com.google.javascript.jscomp.CodingConvention Maven / Gradle / Ivy
/*
* Copyright 2007 The Closure Compiler Authors.
*
* 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 com.google.javascript.jscomp;
import static com.google.common.base.Preconditions.checkArgument;
import com.google.auto.value.AutoValue;
import com.google.common.base.Preconditions;
import com.google.common.collect.ImmutableMap;
import com.google.errorprone.annotations.Immutable;
import com.google.javascript.rhino.ClosurePrimitive;
import com.google.javascript.rhino.Node;
import com.google.javascript.rhino.NominalTypeBuilder;
import com.google.javascript.rhino.StaticSourceFile;
import com.google.javascript.rhino.jstype.FunctionType;
import com.google.javascript.rhino.jstype.JSType;
import com.google.javascript.rhino.jstype.JSTypeRegistry;
import com.google.javascript.rhino.jstype.ObjectType;
import java.io.Serializable;
import java.util.Collection;
import java.util.List;
import java.util.Map;
import java.util.function.Function;
import javax.annotation.Nullable;
/**
* CodingConvention defines a set of hooks to customize the behavior of the
* Compiler for a specific team/company.
*
*/
@Immutable
public interface CodingConvention extends Serializable {
/**
* This checks whether a given variable name, such as a name in all-caps
* should be treated as if it had the @const annotation.
*
* @param variableName potentially constant variable name
* @return {@code true} if the name should be treated as a constant.
*/
public boolean isConstant(String variableName);
/**
* This checks whether a given key of an object literal, such as a
* name in all-caps should be treated as if it had the @const
* annotation.
*/
public boolean isConstantKey(String keyName);
/**
* This checks that a given {@code key} may be used as a key for an enum.
*
* @param key the potential key to an enum
* @return {@code true} if the {@code key} may be used as an enum key,
* {@code false} otherwise
*/
public boolean isValidEnumKey(String key);
/**
* This checks whether a given parameter name should be treated as an
* optional parameter as far as type checking or function call arg count
* checking is concerned. Note that an optional function parameter may be
* declared as a simple type and is automatically converted to a union of the
* declared type and Undefined.
*
* @param parameter The parameter's node.
* @return {@code true} if the parameter should be treated as an optional
* parameter.
*/
public boolean isOptionalParameter(Node parameter);
/**
* This checks whether a given parameter should be treated as a marker
* for a variable argument list function. A VarArgs parameter must be the
* last parameter in a function declaration.
*
* @param parameter The parameter's node.
* @return {@code true} if the parameter should be treated as a variable
* length parameter.
*/
public boolean isVarArgsParameter(Node parameter);
/**
* Used by CheckMissingReturn. When a function call always throws an error,
* it can be the last stm of a block and we don't warn about missing return.
*/
public boolean isFunctionCallThatAlwaysThrows(Node n);
/**
* Checks whether a global variable or function name should be treated as
* exported, or externally referenceable.
*
* @param name A global variable or function name.
* @param local {@code true} if the name is a local variable.
* @return {@code true} if the name should be considered exported.
*/
public boolean isExported(String name, boolean local);
/**
* Should be isExported(name, true) || isExported(name, false);
*/
public boolean isExported(String name);
/**
* Check whether the property name is eligible for renaming.
*
* This method will not block removal or collapsing
* of the property; it will just block renaming if the
* property is not optimized away.
*
* @param name A property name.
* @return {@code true} if the name can not be renamed.
*/
public boolean blockRenamingForProperty(String name);
/**
* @return the package name for the given source file, or null if
* no package name is known.
*/
public String getPackageName(StaticSourceFile source);
/**
* Checks whether a name should be considered private. Private global
* variables and functions can only be referenced within the source file in
* which they are declared. Private properties and methods should only be
* accessed by the class that defines them.
*
* @param name The name of a global variable or function, or a method or
* property.
* @return {@code true} if the name should be considered private.
*/
public boolean isPrivate(String name);
/**
* Whether this CodingConvention includes a convention for what private names should look like.
*/
public boolean hasPrivacyConvention();
/**
* Checks if the given method defines a subclass relationship,
* and if it does, returns information on that relationship. By default,
* always returns null. Meant to be overridden by subclasses.
