src/main/java/com/google/devtools/build/lib/syntax/EvalUtils.java - bazel - Git at Google

 // Copyright 2014 The Bazel Authors. All rights reserved.
 //
 // 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.devtools.build.lib.syntax;

 import com.google.common.base.Preconditions;
 import com.google.common.collect.ImmutableList;
 import com.google.common.collect.ImmutableMap;
 import com.google.common.collect.Iterables;
 import com.google.common.collect.Lists;
 import com.google.common.collect.Ordering;
 import com.google.devtools.build.lib.collect.nestedset.NestedSet;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.Immutable;
 import com.google.devtools.build.lib.events.Location;
 import com.google.devtools.build.lib.skylarkinterface.SkylarkInterfaceUtils;
 import com.google.devtools.build.lib.skylarkinterface.SkylarkModule;
 import com.google.devtools.build.lib.skylarkinterface.SkylarkValue;
 import com.google.devtools.build.lib.vfs.PathFragment;
 import java.util.Collection;
 import java.util.List;
 import java.util.Map;
 import javax.annotation.Nullable;

 /**
  * Utilities used by the evaluator.
  */
 public final class EvalUtils {

   private EvalUtils() {}

   /**
    * The exception that SKYLARK_COMPARATOR might throw. This is an unchecked exception
    * because Comparator doesn't let us declare exceptions. It should normally be caught
    * and wrapped in an EvalException.
    */
   public static class ComparisonException extends RuntimeException {
     public ComparisonException(String msg) {
       super(msg);
     }
   }

   /**
    * Compare two Skylark objects.
    *
    * <p>It may throw an unchecked exception ComparisonException that should be wrapped in an
    * EvalException.
    */
   public static final Ordering<Object> SKYLARK_COMPARATOR =
       new Ordering<Object>() {
         private int compareLists(SkylarkList o1, SkylarkList o2) {
           if (o1 instanceof RangeList || o2 instanceof RangeList) {
             throw new ComparisonException("Cannot compare range objects");
           }

           for (int i = 0; i < Math.min(o1.size(), o2.size()); i++) {
             int cmp = compare(o1.get(i), o2.get(i));
             if (cmp != 0) {
               return cmp;
             }
           }
           return Integer.compare(o1.size(), o2.size());
         }

         @Override
         @SuppressWarnings("unchecked")
         public int compare(Object o1, Object o2) {
           o1 = SkylarkType.convertToSkylark(o1, (Environment) null);
           o2 = SkylarkType.convertToSkylark(o2, (Environment) null);

           if (o1 instanceof SkylarkList
               && o2 instanceof SkylarkList
               && ((SkylarkList) o1).isTuple() == ((SkylarkList) o2).isTuple()) {
             return compareLists((SkylarkList) o1, (SkylarkList) o2);
           }

           if (!(o1.getClass().isAssignableFrom(o2.getClass())
               || o2.getClass().isAssignableFrom(o1.getClass()))) {
             throw new ComparisonException(
                 "Cannot compare " + getDataTypeName(o1) + " with " + getDataTypeName(o2));
           }

           if (o1 instanceof ClassObject) {
             throw new ComparisonException("Cannot compare structs");
           }
           if (o1 instanceof SkylarkNestedSet) {
             throw new ComparisonException("Cannot compare depsets");
           }
           try {
             return ((Comparable<Object>) o1).compareTo(o2);
           } catch (ClassCastException e) {
             throw new ComparisonException(
                 "Cannot compare " + getDataTypeName(o1) + " with " + getDataTypeName(o2));
           }
         }
       };

   /**
    * Checks that an Object is a valid key for a Skylark dict.
    * @param o an Object to validate
    * @throws EvalException if o is not a valid key
    */
   public static void checkValidDictKey(Object o) throws EvalException {
     // TODO(bazel-team): check that all recursive elements are both Immutable AND Comparable.
     if (isImmutable(o)) {
       return;
     }
     // Same error message as Python (that makes it a TypeError).
     throw new EvalException(null, Printer.format("unhashable type: '%r'", o.getClass()));
   }

   /**
    * Is this object known or assumed to be recursively immutable by Skylark?
    * @param o an Object
    * @return true if the object is known to be an immutable value.
    */
   // NB: This is used as the basis for accepting objects in SkylarkNestedSet-s,
   // as well as for accepting objects as keys for Skylark dict-s.
   public static boolean isImmutable(Object o) {
     if (o instanceof SkylarkValue) {
       return ((SkylarkValue) o).isImmutable();
     }
     return isImmutable(o.getClass());
   }

   /**
    * Is this class known to be *recursively* immutable by Skylark?
    * For instance, class Tuple is not it, because it can contain mutable values.
    * @param c a Class
    * @return true if the class is known to represent only recursively immutable values.
    */
   // NB: This is used as the basis for accepting objects in SkylarkNestedSet-s,
   // as well as for accepting objects as keys for Skylark dict-s.
   static boolean isImmutable(Class<?> c) {
     return c.isAnnotationPresent(Immutable.class) // TODO(bazel-team): beware of containers!
         || c.equals(String.class)
         || c.equals(Integer.class)
         || c.equals(Boolean.class);
   }

