Our volunteers haven't translated this article into فارسی yet. Join us and help get the job done!
There are four equality algorithms in ES2015:
- Abstract Equality Comparison (
==
) - Strict Equality Comparison (
===
): used byArray.prototype.indexOf
,Array.prototype.lastIndexOf
, andcase
-matching - SameValueZero: used by
%TypedArray%
andArrayBuffer
constructors, as well asMap
andSet
operations, and up-comingString.prototype.includes
in ES2016 - SameValue: used in all other places
JavaScript provides three different value-comparison operations:
- strict equality (or "triple equals" or "identity") using ===,
- loose equality ("double equals") using ==,
- and
Object.is
(new in ECMAScript 2015).
The choice of which operation to use depends on what sort of comparison you are looking to perform.
Briefly, double equals will perform a type conversion when comparing two things; triple equals will do the same comparison without type conversion (by simply always returning false if the types differ); and Object.is
will behave the same way as triple equals, but with special handling for NaN
and -0
and +0
so that the last two are not said to be the same, while Object.is(NaN, NaN)
will be true
. (Comparing NaN
with NaN
ordinarily—i.e., using either double equals or triple equals—evaluates to false
, because IEEE 754 says so.) Do note that the distinction between these all have to do with their handling of primitives; none of them compares whether the parameters are conceptually similar in structure. For any non-primitive objects x and y which have the same structure but are distinct objects themselves, all of the above forms will evaluate to false.
Strict equality using ===
Strict equality compares two values for equality. Neither value is implicitly converted to some other value before being compared. If the values have different types, the values are considered unequal. Otherwise, if the values have the same type and are not numbers, they're considered equal if they have the same value. Finally, if both values are numbers, they're considered equal if they're both not NaN
and are the same value, or if one is +0
and one is -0
.
var num = 0; var obj = new String("0"); var str = "0"; var b = false; console.log(num === num); // true console.log(obj === obj); // true console.log(str === str); // true console.log(num === obj); // false console.log(num === str); // false console.log(obj === str); // false console.log(null === undefined); // false console.log(obj === null); // false console.log(obj === undefined); // false
Strict equality is almost always the correct comparison operation to use. For all values except numbers, it uses the obvious semantics: a value is only equal to itself. For numbers it uses slightly different semantics to gloss over two different edge cases. The first is that floating point zero is either positively or negatively signed. This is useful in representing certain mathematical solutions, but as most situations don't care about the difference between +0
and -0
, strict equality treats them as the same value. The second is that floating point includes the concept of a not-a-number value, NaN
, to represent the solution to certain ill-defined mathematical problems: negative infinity added to positive infinity, for example. Strict equality treats NaN
as unequal to every other value -- including itself. (The only case in which (x !== x)
is true
is when x
is NaN
.)
Loose equality using ==
Loose equality compares two values for equality, after converting both values to a common type. After conversions (one or both sides may undergo conversions), the final equality comparison is performed exactly as ===
performs it. Loose equality is symmetric: A == B
always has identical semantics to B == A
for any values of A
and B
(except for the order of applied conversions).
The equality comparison is performed as follows for operands of the various types:
Operand B | |||||||
---|---|---|---|---|---|---|---|
Undefined | Null | Number | String | Boolean | Object | ||
Operand A | Undefined | true |
true |
false |
false |
false |
false |
Null | true |
true |
false |
false |
false |
false |
|
Number | false |
false |
A === B |
A === ToNumber(B) |
A === ToNumber(B) |
A == ToPrimitive(B) |
|
String | false |
false |
ToNumber(A) === B |
A === B |
ToNumber(A) === ToNumber(B) |
A == ToPrimitive(B) |
|
Boolean | false |
false |
ToNumber(A) === B |
ToNumber(A) === ToNumber(B) |
A === B |
ToNumber(A) == ToPrimitive(B) |
|
Object | false |
false |
ToPrimitive(A) == B |
ToPrimitive(A) == B |
ToPrimitive(A) == ToNumber(B) |
A === B |
In the above table, ToNumber(A)
attempts to convert its argument to a number before comparison. Its behavior is equivalent to +A
(the unary + operator). ToPrimitive(A)
attempts to convert its object argument to a primitive value, by attempting to invoke varying sequences of A.toString
and A.valueOf
methods on A
.
Traditionally, and according to ECMAScript, all objects are loosely unequal to undefined
and null
. But most browsers permit a very narrow class of objects (specifically, the document.all
object for any page), in some contexts, to act as if they emulate the value undefined
. Loose equality is one such context: null == A
and undefined == A
evaluate to true if, and only if, A is an object that emulates undefined
. In all other cases an object is never loosely equal to undefined
or null
.
var num = 0; var obj = new String("0"); var str = "0"; var b = false; console.log(num == num); // true console.log(obj == obj); // true console.log(str == str); // true console.log(num == obj); // true console.log(num == str); // true console.log(obj == str); // true console.log(null == undefined); // true // both false, except in rare cases console.log(obj == null); console.log(obj == undefined);
Some developers consider that it is pretty much never a good idea to use loose equality. The result of a comparison using strict equality is easier to predict, and as no type coercion takes place the evaluation may be faster.
Same-value equality
Same-value equality addresses a final use case: determining whether two values are functionally identical in all contexts. (This use case demonstrates an instance of the Liskov substitution principle.) One instance occurs when an attempt is made to mutate an immutable property:
// Add an immutable NEGATIVE_ZERO property to the Number constructor. Object.defineProperty(Number, "NEGATIVE_ZERO", { value: -0, writable: false, configurable: false, enumerable: false }); function attemptMutation(v) { Object.defineProperty(Number, "NEGATIVE_ZERO", { value: v }); }
Object.defineProperty
will throw an exception when attempting to change an immutable property would actually change it, but it does nothing if no actual change is requested. If v
is -0
, no change has been requested, and no error will be thrown. But if v
is +0
, Number.NEGATIVE_ZERO
would no longer have its immutable value. Internally, when an immutable property is redefined, the newly-specified value is compared against the current value using same-value equality.