*
* @param callNode A CALL node.
*/
public SubclassRelationship getClassesDefinedByCall(Node callNode);
/**
* Checks if the given method is a call to a class factory, such a factory returns a
* unique class.
*
* @param callNode A CALL node.
*/
public boolean isClassFactoryCall(Node callNode);
/**
* Returns true if passed a string referring to the superclass. The string
* will usually be from the string node at the right of a GETPROP, e.g.
* this.superClass_.
*/
public boolean isSuperClassReference(String propertyName);
/**
* Convenience method for determining if the node indicates the file
* is a "module" file (a file whose top level symbols are not in global
* scope).
*/
boolean extractIsModuleFile(Node node, Node parent);
/**
* Convenience method for determining provided dependencies amongst different
* JS scripts.
*/
public String extractClassNameIfProvide(Node node, Node parent);
/**
* Convenience method for determining required dependencies amongst different
* JS scripts.
*/
public String extractClassNameIfRequire(Node node, Node parent);
/**
* Function name used when exporting properties.
* Signature: fn(object, publicName, symbol).
* @return function name.
*/
public String getExportPropertyFunction();
/**
* Function name used when exporting symbols.
* Signature: fn(publicPath, object).
* @return function name.
*/
public String getExportSymbolFunction();
/**
* Checks if the given CALL node is forward-declaring any types,
* and returns the name of the types if it is.
*/
public List identifyTypeDeclarationCall(Node n);
/**
* In many JS libraries, the function that produces inheritance also
* adds properties to the superclass and/or subclass.
*/
public void applySubclassRelationship(
NominalTypeBuilder parent, NominalTypeBuilder child, SubclassType type);
/**
* Function name for abstract methods. An abstract method can be assigned to
* an interface method instead of an function expression in order to avoid
* linter warnings produced by assigning a function without a return value
* where a return value is expected.
* @return function name.
*/
public String getAbstractMethodName();
/**
* Checks if the given method defines a singleton getter, and if it does,
* returns the name of the class with the singleton getter. By default, always
* returns null. Meant to be overridden by subclasses.
*
* addSingletonGetter needs a coding convention because in the general case,
* it can't be inlined. The function inliner sees that it creates an alias
* to the given class in an inner closure, and bails out.
*
* @param callNode A CALL node.
*/
public String getSingletonGetterClassName(Node callNode);
/**
* In many JS libraries, the function that adds a singleton getter to a class
* adds properties to the class.
*/
public void applySingletonGetter(
NominalTypeBuilder classType, FunctionType getterType);
/**
* @return Whether the function is inlinable by convention.
*/
public boolean isInlinableFunction(Node n);
/**
* @return the delegate relationship created by the call or null.
*/
public DelegateRelationship getDelegateRelationship(Node callNode);
/**
* In many JS libraries, the function that creates a delegate relationship
* also adds properties to the delegator and delegate base.
*/
public void applyDelegateRelationship(
NominalTypeBuilder delegateSuperclass,
NominalTypeBuilder delegateBase,
NominalTypeBuilder delegator,
ObjectType delegateProxy,
FunctionType findDelegate);
/**
* @return the name of the delegate superclass.
*/
public String getDelegateSuperclassName();
/**
* Checks for getprops that set the calling conventions on delegate methods.
*/
public void checkForCallingConventionDefinitions(
Node getPropNode, Map delegateCallingConventions);
/**
* Defines the delegate proxy prototype properties. Their types depend on
* properties of the delegate base methods.
*
* @param delegateProxies List of delegate proxy types.
*/
public void defineDelegateProxyPrototypeProperties(
JSTypeRegistry registry,
List delegateProxies,
Map delegateCallingConventions);
/**
* Gets the name of the global object.
*/
public String getGlobalObject();
/**
* Whether this statement is creating an alias of the global object
*/
public boolean isAliasingGlobalThis(Node n);
/**
* A Bind instance or null.
*/
public Bind describeFunctionBind(Node n);
/**
* A Bind instance or null.
*
* When seeing an expression exp1.bind(recv, arg1, ...);
* we only know that it's a function bind if exp1 has type function.