   /**
    * Returns true if the type is acceptable to be returned to the Skylark language.
    */
   public static boolean isSkylarkAcceptable(Class<?> c) {
     return SkylarkValue.class.isAssignableFrom(c) // implements SkylarkValue
         || c.equals(String.class) // basic values
         || c.equals(Integer.class)
         || c.equals(Boolean.class)
         // there is a registered Skylark ancestor class (useful e.g. when using AutoValue)
         || SkylarkInterfaceUtils.getSkylarkModule(c) != null
         || ImmutableMap.class.isAssignableFrom(c) // will be converted to SkylarkDict
         || NestedSet.class.isAssignableFrom(c) // will be converted to SkylarkNestedSet
         || PathFragment.class.isAssignableFrom(c); // other known class
   }

   // TODO(bazel-team): move the following few type-related functions to SkylarkType
   /**
    * Return the Skylark-type of {@code c}
    *
    * <p>The result will be a type that Skylark understands and is either equal to {@code c}
    * or is a supertype of it. For example, all instances of (all subclasses of) SkylarkList
    * are considered to be SkylarkLists.
    *
    * <p>Skylark's type validation isn't equipped to deal with inheritance so we must tell it which
    * of the superclasses or interfaces of {@code c} is the one that matters for type compatibility.
    *
    * @param c a class
    * @return a super-class of c to be used in validation-time type inference.
    */
   public static Class<?> getSkylarkType(Class<?> c) {
     // TODO(bazel-team): Iterable and Class likely do not belong here.
     if (String.class.equals(c)
         || Boolean.class.equals(c)
         || Integer.class.equals(c)
         || Iterable.class.equals(c)
         || Class.class.equals(c)) {
       return c;
     }
     // TODO(bazel-team): We should require all Skylark-addressable values that aren't builtin types
     // (String/Boolean/Integer) to implement SkylarkValue. We should also require them to have a
     // (possibly inherited) @SkylarkModule annotation.
     Class<?> parent = SkylarkInterfaceUtils.getParentWithSkylarkModule(c);
     if (parent != null) {
       return parent;
     }
     Preconditions.checkArgument(
         SkylarkValue.class.isAssignableFrom(c),
         "%s is not allowed as a Starlark value (getSkylarkType() failed)",
         c);
     return c;
   }

   /**
    * Returns a pretty name for the datatype of object 'o' in the Build language.
    */
   public static String getDataTypeName(Object o) {
     return getDataTypeName(o, false);
   }

   /**
    * Returns a pretty name for the datatype of object {@code object} in Skylark
    * or the BUILD language, with full details if the {@code full} boolean is true.
    */
   public static String getDataTypeName(Object object, boolean fullDetails) {
     Preconditions.checkNotNull(object);
     if (fullDetails) {
       if (object instanceof SkylarkNestedSet) {
         SkylarkNestedSet set = (SkylarkNestedSet) object;
         return "depset of " + set.getContentType() + "s";
       }
       if (object instanceof SelectorList) {
         SelectorList list = (SelectorList) object;
         return "select of " + getDataTypeNameFromClass(list.getType());
       }
     }
     return getDataTypeNameFromClass(object.getClass());
   }

   /**
    * Returns a pretty name for the datatype equivalent of class 'c' in the Build language.
    */
   public static String getDataTypeNameFromClass(Class<?> c) {
     return getDataTypeNameFromClass(c, true);
   }

   /**
    * Returns a pretty name for the datatype equivalent of class 'c' in the Build language.
    * @param highlightNameSpaces Determines whether the result should also contain a special comment
    * when the given class identifies a Skylark name space.
    */
   public static String getDataTypeNameFromClass(Class<?> c, boolean highlightNameSpaces) {
     SkylarkModule module = SkylarkInterfaceUtils.getSkylarkModule(c);
     if (module != null) {
       return module.name()
           + ((module.namespace() && highlightNameSpaces) ? " (a language module)" : "");
     } else if (c.equals(Object.class)) {
       return "unknown";
     } else if (c.equals(String.class)) {
       return "string";
     } else if (c.equals(Integer.class)) {
       return "int";
     } else if (c.equals(Boolean.class)) {
       return "bool";
     } else if (List.class.isAssignableFrom(c)) { // This is a Java List that isn't a SkylarkList
       return "List"; // This case shouldn't happen in normal code, but we keep it for debugging.
     } else if (Map.class.isAssignableFrom(c)) { // This is a Java Map that isn't a SkylarkDict
       return "Map"; // This case shouldn't happen in normal code, but we keep it for debugging.
     } else if (StarlarkFunction.class.isAssignableFrom(c)) {
       return "function";
     } else if (c.equals(SelectorValue.class)) {
       return "select";
     } else if (NestedSet.class.isAssignableFrom(c)) {
       // TODO(bazel-team): no one should be seeing naked NestedSet at all.
       return "depset";
     } else {
       if (c.getSimpleName().isEmpty()) {
         return c.getName();
       } else {
         return c.getSimpleName();
       }
     }
   }

   public static Object checkNotNull(Expression expr, Object obj) throws EvalException {
     if (obj == null) {
       throw new EvalException(
           expr.getLocation(),
           "unexpected null value, please send a bug report. "
               + "This was generated by expression '"
               + expr
               + "'");
     }
     return obj;
   }

