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mirror of https://github.com/janet-lang/janet synced 2024-11-25 17:57:17 +00:00
janet/src/core/array.c
2021-07-24 16:58:21 -04:00

393 lines
14 KiB
C

/*
* Copyright (c) 2021 Calvin Rose
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*/
#ifndef JANET_AMALG
#include "features.h"
#include <janet.h>
#include "gc.h"
#include "util.h"
#include "state.h"
#endif
#include <string.h>
/* Creates a new array */
JanetArray *janet_array(int32_t capacity) {
JanetArray *array = janet_gcalloc(JANET_MEMORY_ARRAY, sizeof(JanetArray));
Janet *data = NULL;
if (capacity > 0) {
janet_vm.next_collection += capacity * sizeof(Janet);
data = (Janet *) janet_malloc(sizeof(Janet) * (size_t) capacity);
if (NULL == data) {
JANET_OUT_OF_MEMORY;
}
}
array->count = 0;
array->capacity = capacity;
array->data = data;
return array;
}
/* Creates a new array from n elements. */
JanetArray *janet_array_n(const Janet *elements, int32_t n) {
JanetArray *array = janet_gcalloc(JANET_MEMORY_ARRAY, sizeof(JanetArray));
array->capacity = n;
array->count = n;
array->data = janet_malloc(sizeof(Janet) * (size_t) n);
if (!array->data) {
JANET_OUT_OF_MEMORY;
}
safe_memcpy(array->data, elements, sizeof(Janet) * n);
return array;
}
/* Ensure the array has enough capacity for elements */
void janet_array_ensure(JanetArray *array, int32_t capacity, int32_t growth) {
Janet *newData;
Janet *old = array->data;
if (capacity <= array->capacity) return;
int64_t new_capacity = ((int64_t) capacity) * growth;
if (new_capacity > INT32_MAX) new_capacity = INT32_MAX;
capacity = (int32_t) new_capacity;
newData = janet_realloc(old, capacity * sizeof(Janet));
if (NULL == newData) {
JANET_OUT_OF_MEMORY;
}
janet_vm.next_collection += (capacity - array->capacity) * sizeof(Janet);
array->data = newData;
array->capacity = capacity;
}
/* Set the count of an array. Extend with nil if needed. */
void janet_array_setcount(JanetArray *array, int32_t count) {
if (count < 0)
return;
if (count > array->count) {
int32_t i;
janet_array_ensure(array, count, 1);
for (i = array->count; i < count; i++) {
array->data[i] = janet_wrap_nil();
}
}
array->count = count;
}
/* Push a value to the top of the array */
void janet_array_push(JanetArray *array, Janet x) {
if (array->count == INT32_MAX) {
janet_panic("array overflow");
}
int32_t newcount = array->count + 1;
janet_array_ensure(array, newcount, 2);
array->data[array->count] = x;
array->count = newcount;
}
/* Pop a value from the top of the array */
Janet janet_array_pop(JanetArray *array) {
if (array->count) {
return array->data[--array->count];
} else {
return janet_wrap_nil();
}
}
/* Look at the last value in the array */
Janet janet_array_peek(JanetArray *array) {
if (array->count) {
return array->data[array->count - 1];
} else {
return janet_wrap_nil();
}
}
/* C Functions */
static Janet cfun_array_new(int32_t argc, Janet *argv) {
janet_fixarity(argc, 1);
int32_t cap = janet_getinteger(argv, 0);
JanetArray *array = janet_array(cap);
return janet_wrap_array(array);
}
static Janet cfun_array_new_filled(int32_t argc, Janet *argv) {
janet_arity(argc, 1, 2);
int32_t count = janet_getinteger(argv, 0);
Janet x = (argc == 2) ? argv[1] : janet_wrap_nil();
JanetArray *array = janet_array(count);
for (int32_t i = 0; i < count; i++) {
array->data[i] = x;
}
array->count = count;
return janet_wrap_array(array);
}
static Janet cfun_array_fill(int32_t argc, Janet *argv) {
janet_arity(argc, 1, 2);
JanetArray *array = janet_getarray(argv, 0);
Janet x = (argc == 2) ? argv[1] : janet_wrap_nil();
for (int32_t i = 0; i < array->count; i++) {
array->data[i] = x;
}
return argv[0];
}
static Janet cfun_array_pop(int32_t argc, Janet *argv) {
janet_fixarity(argc, 1);
JanetArray *array = janet_getarray(argv, 0);
return janet_array_pop(array);
}
static Janet cfun_array_peek(int32_t argc, Janet *argv) {
janet_fixarity(argc, 1);
JanetArray *array = janet_getarray(argv, 0);