* W/out type info, exp1 has certainly a function type only if it's a
* function literal.
*
* If (the old) type checking has already happened, exp1's type is attached to
* the AST node.
* When iCheckTypes is true, describeFunctionBind looks for that type.
*
* The new type inference does not yet attach types to nodes, but we can still
* use type information in describeFunctionBind by passing true for
* callerChecksTypes.
*
* @param callerChecksTypes Trust that the caller of this method has verified
* that the bound node has a function type.
* @param iCheckTypes Check that the bound node has a function type.
*/
public Bind describeFunctionBind(
Node n, boolean callerChecksTypes, boolean iCheckTypes);
/** Bind class */
public static class Bind {
// The target of the bind action
final Node target;
// The node representing the "this" value, maybe null
final Node thisValue;
// The head of a Node list representing the parameters
final Node parameters;
public Bind(Node target, Node thisValue, Node parameters) {
this.target = target;
this.thisValue = thisValue;
this.parameters = parameters;
}
/**
* The number of parameters bound (not including the 'this' value).
*/
int getBoundParameterCount() {
if (parameters == null) {
return 0;
}
Node paramParent = parameters.getParent();
return paramParent.getChildCount() - paramParent.getIndexOfChild(parameters);
}
}
/**
* Builds a {@link Cache} instance from the given call node and returns that instance, or null
* if the {@link Node} does not resemble a cache utility call.
*
* This should match calls to a cache utility method. This type of node is specially considered
* for side-effects since conventionally storing something on a cache object would be seen as a
* side-effect.
*
*/
public Cache describeCachingCall(Node node);
/** Cache class */
public static class Cache {
final Node cacheObj;
final Node key;
final Node valueFn;
final Node keyFn;
public Cache(Node cacheObj, Node key, Node valueFn, Node keyFn) {
this.cacheObj = cacheObj;
this.key = key;
this.valueFn = valueFn;
this.keyFn = keyFn;
}
}
/**
* Whether this CALL function is testing for the existence of a property.
*/
public boolean isPropertyTestFunction(Node call);
/**
* Whether this GETPROP node is an alias for an object prototype.
*/
public boolean isPrototypeAlias(Node getProp);
/**
* Whether this CALL function is returning the string name for a property, but allows renaming.
*/
public boolean isPropertyRenameFunction(String name);
/**
* Checks if the given method performs a object literal cast, and if it does,
* returns information on the cast. By default, always returns null. Meant
* to be overridden by subclasses.
*
* @param callNode A CALL node.
*/
public ObjectLiteralCast getObjectLiteralCast(Node callNode);
/**
* Gets a collection of all properties that are defined indirectly on global
* objects. (For example, Closure defines superClass_ in the goog.inherits
* call).
*/
public Collection getIndirectlyDeclaredProperties();
/**
* Returns the set of AssertionFunction.
*/
public Collection getAssertionFunctions();
/** Specify the kind of inheritance */
static enum SubclassType {
INHERITS,
MIXIN
}
/** Record subclass relations */
static class SubclassRelationship {
final SubclassType type;
final String subclassName;
final String superclassName;
public SubclassRelationship(
SubclassType type, Node subclassNode, Node superclassNode) {
checkArgument(
subclassNode.isQualifiedName(), "Expected qualified name, found: %s", subclassNode);
checkArgument(
superclassNode.isQualifiedName(), "Expected qualified name, found: %s", superclassNode);
this.type = type;
this.subclassName = subclassNode.getQualifiedName();
this.superclassName = superclassNode.getQualifiedName();
}
}
/**
* Delegates provides a mechanism and structure for identifying where classes
* can call out to optional code to augment their functionality. The optional
* code is isolated from the base code through the use of a subclass in the
* optional code derived from the delegate class in the base code.
*/
static class DelegateRelationship {
/** The subclass in the base code. */
final String delegateBase;
/** The class in the base code. */
final String delegator;
DelegateRelationship(String delegateBase, String delegator) {
this.delegateBase = delegateBase;
this.delegator = delegator;
}
}
/**
* An object literal cast provides a mechanism to cast object literals to
* other types without a warning.
