JavaScript 类型数组
are array-like objects that provide a mechanism for reading and writing raw binary data in memory buffers.
As you may already know,
Array
objects grow and shrink dynamically and can have any JavaScript value. JavaScript engines perform optimizations so that these arrays are fast.
However, as web applications become more and more powerful, adding features such as audio and video manipulation, access to raw data using WebSockets, and so forth, it has become clear that there are times when it would be helpful for JavaScript code to be able to quickly and easily manipulate raw binary data. This is where typed arrays come in. Each entry in a JavaScript typed array is a raw binary value in one of a number of supported formats, from 8-bit integers to 64-bit floating-point numbers.
However, typed arrays are
not
to be confused with normal arrays, as calling
Array.isArray()
on a typed array returns
false
. Moreover, not all methods available for normal arrays are supported by typed arrays (e.g. push and pop).
To achieve maximum flexibility and efficiency, JavaScript typed arrays split the implementation into
buffers
and
views
. A buffer (implemented by the
ArrayBuffer
object) is an object representing a chunk of data; it has no format to speak of and offers no mechanism for accessing its contents. In order to access the memory contained in a buffer, you need to use a view. A view provides a context — that is, a data type, starting offset, and the number of elements — that turns the data into a typed array.
ArrayBuffer
is a data type that is used to represent a generic, fixed-length binary data buffer. You can't directly manipulate the contents of an
ArrayBuffer
; instead, you create a typed array view or a
DataView
which represents the buffer in a specific format, and use that to read and write the contents of the buffer.
Typed array views have self-descriptive names and provide views for all the usual numeric types like
Int8
,
Uint32
,
Float64
and so forth. There is one special typed array view, the
Uint8ClampedArray
. It clamps the values between 0 and 255. This is useful for
Canvas data processing
, for example.
| Type | 值范围 | Size in bytes | 描述 | Web IDL 类型 | Equivalent C type |
|---|---|---|---|---|---|
Int8Array
|
-128
to
127
|
1 | 8-bit two's complement signed integer |
byte
|
int8_t
|
Uint8Array
|
0
to
255
|
1 | 8-bit unsigned integer |
octet
|
uint8_t
|
Uint8ClampedArray
|
0
to
255
|
1 | 8-bit unsigned integer (clamped) |
octet
|
uint8_t
|
Int16Array
|
-32768
to
32767
|
2 | 16-bit two's complement signed integer |
short
|
int16_t
|
Uint16Array
|
0
to
65535
|
2 | 16-bit unsigned integer |
unsigned short
|
uint16_t
|
Int32Array
|
-2147483648
to
2147483647
|
4 | 32-bit two's complement signed integer |
long
|
int32_t
|
Uint32Array
|
0
to
4294967295
|
4 | 32-bit unsigned integer |
unsigned long
|
uint32_t
|
Float32Array
|
1.2
×
10
-38
to
3.4
×
10
38
|
4 |
32-bit IEEE floating point number (7 significant digits e.g.,
1.123456
)
|
unrestricted float
|
float
|
Float64Array
|
5.0
×
10
-324
to
1.8
×
10
308
|
8 |
64-bit IEEE floating point number (16 significant digits e.g.,
1.123...15
)
|
unrestricted double
|
double
|
BigInt64Array
|
-2
63
to
2
63
-1
|
8 | 64-bit two's complement signed integer |
bigint
|
int64_t (signed long long)
|
BigUint64Array
|
0
to
2
64
-1
|
8 | 64-bit unsigned integer |
bigint
|
uint64_t (unsigned long long)
|
DataView
is a low-level interface that provides a getter/setter API to read and write arbitrary data to the buffer. This is useful when dealing with different types of data, for example. Typed array views are in the native byte-order (see
Endianness
) of your platform. With a
DataView
you are able to control the byte-order. It is big-endian by default and can be set to little-endian in the getter/setter methods.
These are some examples of APIs that make use of typed arrays; there are others, and more are being added all the time.
FileReader.prototype.readAsArrayBuffer()
FileReader.prototype.readAsArrayBuffer()
method starts reading the contents of the specified
Blob
or
File
.