   /**
    * Returns the truth value of an object, according to Python rules.
    * http://docs.python.org/2/library/stdtypes.html#truth-value-testing
    */
   public static boolean toBoolean(Object o) {
     if (o == null || o == Runtime.NONE) {
       return false;
     } else if (o instanceof Boolean) {
       return (Boolean) o;
     } else if (o instanceof String) {
       return !((String) o).isEmpty();
     } else if (o instanceof Integer) {
       return (Integer) o != 0;
     } else if (o instanceof Collection<?>) {
       return !((Collection<?>) o).isEmpty();
     } else if (o instanceof Map<?, ?>) {
       return !((Map<?, ?>) o).isEmpty();
     } else if (o instanceof NestedSet<?>) {
       return !((NestedSet<?>) o).isEmpty();
     } else if (o instanceof SkylarkNestedSet) {
       return !((SkylarkNestedSet) o).isEmpty();
     } else if (o instanceof Iterable<?>) {
       return !Iterables.isEmpty((Iterable<?>) o);
     } else {
       return true;
     }
   }

   public static Collection<?> toCollection(Object o, Location loc, @Nullable Environment env)
       throws EvalException {
     if (o instanceof Collection) {
       return (Collection<?>) o;
     } else if (o instanceof SkylarkList) {
       return ((SkylarkList) o).getImmutableList();
     } else if (o instanceof Map) {
       // For dictionaries we iterate through the keys only
       if (o instanceof SkylarkDict) {
         // SkylarkDicts handle ordering themselves
         SkylarkDict<?, ?> dict = (SkylarkDict) o;
         List<Object> list = Lists.newArrayListWithCapacity(dict.size());
         for (Map.Entry<?, ?> entries : dict.entrySet()) {
           list.add(entries.getKey());
         }
         return ImmutableList.copyOf(list);
       }
       // For determinism, we sort the keys.
       try {
         return SKYLARK_COMPARATOR.sortedCopy(((Map<?, ?>) o).keySet());
       } catch (ComparisonException e) {
         throw new EvalException(loc, e);
       }
     } else if (o instanceof SkylarkNestedSet) {
       return nestedSetToCollection((SkylarkNestedSet) o, loc, env);
     } else {
       throw new EvalException(loc,
           "type '" + getDataTypeName(o) + "' is not a collection");
     }
   }

   private static Collection<?> nestedSetToCollection(
       SkylarkNestedSet set, Location loc, @Nullable Environment env) throws EvalException {
     if (env != null && env.getSemantics().incompatibleDepsetIsNotIterable()) {
       throw new EvalException(
           loc,
           "type 'depset' is not iterable. Use the `to_list()` method to get a list. Use "
               + "--incompatible_depset_is_not_iterable=false to temporarily disable this check.");
     }
     return set.toCollection();
   }

   public static Iterable<?> toIterable(Object o, Location loc, @Nullable Environment env)
       throws EvalException {
     if (o instanceof SkylarkNestedSet) {
       return nestedSetToCollection((SkylarkNestedSet) o, loc, env);
     } else if (o instanceof Iterable) {
       return (Iterable<?>) o;
     } else if (o instanceof Map) {
       return toCollection(o, loc, env);
     } else {
       throw new EvalException(loc,
           "type '" + getDataTypeName(o) + "' is not iterable");
     }
   }

   /**
    * Given an {@link Iterable}, returns it as-is. Given a {@link SkylarkNestedSet}, returns its
    * contents as an iterable. Throws {@link EvalException} for any other value.
    *
    * <p>This is a kludge for the change that made {@code SkylarkNestedSet} not implement {@code
    * Iterable}. It is different from {@link #toIterable} in its behavior for strings and other types
    * that are not strictly Java-iterable.
    *
    * @throws EvalException if {@code o} is not an iterable or set
    * @deprecated avoid writing APIs that implicitly treat depsets as iterables. It encourages
    *     unnecessary flattening of depsets.
    *     <p>TODO(bazel-team): Remove this if/when implicit iteration over {@code SkylarkNestedSet}
    *     is no longer supported.
    */
   @Deprecated
   public static Iterable<?> toIterableStrict(Object o, Location loc, @Nullable Environment env)
       throws EvalException {
     if (o instanceof Iterable) {
       return (Iterable<?>) o;
     } else if (o instanceof SkylarkNestedSet) {
       return nestedSetToCollection((SkylarkNestedSet) o, loc, env);
     } else {
       throw new EvalException(loc,
           "expected Iterable or depset, but got '" + getDataTypeName(o) + "' (strings and maps "
           + "are not allowed here)");
     }
   }

   public static void lock(Object object, Location loc) {
     if (object instanceof SkylarkMutable) {
       ((SkylarkMutable) object).lock(loc);
     }
   }

   public static void unlock(Object object, Location loc) {
     if (object instanceof SkylarkMutable) {
       ((SkylarkMutable) object).unlock(loc);
     }
   }

   // The following functions for indexing and slicing match the behavior of Python.