*/
static class ObjectLiteralCast {
/** Type to cast to. */
final String typeName;
/** Object to cast. */
final Node objectNode;
/** Error message */
final DiagnosticType diagnosticType;
ObjectLiteralCast(String typeName, Node objectNode,
DiagnosticType diagnosticType) {
this.typeName = typeName;
this.objectNode = objectNode;
this.diagnosticType = diagnosticType;
}
}
/**
* A description of a JavaScript function that will throw an exception when either:
*
*
* - One of its parameters does not match the return type of the function
*
- One of its parameters is falsy. This has some special handling for expressions that the
* match-return-type handling does not have.
*
*/
@Immutable
@AutoValue
abstract class AssertionFunctionSpec {
// TODO(b/126254920): remove this field and always use ClosurePrimitive
@Nullable
abstract String getFunctionName();
@Nullable
abstract ClosurePrimitive getClosurePrimitive();
abstract AssertionKind getAssertionKind();
abstract int getParamIndex(); // the index of the formal parameter that is actually asserted
public enum AssertionKind {
TRUTHY, // an assertion that the parameter is 'truthy'
MATCHES_RETURN_TYPE // an assertion that the parameter matches the inferred return kind
}
static Builder builder() {
return new AutoValue_CodingConvention_AssertionFunctionSpec.Builder().setParamIndex(0);
}
public static Builder forTruthy() {
return builder().setAssertionKind(AssertionKind.TRUTHY);
}
public static Builder forMatchesReturn() {
return builder().setAssertionKind(AssertionKind.MATCHES_RETURN_TYPE);
}
@AutoValue.Builder
public abstract static class Builder {
public abstract Builder setFunctionName(String name);
abstract Builder setClosurePrimitive(ClosurePrimitive primitive);
public abstract Builder setParamIndex(int paramIndex);
abstract Builder setAssertionKind(AssertionKind kind);
abstract AssertionFunctionSpec autoBuild();
public AssertionFunctionSpec build() {
AssertionFunctionSpec spec = autoBuild();
Preconditions.checkState(
spec.getFunctionName() != null || spec.getClosurePrimitive() != null,
"Must provide a function name or ClosurePrimitive for each spec");
return spec;
}
}
private Object getId() {
return getClosurePrimitive() != null ? getClosurePrimitive() : getFunctionName();
}
/** Returns which argument is actually being asserted, or null if fewer args than expected */
@Nullable
Node getAssertedArg(Node firstArg) {
for (int i = 0; i < getParamIndex(); i++) {
if (firstArg == null) {
// If there are fewer arguments than expected, return null instead of crashing in this
// function.
return null;
}
firstArg = firstArg.getNext();
}
return firstArg;
}
}
/** This stores a relation from either name or Closure Primitive to assertion function */
@Immutable
final class AssertionFunctionLookup {
// the key type 'Object' is mutable, but at runtime is only ever a string or ClosurePrimitive
@SuppressWarnings("Immutable")
private final ImmutableMap internal;
private AssertionFunctionLookup(ImmutableMap internal) {
this.internal = internal;
}
/**
* Returns a new map containing all the given {@link AssertionFunctionSpec}s
*
* Assumes that in the input, there is a unique mapping from string name to spec and closure
* primitive to spec.
*/
static AssertionFunctionLookup of(Collection specs) {
ImmutableMap idToSpecMap =
specs.stream()
.collect(
ImmutableMap.toImmutableMap(AssertionFunctionSpec::getId, Function.identity()));
return new AssertionFunctionLookup(idToSpecMap);
}
/**
* Returns the {@link AssertionFunctionSpec} matching the given function reference.
*
* This first looks up specs by their ClosurePrimitive, then falls back to qualified name
*/
@Nullable
AssertionFunctionSpec lookupByCallee(Node callee) {
FunctionType fnType = JSType.toMaybeFunctionType(callee.getJSType());
if (fnType != null && fnType.getClosurePrimitive() != null) {
AssertionFunctionSpec spec = internal.get(fnType.getClosurePrimitive());
if (spec != null) {
return spec;
}
}
// TODO(b/126254920): remove this
if (callee.isQualifiedName()) {
return internal.get(callee.getQualifiedName());
}
return null;
}
}
}