Sat, 07 May 2022 12:54:19 +0200
fix and simplify chunked transfer encoding
/* * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. * * Copyright 2019 Mike Becker, Olaf Wintermann All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #define _GNU_SOURCE /* we want to use qsort_r(), if available */ #define __STDC_WANT_LIB_EXT1__ 1 /* use qsort_s, if available */ #include "ucx/array.h" #include "ucx/utils.h" #include <string.h> #include <stdlib.h> #include <errno.h> #ifndef UCX_ARRAY_DISABLE_QSORT #ifdef __GLIBC__ #if __GLIBC__ > 2 || (__GLIBC__ == 2 && __GLIBC_MINOR__ >= 8) #define ucx_array_sort_impl qsort_r #endif /* glibc version >= 2.8 */ #elif /* not __GLIBC__ */ defined(__APPLE__) || defined(__FreeBSD__) #define ucx_array_sort_impl ucx_qsort_r #define USE_UCX_QSORT_R #elif /* not (__APPLE || __FreeBSD__) */ defined(__sun) #if __STDC_VERSION__ >= 201112L #define ucx_array_sort_impl qsort_s #endif #endif /* __GLIBC__, __APLE__, __FreeBSD__, __sun */ #endif /* UCX_ARRAY_DISABLE_QSORT */ #ifndef ucx_array_sort_impl #define ucx_array_sort_impl ucx_mergesort #endif static int ucx_array_ensurecap(UcxArray *array, size_t reqcap) { size_t required_capacity = array->capacity; while (reqcap > required_capacity) { if (required_capacity * 2 < required_capacity) return 1; required_capacity <<= 1; } if (ucx_array_reserve(array, required_capacity)) { return 1; } return 0; } int ucx_array_util_set_a(UcxAllocator* alloc, void** array, size_t* capacity, size_t elmsize, size_t index, void* data) { if(!alloc || !capacity || !array) { errno = EINVAL; return 1; } size_t newcapacity = *capacity; while(index >= newcapacity) { if(ucx_szmul(newcapacity, 2, &newcapacity)) { errno = EOVERFLOW; return 1; } } size_t memlen, offset; if(ucx_szmul(newcapacity, elmsize, &memlen)) { errno = EOVERFLOW; return 1; } /* we don't need to check index*elmsize - it is smaller than memlen */ void* newptr = alrealloc(alloc, *array, memlen); if(newptr == NULL) { errno = ENOMEM; /* we cannot assume that every allocator sets this */ return 1; } *array = newptr; *capacity = newcapacity; char* dest = *array; dest += elmsize*index; memcpy(dest, data, elmsize); return 0; } int ucx_array_util_setptr_a(UcxAllocator* alloc, void** array, size_t* capacity, size_t index, void* data) { return ucx_array_util_set_a(alloc, array, capacity, sizeof(void*), index, &data); } UcxArray* ucx_array_new(size_t capacity, size_t elemsize) { return ucx_array_new_a(capacity, elemsize, ucx_default_allocator()); } UcxArray* ucx_array_new_a(size_t capacity, size_t elemsize, UcxAllocator* allocator) { UcxArray* array = almalloc(allocator, sizeof(UcxArray)); if(array) { ucx_array_init_a(array, capacity, elemsize, allocator); } return array; } void ucx_array_init(UcxArray* array, size_t capacity, size_t elemsize) { ucx_array_init_a(array, capacity, elemsize, ucx_default_allocator()); } void ucx_array_init_a(UcxArray* array, size_t capacity, size_t elemsize, UcxAllocator* allocator) { array->allocator = allocator; array->elemsize = elemsize; array->size = 0; array->data = alcalloc(allocator, capacity, elemsize); if (array->data) { array->capacity = capacity; } else { array->capacity = 0; } } int ucx_array_clone(UcxArray* dest, UcxArray const* src) { if (ucx_array_ensurecap(dest, src->capacity)) { return 1; } dest->elemsize = src->elemsize; dest->size = src->size; if (dest->data) { memcpy(dest->data, src->data, src->size*src->elemsize); } return 0; } int ucx_array_equals(UcxArray const *array1, UcxArray const *array2, cmp_func cmpfnc, void* data) { if (array1->size != array2->size || array1->elemsize != array2->elemsize) { return 0; } else { if (array1->size == 0) return 1; size_t elemsize; if (cmpfnc == NULL) { cmpfnc = ucx_cmp_mem; elemsize = array1->elemsize; data = &elemsize; } for (size_t i = 0 ; i < array1->size ; i++) { int r = cmpfnc( ucx_array_at(array1, i), ucx_array_at(array2, i), data); if (r != 0) return 0; } return 1; } } void ucx_array_destroy(UcxArray *array) { if(array->data) alfree(array->allocator, array->data); array->data = NULL; array->capacity = array->size = 0; } void ucx_array_free(UcxArray *array) { ucx_array_destroy(array); alfree(array->allocator, array); } int ucx_array_append_from(UcxArray *array, void *data, size_t count) { if (ucx_array_ensurecap(array, array->size + count)) return 1; void* dest = ucx_array_at(array, array->size); if (data) { memcpy(dest, data, array->elemsize*count); } else { memset(dest, 0, array->elemsize*count); } array->size += count; return 0; } int ucx_array_prepend_from(UcxArray *array, void *data, size_t count) { if (ucx_array_ensurecap(array, array->size + count)) return 1; if (array->size > 0) { void *dest = ucx_array_at(array, count); memmove(dest, array->data, array->elemsize*array->size); } if (data) { memcpy(array->data, data, array->elemsize*count); } else { memset(array->data, 0, array->elemsize*count); } array->size += count; return 0; } int ucx_array_set_from(UcxArray *array, size_t index, void *data, size_t count) { if (ucx_array_ensurecap(array, index + count)) return 1; if (index+count > array->size) { array->size = index+count; } void *dest = ucx_array_at(array, index); if (data) { memcpy(dest, data, array->elemsize*count); } else { memset(dest, 0, array->elemsize*count); } return 0; } int ucx_array_concat(UcxArray *array1, const UcxArray *array2) { if (array1->elemsize != array2->elemsize) return 1; size_t capacity = array1->capacity+array2->capacity; if (array1->capacity < capacity) { if (ucx_array_reserve(array1, capacity)) { return 1; } } void* dest = ucx_array_at(array1, array1->size); memcpy(dest, array2->data, array2->size*array2->elemsize); array1->size += array2->size; return 0; } void *ucx_array_at(UcxArray const *array, size_t index) { char* memory = array->data; char* loc = memory + index*array->elemsize; return loc; } size_t ucx_array_find(UcxArray const *array, void *elem, cmp_func cmpfnc, void *data) { size_t elemsize; if (cmpfnc == NULL) { cmpfnc = ucx_cmp_mem; elemsize = array->elemsize; data = &elemsize; } if (array->size > 0) { for (size_t i = 0 ; i < array->size ; i++) { void* ptr = ucx_array_at(array, i); if (cmpfnc(ptr, elem, data) == 0) { return i; } } return array->size; } else { return 0; } } int ucx_array_contains(UcxArray const *array, void *elem, cmp_func cmpfnc, void *data) { return ucx_array_find(array, elem, cmpfnc, data) != array->size; } static void ucx_mergesort_merge(void *arrdata,size_t elemsize, cmp_func cmpfnc, void *data, size_t start, size_t mid, size_t end) { char* array = arrdata; size_t rightstart = mid + 1; if (cmpfnc(array + mid*elemsize, array + rightstart*elemsize, data) <= 0) { /* already sorted */ return; } /* we need memory for one element */ void *value = malloc(elemsize); while (start <= mid && rightstart <= end) { if (cmpfnc(array + start*elemsize, array + rightstart*elemsize, data) <= 0) { start++; } else { /* save the value from the right */ memcpy(value, array + rightstart*elemsize, elemsize); /* shift all left elements one element to the right */ size_t shiftcount = rightstart-start; void *startptr = array + start*elemsize; void *dest = array + (start+1)*elemsize; memmove(dest, startptr, shiftcount*elemsize); /* bring the first value from the right to the left */ memcpy(startptr, value, elemsize); start++; mid++; rightstart++; } } /* free the temporary memory */ free(value); } static void ucx_mergesort_impl(void *arrdata, size_t elemsize, cmp_func cmpfnc, void *data, size_t l, size_t r) { if (l < r) { size_t m = l + (r - l) / 2; ucx_mergesort_impl(arrdata, elemsize, cmpfnc, data, l, m); ucx_mergesort_impl(arrdata, elemsize, cmpfnc, data, m + 1, r); ucx_mergesort_merge(arrdata, elemsize, cmpfnc, data, l, m, r); } } static void ucx_mergesort(void *arrdata, size_t count, size_t elemsize, cmp_func cmpfnc, void *data) { ucx_mergesort_impl(arrdata, elemsize, cmpfnc, data, 0, count-1); } #ifdef USE_UCX_QSORT_R struct cmpfnc_swapargs_info { cmp_func func; void *data; }; static int cmp_func_swap_args(void *data, const void *x, const void *y) { struct cmpfnc_swapargs_info* info = data; return info->func(x, y, info->data); } static void ucx_qsort_r(void *array, size_t count, size_t elemsize, cmp_func cmpfnc, void *data) { struct cmpfnc_swapargs_info info; info.func = cmpfnc; info.data = data; qsort_r(array, count, elemsize, &info, cmp_func_swap_args); } #endif /* USE_UCX_QSORT_R */ void ucx_array_sort(UcxArray* array, cmp_func cmpfnc, void *data) { ucx_array_sort_impl(array->data, array->size, array->elemsize, cmpfnc, data); } void ucx_array_remove(UcxArray *array, size_t index) { array->size--; if (index < array->size) { void* dest = ucx_array_at(array, index); void* src = ucx_array_at(array, index+1); memmove(dest, src, (array->size - index)*array->elemsize); } } void ucx_array_remove_fast(UcxArray *array, size_t index) { array->size--; if (index < array->size) { void* dest = ucx_array_at(array, index); void* src = ucx_array_at(array, array->size); memcpy(dest, src, array->elemsize); } } int ucx_array_shrink(UcxArray* array) { void* newptr = alrealloc(array->allocator, array->data, array->size*array->elemsize); if (newptr) { array->data = newptr; array->capacity = array->size; return 0; } else { return 1; } } int ucx_array_resize(UcxArray* array, size_t capacity) { if (array->capacity >= capacity) { void* newptr = alrealloc(array->allocator, array->data, capacity*array->elemsize); if (newptr) { array->data = newptr; array->capacity = capacity; if (array->size > array->capacity) { array->size = array->capacity; } return 0; } else { return 1; } } else { return ucx_array_reserve(array, capacity); } } int ucx_array_reserve(UcxArray* array, size_t capacity) { if (array->capacity > capacity) { return 0; } else { void* newptr = alrealloc(array->allocator, array->data, capacity*array->elemsize); if (newptr) { array->data = newptr; array->capacity = capacity; return 0; } else { return 1; } } } int ucx_array_grow(UcxArray* array, size_t count) { return ucx_array_reserve(array, array->size+count); }