// Dynamic arenas. // Arenas are used to quickly allocate objects that share a // lifetime. The arena uses ~[u8] vectors as a backing store to // allocate objects from. For each allocated object, the arena stores // a pointer to the type descriptor followed by the // object. (Potentially with alignment padding after each of them.) // When the arena is destroyed, it iterates through all of its chunks, // and uses the tydesc information to trace through the objects, // calling the destructors on them. // One subtle point that needs to be addressed is how to handle // failures while running the user provided initializer function. It // is important to not run the destructor on uninitalized objects, but // how to detect them is somewhat subtle. Since alloc() can be invoked // recursively, it is not sufficient to simply exclude the most recent // object. To solve this without requiring extra space, we use the low // order bit of the tydesc pointer to encode whether the object it // describes has been fully initialized. // As an optimization, objects with destructors are stored in // different chunks than objects without destructors. This reduces // overhead when initializing plain-old-data and means we don't need // to waste time running the destructors of POD. export arena, arena_with_size; import list; import list::{list, cons, nil}; import unsafe::reinterpret_cast; import sys::TypeDesc; import libc::size_t; #[abi = "rust-intrinsic"] extern mod rusti { fn move_val_init(&dst: T, -src: T); fn needs_drop() -> bool; } extern mod rustrt { #[rust_stack] fn rust_call_tydesc_glue(root: *u8, tydesc: *TypeDesc, field: size_t); } // This probably belongs somewhere else. Needs to be kept in sync with // changes to glue... const tydesc_drop_glue_index: size_t = 3 as size_t; // The way arena uses arrays is really deeply awful. The arrays are // allocated, and have capacities reserved, but the fill for the array // will always stay at 0. type chunk = {data: @[u8], mut fill: uint, is_pod: bool}; struct arena { // The head is seperated out from the list as a unbenchmarked // microoptimization, to avoid needing to case on the list to // access the head. priv mut head: chunk; priv mut pod_head: chunk; priv mut chunks: @list; drop { unsafe { destroy_chunk(self.head); for list::each(self.chunks) |chunk| { if !chunk.is_pod { destroy_chunk(chunk); } } } } } fn chunk(size: uint, is_pod: bool) -> chunk { let mut v = @[]; unsafe { at_vec::unsafe::reserve(v, size); } { data: v, mut fill: 0u, is_pod: is_pod } } fn arena_with_size(initial_size: uint) -> arena { return arena {mut head: chunk(initial_size, false), mut pod_head: chunk(initial_size, true), mut chunks: @nil}; } fn arena() -> arena { arena_with_size(32u) } #[inline(always)] fn round_up_to(base: uint, align: uint) -> uint { (base + (align - 1)) & !(align - 1) } // Walk down a chunk, running the destructors for any objects stored // in it. unsafe fn destroy_chunk(chunk: chunk) { let mut idx = 0; let buf = vec::unsafe::to_ptr_slice(chunk.data); let fill = chunk.fill; while idx < fill { let tydesc_data: *uint = reinterpret_cast(ptr::offset(buf, idx)); let (tydesc, is_done) = un_bitpack_tydesc_ptr(*tydesc_data); let size = (*tydesc).size, align = (*tydesc).align; let after_tydesc = idx + sys::size_of::<*TypeDesc>(); let start = round_up_to(after_tydesc, align); //debug!("freeing object: idx = %u, size = %u, align = %u, done = %b", // start, size, align, is_done); if is_done { rustrt::rust_call_tydesc_glue( ptr::offset(buf, start), tydesc, tydesc_drop_glue_index); } // Find where the next tydesc lives idx = round_up_to(start + size, sys::pref_align_of::<*TypeDesc>()); } } // We encode whether the object a tydesc describes has been // initialized in the arena in the low bit of the tydesc pointer. This // is necessary in order to properly do cleanup if a failure occurs // during an initializer. #[inline(always)] unsafe fn bitpack_tydesc_ptr(p: *TypeDesc, is_done: bool) -> uint { let p_bits: uint = reinterpret_cast(p); p_bits | (is_done as uint) } #[inline(always)] unsafe fn