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/*
* Copyright 2007-2014 Adrian Thurston <thurston@complang.org>
*/
/* This file is part of Colm.
*
* Colm 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.
*
* Colm 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 Colm; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include <colm/tree.h>
#include <colm/bytecode.h>
#include <colm/program.h>
#include <assert.h>
#include "internal.h"
#define true 1
#define false 0
void colm_init_list_iter( GenericIter *listIter, Tree **stackRoot,
long argSize, long rootSize, const Ref *rootRef, int genericId )
{
listIter->type = IT_Tree;
listIter->rootRef = *rootRef;
listIter->stackRoot = stackRoot;
listIter->yieldSize = 0;
listIter->rootSize = rootSize;
listIter->ref.kid = 0;
listIter->ref.next = 0;
listIter->argSize = argSize;
listIter->genericId = genericId;
}
void colm_list_iter_destroy( Program *prg, Tree ***psp, GenericIter *iter )
{
if ( (int)iter->type != 0 ) {
int i;
Tree **sp = *psp;
long curStackSize = vm_ssize() - iter->rootSize;
assert( iter->yieldSize == curStackSize );
vm_popn( iter->yieldSize );
for ( i = 0; i < iter->argSize; i++ )
treeDownref( prg, sp, vm_pop() );
iter->type = 0;
*psp = sp;
}
}
Tree *colm_list_iter_advance( Program *prg, Tree ***psp, GenericIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == (vm_ssize() - iter->rootSize) );
if ( iter->ref.kid == 0 ) {
/* Kid is zero, start from the root. */
List *list = *((List**)iter->rootRef.kid);
iter->ref.kid = (Kid*)list->head;
iter->ref.next = 0;
//= iter->rootRef;
//iter
//iterFind( prg, psp, iter, true );
}
else {
/* Have a previous item, continue searching from there. */
//iterFind( prg, psp, iter, false );
ListEl *listEl = (ListEl*)iter->ref.kid;
listEl = listEl->list_next;
iter->ref.kid = (Kid*)listEl;
iter->ref.next = 0;
}
sp = *psp;
iter->yieldSize = vm_ssize() - iter->rootSize;
return (iter->ref.kid ? prg->trueVal : prg->falseVal );
}
Tree *colm_map_iter_advance( Program *prg, Tree ***psp, GenericIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == (vm_ssize() - iter->rootSize) );
if ( iter->ref.kid == 0 ) {
/* Kid is zero, start from the root. */
Map *map = *((Map**)iter->rootRef.kid);
iter->ref.kid = (Kid*)map->head;
iter->ref.next = 0;
//= iter->rootRef;
//iter
//iterFind( prg, psp, iter, true );
}
else {
/* Have a previous item, continue searching from there. */
//iterFind( prg, psp, iter, false );
MapEl *mapEl = (MapEl*)iter->ref.kid;
mapEl = mapEl->next;
iter->ref.kid = (Kid*)mapEl;
iter->ref.next = 0;
}
sp = *psp;
iter->yieldSize = vm_ssize() - iter->rootSize;
return (iter->ref.kid ? prg->trueVal : prg->falseVal );
}
Tree *colm_list_iter_deref_cur( Program *prg, GenericIter *iter )
{
GenericInfo *gi = &prg->rtd->genericInfo[iter->genericId];
ListEl *el = (ListEl*)iter->ref.kid;
struct colm_struct *s = el != 0 ?
colm_struct_container( el, gi->elOffset ) : 0;
return (Tree*)s;
}
Value colm_viter_deref_cur( Program *prg, GenericIter *iter )
{
GenericInfo *gi = &prg->rtd->genericInfo[iter->genericId];
ListEl *el = (ListEl*)iter->ref.kid;
struct colm_struct *s = el != 0 ?
