/*
* Copyright 2004-2006 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 <sstream>
#include "ragel.h"
#include "mlflat.h"
#include "redfsm.h"
#include "gendata.h"
std::ostream &OCamlFlatCodeGen::TO_STATE_ACTION( RedStateAp *state )
{
int act = 0;
if ( state->toStateAction != 0 )
act = state->toStateAction->location+1;
out << act;
return out;
}
std::ostream &OCamlFlatCodeGen::FROM_STATE_ACTION( RedStateAp *state )
{
int act = 0;
if ( state->fromStateAction != 0 )
act = state->fromStateAction->location+1;
out << act;
return out;
}
std::ostream &OCamlFlatCodeGen::EOF_ACTION( RedStateAp *state )
{
int act = 0;
if ( state->eofAction != 0 )
act = state->eofAction->location+1;
out << act;
return out;
}
std::ostream &OCamlFlatCodeGen::TRANS_ACTION( RedTransAp *trans )
{
/* If there are actions, emit them. Otherwise emit zero. */
int act = 0;
if ( trans->action != 0 )
act = trans->action->location+1;
out << act;
return out;
}
std::ostream &OCamlFlatCodeGen::TO_STATE_ACTION_SWITCH()
{
/* Walk the list of functions, printing the cases. */
for ( GenActionList::Iter act = actionList; act.lte(); act++ ) {
/* Write out referenced actions. */
if ( act->numToStateRefs > 0 ) {
/* Write the case label, the action and the case break */
out << "\t| " << act->actionId << " ->\n";
ACTION( out, act, 0, false );
out << "\t()\n";
}
}
genLineDirective( out );
return out;
}
std::ostream &OCamlFlatCodeGen::FROM_STATE_ACTION_SWITCH()
{
/* Walk the list of functions, printing the cases. */
for ( GenActionList::Iter act = actionList; act.lte(); act++ ) {
/* Write out referenced actions. */
if ( act->numFromStateRefs > 0 ) {
/* Write the case label, the action and the case break */
out << "\t| " << act->actionId << " ->\n";
ACTION( out, act, 0, false );
out << "\t()\n";
}
}
genLineDirective( out );
return out;
}
std::ostream &OCamlFlatCodeGen::EOF_ACTION_SWITCH()
{
/* Walk the list of functions, printing the cases. */
for ( GenActionList::Iter act = actionList; act.lte(); act++ ) {
/* Write out referenced actions. */
if ( act->numEofRefs > 0 ) {
/* Write the case label, the action and the case break */
out << "\t| " << act->actionId << " ->\n";
ACTION( out, act, 0, true );
out << "\t()\n";
}
}
genLineDirective( out );
return out;
}
std::ostream &OCamlFlatCodeGen::ACTION_SWITCH()
{
/* Walk the list of functions, printing the cases. */
for ( GenActionList::Iter act = actionList; act.lte(); act++ ) {
/* Write out referenced actions. */
if ( act->numTransRefs > 0 ) {
/* Write the case label, the action and the case break */
out << "\t| " << act->actionId << " ->\n";
ACTION( out, act, 0, false );
out << "\t()\n";
}
}
genLineDirective( out );
return out;
}
std::ostream &OCamlFlatCodeGen::FLAT_INDEX_OFFSET()
{
out << "\t";
int totalStateNum = 0, curIndOffset = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write the index offset. */
out << curIndOffset;
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
/* Move the index offset ahead. */
if ( st->transList != 0 )
curIndOffset += keyOps->span( st->lowKey, st->highKey );
if ( st->defTrans != 0 )
curIndOffset += 1;
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::KEY_SPANS()
{
out << "\t";
int totalStateNum = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write singles length. */
unsigned long long span = 0;
if ( st->transList != 0 )
span = keyOps->span( st->lowKey, st->highKey );
out << span;
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::TO_STATE_ACTIONS()
{
out << "\t";
int totalStateNum = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write any eof action. */
TO_STATE_ACTION(st);