XMLHttpRequest.prototype.send()
XMLHttpRequest
instances'
send()
method now supports typed arrays and
ArrayBuffer
objects as argument.
ImageData.data
Uint8ClampedArray
representing a one-dimensional array containing the data in the RGBA order, with integer values between
0
and
255
包括在内。
First of all, we will need to create a buffer, here with a fixed length of 16-bytes:
let buffer = new ArrayBuffer(16);
At this point, we have a chunk of memory whose bytes are all pre-initialized to 0. There's not a lot we can do with it, though. We can confirm that it is indeed 16 bytes long, and that's about it:
if (buffer.byteLength === 16) {
console.log("Yes, it's 16 bytes.");
} else {
console.log("Oh no, it's the wrong size!");
}
Before we can really work with this buffer, we need to create a view. Let's create a view that treats the data in the buffer as an array of 32-bit signed integers:
let int32View = new Int32Array(buffer);
Now we can access the fields in the array just like a normal array:
for (let i = 0; i < int32View.length; i++) {
int32View[i] = i * 2;
}
This fills out the 4 entries in the array (4 entries at 4 bytes each makes 16 total bytes) with the values
0
,
2
,
4
,和
6
.
Things start to get really interesting when you consider that you can create multiple views onto the same data. For example, given the code above, we can continue like this:
let int16View = new Int16Array(buffer);
for (let i = 0; i < int16View.length; i++) {
console.log('Entry ' + i + ': ' + int16View[i]);
}
Here we create a 16-bit integer view that shares the same buffer as the existing 32-bit view and we output all the values in the buffer as 16-bit integers. Now we get the output
0
,
0
,
2
,
0
,
4
,
0
,
6
,
0
.
You can go a step farther, though. Consider this:
int16View[0] = 32;
console.log('Entry 0 in the 32-bit array is now ' + int32View[0]);
The output from this is
"Entry 0 in the 32-bit array is now 32"
.
In other words, the two arrays are indeed simply viewed on the same data buffer, treating it as different formats. You can do this with any view types .
By combining a single buffer with multiple views of different types, starting at different offsets into the buffer, you can interact with data objects containing multiple data types. This lets you, for example, interact with complex data structures from WebGL , data files, or C structures you need to use while using js-ctypes .
Consider this C structure:
struct someStruct {
unsigned long id;
char username[16];
float amountDue;
};
You can access a buffer containing data in this format like this:
let buffer = new ArrayBuffer(24); // ... read the data into the buffer ... let idView = new Uint32Array(buffer, 0, 1); let usernameView = new Uint8Array(buffer, 4, 16); let amountDueView = new Float32Array(buffer, 20, 1);
Then you can access, for example, the amount due with
amountDueView[0]
.
After processing a typed array, it is sometimes useful to convert it back to a normal array in order to benefit from the
Array
prototype. This can be done using
Array.from()
, or using the following code where
Array.from()
is unsupported.
let typedArray = new Uint8Array([1, 2, 3, 4]),
normalArray = Array.prototype.slice.call(typedArray);
normalArray.length === 4;
normalArray.constructor === Array;
| 规范 |
|---|
|
ECMAScript (ECMA-262)
The definition of 'TypedArray Objects' in that specification. |
| Desktop | Mobile | Server | |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Int8Array
|
Chrome 7 | Edge 12 | Firefox 4 | IE 10 | Opera 11.6 | Safari 5.1 | WebView Android 4 | Chrome Android 18 | Firefox Android 4 | Opera Android 12 | Safari iOS 4.2 | Samsung Internet Android 1.0 | nodejs 0.10 |
Int8Array()
构造函数
|
Chrome 7 | Edge 12 | Firefox 4 | IE 10 | Opera 11.6 | Safari 5.1 | WebView Android 4 | Chrome Android 18 | Firefox Android 4 | Opera Android 12 | Safari iOS 4.2 | Samsung Internet Android 1.0 | nodejs 0.10 |
完整支持
ArrayBuffer
s or typed arrays from
Base64
-encoded strings
StringView
– a C-like representation of strings based on typed arrays