   /**
    * Resolves a positive or negative index to an index in the range [0, length), or throws
    * EvalException if it is out-of-range. If the index is negative, it counts backward from
    * length.
    */
   public static int getSequenceIndex(int index, int length, Location loc)
       throws EvalException {
     int actualIndex = index;
     if (actualIndex < 0) {
       actualIndex += length;
     }
     if (actualIndex < 0 || actualIndex >= length) {
       throw new EvalException(
           loc,
           "index out of range (index is " + index + ", but sequence has " + length + " elements)");
     }
     return actualIndex;
   }

   /**
    * Performs index resolution after verifying that the given object has index type.
    */
   public static int getSequenceIndex(Object index, int length, Location loc)
       throws EvalException {
     if (!(index instanceof Integer)) {
       throw new EvalException(
           loc, "indices must be integers, not " + EvalUtils.getDataTypeName(index));
     }
     return getSequenceIndex(((Integer) index).intValue(), length, loc);
   }

   /**
    * Resolves a positive or negative index to an integer that can denote the left or right boundary
    * of a slice. If reverse is false, the slice has positive stride (i.e., its elements are in their
    * normal order) and the result is guaranteed to be in range [0, length + 1). If reverse is true,
    * the slice has negative stride and the result is in range [-1, length). In either case, if the
    * index is negative, it counts backward from length. Note that an input index of -1 represents
    * the last element's position, while an output integer of -1 represents the imaginary position
    * to the left of the first element.
    */
   public static int clampRangeEndpoint(int index, int length, boolean reverse) {
     if (index < 0) {
       index += length;
     }
     if (!reverse) {
       return Math.max(Math.min(index, length), 0);
     } else {
       return Math.max(Math.min(index, length - 1), -1);
     }
   }

   /**
    * Resolves a positive or negative index to an integer that can denote the boundary for a
    * slice with positive stride.
    */
   public static int clampRangeEndpoint(int index, int length) {
     return clampRangeEndpoint(index, length, false);
   }

   /**
    * Calculates the indices of the elements that should be included in the slice [start:end:step]
    * of a sequence with the given length. Each of start, end, and step must be supplied, and step
    * may not be 0.
    */
   public static List<Integer> getSliceIndices(int start, int end, int step, int length) {
     if (step == 0) {
       throw new IllegalArgumentException("Slice step cannot be zero");
     }
     start = clampRangeEndpoint(start, length, step < 0);
     end = clampRangeEndpoint(end, length, step < 0);
     // precise computation is slightly more involved, but since it can overshoot only by a single
     // element it's fine
     final int expectedMaxSize = Math.abs(start - end) / Math.abs(step) + 1;
     ImmutableList.Builder<Integer> indices = ImmutableList.builderWithExpectedSize(expectedMaxSize);
     for (int current = start; step > 0 ? current < end : current > end; current += step) {
       indices.add(current);
     }
     return indices.build();
   }

   /**
    * Calculates the indices of the elements in a slice, after validating the arguments and replacing
    * Runtime.NONE with default values. Throws an EvalException if a bad argument is given.
    */
   public static List<Integer> getSliceIndices(
       Object startObj, Object endObj, Object stepObj, int length, Location loc)
       throws EvalException {
     int start;
     int end;
     int step;

     if (stepObj == Runtime.NONE) {
       step = 1;
     } else if (stepObj instanceof Integer) {
       step = ((Integer) stepObj).intValue();
     } else {
       throw new EvalException(
           loc, String.format("slice step must be an integer, not '%s'", stepObj));
     }
     if (step == 0) {
       throw new EvalException(loc, "slice step cannot be zero");
     }

     if (startObj == Runtime.NONE) {
       start = (step > 0) ? 0 : length - 1;
     } else if (startObj instanceof Integer) {
       start = ((Integer) startObj).intValue();
     } else {
       throw new EvalException(
           loc, String.format("slice start must be an integer, not '%s'", startObj));
     }
     if (endObj == Runtime.NONE) {
       // If step is negative, can't use -1 for end since that would be converted
       // to the rightmost element's position.
       end = (step > 0) ? length : -length - 1;
     } else if (endObj instanceof Integer) {
       end = ((Integer) endObj).intValue();
     } else {
       throw new EvalException(loc, String.format("slice end must be an integer, not '%s'", endObj));
     }

     return getSliceIndices(start, end, step, length);
   }

   /** @return true if x is Java null or Skylark None */
   public static boolean isNullOrNone(Object x) {
     return x == null || x == Runtime.NONE;
   }

   /**
    * Build a SkylarkDict of kwarg arguments from a list, removing null-s or None-s.
    *
    * @param env the Environment in which this map can be mutated.
    * @param init a series of key, value pairs (as consecutive arguments)
    *   as in {@code optionMap(k1, v1, k2, v2, k3, v3)}
    *   where each key is a String, each value is an arbitrary Objet.
    * @return a {@code Map<String, Object>} that has all the specified entries,
    *   where key, value pairs appearing earlier have precedence,
    *   i.e. {@code k1, v1} may override {@code k3, v3}.
    *
    * Ignore any entry where the value is null or None.
    * Keys cannot be null.
    */
   @SuppressWarnings("unchecked")
   public static <K, V> SkylarkDict<K, V> optionMap(Environment env, Object... init) {
     ImmutableMap.Builder<K, V> b = new ImmutableMap.Builder<>();
     Preconditions.checkState(init.length % 2 == 0);
     for (int i = init.length - 2; i >= 0; i -= 2) {
       K key = (K) Preconditions.checkNotNull(init[i]);
       V value = (V) init[i + 1];
       if (!isNullOrNone(value)) {
         b.put(key, value);
       }
     }
     return SkylarkDict.copyOf(env, b.build());
   }
 }
	// Copyright 2014 The Bazel Authors. All rights reserved.
	//
	// 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.devtools.build.lib.syntax;