colm_struct_container( el, gi->elOffset ) : 0;
Value value = colm_struct_get_field( s, Value, 0 );
if ( gi->valueType == TYPE_TREE )
treeUpref( (Tree*)value );
return value;
}
void initTreeIter( TreeIter *treeIter, Tree **stackRoot,
long argSize, long rootSize,
const Ref *rootRef, int searchId )
{
treeIter->type = IT_Tree;
treeIter->rootRef = *rootRef;
treeIter->searchId = searchId;
treeIter->stackRoot = stackRoot;
treeIter->yieldSize = 0;
treeIter->rootSize = rootSize;
treeIter->ref.kid = 0;
treeIter->ref.next = 0;
treeIter->argSize = argSize;
}
void initRevTreeIter( RevTreeIter *revTriter, Tree **stackRoot,
long argSize, long rootSize,
const Ref *rootRef, int searchId, int children )
{
revTriter->type = IT_RevTree;
revTriter->rootRef = *rootRef;
revTriter->searchId = searchId;
revTriter->stackRoot = stackRoot;
revTriter->yieldSize = children;
revTriter->rootSize = rootSize;
revTriter->kidAtYield = 0;
revTriter->children = children;
revTriter->ref.kid = 0;
revTriter->ref.next = 0;
revTriter->argSize = argSize;
}
void initUserIter( UserIter *userIter, Tree **stackRoot, long rootSize,
long argSize, long searchId )
{
userIter->type = IT_User;
userIter->stackRoot = stackRoot;
userIter->argSize = argSize;
userIter->yieldSize = 0;
userIter->rootSize = rootSize;
userIter->resume = 0;
userIter->frame = 0;
userIter->searchId = searchId;
userIter->ref.kid = 0;
userIter->ref.next = 0;
}
UserIter *uiterCreate( Program *prg, Tree ***psp, FunctionInfo *fi, long searchId )
{
Tree **sp = *psp;
vm_pushn( sizeof(UserIter) / sizeof(Word) );
void *mem = vm_ptop();
UserIter *uiter = mem;
Tree **stackRoot = vm_ptop();
long rootSize = vm_ssize();
initUserIter( uiter, stackRoot, rootSize, fi->argSize, searchId );
*psp = sp;
return uiter;
}
void uiterInit( Program *prg, Tree **sp, UserIter *uiter,
FunctionInfo *fi, int revertOn )
{
/* Set up the first yeild so when we resume it starts at the beginning. */
uiter->ref.kid = 0;
uiter->yieldSize = vm_ssize() - uiter->rootSize;
uiter->frame = &uiter->stackRoot[-IFR_AA];
if ( revertOn )
uiter->resume = prg->rtd->frameInfo[fi->frameId].codeWV;
else
uiter->resume = prg->rtd->frameInfo[fi->frameId].codeWC;
}
void treeIterDestroy( Program *prg, Tree ***psp, TreeIter *iter )
{
if ( (int)iter->type != 0 ) {
int i;
Tree **sp = *psp;
long curStackSize = vm_ssize() - iter->rootSize;
assert( iter->yieldSize == curStackSize );
vm_popn( iter->yieldSize );
for ( i = 0; i < iter->argSize; i++ )
treeDownref( prg, sp, vm_pop() );
iter->type = 0;
*psp = sp;
}
}
void revTreeIterDestroy( struct colm_program *prg, Tree ***psp, RevTreeIter *riter )
{
if ( (int)riter->type != 0 ) {
int i;
Tree **sp = *psp;
long curStackSize = vm_ssize() - riter->rootSize;
assert( riter->yieldSize == curStackSize );
vm_popn( riter->yieldSize );
for ( i = 0; i < riter->argSize; i++ )
treeDownref( prg, sp, vm_pop() );
riter->type = 0;
*psp = sp;
}
}
void userIterDestroy( Program *prg, Tree ***psp, UserIter *uiter )
{
if ( uiter != 0 && (int)uiter->type != 0 ) {
Tree **sp = *psp;
/* We should always be coming from a yield. The current stack size will be
* nonzero and the stack size in the iterator will be correct. */
long curStackSize = vm_ssize() - uiter->rootSize;
assert( uiter->yieldSize == curStackSize );
long argSize = uiter->argSize;
vm_popn( uiter->yieldSize );
vm_popn( sizeof(UserIter) / sizeof(Word) );
vm_popn( argSize );
uiter->type = 0;
*psp = sp;
}
}
void userIterDestroy2( Program *prg, Tree ***psp, UserIter *uiter )
{
if ( uiter != 0 && (int)uiter->type != 0 ) {
Tree **sp = *psp;
/* We should always be coming from a yield. The current stack size will be
