Vector
vector<T> is the only primitive collection type provided by Move. A vector<T> is a homogenous
collection of T's that can grow or shrink by pushing/popping values off the "end".
A vector<T> can be instantiated with any type T. For example, vector<u64>, vector<address>,
vector<0x42::MyModule::MyResource>, and vector<vector<u8>> are all valid vector types.
Literals
General vector Literals
Vectors of any type can be created with vector literals.
| Syntax | Type | Description |
|---|---|---|
vector[] | vector[]: vector<T> where T is any single, non-reference type | An empty vector |
vector[e1, ..., en] | vector[e1, ..., en]: vector<T> where e_i: T s.t. 0 < i <= n and n > 0 | A vector with n elements (of length n) |
In these cases, the type of the vector is inferred, either from the element type or from the
vector's usage. If the type cannot be inferred, or simply for added clarity, the type can be
specified explicitly:
vector<T>[]: vector<T>
vector<T>[e1, ..., en]: vector<T>
Example Vector Literals
(vector[]: vector<bool>);
(vector[0u8, 1u8, 2u8]: vector<u8>);
(vector<u128>[]: vector<u128>);
(vector<address>[@0x42, @0x100]: vector<address>);
vector<u8> literals
A common use-case for vectors in Move is to represent "byte arrays", which are represented with
vector<u8>. These values are often used for cryptographic purposes, such as a public key or a hash
result. These values are so common that specific syntax is provided to make the values more
readable, as opposed to having to use vector[] where each individual u8 value is specified in
numeric form.
There are currently two supported types of vector<u8> literals, byte strings and hex strings.
Byte Strings
Byte strings are quoted string literals prefixed by a b, e.g. b"Hello!\n".
These are ASCII encoded strings that allow for escape sequences. Currently, the supported escape sequences are:
| Escape Sequence | Description |
|---|---|
\n | New line (or Line feed) |
\r | Carriage return |
\t | Tab |
\\ | Backslash |
\0 | Null |
\" | Quote |
\xHH | Hex escape, inserts the hex byte sequence HH |
Hex Strings
Hex strings are quoted string literals prefixed by a x, e.g. x"48656C6C6F210A".
Each byte pair, ranging from 00 to FF, is interpreted as hex encoded u8 value. So each byte
pair corresponds to a single entry in the resulting vector<u8>.
Example String Literals
script {
fun byte_and_hex_strings() {
assert!(b"" == x"", 0);
assert!(b"Hello!\n" == x"48656C6C6F210A", 1);
assert!(b"\x48\x65\x6C\x6C\x6F\x21\x0A" == x"48656C6C6F210A", 2);
assert!(
b"\"Hello\tworld!\"\n \r \\Null=\0" ==
x"2248656C6C6F09776F726C6421220A200D205C4E756C6C3D00",
3
);
}
}
Operations
vector provides several operations via the std::vector module in the Move standard
library, as shown below. More operations may be added over time.
Up-to-date document on vector can be found here.
| Function | Description | Aborts? |
|---|---|---|
vector::empty<T>(): vector<T> | Create an empty vector that can store values of type T | Never |
vector::is_empty<T>(): bool | Return true if the vector v has no elements and false otherwise. | Never |
vector::singleton<T>(t: T): vector<T> | Create a vector of size 1 containing t | Never |
vector::length<T>(v: &vector<T>): u64 | Return the length of the vector v | Never |
vector::push_back<T>(v: &mut vector<T>, t: T) | Add t to the end of v | Never |
vector::pop_back<T>(v: &mut vector<T>): T | Remove and return the last element in v | If v is empty |
vector::borrow<T>(v: &vector<T>, i: u64): &T | Return an immutable reference to the T at index i | If i is not in bounds |
vector::borrow_mut<T>(v: &mut vector<T>, i: u64): &mut T | Return a mutable reference to the T at index i | If i is not in bounds |
vector::destroy_empty<T>(v: vector<T>) | Delete v | If v is not empty |
vector::append<T>(v1: &mut vector<T>, v2: vector<T>) | Add the elements in v2 to the end of v1 | Never |
vector::reverse_append<T>(lhs: &mut vector<T>, other: vector<T>) | Pushes all of the elements of the other vector into the lhs vector, in the reverse order as they occurred in other | Never |
vector::contains<T>(v: &vector<T>, e: &T): bool | Return true if e is in the vector v. Otherwise, returns false | Never |
vector::swap<T>(v: &mut vector<T>, i: u64, j: u64) | Swaps the elements at the ith and jth indices in the vector v | If i or j is out of bounds |
vector::reverse<T>(v: &mut vector<T>) | Reverses the order of the elements in the vector v in place | Never |
vector::reverse_slice<T>(v: &mut vector<T>, l: u64, r: u64) | Reverses the order of the elements [l, r) in the vector v in place | Never |
vector::index_of<T>(v: &vector<T>, e: &T): (bool, u64) | Return (true, i) if e is in the vector v at index i. Otherwise, returns (false, 0) | Never |
vector::insert<T>(v: &mut vector<T>, i: u64, e: T) | Insert a new element e at position 0 <= i <= length, using O(length - i) time | If i is out of bounds |
vector::remove<T>(v: &mut vector<T>, i: u64): T | Remove the ith element of the vector v, shifting all subsequent elements. This is O(n) and preserves ordering of elements in the vector | If i is out of bounds |
vector::swap_remove<T>(v: &mut vector<T>, i: u64): T | Swap the ith element of the vector v with the last element and then pop the element, This is O(1), but does not preserve ordering of elements in the vector | If i is out of bounds |
vector::trim<T>(v: &mut vector<T>, new_len: u64): u64 | Trim the vector v to the smaller size new_len and return the evicted elements in order | new_len is larger than the length of v |
vector::trim_reverse<T>(v: &mut vector<T>, new_len: u64): u64 | Trim the vector v to the smaller size new_len and return the evicted elements in the reverse order | new_len is larger than the length of v |
vector::rotate<T>(v: &mut vector<T>, rot: u64): u64 | rotate(&mut [1, 2, 3, 4, 5], 2) -> [3, 4, 5, 1, 2] in place, returns the split point ie. 3 in this example | Never |
vector::rotate_slice<T>(v: &mut vector<T>, left: u64, rot: u64, right: u64): u64 | rotate a slice [left, right) with left <= rot <= right in place, returns the split point | Never |
Example
use std::vector;
let v = vector::empty<u64>();
vector::push_back(&mut v, 5);
vector::push_back(&mut v, 6);
assert!(*vector::borrow(&v, 0) == 5, 42);
assert!(*vector::borrow(&v, 1) == 6, 42);
assert!(vector::pop_back(&mut v) == 6, 42);
assert!(vector::pop_back(&mut v) == 5, 42);
Destroying and copying vectors
Some behaviors of vector<T> depend on the abilities of the element type, T. For example, vectors
containing elements that do not have drop cannot be implicitly discarded like v in the example
above--they must be explicitly destroyed with vector::destroy_empty.
Note that vector::destroy_empty will abort at runtime unless vec contains zero elements:
fun destroy_any_vector<T>(vec: vector<T>) {
vector::destroy_empty(vec) // deleting this line will cause a compiler error
}
But no error would occur for dropping a vector that contains elements with drop:
fun destroy_droppable_vector<T: drop>(vec: vector<T>) {
// valid!
// nothing needs to be done explicitly to destroy the vector
}
Similarly, vectors cannot be copied unless the element type has copy. In other words, a
vector<T> has copy if and only if T has copy.
For more details see the sections on type abilities and generics.
Ownership
As mentioned above, vector values can be copied only if the
elements can be copied.