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/*
* Copyright 2006-2012 Adrian Thurston <thurston@complang.org>
*/
#include <string.h>
#include <assert.h>
#include "fsmgraph.h"
#include <iostream>
using namespace std;
/* Insert a transition into an inlist. The head must be supplied. */
void FsmGraph::attachToInList( FsmState *from, FsmState *to,
FsmTrans *&head, FsmTrans *trans )
{
trans->ilnext = head;
trans->ilprev = 0;
/* If in trans list is not empty, set the head->prev to trans. */
if ( head != 0 )
head->ilprev = trans;
/* Now insert ourselves at the front of the list. */
head = trans;
/* Keep track of foreign transitions for from and to. */
if ( from != to ) {
if ( misfitAccounting ) {
/* If the number of foreign in transitions is about to go up to 1 then
* move it from the misfit list to the main list. */
if ( to->foreignInTrans == 0 )
stateList.append( misfitList.detach( to ) );
}
to->foreignInTrans += 1;
}
};
/* Detach a transition from an inlist. The head of the inlist must be supplied. */
void FsmGraph::detachFromInList( FsmState *from, FsmState *to,
FsmTrans *&head, FsmTrans *trans )
{
/* Detach in the inTransList. */
if ( trans->ilprev == 0 )
head = trans->ilnext;
else
trans->ilprev->ilnext = trans->ilnext;
if ( trans->ilnext != 0 )
trans->ilnext->ilprev = trans->ilprev;
/* Keep track of foreign transitions for from and to. */
if ( from != to ) {
to->foreignInTrans -= 1;
if ( misfitAccounting ) {
/* If the number of foreign in transitions goes down to 0 then move it
* from the main list to the misfit list. */
if ( to->foreignInTrans == 0 )
misfitList.append( stateList.detach( to ) );
}
}
}
/* Attach states on the default transition, range list or on out/in list key.
* First makes a new transition. If there is already a transition out from
* fromState on the default, then will assertion fail. */
FsmTrans *FsmGraph::attachNewTrans( FsmState *from, FsmState *to, Key lowKey, Key highKey )
{
/* Make the new transition. */
FsmTrans *retVal = new FsmTrans();
/* The transition is now attached. Remember the parties involved. */
retVal->fromState = from;
retVal->toState = to;
/* Make the entry in the out list for the transitions. */
from->outList.append( retVal );
/* Set the the keys of the new trans. */
retVal->lowKey = lowKey;
retVal->highKey = highKey;
/* Attach using inList as the head pointer. */
if ( to != 0 )
attachToInList( from, to, to->inList.head, retVal );
return retVal;
}
/* Attach for range lists or for the default transition. This attach should
* be used when a transition already is allocated and must be attached to a
* target state. Does not handle adding the transition into the out list. */
void FsmGraph::attachTrans( FsmState *from, FsmState *to, FsmTrans *trans )
{
assert( trans->fromState == 0 && trans->toState == 0 );
trans->fromState = from;
trans->toState = to;
if ( to != 0 ) {
/* Attach using the inList pointer as the head pointer. */
attachToInList( from, to, to->inList.head, trans );
}
}
/* Redirect a transition away from error and towards some state. This is just
* like attachTrans except it requires fromState to be set and does not touch
* it. */
void FsmGraph::redirectErrorTrans( FsmState *from, FsmState *to, FsmTrans *trans )
{
assert( trans->fromState != 0 && trans->toState == 0 );
trans->toState = to;
if ( to != 0 ) {
/* Attach using the inList pointer as the head pointer. */
attachToInList( from, to, to->inList.head, trans );
}
}
/* Detach for out/in lists or for default transition. */
void FsmGraph::detachTrans( FsmState *from, FsmState *to, FsmTrans *trans )
{
assert( trans->fromState == from && trans->toState == to );
trans->fromState = 0;
trans->toState = 0;
if ( to != 0 ) {
/* Detach using to's inList pointer as the head. */
detachFromInList( from, to, to->inList.head, trans );
}
}
/* Detach a state from the graph. Detaches and deletes transitions in and out
* of the state. Empties inList and outList. Removes the state from the final
* state set. A detached state becomes useless and should be deleted. */
void FsmGraph::detachState( FsmState *state )
{
/* Detach the in transitions from the inList list of transitions. */
while ( state->inList.head != 0 ) {
/* Get pointers to the trans and the state. */
FsmTrans *trans = state->inList.head;
FsmState *fromState = trans->fromState;
/* Detach the transitions from the source state. */
detachTrans( fromState, state, trans );
/* Ok to delete the transition. */
fromState->outList.detach( trans );
delete trans;
}
/* Remove the entry points in on the machine. */
while ( state->entryIds.length() > 0 )
unsetEntry( state->entryIds[0], state );
/* Detach out range transitions. */
for ( TransList::Iter trans = state->outList; trans.lte(); ) {
TransList::Iter next = trans.next();
detachTrans( state, trans->toState, trans );
delete trans;