Same-value equality is provided by the Object.is
method.
Same-value-zero equality
Similar to same-value equality, but considered +0 and -0 equal.
Abstract equality, strict equality, and same value in the specification
In ES5, the comparison performed by ==
is described in Section 11.9.3, The Abstract Equality Algorithm. The ===
comparison is 11.9.6, The Strict Equality Algorithm. (Go look at these. They're brief and readable. Hint: read the strict equality algorithm first.) ES5 also describes, in Section 9.12, The SameValue Algorithm for use internally by the JS engine. It's largely the same as the Strict Equality Algorithm, except that 11.9.6.4 and 9.12.4 differ in handling Number
s. ES2015 simply proposes to expose this algorithm through Object.is
.
We can see that with double and triple equals, with the exception of doing a type check upfront in 11.9.6.1, the Strict Equality Algorithm is a subset of the Abstract Equality Algorithm, because 11.9.6.2–7 correspond to 11.9.3.1.a–f.
A model for understanding equality comparisons?
Prior to ES2015, you might have said of double equals and triple equals that one is an "enhanced" version of the other. For example, someone might say that double equals is an extended version of triple equals, because the former does everything that the latter does, but with type conversion on its operands. E.g., 6 == "6"
. (Alternatively, someone might say that double equals is the baseline, and triple equals is an enhanced version, because it requires the two operands to be the same type, so it adds an extra constraint. Which one is the better model for understanding depends on how you choose to view things.)
However, this way of thinking about the built-in sameness operators is not a model that can be stretched to allow a place for ES2015's Object.is
on this "spectrum". Object.is
isn't simply "looser" than double equals or "stricter" than triple equals, nor does it fit somewhere in between (i.e., being both stricter than double equals, but looser than triple equals). We can see from the sameness comparisons table below that this is due to the way that Object.is
handles NaN
. Notice that if Object.is(NaN, NaN)
evaluated to false
, we could say that it fits on the loose/strict spectrum as an even stricter form of triple equals, one that distinguishes between -0
and +0
. The NaN
handling means this is untrue, however. Unfortunately, Object.is
simply has to be thought of in terms of its specific characteristics, rather than its looseness or strictness with regard to the equality operators.
x | y | == |
=== |
Object.is |
---|---|---|---|---|
undefined |
undefined |
true |
true |
true |
null |
null |
true |
true |
true |
true |
true |
true |
true |
true |
false |
false |
true |
true |
true |
"foo" |
"foo" |
true |
true |
true |
{ foo: "bar" } |
x |
true |
true |
true |
0 |
0 |
true |
true |
true |
+0 |
-0 |
true |
true |
false |
0 |
false |
true |
false |
false |
"" |
false |
true |
false |
false |
"" |
0 |
true |
false |
false |
"0" |
0 |
true |
false |
false |
"17" |
17 |
true |
false |
false |
[1,2] |
"1,2" |
true |
false |
false |
new String("foo") |
"foo" |
true |
false |
false |
null |
undefined |
true |
false |
false |
null |
false |
false |
false |
false |
undefined |
false |
false |
false |
false |
{ foo: "bar" } |
{ foo: "bar" } |
false |
false |
false |
new String("foo") |
new String("foo") |
false |
false |
false |
0 |
null |
false |
false |
false |
0 |
NaN |
false |
false |
false |
"foo" |
NaN |
false |
false |
false |
NaN |
NaN |
false |
false |
true |
When to use Object.is
versus triple equals
Aside from the way it treats NaN
, generally, the only time Object.is
's special behavior towards zeros is likely to be of interest is in the pursuit of certain meta-programming schemes, especially regarding property descriptors when it is desirable for your work to mirror some of the characteristics of Object.defineProperty
. If your use case does not require this, it is suggested to avoid Object.is
and use ===
instead. Even if your requirements involve having comparisons between two NaN
values evaluate to true
, generally it is easier to special-case the NaN
checks (using the isNaN
method available from previous versions of ECMAScript) than it is to work out how surrounding computations might affect the sign of any zeros you encounter in your comparison.
Here's an in-exhaustive list of built-in methods and operators that might cause a distinction between -0
and +0
to manifest itself in your code:
-
It's obvious that negating
0
produces-0
. But the abstraction of an expression can cause-0
to creep in when you don't realize it. For example, consider:let stoppingForce = obj.mass * -obj.velocity
If
obj.velocity
is0
(or computes to0
), a-0
is introduced at that place and propogates out intostoppingForce
.
- It's possible for a
-0
to be introduced into an expression as a return value of these methods in some cases, even when no-0
exists as one of the parameters. E.g., usingMath.pow
to raise-Infinity
to the power of any negative, odd exponent evaluates to-0
. Refer to the documentation for the individual methods.
- It's possible to get a
-0
return value out of these methods in some cases where a-0
exists as one of the parameters. E.g.,Math.min(-0, +0)
evalutes to-0
. Refer to the documentation for the individual methods.
~
<<
>>
- Each of these operators uses the ToInt32 algorithm internally. Since there is only one representation for 0 in the internal 32-bit integer type,
-0
will not survive a round trip after an inverse operation. E.g., bothObject.is(~~(-0), -0)
andObject.is(-0 << 2 >> 2, -0)
evaluate tofalse
.
Relying on Object.is
when the signedness of zeros is not taken into account can be hazardous. Of course, when the intent is to distinguish between -0
and +0
, it does exactly what's desired.