	import com.google.common.base.Preconditions;
	import com.google.common.collect.ImmutableList;
	import com.google.common.collect.ImmutableMap;
	import com.google.common.collect.Iterables;
	import com.google.common.collect.Lists;
	import com.google.common.collect.Ordering;
	import com.google.devtools.build.lib.collect.nestedset.NestedSet;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.Immutable;
	import com.google.devtools.build.lib.events.Location;
	import com.google.devtools.build.lib.skylarkinterface.SkylarkInterfaceUtils;
	import com.google.devtools.build.lib.skylarkinterface.SkylarkModule;
	import com.google.devtools.build.lib.skylarkinterface.SkylarkValue;
	import com.google.devtools.build.lib.vfs.PathFragment;
	import java.util.Collection;
	import java.util.List;
	import java.util.Map;
	import javax.annotation.Nullable;

	/**
	* Utilities used by the evaluator.
	*/
	public final class EvalUtils {

	private EvalUtils() {}

	/**
	* The exception that SKYLARK_COMPARATOR might throw. This is an unchecked exception
	* because Comparator doesn't let us declare exceptions. It should normally be caught
	* and wrapped in an EvalException.
	*/
	public static class ComparisonException extends RuntimeException {
	public ComparisonException(String msg) {
	super(msg);
	}
	}

	/**
	* Compare two Skylark objects.
	*
	* <p>It may throw an unchecked exception ComparisonException that should be wrapped in an
	* EvalException.
	*/
	public static final Ordering<Object> SKYLARK_COMPARATOR =
	new Ordering<Object>() {
	private int compareLists(SkylarkList o1, SkylarkList o2) {
	if (o1 instanceof RangeList \|\| o2 instanceof RangeList) {
	throw new ComparisonException("Cannot compare range objects");
	}

	for (int i = 0; i < Math.min(o1.size(), o2.size()); i++) {
	int cmp = compare(o1.get(i), o2.get(i));
	if (cmp != 0) {
	return cmp;
	}
	}
	return Integer.compare(o1.size(), o2.size());
	}

	@Override
	@SuppressWarnings("unchecked")
	public int compare(Object o1, Object o2) {
	o1 = SkylarkType.convertToSkylark(o1, (Environment) null);
	o2 = SkylarkType.convertToSkylark(o2, (Environment) null);

	if (o1 instanceof SkylarkList
	&& o2 instanceof SkylarkList
	&& ((SkylarkList) o1).isTuple() == ((SkylarkList) o2).isTuple()) {
	return compareLists((SkylarkList) o1, (SkylarkList) o2);
	}

	if (!(o1.getClass().isAssignableFrom(o2.getClass())
	\|\| o2.getClass().isAssignableFrom(o1.getClass()))) {
	throw new ComparisonException(
	"Cannot compare " + getDataTypeName(o1) + " with " + getDataTypeName(o2));
	}

	if (o1 instanceof ClassObject) {
	throw new ComparisonException("Cannot compare structs");
	}
	if (o1 instanceof SkylarkNestedSet) {
	throw new ComparisonException("Cannot compare depsets");
	}
	try {
	return ((Comparable<Object>) o1).compareTo(o2);
	} catch (ClassCastException e) {
	throw new ComparisonException(
	"Cannot compare " + getDataTypeName(o1) + " with " + getDataTypeName(o2));
	}
	}
	};

	/**
	* Checks that an Object is a valid key for a Skylark dict.
	* @param o an Object to validate
	* @throws EvalException if o is not a valid key
	*/
	public static void checkValidDictKey(Object o) throws EvalException {
	// TODO(bazel-team): check that all recursive elements are both Immutable AND Comparable.
	if (isImmutable(o)) {
	return;
	}
	// Same error message as Python (that makes it a TypeError).
	throw new EvalException(null, Printer.format("unhashable type: '%r'", o.getClass()));
	}

	/**
	* Is this object known or assumed to be recursively immutable by Skylark?
	* @param o an Object
	* @return true if the object is known to be an immutable value.
	*/
	// NB: This is used as the basis for accepting objects in SkylarkNestedSet-s,
	// as well as for accepting objects as keys for Skylark dict-s.
	public static boolean isImmutable(Object o) {
	if (o instanceof SkylarkValue) {
	return ((SkylarkValue) o).isImmutable();
	}
	return isImmutable(o.getClass());
	}

	/**
	* Is this class known to be recursively immutable by Skylark?
	* For instance, class Tuple is not it, because it can contain mutable values.
	* @param c a Class
	* @return true if the class is known to represent only recursively immutable values.
	*/
	// NB: This is used as the basis for accepting objects in SkylarkNestedSet-s,
	// as well as for accepting objects as keys for Skylark dict-s.
	static boolean isImmutable(Class<?> c) {
	return c.isAnnotationPresent(Immutable.class) // TODO(bazel-team): beware of containers!
	\|\| c.equals(String.class)
	\|\| c.equals(Integer.class)
	\|\| c.equals(Boolean.class);
	}