* nonzero and the stack size in the iterator will be correct. */
long curStackSize = vm_ssize() - uiter->rootSize;
assert( uiter->yieldSize == curStackSize );
long argSize = uiter->argSize;
vm_popn( uiter->yieldSize );
vm_popn( sizeof(UserIter) / sizeof(Word) );
vm_popn( argSize );
vm_pop();
uiter->type = 0;
*psp = sp;
}
}
Tree *treeIterDerefCur( TreeIter *iter )
{
return iter->ref.kid == 0 ? 0 : iter->ref.kid->tree;
}
void setTriterCur( Program *prg, TreeIter *iter, Tree *tree )
{
iter->ref.kid->tree = tree;
}
void setUiterCur( Program *prg, UserIter *uiter, Tree *tree )
{
uiter->ref.kid->tree = tree;
}
void splitIterCur( Program *prg, Tree ***psp, TreeIter *iter )
{
if ( iter->ref.kid == 0 )
return;
splitRef( prg, psp, &iter->ref );
}
void iterFind( Program *prg, Tree ***psp, TreeIter *iter, int tryFirst )
{
int anyTree = iter->searchId == prg->rtd->anyId;
Tree **top = iter->stackRoot;
Kid *child;
Tree **sp = *psp;
rec_call:
if ( tryFirst && ( iter->ref.kid->tree->id == iter->searchId || anyTree ) ) {
*psp = sp;
return;
}
else {
child = treeChild( prg, iter->ref.kid->tree );
if ( child != 0 ) {
vm_contiguous( 2 );
vm_push( (SW) iter->ref.next );
vm_push( (SW) iter->ref.kid );
iter->ref.kid = child;
iter->ref.next = (Ref*)vm_ptop();
while ( iter->ref.kid != 0 ) {
tryFirst = true;
goto rec_call;
rec_return:
iter->ref.kid = iter->ref.kid->next;
}
iter->ref.kid = (Kid*)vm_pop();
iter->ref.next = (Ref*)vm_pop();
}
}
if ( top != vm_ptop() )
goto rec_return;
iter->ref.kid = 0;
*psp = sp;
}
Tree *treeIterAdvance( Program *prg, Tree ***psp, TreeIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == (vm_ssize() - iter->rootSize) );
if ( iter->ref.kid == 0 ) {
/* Kid is zero, start from the root. */
iter->ref = iter->rootRef;
iterFind( prg, psp, iter, true );
}
else {
/* Have a previous item, continue searching from there. */
iterFind( prg, psp, iter, false );
}
sp = *psp;
iter->yieldSize = vm_ssize() - iter->rootSize;
return (iter->ref.kid ? prg->trueVal : prg->falseVal );
}
Tree *treeIterNextChild( Program *prg, Tree ***psp, TreeIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == (vm_ssize() - iter->rootSize) );
Kid *kid = 0;
if ( iter->ref.kid == 0 ) {
/* Kid is zero, start from the first child. */
Kid *child = treeChild( prg, iter->rootRef.kid->tree );
if ( child == 0 )
iter->ref.next = 0;
else {
/* Make a reference to the root. */
vm_contiguous( 2 );
vm_push( (SW) iter->rootRef.next );
vm_push( (SW) iter->rootRef.kid );
iter->ref.next = (Ref*)vm_ptop();
kid = child;
}
}
else {
/* Start at next. */
kid = iter->ref.kid->next;
}
if ( iter->searchId != prg->rtd->anyId ) {
/* Have a previous item, go to the next sibling. */
while ( kid != 0 && kid->tree->id != iter->searchId )
kid = kid->next;
}
iter->ref.kid = kid;
iter->yieldSize = vm_ssize() - iter->rootSize;
*psp = sp;
return ( iter->ref.kid ? prg->trueVal : prg->falseVal );
}
Tree *treeRevIterPrevChild( Program *prg, Tree ***psp, RevTreeIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == ( vm_ssize() - iter->rootSize ) );
if ( iter->kidAtYield != iter->ref.kid ) {
/* Need to reload the kids. */
vm_popn( iter->children );
int c;
Kid *kid = treeChild( prg, iter->rootRef.kid->tree );
for ( c = 0; c < iter->children; c++ ) {
vm_push( (SW)kid );
kid = kid->next;
}
}
if ( iter->ref.kid != 0 ) {
vm_pop_ignore();
iter->children -= 1;
}
if ( iter->searchId != prg->rtd->anyId ) {
/* Have a previous item, go to the next sibling. */
while ( iter->children > 0 && ((Kid*)(vm_top()))->tree->id != iter->searchId ) {
iter->children -= 1;
vm_pop_ignore();
