arrays: add rotate_left and rotate_right (#13388)

pull/13404/head weekly.2022.06
playX 2022-02-07 14:20:45 +03:00 committed by GitHub
parent 5df83812a0
commit 4ef7d26133
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2 changed files with 199 additions and 0 deletions

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@ -377,3 +377,156 @@ pub fn binary_search<T>(arr []T, target T) ?int {
}
return error('')
}
// rotate_left rotates the array in-place such that the first `mid` elements of the array move to the end
// while the last `arr.len - mid` elements move to the front. After calling `rotate_left`, the element
// previously at index `mid` will become the first element in the array.
// Example:
// ```v
// mut x := [1,2,3,4,5,6]
// arrays.rotate_left(mut x,2)
// println(x) // [3, 4, 5, 6, 1, 2]
// ```
pub fn rotate_left<T>(mut arr []T, mid int) {
assert mid <= arr.len && mid >= 0
k := arr.len - mid
p := &T(arr.data)
unsafe {
ptr_rotate<T>(mid, &T(usize(voidptr(p)) + usize(sizeof(T)) * usize(mid)), k)
}
}
// rotate_right rotates the array in-place such that the first `arr.len - k` elements of the array move to the end
// while the last `k` elements move to the front. After calling `rotate_right`, the element previously at index `arr.len - k`
// will become the first element in the array.
// Example:
// ```v
// mut x := [1,2,3,4,5,6]
// arrays.rotate_right(mut x, 2)
// println(x) // [5, 6, 1, 2, 3, 4]
// ```
pub fn rotate_right<T>(mut arr []T, k int) {
assert k <= arr.len && k >= 0
mid := arr.len - k
p := &T(arr.data)
unsafe {
ptr_rotate<T>(mid, &T(usize(voidptr(p)) + usize(sizeof(T)) * usize(mid)), k)
}
}
[unsafe]
fn ptr_rotate<T>(left_ int, mid &T, right_ int) {
mut left := usize(left_)
mut right := usize(right_)
for {
delta := if left < right { left } else { right }
if delta <= raw_array_cap<T>() {
break
}
unsafe {
swap_nonoverlapping<T>(&T(usize(voidptr(mid)) - left * usize(sizeof(T))),
&T(usize(voidptr(mid)) + usize(right - delta) * usize(sizeof(T))), int(delta))
}
if left <= right {
right -= delta
} else {
left -= delta
}
}
unsafe {
sz := usize(sizeof(T))
rawarray := C.malloc(raw_array_malloc_size<T>())
dim := &T(usize(voidptr(mid)) - left * sz + right * sz)
if left <= right {
C.memcpy(rawarray, voidptr(usize(voidptr(mid)) - left * sz), left * sz)
C.memmove(voidptr(usize(voidptr(mid)) - left * sz), voidptr(mid), right * sz)
C.memcpy(voidptr(dim), rawarray, left * sz)
} else {
C.memcpy(rawarray, voidptr(mid), right * sz)
C.memmove(voidptr(dim), voidptr(usize(voidptr(mid)) - left * sz), left * sz)
C.memcpy(voidptr(usize(voidptr(mid)) - left * sz), rawarray, right * sz)
}
C.free(rawarray)
}
}
struct Block {
mut:
x u64
y u64
z u64
w u64
}
struct UnalignedBlock {
mut:
x u64
y u64
z u64
w u64
}
const (
extra_size = 32 * sizeof(usize)
)
fn raw_array_cap<T>() usize {
if sizeof(T) > arrays.extra_size {
return 1
} else {
return arrays.extra_size / sizeof(T)
}
}
fn raw_array_malloc_size<T>() usize {
if sizeof(T) > arrays.extra_size {
return usize(sizeof(T)) * 2
} else {
return 32 * usize(sizeof(usize))
}
}
[unsafe]
fn memswap(x voidptr, y voidptr, len usize) {
block_size := sizeof(Block)
mut i := usize(0)
for i + block_size <= len {
mut t_ := Block{}
t := voidptr(&t_)
xi := usize(x) + i
yi := usize(y) + i
unsafe {
C.memcpy(t, voidptr(xi), block_size)
C.memcpy(voidptr(xi), voidptr(yi), block_size)
C.memcpy(t, voidptr(yi), block_size)
}
i += block_size
}
if i < len {
mut t_ := UnalignedBlock{}
t := voidptr(&t_)
rem := len - i
xi := usize(x) + i
yi := usize(y) + i
unsafe {
C.memcpy(t, voidptr(xi), rem)
C.memcpy(voidptr(xi), voidptr(yi), rem)
C.memcpy(voidptr(yi), t, rem)
}
}
}
[unsafe]
fn swap_nonoverlapping<T>(x_ &T, y_ &T, count int) {
x := voidptr(x_)
y := voidptr(y_)
len := usize(sizeof(T)) * usize(count)
unsafe {
memswap(x, y, len)
}
}

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@ -218,3 +218,49 @@ fn test_upper_bound() ? {
assert (upper_bound(b, 4) or { -1 }) == -1
assert upper_bound(c, 2) ? == 2
}
fn test_rotate_right() {
mut x := [1, 2, 3, 4, 5, 6]
rotate_right(mut x, 2)
assert x == [5, 6, 1, 2, 3, 4]
}
fn test_rotate_left() {
mut x := [1, 2, 3, 4, 5, 6]
rotate_left(mut x, 2)
assert x == [3, 4, 5, 6, 1, 2]
}
struct Abc {
x u64 = 1
y u64 = 2
z u64 = 3
}
fn test_rotate_right_struct() {
mut x := [Abc{1, 0, 1}, Abc{2, 0, 1}, Abc{3, 0, 1}, Abc{4, 0, 1},
Abc{5, 0, 1}, Abc{6, 0, 1}]
rotate_right(mut x, 2)
assert x == [Abc{5, 0, 1}, Abc{6, 0, 1}, Abc{1, 0, 1}, Abc{2, 0, 1},
Abc{3, 0, 1}, Abc{4, 0, 1}]
}
fn test_rotate_left_struct() {
mut x := [Abc{1, 0, 1}, Abc{2, 0, 1}, Abc{3, 0, 1}, Abc{4, 0, 1},
Abc{5, 0, 1}, Abc{6, 0, 1}]
rotate_left(mut x, 2)
assert x == [Abc{3, 0, 1}, Abc{4, 0, 1}, Abc{5, 0, 1}, Abc{6, 0, 1},
Abc{1, 0, 1}, Abc{2, 0, 1}]
}
fn test_rotate_right_string() {
mut x := ['x1', 'x2', 'x3', 'x4', 'x5', 'x6']
rotate_right(mut x, 2)
assert x == ['x5', 'x6', 'x1', 'x2', 'x3', 'x4']
}
fn test_rotate_left_string() {
mut x := ['x1', 'x2', 'x3', 'x4', 'x5', 'x6']
rotate_left(mut x, 2)
assert x == ['x3', 'x4', 'x5', 'x6', 'x1', 'x2']
}