	/**
	* Returns true if the type is acceptable to be returned to the Skylark language.
	*/
	public static boolean isSkylarkAcceptable(Class<?> c) {
	return SkylarkValue.class.isAssignableFrom(c) // implements SkylarkValue
	\|\| c.equals(String.class) // basic values
	\|\| c.equals(Integer.class)
	\|\| c.equals(Boolean.class)
	// there is a registered Skylark ancestor class (useful e.g. when using AutoValue)
	\|\| SkylarkInterfaceUtils.getSkylarkModule(c) != null
	\|\| ImmutableMap.class.isAssignableFrom(c) // will be converted to SkylarkDict
	\|\| NestedSet.class.isAssignableFrom(c) // will be converted to SkylarkNestedSet
	\|\| PathFragment.class.isAssignableFrom(c); // other known class
	}

	// TODO(bazel-team): move the following few type-related functions to SkylarkType
	/**
	* Return the Skylark-type of {@code c}
	*
	* <p>The result will be a type that Skylark understands and is either equal to {@code c}
	* or is a supertype of it. For example, all instances of (all subclasses of) SkylarkList
	* are considered to be SkylarkLists.
	*
	* <p>Skylark's type validation isn't equipped to deal with inheritance so we must tell it which
	* of the superclasses or interfaces of {@code c} is the one that matters for type compatibility.
	*
	* @param c a class
	* @return a super-class of c to be used in validation-time type inference.
	*/
	public static Class<?> getSkylarkType(Class<?> c) {
	// TODO(bazel-team): Iterable and Class likely do not belong here.
	if (String.class.equals(c)
	\|\| Boolean.class.equals(c)
	\|\| Integer.class.equals(c)
	\|\| Iterable.class.equals(c)
	\|\| Class.class.equals(c)) {
	return c;
	}
	// TODO(bazel-team): We should require all Skylark-addressable values that aren't builtin types
	// (String/Boolean/Integer) to implement SkylarkValue. We should also require them to have a
	// (possibly inherited) @SkylarkModule annotation.
	Class<?> parent = SkylarkInterfaceUtils.getParentWithSkylarkModule(c);
	if (parent != null) {
	return parent;
	}
	Preconditions.checkArgument(
	SkylarkValue.class.isAssignableFrom(c),
	"%s is not allowed as a Starlark value (getSkylarkType() failed)",
	c);
	return c;
	}

	/**
	* Returns a pretty name for the datatype of object 'o' in the Build language.
	*/
	public static String getDataTypeName(Object o) {
	return getDataTypeName(o, false);
	}

	/**
	* Returns a pretty name for the datatype of object {@code object} in Skylark
	* or the BUILD language, with full details if the {@code full} boolean is true.
	*/
	public static String getDataTypeName(Object object, boolean fullDetails) {
	Preconditions.checkNotNull(object);
	if (fullDetails) {
	if (object instanceof SkylarkNestedSet) {
	SkylarkNestedSet set = (SkylarkNestedSet) object;
	return "depset of " + set.getContentType() + "s";
	}
	if (object instanceof SelectorList) {
	SelectorList list = (SelectorList) object;
	return "select of " + getDataTypeNameFromClass(list.getType());
	}
	}
	return getDataTypeNameFromClass(object.getClass());
	}

	/**
	* Returns a pretty name for the datatype equivalent of class 'c' in the Build language.
	*/
	public static String getDataTypeNameFromClass(Class<?> c) {
	return getDataTypeNameFromClass(c, true);
	}

	/**
	* Returns a pretty name for the datatype equivalent of class 'c' in the Build language.
	* @param highlightNameSpaces Determines whether the result should also contain a special comment
	* when the given class identifies a Skylark name space.
	*/
	public static String getDataTypeNameFromClass(Class<?> c, boolean highlightNameSpaces) {
	SkylarkModule module = SkylarkInterfaceUtils.getSkylarkModule(c);
	if (module != null) {
	return module.name()
	+ ((module.namespace() && highlightNameSpaces) ? " (a language module)" : "");
	} else if (c.equals(Object.class)) {
	return "unknown";
	} else if (c.equals(String.class)) {
	return "string";
	} else if (c.equals(Integer.class)) {
	return "int";
	} else if (c.equals(Boolean.class)) {
	return "bool";
	} else if (List.class.isAssignableFrom(c)) { // This is a Java List that isn't a SkylarkList
	return "List"; // This case shouldn't happen in normal code, but we keep it for debugging.
	} else if (Map.class.isAssignableFrom(c)) { // This is a Java Map that isn't a SkylarkDict
	return "Map"; // This case shouldn't happen in normal code, but we keep it for debugging.
	} else if (StarlarkFunction.class.isAssignableFrom(c)) {
	return "function";
	} else if (c.equals(SelectorValue.class)) {
	return "select";
	} else if (NestedSet.class.isAssignableFrom(c)) {
	// TODO(bazel-team): no one should be seeing naked NestedSet at all.
	return "depset";
	} else {
	if (c.getSimpleName().isEmpty()) {
	return c.getName();
	} else {
	return c.getSimpleName();
	}
	}
	}

	public static Object checkNotNull(Expression expr, Object obj) throws EvalException {
	if (obj == null) {
	throw new EvalException(
	expr.getLocation(),
	"unexpected null value, please send a bug report. "
	+ "This was generated by expression '"
	+ expr
	+ "'");
	}
	return obj;
	}

