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/*
* Copyright (C) 2008 Steve Ratcliffe
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*
* 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.
*
*
* Author: Steve Ratcliffe
* Create date: 08-Nov-2008
*/
package uk.me.parabola.mkgmap.osmstyle;
import java.util.Arrays;
import java.util.BitSet;
import java.util.Collection;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Iterator;
import java.util.Map.Entry;
import java.util.Set;
import uk.me.parabola.log.Logger;
import uk.me.parabola.mkgmap.osmstyle.eval.AbstractBinaryOp;
import uk.me.parabola.mkgmap.osmstyle.eval.AbstractOp;
import uk.me.parabola.mkgmap.osmstyle.eval.LinkedBinaryOp;
import uk.me.parabola.mkgmap.osmstyle.eval.LinkedOp;
import uk.me.parabola.mkgmap.osmstyle.eval.Op;
import uk.me.parabola.mkgmap.reader.osm.Element;
import uk.me.parabola.mkgmap.reader.osm.Rule;
import uk.me.parabola.mkgmap.reader.osm.TypeResult;
import uk.me.parabola.mkgmap.reader.osm.WatchableTypeResult;
/**
* A list of rules and the logic to select the correct one.
*
* A separate {@link RuleIndex} class is used to speed access to the rule list.
*
* @author Steve Ratcliffe
*/
public class RuleSet
implements Rule,
Iterable<Rule
> {
private static final Logger log =
Logger.
getLogger(RuleSet.
class);
private Rule
[] rules
;
private Rule finalizeRule
;
// identifies cached values
int cacheId
;
boolean compiled =
false;
private RuleIndex index =
new RuleIndex
();
private final Set<String> usedTags =
new HashSet<String>();
@
Override
public void resolveType
(Element el, TypeResult result
) {
cacheId = resolveType
(cacheId, el, result
);
}
/**
* Resolve the type for this element by running the rules in order.
*
* This is a very performance critical part of the style system as parts
* of the code are run for every tag in the input file.
*
* @param el The element as read from an OSM xml file in 'tag' format.
* @param result A GType describing the Garmin type of the first rule that
* matches is returned here. If continue types are used then more than
* one type may be saved here. If there are no matches then nothing will
* be saved.
*/
public int resolveType
(int cacheId,
Element el, TypeResult result
) {
WatchableTypeResult a =
new WatchableTypeResult
(result
);
if (!compiled || cacheId ==
Integer.
MAX_VALUE)
compile
();
// new element, invalidate all caches
cacheId++
;
// Get all the rules that could match from the index.
BitSet candidates =
new BitSet();
for (Entry
<Short,
String> tagEntry : el.
getFastTagEntryIterator()) {
BitSet rules = index.
getRulesForTag(tagEntry.
getKey(), tagEntry.
getValue());
if (rules
!=
null && !rules.
isEmpty() )
candidates.
or(rules
);
}
for (int i = candidates.
nextSetBit(0); i
>=
0; i = candidates.
nextSetBit(i +
1)) {
a.
reset();
cacheId = rules
[i
].
resolveType(cacheId, el, a
);
if (a.
isResolved())
return cacheId
;
}
return cacheId
;
}
public Iterator<Rule
> iterator
() {
if (rules ==
null)
prepare
();
return Arrays.
asList(rules
).
iterator();
}
/**
* Add a rule to this rule set.
* @param keystring The string form of the first term of the rule. It will
* be A=B or A=*. (In the future we may allow other forms).
* @param rule The actual rule.
* @param changeableTags The tags that may be changed by the rule. This
* will be either a plain tag name A, or with a value A=B.
*/
public void add
(String keystring, Rule rule,
Set<String> changeableTags
) {
compiled =
false;
index.
addRuleToIndex(new RuleDetails
(keystring, rule, changeableTags
));
}
/**
* Add all rules from the given rule set to this one.
* @param rs The other rule set.
*/
public void addAll
(RuleSet rs
) {
for (RuleDetails rd : rs.
index.
getRuleDetails())
add
(rd.
getKeystring(), rd.
getRule(), rd.
getChangingTags());
}
/**
* Format the rule set. Warning: this doesn't produce a valid input
* rule file.
*/
public String toString
() {
StringBuilder sb =
new StringBuilder();
for (Rule rule : rules
) {
sb.
append(rule.
toString());
}
return sb.
toString();
}
/**
* Merge the two rulesets together so that they appear to be one.