un_bitpack_tydesc_ptr(p: uint) -> (*TypeDesc, bool) { (reinterpret_cast(p & !1), p & 1 == 1) } // The duplication between the POD and non-POD functions is annoying. impl &arena { // Functions for the POD part of the arena fn alloc_pod_grow(n_bytes: uint, align: uint) -> *u8 { // Allocate a new chunk. let chunk_size = at_vec::capacity(self.pod_head.data); let new_min_chunk_size = uint::max(n_bytes, chunk_size); self.chunks = @cons(copy self.pod_head, self.chunks); self.pod_head = chunk(uint::next_power_of_two(new_min_chunk_size + 1u), true); return self.alloc_pod_inner(n_bytes, align); } #[inline(always)] fn alloc_pod_inner(n_bytes: uint, align: uint) -> *u8 { let head = &mut self.pod_head; let start = round_up_to(head.fill, align); let end = start + n_bytes; if end > at_vec::capacity(head.data) { return self.alloc_pod_grow(n_bytes, align); } head.fill = end; //debug!("idx = %u, size = %u, align = %u, fill = %u", // start, n_bytes, align, head.fill); unsafe { ptr::offset(vec::unsafe::to_ptr_slice(head.data), start) } } #[inline(always)] fn alloc_pod(op: fn() -> T) -> &self/T { unsafe { let tydesc = sys::get_type_desc::(); let ptr = self.alloc_pod_inner((*tydesc).size, (*tydesc).align); let ptr: *mut T = reinterpret_cast(ptr); rusti::move_val_init(*ptr, op()); return reinterpret_cast(ptr); } } // Functions for the non-POD part of the arena fn alloc_nonpod_grow(n_bytes: uint, align: uint) -> (*u8, *u8) { // Allocate a new chunk. let chunk_size = at_vec::capacity(self.head.data); let new_min_chunk_size = uint::max(n_bytes, chunk_size); self.chunks = @cons(copy self.head, self.chunks); self.head = chunk(uint::next_power_of_two(new_min_chunk_size + 1u), false); return self.alloc_nonpod_inner(n_bytes, align); } #[inline(always)] fn alloc_nonpod_inner(n_bytes: uint, align: uint) -> (*u8, *u8) { let head = &mut self.head; let tydesc_start = head.fill; let after_tydesc = head.fill + sys::size_of::<*TypeDesc>(); let start = round_up_to(after_tydesc, align); let end = start + n_bytes; if end > at_vec::capacity(head.data) { return self.alloc_nonpod_grow(n_bytes, align); } head.fill = round_up_to(end, sys::pref_align_of::<*TypeDesc>()); //debug!("idx = %u, size = %u, align = %u, fill = %u", // start, n_bytes, align, head.fill); unsafe { let buf = vec::unsafe::to_ptr_slice(head.data); return (ptr::offset(buf, tydesc_start), ptr::offset(buf, start)); } } #[inline(always)] fn alloc_nonpod(op: fn() -> T) -> &self/T { unsafe { let tydesc = sys::get_type_desc::(); let (ty_ptr, ptr) = self.alloc_nonpod_inner((*tydesc).size, (*tydesc).align); let ty_ptr: *mut uint = reinterpret_cast(ty_ptr); let ptr: *mut T = reinterpret_cast(ptr); // Write in our tydesc along with a bit indicating that it // has *not* been initialized yet. *ty_ptr = reinterpret_cast(tydesc); // Actually initialize it rusti::move_val_init(*ptr, op()); // Now that we are done, update the tydesc to indicate that // the object is there. *ty_ptr = bitpack_tydesc_ptr(tydesc, true); return reinterpret_cast(ptr); } } // The external interface #[inline(always)] fn alloc(op: fn() -> T) -> &self/T { if !rusti::needs_drop::() { self.alloc_pod(op) } else { self.alloc_nonpod(op) } } } #[test] fn test_arena_destructors() { let arena = arena::arena(); for uint::range(0, 10) |i| { // Arena allocate something with drop glue to make sure it // doesn't leak. do arena.alloc { @i }; // Allocate something with funny size and alignment, to keep // things interesting. do arena.alloc { [0u8, 1u8, 2u8]/3 }; } } #[test] #[should_fail] #[ignore(cfg(windows))] fn test_arena_destructors_fail() { let arena = arena::arena(); // Put some stuff in the arena. for uint::range(0, 10) |i| { // Arena allocate something with drop glue to make sure it // doesn't leak. do arena.alloc { @i }; // Allocate something with funny size and alignment, to keep // things interesting. do arena.alloc { [0u8, 1u8, 2u8]/3 }; } // Now, fail while allocating do arena.alloc::<@int> { // First, recursively allocate something else; that needs to // get freed too. do arena.alloc { @20 }; // Now fail. fail; }; }