	/**
	* Returns the truth value of an object, according to Python rules.
	* http://docs.python.org/2/library/stdtypes.html#truth-value-testing
	*/
	public static boolean toBoolean(Object o) {
	if (o == null \|\| o == Runtime.NONE) {
	return false;
	} else if (o instanceof Boolean) {
	return (Boolean) o;
	} else if (o instanceof String) {
	return !((String) o).isEmpty();
	} else if (o instanceof Integer) {
	return (Integer) o != 0;
	} else if (o instanceof Collection<?>) {
	return !((Collection<?>) o).isEmpty();
	} else if (o instanceof Map<?, ?>) {
	return !((Map<?, ?>) o).isEmpty();
	} else if (o instanceof NestedSet<?>) {
	return !((NestedSet<?>) o).isEmpty();
	} else if (o instanceof SkylarkNestedSet) {
	return !((SkylarkNestedSet) o).isEmpty();
	} else if (o instanceof Iterable<?>) {
	return !Iterables.isEmpty((Iterable<?>) o);
	} else {
	return true;
	}
	}

	public static Collection<?> toCollection(Object o, Location loc, @Nullable Environment env)
	throws EvalException {
	if (o instanceof Collection) {
	return (Collection<?>) o;
	} else if (o instanceof SkylarkList) {
	return ((SkylarkList) o).getImmutableList();
	} else if (o instanceof Map) {
	// For dictionaries we iterate through the keys only
	if (o instanceof SkylarkDict) {
	// SkylarkDicts handle ordering themselves
	SkylarkDict<?, ?> dict = (SkylarkDict) o;
	List<Object> list = Lists.newArrayListWithCapacity(dict.size());
	for (Map.Entry<?, ?> entries : dict.entrySet()) {
	list.add(entries.getKey());
	}
	return ImmutableList.copyOf(list);
	}
	// For determinism, we sort the keys.
	try {
	return SKYLARK_COMPARATOR.sortedCopy(((Map<?, ?>) o).keySet());
	} catch (ComparisonException e) {
	throw new EvalException(loc, e);
	}
	} else if (o instanceof SkylarkNestedSet) {
	return nestedSetToCollection((SkylarkNestedSet) o, loc, env);
	} else {
	throw new EvalException(loc,
	"type '" + getDataTypeName(o) + "' is not a collection");
	}
	}

	private static Collection<?> nestedSetToCollection(
	SkylarkNestedSet set, Location loc, @Nullable Environment env) throws EvalException {
	if (env != null && env.getSemantics().incompatibleDepsetIsNotIterable()) {
	throw new EvalException(
	loc,
	"type 'depset' is not iterable. Use the `to_list()` method to get a list. Use "
	+ "--incompatible_depset_is_not_iterable=false to temporarily disable this check.");
	}
	return set.toCollection();
	}

	public static Iterable<?> toIterable(Object o, Location loc, @Nullable Environment env)
	throws EvalException {
	if (o instanceof SkylarkNestedSet) {
	return nestedSetToCollection((SkylarkNestedSet) o, loc, env);
	} else if (o instanceof Iterable) {
	return (Iterable<?>) o;
	} else if (o instanceof Map) {
	return toCollection(o, loc, env);
	} else {
	throw new EvalException(loc,
	"type '" + getDataTypeName(o) + "' is not iterable");
	}
	}

	/**
	* Given an {@link Iterable}, returns it as-is. Given a {@link SkylarkNestedSet}, returns its
	* contents as an iterable. Throws {@link EvalException} for any other value.
	*
	* <p>This is a kludge for the change that made {@code SkylarkNestedSet} not implement {@code
	* Iterable}. It is different from {@link #toIterable} in its behavior for strings and other types
	* that are not strictly Java-iterable.
	*
	* @throws EvalException if {@code o} is not an iterable or set
	* @deprecated avoid writing APIs that implicitly treat depsets as iterables. It encourages
	* unnecessary flattening of depsets.
	* <p>TODO(bazel-team): Remove this if/when implicit iteration over {@code SkylarkNestedSet}
	* is no longer supported.
	*/
	@Deprecated
	public static Iterable<?> toIterableStrict(Object o, Location loc, @Nullable Environment env)
	throws EvalException {
	if (o instanceof Iterable) {
	return (Iterable<?>) o;
	} else if (o instanceof SkylarkNestedSet) {
	return nestedSetToCollection((SkylarkNestedSet) o, loc, env);
	} else {
	throw new EvalException(loc,
	"expected Iterable or depset, but got '" + getDataTypeName(o) + "' (strings and maps "
	+ "are not allowed here)");
	}
	}

	public static void lock(Object object, Location loc) {
	if (object instanceof SkylarkMutable) {
	((SkylarkMutable) object).lock(loc);
	}
	}

	public static void unlock(Object object, Location loc) {
	if (object instanceof SkylarkMutable) {
	((SkylarkMutable) object).unlock(loc);
	}
	}

	// The following functions for indexing and slicing match the behavior of Python.