* @param rs The other rule set, it will have lower priority, that is the
* rules will be tried after the rules of this ruleset.
*/
public void merge
(RuleSet rs
) {
// We have to basically rebuild the index and reset the rule list.
RuleIndex newIndex =
new RuleIndex
();
for (RuleDetails rd : index.
getRuleDetails())
newIndex.
addRuleToIndex(rd
);
for (RuleDetails rd : rs.
index.
getRuleDetails())
newIndex.
addRuleToIndex(rd
);
index = newIndex
;
rules = newIndex.
getRules();
//System.out.println("Merging used tags: "
// + getUsedTags().toString()
// + " + "
// + rs.getUsedTags());
addUsedTags
(rs.
usedTags);
//System.out.println("Result: " + getUsedTags().toString());
compiled =
false;
}
/**
* Prepare this rule set for use. The index is built and and the rules
* are saved to an array for fast access.
*/
public void prepare
() {
index.
prepare();
rules = index.
getRules();
compile
();
}
public Set<String> getUsedTags
() {
return usedTags
;
}
public void addUsedTags
(Collection<String> usedTags
) {
this.
usedTags.
addAll(usedTags
);
}
/**
* Compile the rules and reset caches. Detect common sub-expressions and
* make sure that all rules use the same instance of these common
* sub-expressions.
*/
private void compile
(){
HashMap<String, Op
> tests =
new HashMap<String, Op
>();
for (Rule rule:rules
){
Op op
;
if (rule
instanceof ExpressionRule
)
op =
((ExpressionRule
)rule
).
getOp();
else if (rule
instanceof ActionRule
)
op =
((ActionRule
) rule
).
getOp();
else {
log.
error("unexpected rule instance");
continue;
}
if (op
instanceof AbstractBinaryOp
){
AbstractBinaryOp binOp =
(AbstractBinaryOp
) op
;
binOp.
setFirst(compileOp
(tests, binOp.
getFirst()));
binOp.
setSecond(compileOp
(tests, binOp.
getSecond()));
op = compileOp
(tests, binOp
);
} else if (op
instanceof AbstractOp
){
op = compileOp
(tests, op
);
} else if (op
instanceof LinkedBinaryOp
){
((LinkedBinaryOp
) op
).
setFirst(compileOp
(tests,
((LinkedBinaryOp
) op
).
getFirst()));
((LinkedBinaryOp
) op
).
setSecond(compileOp
(tests,
((LinkedBinaryOp
) op
).
getSecond()));
} else if (op
instanceof LinkedOp
) {
Op wrappedOp = compileOp
(tests,
((LinkedOp
) op
).
getFirst());
op.
setFirst(wrappedOp
);
} else {
log.
error("unexpected op instance");
continue;
}
if (rule
instanceof ExpressionRule
)
((ExpressionRule
)rule
).
setOp(op
);
else if (rule
instanceof ActionRule
)
((ActionRule
) rule
).
setOp(op
);
else {
log.
error("unexpected rule instance");
continue;
}
}
cacheId =
0;
compiled =
true;
}
private Op compileOp
(HashMap<String, Op
> tests, Op op
){
if (op
instanceof AbstractBinaryOp
){
AbstractBinaryOp binOp =
(AbstractBinaryOp
) op
;
binOp.
setFirst(compileOp
(tests, binOp.
getFirst()));
binOp.
setSecond(compileOp
(tests, binOp.
getSecond()));
}
if (op
instanceof LinkedOp
){
// LinkedOp is referenced by other OPs, don't replace it
return op
;
}
String test = op.
toString();
Op commonOp = tests.
get(test
);
if (commonOp ==
null){
if (op
instanceof AbstractOp
)
((AbstractOp
)op
).
resetCache();
tests.
put(test, op
);
commonOp = op
;
}
return commonOp
;
}
public void setFinalizeRule
(Rule finalizeRule
) {
if (rules ==
null) {
// this method must be called after prepare() is called so
// that we have rules to which the finalize rules can be applied
throw new IllegalStateException("First call prepare() before setting the finalize rules");
}
for (Rule rule : rules
)
rule.
setFinalizeRule(finalizeRule
);
compiled =
false;
this.
finalizeRule = finalizeRule
;
}
@
Override
public void printStats
(String header
) {
if (rules ==
null)
return;
for (Rule rule : rules
){
rule.
printStats(header
);
}
if (finalizeRule
!=
null)
finalizeRule.
printStats(header
);
}
}