return janet_array_peek(array);
}
static Janet cfun_array_push(int32_t argc, Janet *argv) {
janet_arity(argc, 1, -1);
JanetArray *array = janet_getarray(argv, 0);
if (INT32_MAX - argc + 1 <= array->count) {
janet_panic("array overflow");
}
int32_t newcount = array->count - 1 + argc;
janet_array_ensure(array, newcount, 2);
if (argc > 1) memcpy(array->data + array->count, argv + 1, (size_t)(argc - 1) * sizeof(Janet));
array->count = newcount;
return argv[0];
}
static Janet cfun_array_ensure(int32_t argc, Janet *argv) {
janet_fixarity(argc, 3);
JanetArray *array = janet_getarray(argv, 0);
int32_t newcount = janet_getinteger(argv, 1);
int32_t growth = janet_getinteger(argv, 2);
if (newcount < 1) janet_panic("expected positive integer");
janet_array_ensure(array, newcount, growth);
return argv[0];
}
static Janet cfun_array_slice(int32_t argc, Janet *argv) {
JanetView view = janet_getindexed(argv, 0);
JanetRange range = janet_getslice(argc, argv);
JanetArray *array = janet_array(range.end - range.start);
if (array->data)
memcpy(array->data, view.items + range.start, sizeof(Janet) * (range.end - range.start));
array->count = range.end - range.start;
return janet_wrap_array(array);
}
static Janet cfun_array_concat(int32_t argc, Janet *argv) {
int32_t i;
janet_arity(argc, 1, -1);
JanetArray *array = janet_getarray(argv, 0);
for (i = 1; i < argc; i++) {
switch (janet_type(argv[i])) {
default:
janet_array_push(array, argv[i]);
break;
case JANET_ARRAY:
case JANET_TUPLE: {
int32_t j, len = 0;
const Janet *vals = NULL;
janet_indexed_view(argv[i], &vals, &len);
for (j = 0; j < len; j++)
janet_array_push(array, vals[j]);
}
break;
}
}
return janet_wrap_array(array);
}
static Janet cfun_array_insert(int32_t argc, Janet *argv) {
size_t chunksize, restsize;
janet_arity(argc, 2, -1);
JanetArray *array = janet_getarray(argv, 0);
int32_t at = janet_getinteger(argv, 1);
if (at < 0) {
at = array->count + at + 1;
}
if (at < 0 || at > array->count)
janet_panicf("insertion index %d out of range [0,%d]", at, array->count);
chunksize = (argc - 2) * sizeof(Janet);
restsize = (array->count - at) * sizeof(Janet);
if (INT32_MAX - (argc - 2) < array->count) {
janet_panic("array overflow");
}
janet_array_ensure(array, array->count + argc - 2, 2);
if (restsize) {
memmove(array->data + at + argc - 2,
array->data + at,
restsize);
}
safe_memcpy(array->data + at, argv + 2, chunksize);
array->count += (argc - 2);
return argv[0];
}
static Janet cfun_array_remove(int32_t argc, Janet *argv) {
janet_arity(argc, 2, 3);
JanetArray *array = janet_getarray(argv, 0);
int32_t at = janet_getinteger(argv, 1);
int32_t n = 1;
if (at < 0) {
at = array->count + at + 1;
}
if (at < 0 || at > array->count)
janet_panicf("removal index %d out of range [0,%d]", at, array->count);
if (argc == 3) {
n = janet_getinteger(argv, 2);
if (n < 0)
janet_panicf("expected non-negative integer for argument n, got %v", argv[2]);
}
if (at + n > array->count) {
n = array->count - at;
}
memmove(array->data + at,
array->data + at + n,
(array->count - at - n) * sizeof(Janet));
array->count -= n;
return argv[0];
}
static Janet cfun_array_trim(int32_t argc, Janet *argv) {
janet_fixarity(argc, 1);
JanetArray *array = janet_getarray(argv, 0);
if (array->count) {
if (array->count < array->capacity) {
Janet *newData = janet_realloc(array->data, array->count * sizeof(Janet));
if (NULL == newData) {
JANET_OUT_OF_MEMORY;
}
array->data = newData;
array->capacity = array->count;
}
} else {
array->capacity = 0;
janet_free(array->data);
array->data = NULL;
}
return argv[0];
}
static Janet cfun_array_clear(int32_t argc, Janet *argv) {
janet_fixarity(argc, 1);
JanetArray *array = janet_getarray(argv, 0);
array->count = 0;
return argv[0];
}
static const JanetReg array_cfuns[] = {
{
"array/new", cfun_array_new,
JDOC("(array/new capacity)\n\n"
"Creates a new empty array with a pre-allocated capacity. The same as "
"(array) but can be more efficient if the maximum size of an array is known.")