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::FROM_STATE_ACTIONS()
{
out << "\t";
int totalStateNum = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write any eof action. */
FROM_STATE_ACTION(st);
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::EOF_ACTIONS()
{
out << "\t";
int totalStateNum = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write any eof action. */
EOF_ACTION(st);
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::EOF_TRANS()
{
out << "\t";
int totalStateNum = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write any eof action. */
long trans = 0;
if ( st->eofTrans != 0 ) {
assert( st->eofTrans->pos >= 0 );
trans = st->eofTrans->pos+1;
}
out << trans;
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::COND_KEYS()
{
out << '\t';
int totalTrans = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Emit just cond low key and cond high key. */
out << ALPHA_KEY( st->condLowKey ) << ARR_SEP();
out << ALPHA_KEY( st->condHighKey ) << ARR_SEP();
if ( ++totalTrans % IALL == 0 )
out << "\n\t";
}
/* Output one last number so we don't have to figure out when the last
* entry is and avoid writing a comma. */
out << /*"(char) " <<*/ 0 << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::COND_KEY_SPANS()
{
out << "\t";
int totalStateNum = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write singles length. */
unsigned long long span = 0;
if ( st->condList != 0 )
span = keyOps->span( st->condLowKey, st->condHighKey );
out << span;
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::CONDS()
{
int totalTrans = 0;
out << '\t';
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
if ( st->condList != 0 ) {
/* Walk the singles. */
unsigned long long span = keyOps->span( st->condLowKey, st->condHighKey );
for ( unsigned long long pos = 0; pos < span; pos++ ) {
if ( st->condList[pos] != 0 )
out << st->condList[pos]->condSpaceId + 1 << ARR_SEP();
else
out << "0" << ARR_SEP();
if ( ++totalTrans % IALL == 0 )
out << "\n\t";
}
}
}
/* Output one last number so we don't have to figure out when the last
* entry is and avoid writing a comma. */
out << 0 << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::COND_INDEX_OFFSET()
{
out << "\t";
int totalStateNum = 0, curIndOffset = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Write the index offset. */
out << curIndOffset;
if ( !st.last() ) {
out << ARR_SEP();
if ( ++totalStateNum % IALL == 0 )
out << "\n\t";
}
/* Move the index offset ahead. */
if ( st->condList != 0 )
curIndOffset += keyOps->span( st->condLowKey, st->condHighKey );
}
out << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::KEYS()
{
out << '\t';
int totalTrans = 0;
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
/* Emit just low key and high key. */
out << ALPHA_KEY( st->lowKey ) << ARR_SEP();
out << ALPHA_KEY( st->highKey ) << ARR_SEP();
if ( ++totalTrans % IALL == 0 )
out << "\n\t";
}
/* Output one last number so we don't have to figure out when the last
* entry is and avoid writing a comma. */
out << /*"(char) " <<*/ 0 << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::INDICIES()
{
int totalTrans = 0;
out << '\t';
for ( RedStateList::Iter st = redFsm->stateList; st.lte(); st++ ) {
if ( st->transList != 0 ) {
/* Walk the singles. */
unsigned long long span = keyOps->span( st->lowKey, st->highKey );
for ( unsigned long long pos = 0; pos < span; pos++ ) {
out << st->transList[pos]->id << ARR_SEP();
if ( ++totalTrans % IALL == 0 )
out << "\n\t";
}
}
/* The state's default index goes next. */
if ( st->defTrans != 0 )
out << st->defTrans->id << ARR_SEP();
if ( ++totalTrans % IALL == 0 )