trans = next;
}
/* Delete all of the out range pointers. */
state->outList.abandon();
/* Unset final stateness before detaching from graph. */
if ( state->stateBits & SB_ISFINAL )
finStateSet.remove( state );
}
/* Duplicate a transition. Makes a new transition that is attached to the same
* dest as srcTrans. The new transition has functions and priority taken from
* srcTrans. Used for merging a transition in to a free spot. The trans can
* just be dropped in. It does not conflict with an existing trans and need
* not be crossed. Returns the new transition. */
FsmTrans *FsmGraph::dupTrans( FsmState *from, FsmTrans *srcTrans )
{
/* Make a new transition. */
FsmTrans *newTrans = new FsmTrans();
/* We can attach the transition, one does not exist. */
attachTrans( from, srcTrans->toState, newTrans );
/* Call the user callback to add in the original source transition. */
addInTrans( newTrans, srcTrans );
return newTrans;
}
/* In crossing, src trans and dest trans both go to existing states. Make one
* state from the sets of states that src and dest trans go to. */
FsmTrans *FsmGraph::fsmAttachStates( MergeData &md, FsmState *from,
FsmTrans *destTrans, FsmTrans *srcTrans )
{
/* The priorities are equal. We must merge the transitions. Does the
* existing trans go to the state we are to attach to? ie, are we to
* simply double up the transition? */
FsmState *toState = srcTrans->toState;
FsmState *existingState = destTrans->toState;
if ( existingState == toState ) {
/* The transition is a double up to the same state. Copy the src
* trans into itself. We don't need to merge in the from out trans
* data, that was done already. */
addInTrans( destTrans, srcTrans );
}
else {
/* The trans is not a double up. Dest trans cannot be the same as src
* trans. Set up the state set. */
StateSet stateSet;
/* We go to all the states the existing trans goes to, plus... */
if ( existingState->stateDictEl == 0 )
stateSet.insert( existingState );
else
stateSet.insert( existingState->stateDictEl->stateSet );
/* ... all the states that we have been told to go to. */
if ( toState->stateDictEl == 0 )
stateSet.insert( toState );
else
stateSet.insert( toState->stateDictEl->stateSet );
/* Look for the state. If it is not there already, make it. */
StateDictEl *lastFound;
if ( md.stateDict.insert( stateSet, &lastFound ) ) {
/* Make a new state representing the combination of states in
* stateSet. It gets added to the fill list. This means that we
* need to fill in it's transitions sometime in the future. We
* don't do that now (ie, do not recurse). */
FsmState *combinState = addState();
/* Link up the dict element and the state. */
lastFound->targState = combinState;
combinState->stateDictEl = lastFound;
/* Add to the fill list. */
md.fillListAppend( combinState );
}
/* Get the state insertted/deleted. */
FsmState *targ = lastFound->targState;
/* Detach the state from existing state. */
detachTrans( from, existingState, destTrans );
/* Re-attach to the new target. */
attachTrans( from, targ, destTrans );
/* Add in src trans to the existing transition that we redirected to
* the new state. We don't need to merge in the from out trans data,
* that was done already. */
addInTrans( destTrans, srcTrans );
}
return destTrans;
}
/* Two transitions are to be crossed, handle the possibility of either going
* to the error state. */
FsmTrans *FsmGraph::mergeTrans( MergeData &md, FsmState *from,
FsmTrans *destTrans, FsmTrans *srcTrans )
{
FsmTrans *retTrans = 0;
if ( destTrans->toState == 0 && srcTrans->toState == 0 ) {
/* Error added into error. */
addInTrans( destTrans, srcTrans );
retTrans = destTrans;
}
else if ( destTrans->toState == 0 && srcTrans->toState != 0 ) {
/* Non error added into error we need to detach and reattach, */
detachTrans( from, destTrans->toState, destTrans );
attachTrans( from, srcTrans->toState, destTrans );
addInTrans( destTrans, srcTrans );
retTrans = destTrans;
}
else if ( srcTrans->toState == 0 ) {
/* Dest goes somewhere but src doesn't, just add it it in. */
addInTrans( destTrans, srcTrans );
retTrans = destTrans;
}
else {
/* Both go somewhere, run the actual cross. */
retTrans = fsmAttachStates( md, from, destTrans, srcTrans );
}
return retTrans;
}
/* Find the trans with the higher priority. If src is lower priority then dest then
* src is ignored. If src is higher priority than dest, then src overwrites dest. If
* the priorities are equal, then they are merged. */
FsmTrans *FsmGraph::crossTransitions( MergeData &md, FsmState *from,
FsmTrans *destTrans, FsmTrans *srcTrans )
{
FsmTrans *retTrans;
/* Compare the priority of the dest and src transitions. */
int compareRes = comparePrior( destTrans->priorTable, srcTrans->priorTable );
if ( compareRes < 0 ) {
/* Src trans has a higher priority than dest, src overwrites dest.
