//! The memory subsystem. //! //! Generally, we use `Pointer` to denote memory addresses. However, some operations //! have a "size"-like parameter, and they take `Scalar` for the address because //! if the size is 0, then the pointer can also be a (properly aligned, non-NULL) //! integer. It is crucial that these operations call `check_align` *before* //! short-circuiting the empty case! use std::collections::VecDeque; use std::ptr; use std::borrow::Cow; use rustc::ty::{self, Instance, ParamEnv, query::TyCtxtAt}; use rustc::ty::layout::{Align, TargetDataLayout, Size, HasDataLayout}; use rustc_data_structures::fx::{FxHashSet, FxHashMap}; use syntax::ast::Mutability; use super::{ Pointer, AllocId, Allocation, GlobalId, AllocationExtra, InterpResult, Scalar, GlobalAlloc, PointerArithmetic, Machine, AllocMap, MayLeak, ErrorHandled, CheckInAllocMsg, }; #[derive(Debug, PartialEq, Copy, Clone)] pub enum MemoryKind { /// Error if deallocated except during a stack pop Stack, /// Error if ever deallocated Vtable, /// Additional memory kinds a machine wishes to distinguish from the builtin ones Machine(T), } impl MayLeak for MemoryKind { #[inline] fn may_leak(self) -> bool { match self { MemoryKind::Stack => false, MemoryKind::Vtable => true, MemoryKind::Machine(k) => k.may_leak() } } } /// Used by `get_size_and_align` to indicate whether the allocation needs to be live. #[derive(Debug, Copy, Clone)] pub enum AllocCheck { /// Allocation must be live and not a function pointer. Dereferencable, /// Allocations needs to be live, but may be a function pointer. Live, /// Allocation may be dead. MaybeDead, } /// The value of a function pointer. #[derive(Debug, Copy, Clone)] pub enum FnVal<'tcx, Other> { Instance(Instance<'tcx>), Other(Other), } impl<'tcx, Other> FnVal<'tcx, Other> { pub fn as_instance(self) -> InterpResult<'tcx, Instance<'tcx>> { match self { FnVal::Instance(instance) => Ok(instance), FnVal::Other(_) => throw_unsup_format!( "'foreign' function pointers are not supported in this context" ), } } } // `Memory` has to depend on the `Machine` because some of its operations // (e.g., `get`) call a `Machine` hook. pub struct Memory<'mir, 'tcx, M: Machine<'mir, 'tcx>> { /// Allocations local to this instance of the miri engine. The kind /// helps ensure that the same mechanism is used for allocation and /// deallocation. When an allocation is not found here, it is a /// static and looked up in the `tcx` for read access. Some machines may /// have to mutate this map even on a read-only access to a static (because /// they do pointer provenance tracking and the allocations in `tcx` have /// the wrong type), so we let the machine override this type. /// Either way, if the machine allows writing to a static, doing so will /// create a copy of the static allocation here. // FIXME: this should not be public, but interning currently needs access to it pub(super) alloc_map: M::MemoryMap, /// Map for "extra" function pointers. extra_fn_ptr_map: FxHashMap, /// To be able to compare pointers with NULL, and to check alignment for accesses /// to ZSTs (where pointers may dangle), we keep track of the size even for allocations /// that do not exist any more. // FIXME: this should not be public, but interning currently needs access to it pub(super) dead_alloc_map: FxHashMap, /// Extra data added by the machine. pub extra: M::MemoryExtra, /// Lets us implement `HasDataLayout`, which is awfully convenient. pub tcx: TyCtxtAt<'tcx>, } impl<'mir, 'tcx, M: Machine<'mir, 'tcx>> HasDataLayout for Memory<'mir, 'tcx, M> { #[inline] fn data_layout(&self) -> &TargetDataLayout { &self.tcx.data_layout } } // FIXME: Really we shouldn't clone memory, ever. Snapshot machinery should instead // carefully copy only the reachable parts. impl<'mir, 'tcx, M> Clone for