out << "\n\t";
}
/* Output one last number so we don't have to figure out when the last
* entry is and avoid writing a comma. */
out << 0 << "\n";
return out;
}
std::ostream &OCamlFlatCodeGen::TRANS_TARGS()
{
/* Transitions must be written ordered by their id. */
RedTransAp **transPtrs = new RedTransAp*[redFsm->transSet.length()];
for ( TransApSet::Iter trans = redFsm->transSet; trans.lte(); trans++ )
transPtrs[trans->id] = trans;
/* Keep a count of the num of items in the array written. */
out << '\t';
int totalStates = 0;
for ( int t = 0; t < redFsm->transSet.length(); t++ ) {
/* Record the position, need this for eofTrans. */
RedTransAp *trans = transPtrs[t];
trans->pos = t;
/* Write out the target state. */
out << trans->targ->id;
if ( t < redFsm->transSet.length()-1 ) {
out << ARR_SEP();
if ( ++totalStates % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
delete[] transPtrs;
return out;
}
std::ostream &OCamlFlatCodeGen::TRANS_ACTIONS()
{
/* Transitions must be written ordered by their id. */
RedTransAp **transPtrs = new RedTransAp*[redFsm->transSet.length()];
for ( TransApSet::Iter trans = redFsm->transSet; trans.lte(); trans++ )
transPtrs[trans->id] = trans;
/* Keep a count of the num of items in the array written. */
out << '\t';
int totalAct = 0;
for ( int t = 0; t < redFsm->transSet.length(); t++ ) {
/* Write the function for the transition. */
RedTransAp *trans = transPtrs[t];
TRANS_ACTION( trans );
if ( t < redFsm->transSet.length()-1 ) {
out << ARR_SEP();
if ( ++totalAct % IALL == 0 )
out << "\n\t";
}
}
out << "\n";
delete[] transPtrs;
return out;
}
void OCamlFlatCodeGen::LOCATE_TRANS()
{
std::ostringstream temp;
temp << "inds + (\n"
" if slen > 0 && " << AT( K(), "keys" ) << " <= " << GET_WIDE_KEY() << " &&\n"
" " << GET_WIDE_KEY() << " <= " << AT( K(), "keys+1" ) << " then\n"
" " << GET_WIDE_KEY() << " - " << AT(K(), "keys" ) << " else slen)";
out <<
" let keys = " << vCS() << " lsl 1 in\n"
" let inds = " << AT( IO(), vCS() ) << " in\n"
"\n"
" let slen = " << AT( SP(), vCS() ) << " in\n"
" state.trans <- " << AT( I(), temp.str() ) << ";\n"
"\n";
}
void OCamlFlatCodeGen::GOTO( ostream &ret, int gotoDest, bool inFinish )
{
ret << "begin " << vCS() << " <- " << gotoDest << "; " <<
CTRL_FLOW() << "raise Goto_again end";
}
void OCamlFlatCodeGen::GOTO_EXPR( ostream &ret, GenInlineItem *ilItem, bool inFinish )
{
ret << "begin " << vCS() << " <- (";
INLINE_LIST( ret, ilItem->children, 0, inFinish );
ret << "); " << CTRL_FLOW() << " raise Goto_again end";
}
void OCamlFlatCodeGen::CURS( ostream &ret, bool inFinish )
{
ret << "(_ps)";
}
void OCamlFlatCodeGen::TARGS( ostream &ret, bool inFinish, int targState )
{
ret << "(" << vCS() << ")";
}
void OCamlFlatCodeGen::NEXT( ostream &ret, int nextDest, bool inFinish )
{
ret << vCS() << " <- " << nextDest << ";";
}
void OCamlFlatCodeGen::NEXT_EXPR( ostream &ret, GenInlineItem *ilItem, bool inFinish )
{
ret << vCS() << " <- (";
INLINE_LIST( ret, ilItem->children, 0, inFinish );
ret << ");";
}
void OCamlFlatCodeGen::CALL( ostream &ret, int callDest, int targState, bool inFinish )
{
if ( prePushExpr != 0 ) {
ret << "begin ";
INLINE_LIST( ret, prePushExpr, 0, false );
}
ret << "begin " << AT( STACK(), POST_INCR(TOP()) ) << " <- " << vCS() << "; ";
ret << vCS() << " <- " << callDest << "; " << CTRL_FLOW() << "raise Goto_again end ";
if ( prePushExpr != 0 )
ret << "end";
}
void OCamlFlatCodeGen::CALL_EXPR( ostream &ret, GenInlineItem *ilItem, int targState, bool inFinish )
{
if ( prePushExpr != 0 ) {
ret << "begin ";
INLINE_LIST( ret, prePushExpr, 0, false );
}