}
}
if ( iter->children == 0 ) {
iter->ref.next = 0;
iter->ref.kid = 0;
}
else {
iter->ref.next = &iter->rootRef;
iter->ref.kid = (Kid*)vm_top();
}
/* We will use this to detect a split above the iterated tree. */
iter->kidAtYield = iter->ref.kid;
iter->yieldSize = vm_ssize() - iter->rootSize;
*psp = sp;
return (iter->ref.kid ? prg->trueVal : prg->falseVal );
}
void iterFindRepeat( Program *prg, Tree ***psp, TreeIter *iter, int tryFirst )
{
Tree **sp = *psp;
int anyTree = iter->searchId == prg->rtd->anyId;
Tree **top = iter->stackRoot;
Kid *child;
rec_call:
if ( tryFirst && ( iter->ref.kid->tree->id == iter->searchId || anyTree ) ) {
*psp = sp;
return;
}
else {
/* The repeat iterator is just like the normal top-down-left-right,
* execept it only goes into the children of a node if the node is the
* root of the iteration, or if does not have any neighbours to the
* right. */
if ( top == vm_ptop() || iter->ref.kid->next == 0 ) {
child = treeChild( prg, iter->ref.kid->tree );
if ( child != 0 ) {
vm_contiguous( 2 );
vm_push( (SW) iter->ref.next );
vm_push( (SW) iter->ref.kid );
iter->ref.kid = child;
iter->ref.next = (Ref*)vm_ptop();
while ( iter->ref.kid != 0 ) {
tryFirst = true;
goto rec_call;
rec_return:
iter->ref.kid = iter->ref.kid->next;
}
iter->ref.kid = (Kid*)vm_pop();
iter->ref.next = (Ref*)vm_pop();
}
}
}
if ( top != vm_ptop() )
goto rec_return;
iter->ref.kid = 0;
*psp = sp;
}
Tree *treeIterNextRepeat( Program *prg, Tree ***psp, TreeIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == ( vm_ssize() - iter->rootSize ) );
if ( iter->ref.kid == 0 ) {
/* Kid is zero, start from the root. */
iter->ref = iter->rootRef;
iterFindRepeat( prg, psp, iter, true );
}
else {
/* Have a previous item, continue searching from there. */
iterFindRepeat( prg, psp, iter, false );
}
sp = *psp;
iter->yieldSize = vm_ssize() - iter->rootSize;
return (iter->ref.kid ? prg->trueVal : prg->falseVal );
}
void iterFindRevRepeat( Program *prg, Tree ***psp, TreeIter *iter, int tryFirst )
{
Tree **sp = *psp;
int anyTree = iter->searchId == prg->rtd->anyId;
Tree **top = iter->stackRoot;
Kid *child;
if ( tryFirst ) {
while ( true ) {
if ( top == vm_ptop() || iter->ref.kid->next == 0 ) {
child = treeChild( prg, iter->ref.kid->tree );
if ( child == 0 )
break;
vm_contiguous( 2 );
vm_push( (SW) iter->ref.next );
vm_push( (SW) iter->ref.kid );
iter->ref.kid = child;
iter->ref.next = (Ref*)vm_ptop();
}
else {
/* Not the top and not there is a next, go over to it. */
iter->ref.kid = iter->ref.kid->next;
}
}
goto first;
}
while ( true ) {
if ( top == vm_ptop() ) {
iter->ref.kid = 0;
return;
}
if ( iter->ref.kid->next == 0 ) {
/* Go up one and then down. Remember we can't use iter->ref.next
* because the chain may have been split, setting it null (to
* prevent repeated walks up). */
Ref *ref = (Ref*)vm_ptop();
iter->ref.kid = treeChild( prg, ref->kid->tree );
}
else {
iter->ref.kid = (Kid*)vm_pop();
iter->ref.next = (Ref*)vm_pop();
}
first:
if ( iter->ref.kid->tree->id == iter->searchId || anyTree ) {
*psp = sp;
return;
}
}
*psp = sp;
return;
}
Tree *treeIterPrevRepeat( Program *prg, Tree ***psp, TreeIter *iter )
{
Tree **sp = *psp;
assert( iter->yieldSize == (vm_ssize() - iter->rootSize) );
if ( iter->ref.kid == 0 ) {
/* Kid is zero, start from the root. */
iter->ref = iter->rootRef;
iterFindRevRepeat( prg, psp, iter, true );
}
else {
/* Have a previous item, continue searching from there. */
iterFindRevRepeat( prg, psp, iter, false );
}
sp = *psp;
iter->yieldSize = vm_ssize() - iter->rootSize;
return (iter->ref.kid ? prg->trueVal : prg->falseVal );
}
|