use super::*; #[test] fn allocator_param() { use crate::alloc::AllocErr; // Writing a test of integration between third-party // allocators and `RawVec` is a little tricky because the `RawVec` // API does not expose fallible allocation methods, so we // cannot check what happens when allocator is exhausted // (beyond detecting a panic). // // Instead, this just checks that the `RawVec` methods do at // least go through the Allocator API when it reserves // storage. // A dumb allocator that consumes a fixed amount of fuel // before allocation attempts start failing. struct BoundedAlloc { fuel: usize, } unsafe impl AllocRef for BoundedAlloc { unsafe fn alloc(&mut self, layout: Layout) -> Result<(NonNull, usize), AllocErr> { let size = layout.size(); if size > self.fuel { return Err(AllocErr); } match Global.alloc(layout) { ok @ Ok(_) => { self.fuel -= size; ok } err @ Err(_) => err, } } unsafe fn dealloc(&mut self, ptr: NonNull, layout: Layout) { Global.dealloc(ptr, layout) } } let a = BoundedAlloc { fuel: 500 }; let mut v: RawVec = RawVec::with_capacity_in(50, a); assert_eq!(v.a.fuel, 450); v.reserve(50, 150); // (causes a realloc, thus using 50 + 150 = 200 units of fuel) assert_eq!(v.a.fuel, 250); } #[test] fn reserve_does_not_overallocate() { { let mut v: RawVec = RawVec::new(); // First, `reserve` allocates like `reserve_exact`. v.reserve(0, 9); assert_eq!(9, v.capacity()); } { let mut v: RawVec = RawVec::new(); v.reserve(0, 7); assert_eq!(7, v.capacity()); // 97 if more than double of 7, so `reserve` should work // like `reserve_exact`. v.reserve(7, 90); assert_eq!(97, v.capacity()); } { let mut v: RawVec = RawVec::new(); v.reserve(0, 12); assert_eq!(12, v.capacity()); v.reserve(12, 3); // 3 is less than half of 12, so `reserve` must grow // exponentially. At the time of writing this test grow // factor is 2, so new capacity is 24, however, grow factor // of 1.5 is OK too. Hence `>= 18` in assert. assert!(v.capacity() >= 12 + 12 / 2); } }