ret << "begin " << AT(STACK(), POST_INCR(TOP()) ) << " <- " << vCS() << "; " << vCS() << " <- (";
INLINE_LIST( ret, ilItem->children, targState, inFinish );
ret << "); " << CTRL_FLOW() << "raise Goto_again end ";
if ( prePushExpr != 0 )
ret << "end";
}
void OCamlFlatCodeGen::RET( ostream &ret, bool inFinish )
{
ret << "begin " << vCS() << " <- " << AT(STACK(), PRE_DECR(TOP()) ) << "; ";
if ( postPopExpr != 0 ) {
ret << "begin ";
INLINE_LIST( ret, postPopExpr, 0, false );
ret << "end ";
}
ret << CTRL_FLOW() << "raise Goto_again end";
}
void OCamlFlatCodeGen::BREAK( ostream &ret, int targState )
{
outLabelUsed = true;
ret << "begin " << P() << " <- " << P() << " + 1; " << CTRL_FLOW() << "raise Goto_out end";
}
void OCamlFlatCodeGen::writeData()
{
/* If there are any transtion functions then output the array. If there
* are none, don't bother emitting an empty array that won't be used. */
if ( redFsm->anyActions() ) {
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxActArrItem), A() );
ACTIONS_ARRAY();
CLOSE_ARRAY() <<
"\n";
}
if ( redFsm->anyConditions() ) {
OPEN_ARRAY( WIDE_ALPH_TYPE(), CK() );
COND_KEYS();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxCondSpan), CSP() );
COND_KEY_SPANS();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxCond), C() );
CONDS();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxCondIndexOffset), CO() );
COND_INDEX_OFFSET();
CLOSE_ARRAY() <<
"\n";
}
OPEN_ARRAY( WIDE_ALPH_TYPE(), K() );
KEYS();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxSpan), SP() );
KEY_SPANS();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxFlatIndexOffset), IO() );
FLAT_INDEX_OFFSET();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxIndex), I() );
INDICIES();
CLOSE_ARRAY() <<
"\n";
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxState), TT() );
TRANS_TARGS();
CLOSE_ARRAY() <<
"\n";
if ( redFsm->anyActions() ) {
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxActionLoc), TA() );
TRANS_ACTIONS();
CLOSE_ARRAY() <<
"\n";
}
if ( redFsm->anyToStateActions() ) {
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxActionLoc), TSA() );
TO_STATE_ACTIONS();
CLOSE_ARRAY() <<
"\n";
}
if ( redFsm->anyFromStateActions() ) {
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxActionLoc), FSA() );
FROM_STATE_ACTIONS();
CLOSE_ARRAY() <<
"\n";
}
if ( redFsm->anyEofActions() ) {
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxActionLoc), EA() );
EOF_ACTIONS();
CLOSE_ARRAY() <<
"\n";
}
if ( redFsm->anyEofTrans() ) {
OPEN_ARRAY( ARRAY_TYPE(redFsm->maxIndexOffset+1), ET() );
EOF_TRANS();
CLOSE_ARRAY() <<
"\n";
}
STATE_IDS();
out << "type " << TYPE_STATE() << " = { mutable trans : int; mutable acts : int; mutable nacts : int; }"
<< TOP_SEP();
out << "exception Goto_match" << TOP_SEP();
out << "exception Goto_again" << TOP_SEP();
out << "exception Goto_eof_trans" << TOP_SEP();
}
void OCamlFlatCodeGen::COND_TRANSLATE()
{
out <<
" _widec = " << GET_KEY() << ";\n";
out <<
" _keys = " << vCS() << "<<1;\n"
" _conds = " << CO() << "[" << vCS() << "];\n"
// " _keys = " << ARR_OFF( CK(), "(" + vCS() + "<<1)" ) << ";\n"
// " _conds = " << ARR_OFF( C(), CO() + "[" + vCS() + "]" ) << ";\n"
"\n"
" _slen = " << CSP() << "[" << vCS() << "];\n"
" if (_slen > 0 && " << CK() << "[_keys] <="
<< GET_WIDE_KEY() << " &&\n"
" " << GET_WIDE_KEY() << " <= " << CK() << "[_keys+1])\n"
" _cond = " << C() << "[_conds+" << GET_WIDE_KEY() << " - " <<
CK() << "[_keys]];\n"
" else\n"
" _cond = 0;"
"\n";
/* XXX This version of the code doesn't work because Mono is weird. Works
* fine in Microsoft's csc, even though the bug report filed claimed it
* didn't.