},
{
"array/new-filled", cfun_array_new_filled,
JDOC("(array/new-filled count &opt value)\n\n"
"Creates a new array of `count` elements, all set to `value`, which defaults to nil. Returns the new array.")
},
{
"array/fill", cfun_array_fill,
JDOC("(array/fill arr &opt value)\n\n"
"Replace all elements of an array with `value` (defaulting to nil) without changing the length of the array. "
"Returns the modified array.")
},
{
"array/pop", cfun_array_pop,
JDOC("(array/pop arr)\n\n"
"Remove the last element of the array and return it. If the array is empty, will return nil. Modifies "
"the input array.")
},
{
"array/peek", cfun_array_peek,
JDOC("(array/peek arr)\n\n"
"Returns the last element of the array. Does not modify the array.")
},
{
"array/push", cfun_array_push,
JDOC("(array/push arr x)\n\n"
"Insert an element in the end of an array. Modifies the input array and returns it.")
},
{
"array/ensure", cfun_array_ensure,
JDOC("(array/ensure arr capacity growth)\n\n"
"Ensures that the memory backing the array is large enough for `capacity` "
"items at the given rate of growth. Capacity and growth must be integers. "
"If the backing capacity is already enough, then this function does nothing. "
"Otherwise, the backing memory will be reallocated so that there is enough space.")
},
{
"array/slice", cfun_array_slice,
JDOC("(array/slice arrtup &opt start end)\n\n"
"Takes a slice of array or tuple from `start` to `end`. The range is half open, "
"[start, end). Indexes can also be negative, indicating indexing from the "
"end of the array. By default, `start` is 0 and `end` is the length of the array. "
"Note that index -1 is synonymous with index `(length arrtup)` to allow a full "
"negative slice range. Returns a new array.")
},
{
"array/concat", cfun_array_concat,
JDOC("(array/concat arr & parts)\n\n"
"Concatenates a variable number of arrays (and tuples) into the first argument, "
"which must be an array. If any of the parts are arrays or tuples, their elements will "
"be inserted into the array. Otherwise, each part in `parts` will be appended to `arr` in order. "
"Return the modified array `arr`.")
},
{
"array/insert", cfun_array_insert,
JDOC("(array/insert arr at & xs)\n\n"
"Insert all `xs` into array `arr` at index `at`. `at` should be an integer between "
"0 and the length of the array. A negative value for `at` will index backwards from "
"the end of the array, such that inserting at -1 appends to the array. "
"Returns the array.")
},
{
"array/remove", cfun_array_remove,
JDOC("(array/remove arr at &opt n)\n\n"
"Remove up to `n` elements starting at index `at` in array `arr`. `at` can index from "
"the end of the array with a negative index, and `n` must be a non-negative integer. "
"By default, `n` is 1. "
"Returns the array.")
},
{
"array/trim", cfun_array_trim,
JDOC("(array/trim arr)\n\n"
"Set the backing capacity of an array to its current length. Returns the modified array.")
},
{
"array/clear", cfun_array_clear,
JDOC("(array/clear arr)\n\n"
"Empties an array, setting it's count to 0 but does not free the backing capacity. "
"Returns the modified array.")
},
{NULL, NULL, NULL}
};
/* Load the array module */
void janet_lib_array(JanetTable *env) {
janet_core_cfuns(env, NULL, array_cfuns);
}