}
string D2CodeGen::PTR_CONST()
{
return "const(";
}
string D2CodeGen::PTR_CONST_END()
{
return ")";
}
std::ostream &D2CodeGen::OPEN_ARRAY( string type, string name )
{
out << "enum " << type << "[] " << name << " = [\n";
return out;
}
std::ostream &D2CodeGen::CLOSE_ARRAY()
{
return out << "];\n";
}
std::ostream &D2CodeGen::STATIC_VAR( string type, string name )
{
out << "enum " << type << " " << name;
return out;
}
string D2CodeGen::ARR_OFF( string ptr, string offset )
{
return "&" + ptr + "[" + offset + "]";
}
string D2CodeGen::CAST( string type )
{
return "cast(" + type + ")";
}
string D2CodeGen::UINT( )
{
return "uint";
}
std::ostream &D2CodeGen::SWITCH_DEFAULT()
{
out << " default: break;\n";
return out;
}
string D2CodeGen::CTRL_FLOW()
{
return "if (true) ";
}
void D2CodeGen::writeExports()
{
if ( exportList.length() > 0 ) {
for ( ExportList::Iter ex = exportList; ex.lte(); ex++ ) {
out << "enum " << ALPH_TYPE() << " " << DATA_PREFIX() <<
"ex_" << ex->name << " = " << KEY(ex->key) << ";\n";
}
out << "\n";
}
}
void D2CodeGen::SUB_ACTION( ostream &ret, GenInlineItem *item,
int targState, bool inFinish, bool csForced )
{
if ( item->children->length() > 0 ) {
/* Write the block and close it off. */
ret << "{{";
INLINE_LIST( ret, item->children, targState, inFinish, csForced );
ret << "}}";
}
}
void D2CodeGen::ACTION( ostream &ret, GenAction *action, int targState,
bool inFinish, bool csForced )
{
/* Write the preprocessor line info for going into the source file. */
cdLineDirective( ret, action->loc.fileName, action->loc.line );
/* Write the block and close it off. */
ret << "\t{{";
INLINE_LIST( ret, action->inlineList, targState, inFinish, csForced );
ret << "}}\n";
}
/*
* End D2-specific code.
*/
void FsmCodeGen::finishRagelDef()
{
if ( codeStyle == GenGoto || codeStyle == GenFGoto ||
codeStyle == GenIpGoto || codeStyle == GenSplit )
{
/* For directly executable machines there is no required state
* ordering. Choose a depth-first ordering to increase the
* potential for fall-throughs. */
redFsm->depthFirstOrdering();
}
else {
/* The frontend will do this for us, but it may be a good idea to
* force it if the intermediate file is edited. */
redFsm->sortByStateId();
}
/* Choose default transitions and the single transition. */
redFsm->chooseDefaultSpan();
/* Maybe do flat expand, otherwise choose single. */
if ( codeStyle == GenFlat || codeStyle == GenFFlat )
redFsm->makeFlat();
else
redFsm->chooseSingle();
/* If any errors have occured in the input file then don't write anything. */
if ( gblErrorCount > 0 )
return;
if ( codeStyle == GenSplit )
redFsm->partitionFsm( numSplitPartitions );
if ( codeStyle == GenIpGoto || codeStyle == GenSplit )
redFsm->setInTrans();
/* Anlayze Machine will find the final action reference counts, among
* other things. We will use these in reporting the usage
* of fsm directives in action code. */
analyzeMachine();
/* Determine if we should use indicies. */
calcIndexSize();
}
ostream &FsmCodeGen::source_warning( const InputLoc &loc )
{
cerr << sourceFileName << ":" << loc.line << ":" << loc.col << ": warning: ";
return cerr;
}
ostream &FsmCodeGen::source_error( const InputLoc &loc )
{
gblErrorCount += 1;
assert( sourceFileName != 0 );
cerr << sourceFileName << ":" << loc.line << ":" << loc.col << ": ";
return cerr;
}