* Detach dest and return a copy of src. */
detachTrans( from, destTrans->toState, destTrans );
retTrans = dupTrans( from, srcTrans );
}
else if ( compareRes > 0 ) {
/* The dest trans has a higher priority, use dest. */
retTrans = destTrans;
}
else {
/* Src trans and dest trans have the same priority, they must be merged. */
retTrans = mergeTrans( md, from, destTrans, srcTrans );
}
/* Return the transition that resulted from the cross. */
return retTrans;
}
/* Copy the transitions in srcList to the outlist of dest. The srcList should
* not be the outList of dest, otherwise you would be copying the contents of
* srcList into itself as it's iterated: bad news. */
void FsmGraph::outTransCopy( MergeData &md, FsmState *dest, FsmTrans *srcList )
{
/* The destination list. */
TransList destList;
/* Set up an iterator to stop at breaks. */
PairIter<FsmTrans> outPair( dest->outList.head, srcList );
for ( ; !outPair.end(); outPair++ ) {
switch ( outPair.userState ) {
case RangeInS1: {
/* The pair iter is the authority on the keys. It may have needed
* to break the dest range. */
FsmTrans *destTrans = outPair.s1Tel.trans;
destTrans->lowKey = outPair.s1Tel.lowKey;
destTrans->highKey = outPair.s1Tel.highKey;
destList.append( destTrans );
break;
}
case RangeInS2: {
/* Src range may get crossed with dest's default transition. */
FsmTrans *newTrans = dupTrans( dest, outPair.s2Tel.trans );
/* Set up the transition's keys and append to the dest list. */
newTrans->lowKey = outPair.s2Tel.lowKey;
newTrans->highKey = outPair.s2Tel.highKey;
destList.append( newTrans );
break;
}
case RangeOverlap: {
/* Exact overlap, cross them. */
FsmTrans *newTrans = crossTransitions( md, dest,
outPair.s1Tel.trans, outPair.s2Tel.trans );
/* Set up the transition's keys and append to the dest list. */
newTrans->lowKey = outPair.s1Tel.lowKey;
newTrans->highKey = outPair.s1Tel.highKey;
destList.append( newTrans );
break;
}
case BreakS1: {
/* Since we are always writing to the dest trans, the dest needs
* to be copied when it is broken. The copy goes into the first
* half of the break to "break it off". */
outPair.s1Tel.trans = dupTrans( dest, outPair.s1Tel.trans );
break;
}
case BreakS2:
break;
}
}
/* Abandon the old outList and transfer destList into it. */
dest->outList.transfer( destList );
}
/* Move all the transitions that go into src so that they go into dest. */
void FsmGraph::inTransMove( FsmState *dest, FsmState *src )
{
/* Do not try to move in trans to and from the same state. */
assert( dest != src );
/* If src is the start state, dest becomes the start state. */
if ( src == startState ) {
unsetStartState();
setStartState( dest );
}
/* For each entry point into, create an entry point into dest, when the
* state is detached, the entry points to src will be removed. */
for ( EntryIdSet::Iter enId = src->entryIds; enId.lte(); enId++ )
changeEntry( *enId, dest, src );
/* Move the transitions in inList. */
while ( src->inList.head != 0 ) {
/* Get trans and from state. */
FsmTrans *trans = src->inList.head;
FsmState *fromState = trans->fromState;
/* Detach from src, reattach to dest. */
detachTrans( fromState, src, trans );
attachTrans( fromState, dest, trans );
}
}
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