#import "fmt.odin"; #import "os.odin"; swap :: proc(b: u16) -> u16 #foreign __llvm_core "llvm.bswap.i16"; swap :: proc(b: u32) -> u32 #foreign __llvm_core "llvm.bswap.i32"; swap :: proc(b: u64) -> u64 #foreign __llvm_core "llvm.bswap.i64"; set :: proc(data: rawptr, value: i32, len: int) -> rawptr { return __mem_set(data, value, len); } zero :: proc(data: rawptr, len: int) -> rawptr { return __mem_zero(data, len); } copy :: proc(dst, src: rawptr, len: int) -> rawptr { return __mem_copy(dst, src, len); } copy_non_overlapping :: proc(dst, src: rawptr, len: int) -> rawptr { return __mem_copy_non_overlapping(dst, src, len); } compare :: proc(a, b: []u8) -> int { return __mem_compare(&a[0], &b[0], min(len(a), len(b))); } kilobytes :: proc(x: int) -> int #inline { return (x) * 1024; } megabytes :: proc(x: int) -> int #inline { return kilobytes(x) * 1024; } gigabytes :: proc(x: int) -> int #inline { return megabytes(x) * 1024; } terabytes :: proc(x: int) -> int #inline { return gigabytes(x) * 1024; } is_power_of_two :: proc(x: int) -> bool { if x <= 0 { return false; } return (x & (x-1)) == 0; } align_forward :: proc(ptr: rawptr, align: int) -> rawptr { assert(is_power_of_two(align)); a := uint(align); p := uint(ptr); modulo := p & (a-1); if modulo != 0 { p += a - modulo; } return rawptr(p); } AllocationHeader :: struct { size: int, } allocation_header_fill :: proc(header: ^AllocationHeader, data: rawptr, size: int) { header.size = size; ptr := ^int(header+1); for i := 0; rawptr(ptr) < data; i++ { (ptr+i)^ = -1; } } allocation_header :: proc(data: rawptr) -> ^AllocationHeader { if data == nil { return nil; } p := ^int(data); for (p-1)^ == -1 { p = (p-1); } return ^AllocationHeader(p-1); } // Custom allocators Arena :: struct { backing: Allocator, offset: int, memory: []u8, temp_count: int, } ArenaTempMemory :: struct { arena: ^Arena, original_count: int, } init_arena_from_memory :: proc(using a: ^Arena, data: []u8) { backing = Allocator{}; memory = data[0..<0]; temp_count = 0; } init_arena_from_context :: proc(using a: ^Arena, size: int) { backing = context.allocator; memory = make([]u8, size); temp_count = 0; } free_arena :: proc(using a: ^Arena) { if backing.procedure != nil { push_allocator backing { free(memory); memory = nil; offset = 0; } } } arena_allocator :: proc(arena: ^Arena) -> Allocator { return Allocator{ procedure = arena_allocator_proc, data = arena, }; } arena_allocator_proc :: proc(allocator_data: rawptr, mode: AllocatorMode, size, alignment: int, old_memory: rawptr, old_size: int, flags: u64) -> rawptr { using AllocatorMode; arena := ^Arena(allocator_data); match mode { case Alloc: total_size := size + alignment; if arena.offset + total_size > len(arena.memory) { fmt.fprintln(os.stderr, "Arena out of memory"); return nil; } #no_bounds_check end := &arena.memory[arena.offset]; ptr := align_forward(end, alignment); arena.offset += total_size; return zero(ptr, size); case Free: // NOTE(bill): Free all at once // Use ArenaTempMemory if you want to free a block case FreeAll: arena.offset = 0; case Resize: return default_resize_align(old_memory, old_size, size, alignment); } return nil; } begin_arena_temp_memory :: proc(a: ^Arena) -> ArenaTempMemory { tmp: ArenaTempMemory; tmp.arena = a; tmp.original_count = len(a.memory); a.temp_count++; return tmp; } end_arena_temp_memory :: proc(using tmp: ArenaTempMemory) { assert(len(arena.memory) >= original_count); assert(arena.temp_count > 0); arena.memory = arena.memory[0.. int { prev_pow2 :: proc(n: i64) -> i64 { if n <= 0 { return 0; } n |= n >> 1; n |= n >> 2; n |= n >> 4; n |= n >> 8; n |= n >> 16; n |= n >> 32; return n - (n >> 1); } WORD_SIZE :: size_of(int); MAX_ALIGN :: size_of([vector 64]f64); // TODO(bill): Should these constants be builtin constants? using TypeInfo; match info in type_info { case Named: return align_of_type_info(info.base); case Integer: return info.size; case Float: return info.size; case String: return WORD_SIZE; case Boolean: return 1; case Any: return WORD_SIZE; case Pointer: return WORD_SIZE; case Procedure: return WORD_SIZE; case Array: return align_of_type_info(info.elem); case DynamicArray: return WORD_SIZE; case Slice: return WORD_SIZE; case Vector: size := size_of_type_info(info.elem); count := int(max(prev_pow2(i64(info.count)), 1)); total := size * count; return clamp(total, 1, MAX_ALIGN); case Tuple: return info.align; case Struct: return info.align; case Union: return info.align; case RawUnion: return info.align; case Enum: return align_of_type_info(info.base); case Map: return align_of_type_info(info.generated_struct); } return 0; } align_formula :: proc(size, align: int) -> int { result := size + align-1; return result - result%align; } size_of_type_info :: proc(type_info: ^TypeInfo) -> int { WORD_SIZE :: size_of(int); using TypeInfo; match info in type_info { case Named: return size_of_type_info(info.base); case Integer: return info.size; case Float: return info.size; case String: return 2*WORD_SIZE; case Boolean: return 1; case Any: return 2*WORD_SIZE; case Pointer: return WORD_SIZE; case Procedure: return WORD_SIZE; case Array: count := info.count; if count == 0 { return 0; } size := size_of_type_info(info.elem); align := align_of_type_info(info.elem); alignment := align_formula(size, align); return alignment*(count-1) + size; case DynamicArray: return size_of(rawptr) + 2*size_of(int) + size_of(Allocator); case Slice: return 2*WORD_SIZE; case Vector: count := info.count; if count == 0 { return 0; } size := size_of_type_info(info.elem); align := align_of_type_info(info.elem); alignment := align_formula(size, align); return alignment*(count-1) + size; case Struct: return info.size; case Union: return info.size; case RawUnion: return info.size; case Enum: return size_of_type_info(info.base); case Map: return size_of_type_info(info.generated_struct); } return 0; }