" _slen = " << CSP() << "[" << vCS() << "];\n"
" _cond = _slen > 0 && " << CK() << "[_keys] <="
<< GET_WIDE_KEY() << " &&\n"
" " << GET_WIDE_KEY() << " <= " << CK() << "[_keys+1] ?\n"
" " << C() << "[_conds+" << GET_WIDE_KEY() << " - " << CK()
<< "[_keys]] : 0;\n"
"\n";
*/
out <<
" switch ( _cond ) {\n";
for ( CondSpaceList::Iter csi = condSpaceList; csi.lte(); csi++ ) {
GenCondSpace *condSpace = csi;
out << " case " << condSpace->condSpaceId + 1 << ": {\n";
out << TABS(2) << "_widec = " << CAST(WIDE_ALPH_TYPE()) << "(" <<
KEY(condSpace->baseKey) << " + (" << GET_KEY() <<
" - " << KEY(keyOps->minKey) << "));\n";
for ( GenCondSet::Iter csi = condSpace->condSet; csi.lte(); csi++ ) {
out << TABS(2) << "if ( ";
CONDITION( out, *csi );
Size condValOffset = ((1 << csi.pos()) * keyOps->alphSize());
out << " ) _widec += " << condValOffset << ";\n";
}
out << " }\n";
out << " break;\n";
}
SWITCH_DEFAULT();
out <<
" }\n";
}
void OCamlFlatCodeGen::writeExec()
{
testEofUsed = false;
outLabelUsed = false;
initVarTypes();
out <<
" begin\n";
// " " << slenType << " _slen";
// if ( redFsm->anyRegCurStateRef() )
// out << ", _ps";
// out <<
// " " << transType << " _trans";
// if ( redFsm->anyConditions() )
// out << ", _cond";
// out << ";\n";
// if ( redFsm->anyToStateActions() ||
// redFsm->anyRegActions() || redFsm->anyFromStateActions() )
// {
// out <<
// " int _acts;\n"
// " int _nacts;\n";
// }
// out <<
// " " << "int _keys;\n"
// " " << indsType << " _inds;\n";
/*
" " << PTR_CONST() << WIDE_ALPH_TYPE() << POINTER() << "_keys;\n"
" " << PTR_CONST() << ARRAY_TYPE(redFsm->maxIndex) << POINTER() << "_inds;\n";*/
if ( redFsm->anyConditions() ) {
out <<
" " << condsType << " _conds;\n"
" " << WIDE_ALPH_TYPE() << " _widec;\n";
}
out << "\n";
out <<
" let state = { trans = 0; acts = 0; nacts = 0; } in\n"
" let rec do_start () =\n";
if ( !noEnd ) {
testEofUsed = true;
out <<
" if " << P() << " = " << PE() << " then\n"
" do_test_eof ()\n"
"\telse\n";
}
if ( redFsm->errState != 0 ) {
outLabelUsed = true;
out <<
" if " << vCS() << " = " << redFsm->errState->id << " then\n"
" do_out ()\n"
"\telse\n";
}
out << "\tdo_resume ()\n";
out << "and do_resume () =\n";
if ( redFsm->anyFromStateActions() ) {
out <<
" state.acts <- " << AT( FSA(), vCS() ) << ";\n"
" state.nacts <- " << AT( A(), POST_INCR("state.acts") ) << ";\n"
" while " << POST_DECR("state.nacts") << " > 0 do\n"
" begin match " << AT( A(), POST_INCR("state.acts") ) << " with\n";
FROM_STATE_ACTION_SWITCH();
SWITCH_DEFAULT() <<
" end\n"
" done;\n"
"\n";
}
if ( redFsm->anyConditions() )
COND_TRANSLATE();
// out << "\tbegin try\n";
LOCATE_TRANS();
// out << "\twith Goto_match -> () end;\n";
out << "\tdo_eof_trans ()\n";
// if ( redFsm->anyEofTrans() )
out << "and do_eof_trans () =\n";
