/* radare - LGPL - Copyright 2017-2020 - maskray, thestr4ng3r */ #include "r_vector.h" // Optimize memory usage on glibc #if __WORDSIZE == 32 // Chunk size 24, minus 4 (chunk header), minus 8 for capacity and len, 12 bytes remaining for 3 void * #define INITIAL_VECTOR_LEN 3 #else // For __WORDSIZE == 64 // Chunk size 48, minus 8 (chunk header), minus 8 for capacity and len, 32 bytes remaining for 4 void * #define INITIAL_VECTOR_LEN 4 #endif #define NEXT_VECTOR_CAPACITY (vec->capacity < INITIAL_VECTOR_LEN \ ? INITIAL_VECTOR_LEN \ : vec->capacity <= 12 ? vec->capacity * 2 \ : vec->capacity + (vec->capacity >> 1)) #define RESIZE_OR_RETURN_NULL(next_capacity) do { \ size_t new_capacity = next_capacity; \ void **new_a = realloc (vec->a, vec->elem_size * new_capacity); \ if (!new_a) { \ return NULL; \ } \ vec->a = new_a; \ vec->capacity = new_capacity; \ } while (0) R_API void r_vector_init(RVector *vec, size_t elem_size, RVectorFree free, void *free_user) { r_return_if_fail (vec); vec->a = NULL; vec->capacity = vec->len = 0; vec->elem_size = elem_size; vec->free = free; vec->free_user = free_user; } R_API RVector *r_vector_new(size_t elem_size, RVectorFree free, void *free_user) { RVector *vec = R_NEW (RVector); if (!vec) { return NULL; } r_vector_init (vec, elem_size, free, free_user); return vec; } static void vector_free_elems(RVector *vec) { if (vec->free) { while (vec->len > 0) { vec->free (r_vector_index_ptr (vec, --vec->len), vec->free_user); } } else { vec->len = 0; } } R_API void r_vector_fini(RVector *vec) { r_return_if_fail (vec); r_vector_clear (vec); vec->free = NULL; vec->free_user = NULL; } R_API void r_vector_clear(RVector *vec) { r_return_if_fail (vec); vector_free_elems (vec); R_FREE (vec->a); vec->capacity = 0; } R_API void r_vector_free(RVector *vec) { if (vec) { r_vector_fini (vec); free (vec); } } static bool vector_clone(RVector *dst, RVector *src) { r_return_val_if_fail (dst && src, false); dst->capacity = src->capacity; dst->len = src->len; dst->elem_size = src->elem_size; dst->free = src->free; dst->free_user = src->free_user; if (!dst->len) { dst->a = NULL; } else { dst->a = malloc (src->elem_size * src->capacity); if (!dst->a) { return false; } memcpy (dst->a, src->a, src->elem_size * src->len); } return true; } R_API RVector *r_vector_clone(RVector *vec) { r_return_val_if_fail (vec, NULL); RVector *ret = R_NEW (RVector); if (!ret) { return NULL; } if (!vector_clone (ret, vec)) { free (ret); return NULL; } return ret; } R_API void r_vector_assign(RVector *vec, void *p, void *elem) { r_return_if_fail (vec && p && elem); memcpy (p, elem, vec->elem_size); } R_API void *r_vector_assign_at(RVector *vec, size_t index, void *elem) { void *p = r_vector_index_ptr (vec, index); if (elem) { r_vector_assign (vec, p, elem); } return p; } R_API void r_vector_remove_at(RVector *vec, size_t index, void *into) { r_return_if_fail (vec); void *p = r_vector_index_ptr (vec, index); if (into) { r_vector_assign (vec, into, p); } vec->len--; if (index < vec->len) { memmove (p, (char *)p + vec->elem_size, vec->elem_size * (vec->len - index)); } } R_API void *r_vector_insert(RVector *vec, size_t index, void *x) { r_return_val_if_fail (vec && index <= vec->len, NULL); if (vec->len >= vec->capacity) { RESIZE_OR_RETURN_NULL (NEXT_VECTOR_CAPACITY); } void *p = r_vector_index_ptr (vec, index); if (index < vec->len) { memmove ((char *)p + vec->elem_size, p, vec->elem_size * (vec->len - index)); } vec->len++; if (x) { r_vector_assign (vec, p, x); } return p; } R_API void *r_vector_insert_range(RVector *vec, size_t index, void *first, size_t count) { r_return_val_if_fail (vec && index <= vec->len, NULL); if (vec->len + count > vec->capacity) { RESIZE_OR_RETURN_NULL (R_MAX (NEXT_VECTOR_CAPACITY, vec->len + count)); } size_t sz = count * vec->elem_size; void *p = r_vector_index_ptr (vec, index); if (index < vec->len) { memmove ((char *)p + sz, p, vec->elem_size * (vec->len - index)); } vec->len += count; if (first) { memcpy (p, first, sz); } return p; } R_API void r_vector_pop(RVector *vec, void *into) { r_return_if_fail (vec); if (into) { r_vector_assign (vec, into, r_vector_index_ptr (vec, vec->len - 1)); } vec->len--; } R_API void r_vector_pop_front(RVector *vec, void *into) { r_return_if_fail (vec); r_vector_remove_at (vec, 0, into); } R_API void *r_vector_push(RVector *vec, void *x) { r_return_val_if_fail (vec, NULL); if (vec->len >= vec->capacity) { RESIZE_OR_RETURN_NULL (NEXT_VECTOR_CAPACITY); } void *p = r_vector_index_ptr (vec, vec->len++); if (x) { r_vector_assign (vec, p, x); } return p; } R_API void *r_vector_push_front(RVector *vec, void *x) { r_return_val_if_fail (vec, NULL); return r_vector_insert (vec, 0, x); } R_API void *r_vector_reserve(RVector *vec, size_t capacity) { r_return_val_if_fail (vec, NULL); if (vec->capacity < capacity) { RESIZE_OR_RETURN_NULL (capacity); } return vec->a; } R_API void *r_vector_shrink(RVector *vec) { r_return_val_if_fail (vec, NULL); if (vec->len < vec->capacity) { RESIZE_OR_RETURN_NULL (vec->len); } return vec->a; } R_API void *r_vector_flush(RVector *vec) { r_return_val_if_fail (vec, NULL); r_vector_shrink (vec); void *r = vec->a; vec->a = NULL; vec->capacity = vec->len = 0; return r; } // pvector static void pvector_free_elem(void *e, void *user) { void *p = *((void **)e); RPVectorFree elem_free = (RPVectorFree)user; elem_free (p); } R_API void r_pvector_init(RPVector *vec, RPVectorFree free) { r_vector_init (&vec->v, sizeof (void *), free ? pvector_free_elem : NULL, free); } R_API RPVector *r_pvector_new(RPVectorFree free) { RPVector *v = R_NEW (RPVector); if (!v) { return NULL; } r_pvector_init (v, free); return v; } R_API RPVector *r_pvector_new_with_len(RPVectorFree free, size_t length) { RPVector *v = r_pvector_new (free); if (!v) { return NULL; } void** p = r_pvector_reserve (v, length); if (!p) { r_pvector_free (v); return NULL; } memset (p, 0, v->v.elem_size * v->v.capacity); v->v.len = length; return v; } R_API void r_pvector_clear(RPVector *vec) { r_return_if_fail (vec); r_vector_clear (&vec->v); } R_API void r_pvector_fini(RPVector *vec) { r_return_if_fail (vec); r_vector_fini (&vec->v); } R_API void r_pvector_free(RPVector *vec) { if (!vec) { return; } r_vector_fini (&vec->v); free (vec); } R_API void **r_pvector_contains(RPVector *vec, void *x) { r_return_val_if_fail (vec, NULL); size_t i; for (i = 0; i < vec->v.len; i++) { if (((void **)vec->v.a)[i] == x) { return &((void **)vec->v.a)[i]; } } return NULL; } R_API void *r_pvector_remove_at(RPVector *vec, size_t index) { r_return_val_if_fail (vec, NULL); void *r = r_pvector_at (vec, index); r_vector_remove_at (&vec->v, index, NULL); return r; } R_API void r_pvector_remove_data(RPVector *vec, void *x) { void **el = r_pvector_contains (vec, x); if (!el) { return; } size_t index = el - (void **)vec->v.a; r_vector_remove_at (&vec->v, index, NULL); } R_API void *r_pvector_pop(RPVector *vec) { r_return_val_if_fail (vec, NULL); if (r_pvector_len (vec) < 1) { return NULL; } void *r = r_pvector_at (vec, vec->v.len - 1); r_vector_pop (&vec->v, NULL); return r; } R_API void *r_pvector_pop_front(RPVector *vec) { r_return_val_if_fail (vec, NULL); if (r_pvector_len (vec) < 1) { return NULL; } void *r = r_pvector_at (vec, 0); r_vector_pop_front (&vec->v, NULL); return r; } // CLRS Quicksort. It is slow, but simple. static void quick_sort(void **a, size_t n, RPVectorComparator cmp) { if (n <= 1) { return; } size_t i = rand() % n, j = 0; void *t, *pivot = a[i]; a[i] = a[n - 1]; for (i = 0; i < n - 1; i++) { if (cmp (a[i], pivot) < 0) { t = a[i]; a[i] = a[j]; a[j] = t; j++; } } a[n - 1] = a[j]; a[j] = pivot; quick_sort (a, j, cmp); quick_sort (a + j + 1, n - j - 1, cmp); } R_API void r_pvector_sort(RPVector *vec, RPVectorComparator cmp) { r_return_if_fail (vec && cmp); quick_sort (vec->v.a, vec->v.len, cmp); }