Merge remote-tracking branch 'origin/GT-2754-dragonmacher' into Ghidra_9.0.3

This commit is contained in:
ghidravore 2019-04-17 18:35:46 -04:00
commit b520ee2fc4
4 changed files with 143 additions and 13 deletions

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@ -0,0 +1,69 @@
/* ###
* IP: GHIDRA
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package ghidra.app.extension.datatype.finder;
import java.util.List;
import ghidra.app.decompiler.ClangFieldToken;
import ghidra.app.decompiler.ClangLine;
import ghidra.app.services.DataTypeReference;
import ghidra.program.model.data.Composite;
import ghidra.program.model.data.DataType;
/**
* This class represents the use of a field of a {@link Composite} data type <b>where there is
* no variable in the Decompiler</b> for that data type. A normal variable access in the
* Decompiler may look like so:
* <pre>
* Foo f;
* ...
* return f.some_field;
* </pre>
*
* Alternatively, an anonymous variable access would look like this:
* <pre>
* Bar b;
* ...
* return b-><b>foo_array[1].some_field</b>;
* </pre>
*
* In this case, <code><b>foo_array[1]</b></code> is a <code>Foo</code>, whose
* <code><b>some_field</b></code> is
* being accessed anonymously, since there is no variable of <code>Foo</code> declared
* in the current function.
*/
public class AnonymousVariableAccessDR extends DecompilerReference {
protected AnonymousVariableAccessDR(ClangLine line, ClangFieldToken token) {
super(line, token);
}
@Override
public void accumulateMatches(DataType dt, String fieldName, List<DataTypeReference> results) {
ClangFieldToken field = (ClangFieldToken) sourceToken;
DataType fieldDt = field.getDataType();
if (!isEqual(dt, fieldDt)) {
return;
}
if (field.getText().equals(fieldName)) {
results.add(new DataTypeReference(fieldDt, fieldName, getFunction(), getAddress(),
getContext()));
}
}
}

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@ -20,6 +20,8 @@ import java.util.concurrent.atomic.AtomicInteger;
import java.util.function.Consumer;
import java.util.function.Predicate;
import org.apache.commons.collections4.IterableUtils;
import ghidra.app.decompiler.*;
import ghidra.app.decompiler.component.DecompilerUtils;
import ghidra.app.decompiler.parallel.*;
@ -225,13 +227,13 @@ public class DecompilerDataTypeReferenceFinder implements DataTypeReferenceFinde
private DataType dataType;
private String fieldName;
/** Search for Data Type access only--no field usage */
/* Search for Data Type access only--no field usage */
DecompilerDataTypeFinderQCallback(Program program, DataType dataType,
Consumer<DataTypeReference> callback) {
this(program, dataType, null, callback);
}
/** Search for composite field access */
/* Search for composite field access */
DecompilerDataTypeFinderQCallback(Program program, DataType dataType, String fieldName,
Consumer<DataTypeReference> callback) {
@ -336,14 +338,38 @@ public class DecompilerDataTypeReferenceFinder implements DataTypeReferenceFinde
return result;
}
/**
* Uses the given line to find variables (also parameters and return types) and any
* accesses to them in that line. A given variable may be used directly or, as in
* the case with Composite types, may have one of its fields accessed. Each result
* found by this method will be at least a variable access and may also itself have
* field accesses.
*
* <p>Sometimes a line is structured such that there are anonymous variable accesses. This
* is the case where a Composite is being accessed, but the Composite itself is
* not a variable in the current function. See {@link AnonymousVariableAccessDR} for
* more details.
*
* @param line the current line being processed from the Decompiler
* @param results the accumulator into which matches will be placed
*/
private void findVariablesInLine(ClangLine line, List<DecompilerReference> results) {
List<ClangToken> allTokens = line.getAllTokens();
Iterable<ClangToken> filteredTokens = IterableUtils.filteredIterable(allTokens,
token -> {
// Only include desirable tokens (this is really just for easier debugging).
// Update this filter if the loop below ever needs other types of tokens.
return (token instanceof ClangTypeToken) ||
(token instanceof ClangVariableToken) || (token instanceof ClangFieldToken);
});
// gather any casts until we can use them (the type they modify will follow)
List<DecompilerVariable> castsSoFar = new ArrayList<>();
VariableDR declaration = null;
VariableAccessDR access = null;
for (ClangToken token : line.getAllTokens()) {
for (ClangToken token : filteredTokens) {
if (token instanceof ClangTypeToken) {
@ -371,16 +397,15 @@ public class DecompilerDataTypeReferenceFinder implements DataTypeReferenceFinde
//
// Observations:
// 1) 'variableAccess' will be null if we are on a C statement that
// is a declaration (parameter or variable). In this case, 'ref' will
// be an instance of VariableDR.
// 2) 'variableAccess' will be null the first time a variable is used in
// 1) 'access' will be null if we are on a C statement that
// is a declaration (parameter or variable). In this case,
// 'declaration' will be an instance of VariableDR.
// 2) 'access' will be null the first time a variable is used in
// a statement.
// 3) if 'variableAccess' is non-null, but already has a variable assigned,
// 3) if 'access' is non-null, but already has a variable assigned,
// then this means the current ClangVariableToken represents a new
// variable access/usage.
//
if (declaration != null) {
declaration.setVariable((ClangVariableToken) token);
declaration = null;
@ -415,12 +440,32 @@ public class DecompilerDataTypeReferenceFinder implements DataTypeReferenceFinde
}
}
access.addField((ClangFieldToken) token, casts);
ClangFieldToken field = (ClangFieldToken) token;
if (typesDoNotMatch(access, field)) {
// this can happen when a field is used anonymously, such as directly
// after a nested array index operation
results.add(new AnonymousVariableAccessDR(line, field));
continue;
}
access.addField(field, casts);
castsSoFar.clear();
}
}
}
private boolean typesDoNotMatch(VariableAccessDR access, ClangFieldToken field) {
DecompilerVariable variable = access.getVariable();
if (variable == null) {
return false; // should not happen
}
DataType variableDt = variable.getDataType();
DataType fieldDt = field.getDataType();
return !DecompilerReference.isEqual(variableDt, fieldDt);
}
private VariableAccessDR getLastAccess(List<DecompilerReference> variables) {
// for now, assume that the last access will be the last item we added
if (variables.isEmpty()) {

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@ -83,6 +83,10 @@ public abstract class DecompilerReference {
return var.getAddress();
}
public ClangLine getLine() {
return line;
}
protected String getContext() {
String context = getContext(variable);
return context;

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@ -104,7 +104,19 @@ public abstract class DecompilerVariable {
}
Varnode output = op.getOutput();
return output.getHigh().getDataType();
if (output == null) {
// can happen when a variable in volatile memory is used in a write_volatile
// pseudo operation
return null;
}
HighVariable high = output.getHigh();
if (high == null) {
// not sure if this can happen; just in case
return null;
}
return high.getDataType();
}
private DataType getDataType(Varnode varnode) {