#ifndef ALIGNED_VECTOR_H #define ALIGNED_VECTOR_H #include #include #include #include #define ALIGNED_VECTOR_INITIAL_CAPACITY 256u typedef struct { unsigned int size; unsigned int capacity; unsigned char* data; unsigned int element_size; } AlignedVector; inline void aligned_vector_reserve(AlignedVector* vector, unsigned int element_count); inline void aligned_vector_resize(AlignedVector* vector, const unsigned int element_count); inline void aligned_vector_init(AlignedVector* vector, unsigned int element_size) { vector->size = vector->capacity = 0; vector->element_size = element_size; vector->data = NULL; /* Reserve some initial capacity */ aligned_vector_reserve(vector, ALIGNED_VECTOR_INITIAL_CAPACITY); } inline void aligned_vector_reserve(AlignedVector* vector, unsigned int element_count) { if(element_count <= vector->capacity) { return; } unsigned int original_byte_size = vector->size * vector->element_size; unsigned int new_byte_size = element_count * vector->element_size; unsigned char* original_data = vector->data; vector->data = (unsigned char*) memalign(0x20, new_byte_size); if(original_data) { memcpy(vector->data, original_data, original_byte_size); free(original_data); } vector->capacity = element_count; } inline void aligned_vector_push_back(AlignedVector* vector, const void* objs, unsigned int count) { /* Resize enough room */ unsigned int initial_size = vector->size; aligned_vector_resize(vector, vector->size + count); unsigned char* dest = vector->data + (vector->element_size * initial_size); /* Copy the objects in */ memcpy(dest, objs, vector->element_size * count); } inline void aligned_vector_resize(AlignedVector* vector, const unsigned int element_count) { /* Don't change memory when resizing downwards, just change the size */ if(element_count <= vector->size) { vector->size = element_count; return; } if(vector->capacity < element_count) { /* Reserve more than we need so that a subsequent push_back doesn't trigger yet another * resize */ aligned_vector_reserve(vector, (int) ceil(((float)element_count) * 1.5f)); } vector->size = element_count; } inline void* aligned_vector_at(AlignedVector* vector, const unsigned int index) { return &vector->data[index * vector->element_size]; } inline void* aligned_vector_extend(AlignedVector* vector, const unsigned int additional_count) { const unsigned int current = vector->size; aligned_vector_resize(vector, vector->size + additional_count); return aligned_vector_at(vector, current); } inline void aligned_vector_clear(AlignedVector* vector) { vector->size = 0; } inline void aligned_vector_shrink_to_fit(AlignedVector* vector) { if(vector->size == 0) { free(vector->data); vector->data = NULL; vector->capacity = 0; } else { unsigned int new_byte_size = vector->size * vector->element_size; unsigned char* original_data = vector->data; vector->data = (unsigned char*) memalign(0x20, new_byte_size); if(original_data) { memcpy(vector->data, original_data, new_byte_size); free(original_data); } vector->capacity = vector->size; } } inline void aligned_vector_cleanup(AlignedVector* vector) { aligned_vector_clear(vector); aligned_vector_shrink_to_fit(vector); } #endif // ALIGNED_VECTOR_H