if ( redFsm->anyRegCurStateRef() )
out << " let ps = " << vCS() << " in\n";
out <<
" " << vCS() << " <- " << AT( TT() ,"state.trans" ) << ";\n"
"\n";
if ( redFsm->anyRegActions() ) {
out <<
"\tbegin try\n"
" match " << AT( TA(), "state.trans" ) << " with\n"
"\t| 0 -> raise Goto_again\n"
"\t| _ ->\n"
" state.acts <- " << AT( TA(), "state.trans" ) << ";\n"
" state.nacts <- " << AT( A(), POST_INCR("state.acts") ) << ";\n"
" while " << POST_DECR("state.nacts") << " > 0 do\n"
" begin match " << AT( A(), POST_INCR("state.acts") ) << " with\n";
ACTION_SWITCH();
SWITCH_DEFAULT() <<
" end;\n"
" done\n"
"\twith Goto_again -> () end;\n";
}
out << "\tdo_again ()\n";
// if ( redFsm->anyRegActions() || redFsm->anyActionGotos() ||
// redFsm->anyActionCalls() || redFsm->anyActionRets() )
out << "\tand do_again () =\n";
if ( redFsm->anyToStateActions() ) {
out <<
" state.acts <- " << AT( TSA(), vCS() ) << ";\n"
" state.nacts <- " << AT( A(), POST_INCR("state.acts") ) << ";\n"
" while " << POST_DECR("state.nacts") << " > 0 do\n"
" begin match " << AT( A(), POST_INCR("state.acts") ) << " with\n";
TO_STATE_ACTION_SWITCH();
SWITCH_DEFAULT() <<
" end\n"
" done;\n"
"\n";
}
if ( redFsm->errState != 0 ) {
outLabelUsed = true;
out <<
" match " << vCS() << " with\n"
"\t| " << redFsm->errState->id << " -> do_out ()\n"
"\t| _ ->\n";
}
out << "\t" << P() << " <- " << P() << " + 1;\n";
if ( !noEnd ) {
out <<
" if " << P() << " <> " << PE() << " then\n"
" do_resume ()\n"
"\telse do_test_eof ()\n";
}
else {
out <<
" do_resume ()\n";
}
// if ( testEofUsed )
out << "and do_test_eof () =\n";
if ( redFsm->anyEofTrans() || redFsm->anyEofActions() ) {
out <<
" if " << P() << " = " << vEOF() << " then\n"
" begin try\n";
if ( redFsm->anyEofTrans() ) {
out <<
" if " << AT( ET(), vCS() ) << " > 0 then\n"
" begin\n"
" state.trans <- " << CAST(transType) << "(" << AT( ET(), vCS() ) << " - 1);\n"
" raise Goto_eof_trans;\n"
" end;\n";
}
if ( redFsm->anyEofActions() ) {
out <<
" let __acts = ref " << AT( EA(), vCS() ) << " in\n"
" let __nacts = ref " << AT( A(), "!__acts" ) << " in\n"
" incr __acts;\n"
" while !__nacts > 0 do\n"
" decr __nacts;\n"
" begin match " << AT( A(), POST_INCR("__acts.contents") ) << " with\n";
EOF_ACTION_SWITCH();
SWITCH_DEFAULT() <<
" end;\n"
" done\n";
}
out <<
" with Goto_again -> do_again ()\n"
" | Goto_eof_trans -> do_eof_trans () end\n"
"\n";
}
else
{
out << "\t()\n";
}
if ( outLabelUsed )
out << " and do_out () = ()\n";
out << "\tin do_start ()\n";
out << " end;\n";
}
void OCamlFlatCodeGen::initVarTypes()
{
slenType = ARRAY_TYPE(MAX(redFsm->maxSpan, redFsm->maxCondSpan));
transType = ARRAY_TYPE(redFsm->maxIndex+1);
indsType = ARRAY_TYPE(redFsm->maxFlatIndexOffset);
condsType = ARRAY_TYPE(redFsm->maxCondIndexOffset);
}
