/* * Copyright (c) 2018 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. */ #include #include "gc.h" #include /* Initializes an array */ JanetArray *janet_array_init(JanetArray *array, int32_t capacity) { Janet *data = NULL; if (capacity > 0) { data = (Janet *) malloc(sizeof(Janet) * capacity); if (NULL == data) { JANET_OUT_OF_MEMORY; } } array->count = 0; array->capacity = capacity; array->data = data; return array; } void janet_array_deinit(JanetArray *array) { free(array->data); } /* Creates a new array */ JanetArray *janet_array(int32_t capacity) { JanetArray *array = janet_gcalloc(JANET_MEMORY_ARRAY, sizeof(JanetArray)); return janet_array_init(array, capacity); } /* 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 = malloc(sizeof(Janet) * n); if (!array->data) { JANET_OUT_OF_MEMORY; } 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; capacity *= growth; newData = realloc(old, capacity * sizeof(Janet)); if (NULL == newData) { JANET_OUT_OF_MEMORY; } 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) { 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 int cfun_new(JanetArgs args) { int32_t cap; JanetArray *array; JANET_FIXARITY(args, 1); JANET_ARG_INTEGER(cap, args, 0); array = janet_array(cap); JANET_RETURN_ARRAY(args, array); } static int cfun_pop(JanetArgs args) { JanetArray *array; JANET_FIXARITY(args, 1); JANET_ARG_ARRAY(array, args, 0); JANET_RETURN(args, janet_array_pop(array)); } static int cfun_peek(JanetArgs args) { JanetArray *array; JANET_FIXARITY(args, 1); JANET_ARG_ARRAY(array, args, 0); JANET_RETURN(args, janet_array_peek(array)); } static int cfun_push(JanetArgs args) { JanetArray *array; int32_t newcount; JANET_MINARITY(args, 1); JANET_ARG_ARRAY(array, args, 0); newcount = array->count - 1 + args.n; janet_array_ensure(array, newcount, 2); if (args.n > 1) memcpy(array->data + array->count, args.v + 1, (args.n - 1) * sizeof(Janet)); array->count = newcount; JANET_RETURN(args, args.v[0]); } static int cfun_ensure(JanetArgs args) { JanetArray *array; int32_t newcount; int32_t growth; JANET_FIXARITY(args, 3); JANET_ARG_ARRAY(array, args, 0); JANET_ARG_INTEGER(newcount, args, 1); JANET_ARG_INTEGER(growth, args, 2); if (newcount < 0) JANET_THROW(args, "expected positive integer"); janet_array_ensure(array, newcount, growth); JANET_RETURN(args, args.v[0]); } static int cfun_slice(JanetArgs args) { const Janet *vals; int32_t len; JanetArray *ret; int32_t start, end; JANET_MINARITY(args, 1); JANET_MAXARITY(args, 3); if (!janet_indexed_view(args.v[0], &vals, &len)) JANET_THROW(args, "expected array|tuple"); /* Get start */ if (args.n < 2) { start = 0; } else if (janet_checktype(args.v[1], JANET_INTEGER)) { start = janet_unwrap_integer(args.v[1]); } else { JANET_THROW(args, "expected integer"); } /* Get end */ if (args.n < 3) { end = -1; } else if (janet_checktype(args.v[2], JANET_INTEGER)) { end = janet_unwrap_integer(args.v[2]); } else { JANET_THROW(args, "expected integer"); } if (start < 0) start = len + start; if (end < 0) end = len + end + 1; if (end >= start) { ret = janet_array(end - start); memcpy(ret->data, vals + start, sizeof(Janet) * (end - start)); ret->count = end - start; } else { ret = janet_array(0); } JANET_RETURN_ARRAY(args, ret); } static int cfun_concat(JanetArgs args) { int32_t i; JanetArray *array; JANET_MINARITY(args, 1); JANET_ARG_ARRAY(array, args, 0); for (i = 1; i < args.n; i++) { switch (janet_type(args.v[i])) { default: janet_array_push(array, args.v[i]); break; case JANET_ARRAY: case JANET_TUPLE: { int32_t j, len; const Janet *vals; janet_indexed_view(args.v[i], &vals, &len); for (j = 0; j < len; j++) janet_array_push(array, vals[j]); } break; } } JANET_RETURN_ARRAY(args, array); } static const JanetReg cfuns[] = { {"array.new", cfun_new, "(array.new capacity)\n\n" "Creates a new empty array with a preallocated capacity. The same as " "(array) but can be more efficient if the maximum size of an array is known." }, {"array.pop", cfun_pop, "(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_peek, "(array.peel arr)\n\n" "Returns the last element of the array. Does not modify the array." }, {"array.push", cfun_push, "(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_ensure, "(array.ensure arr capacity)\n\n" "Ensures that the memory backing the array has enough memory for capacity " "items. Capacity must be an integer. 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_slice, "(array.slice arrtup)\n\n" "Returns a copy of an array or tuple.\n\n" "(array.slice arrtup start)\n\n" "Takes a slice of an array or tuple from the index start to the last element. Indexes " "are from 0, or can be negative to index from the end of the array, Where -1 is the last " "element of the array. Returns a new array.\n\n" "(array.slice arrtup 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 " "end of the array. Returns a new array." }, {"array.concat", cfun_concat, "(array.concat arr & parts)\n\n" "Concatenates a variadic number of arrays (and tuples) into the first argument " "which must 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." }, {NULL, NULL, NULL} }; /* Load the array module */ int janet_lib_array(JanetArgs args) { JanetTable *env = janet_env(args); janet_cfuns(env, NULL, cfuns); return 0; }