	/**
	* Resolves a positive or negative index to an index in the range [0, length), or throws
	* EvalException if it is out-of-range. If the index is negative, it counts backward from
	* length.
	*/
	public static int getSequenceIndex(int index, int length, Location loc)
	throws EvalException {
	int actualIndex = index;
	if (actualIndex < 0) {
	actualIndex += length;
	}
	if (actualIndex < 0 \|\| actualIndex >= length) {
	throw new EvalException(
	loc,
	"index out of range (index is " + index + ", but sequence has " + length + " elements)");
	}
	return actualIndex;
	}

	/**
	* Performs index resolution after verifying that the given object has index type.
	*/
	public static int getSequenceIndex(Object index, int length, Location loc)
	throws EvalException {
	if (!(index instanceof Integer)) {
	throw new EvalException(
	loc, "indices must be integers, not " + EvalUtils.getDataTypeName(index));
	}
	return getSequenceIndex(((Integer) index).intValue(), length, loc);
	}

	/**
	* Resolves a positive or negative index to an integer that can denote the left or right boundary
	* of a slice. If reverse is false, the slice has positive stride (i.e., its elements are in their
	* normal order) and the result is guaranteed to be in range [0, length + 1). If reverse is true,
	* the slice has negative stride and the result is in range [-1, length). In either case, if the
	* index is negative, it counts backward from length. Note that an input index of -1 represents
	* the last element's position, while an output integer of -1 represents the imaginary position
	* to the left of the first element.
	*/
	public static int clampRangeEndpoint(int index, int length, boolean reverse) {
	if (index < 0) {
	index += length;
	}
	if (!reverse) {
	return Math.max(Math.min(index, length), 0);
	} else {
	return Math.max(Math.min(index, length - 1), -1);
	}
	}

	/**
	* Resolves a positive or negative index to an integer that can denote the boundary for a
	* slice with positive stride.
	*/
	public static int clampRangeEndpoint(int index, int length) {
	return clampRangeEndpoint(index, length, false);
	}

	/**
	* Calculates the indices of the elements that should be included in the slice [start:end:step]
	* of a sequence with the given length. Each of start, end, and step must be supplied, and step
	* may not be 0.
	*/
	public static List<Integer> getSliceIndices(int start, int end, int step, int length) {
	if (step == 0) {
	throw new IllegalArgumentException("Slice step cannot be zero");
	}
	start = clampRangeEndpoint(start, length, step < 0);
	end = clampRangeEndpoint(end, length, step < 0);
	// precise computation is slightly more involved, but since it can overshoot only by a single
	// element it's fine
	final int expectedMaxSize = Math.abs(start - end) / Math.abs(step) + 1;
	ImmutableList.Builder<Integer> indices = ImmutableList.builderWithExpectedSize(expectedMaxSize);
	for (int current = start; step > 0 ? current < end : current > end; current += step) {
	indices.add(current);
	}
	return indices.build();
	}

	/**
	* Calculates the indices of the elements in a slice, after validating the arguments and replacing
	* Runtime.NONE with default values. Throws an EvalException if a bad argument is given.
	*/
	public static List<Integer> getSliceIndices(
	Object startObj, Object endObj, Object stepObj, int length, Location loc)
	throws EvalException {
	int start;
	int end;
	int step;

	if (stepObj == Runtime.NONE) {
	step = 1;
	} else if (stepObj instanceof Integer) {
	step = ((Integer) stepObj).intValue();
	} else {
	throw new EvalException(
	loc, String.format("slice step must be an integer, not '%s'", stepObj));
	}
	if (step == 0) {
	throw new EvalException(loc, "slice step cannot be zero");
	}

	if (startObj == Runtime.NONE) {
	start = (step > 0) ? 0 : length - 1;
	} else if (startObj instanceof Integer) {
	start = ((Integer) startObj).intValue();
	} else {
	throw new EvalException(
	loc, String.format("slice start must be an integer, not '%s'", startObj));
	}
	if (endObj == Runtime.NONE) {
	// If step is negative, can't use -1 for end since that would be converted
	// to the rightmost element's position.
	end = (step > 0) ? length : -length - 1;
	} else if (endObj instanceof Integer) {
	end = ((Integer) endObj).intValue();
	} else {
	throw new EvalException(loc, String.format("slice end must be an integer, not '%s'", endObj));
	}

	return getSliceIndices(start, end, step, length);
	}

	/** @return true if x is Java null or Skylark None */
	public static boolean isNullOrNone(Object x) {
	return x == null \|\| x == Runtime.NONE;
	}

	/**
	* Build a SkylarkDict of kwarg arguments from a list, removing null-s or None-s.
	*
	* @param env the Environment in which this map can be mutated.
	* @param init a series of key, value pairs (as consecutive arguments)
	* as in {@code optionMap(k1, v1, k2, v2, k3, v3)}
	* where each key is a String, each value is an arbitrary Objet.
	* @return a {@code Map<String, Object>} that has all the specified entries,
	* where key, value pairs appearing earlier have precedence,
	* i.e. {@code k1, v1} may override {@code k3, v3}.
	*
	* Ignore any entry where the value is null or None.
	* Keys cannot be null.
	*/
	@SuppressWarnings("unchecked")
	public static <K, V> SkylarkDict<K, V> optionMap(Environment env, Object... init) {
	ImmutableMap.Builder<K, V> b = new ImmutableMap.Builder<>();
	Preconditions.checkState(init.length % 2 == 0);
	for (int i = init.length - 2; i >= 0; i -= 2) {
	K key = (K) Preconditions.checkNotNull(init[i]);
	V value = (V) init[i + 1];
	if (!isNullOrNone(value)) {
	b.put(key, value);
	}
	}
	return SkylarkDict.copyOf(env, b.build());
	}
	}