Memory<'mir, 'tcx, M> where M: Machine<'mir, 'tcx, PointerTag = (), AllocExtra = (), MemoryExtra = ()>, M::MemoryMap: AllocMap, Allocation)>, { fn clone(&self) -> Self { Memory { alloc_map: self.alloc_map.clone(), extra_fn_ptr_map: self.extra_fn_ptr_map.clone(), dead_alloc_map: self.dead_alloc_map.clone(), extra: (), tcx: self.tcx, } } } impl<'mir, 'tcx, M: Machine<'mir, 'tcx>> Memory<'mir, 'tcx, M> { pub fn new(tcx: TyCtxtAt<'tcx>, extra: M::MemoryExtra) -> Self { Memory { alloc_map: M::MemoryMap::default(), extra_fn_ptr_map: FxHashMap::default(), dead_alloc_map: FxHashMap::default(), extra, tcx, } } #[inline] pub fn tag_static_base_pointer(&self, ptr: Pointer) -> Pointer { ptr.with_tag(M::tag_static_base_pointer(&self.extra, ptr.alloc_id)) } pub fn create_fn_alloc( &mut self, fn_val: FnVal<'tcx, M::ExtraFnVal>, ) -> Pointer { let id = match fn_val { FnVal::Instance(instance) => self.tcx.alloc_map.lock().create_fn_alloc(instance), FnVal::Other(extra) => { // FIXME(RalfJung): Should we have a cache here? let id = self.tcx.alloc_map.lock().reserve(); let old = self.extra_fn_ptr_map.insert(id, extra); assert!(old.is_none()); id } }; self.tag_static_base_pointer(Pointer::from(id)) } pub fn allocate( &mut self, size: Size, align: Align, kind: MemoryKind, ) -> Pointer { let alloc = Allocation::undef(size, align); self.allocate_with(alloc, kind) } pub fn allocate_static_bytes( &mut self, bytes: &[u8], kind: MemoryKind, ) -> Pointer { let alloc = Allocation::from_byte_aligned_bytes(bytes); self.allocate_with(alloc, kind) } pub fn allocate_with( &mut self, alloc: Allocation, kind: MemoryKind, ) -> Pointer { let id = self.tcx.alloc_map.lock().reserve(); let (alloc, tag) = M::tag_allocation(&self.extra, id, Cow::Owned(alloc), Some(kind)); self.alloc_map.insert(id, (kind, alloc.into_owned())); Pointer::from(id).with_tag(tag) } pub fn reallocate( &mut self, ptr: Pointer, old_size_and_align: Option<(Size, Align)>, new_size: Size, new_align: Align, kind: MemoryKind, ) -> InterpResult<'tcx, Pointer> { if ptr.offset.bytes() != 0 { throw_unsup!(ReallocateNonBasePtr) } // For simplicities' sake, we implement reallocate as "alloc, copy, dealloc". // This happens so rarely, the perf advantage is outweighed by the maintenance cost. let new_ptr = self.allocate(new_size, new_align, kind); let old_size = match old_size_and_align { Some((size, _align)) => size, None => self.get(ptr.alloc_id)?.size, }; self.copy( ptr, new_ptr, old_size.min(new_size), /*nonoverlapping*/ true, )?; self.deallocate(ptr, old_size_and_align, kind)?; Ok(new_ptr) } /// Deallocate a local, or do nothing if that local has been made into a static pub fn deallocate_local(&mut self, ptr: Pointer) -> InterpResult<'tcx> { // The allocation might be already removed by static interning. // This can only really happen in the CTFE instance, not in miri. if self.alloc_map.contains_key(&ptr.alloc_id) { self.deallocate(ptr, None, MemoryKind::Stack) } else { Ok(()) } } pub fn deallocate( &mut self, ptr: Pointer, old_size_and_align: Option<(Size, Align)>, kind: MemoryKind, ) -> InterpResult<'tcx> { trace!("deallocating: {}", ptr.alloc_id); if ptr.offset.bytes() != 0 { throw_unsup!(DeallocateNonBasePtr) } let (alloc_kind, mut alloc) = match self.alloc_map.remove(&ptr.alloc_id) { Some(alloc) => alloc, None => { // Deallocating static memory -- always an error return Err(match self.tcx.alloc_map.lock().get(ptr.alloc_id) { Some(GlobalAlloc::Function(..)) => err_unsup!(DeallocatedWrongMemoryKind( "function".to_string(), format!("{:?}", kind), )), Some(GlobalAlloc::Static(..)) | Some(GlobalAlloc::Memory(..)) => err_unsup!( DeallocatedWrongMemoryKind("static".to_string(), format!("{:?}", kind)) ), None => err_unsup!(DoubleFree), } .into()); } }; if alloc_kind != kind { throw_unsup!(DeallocatedWrongMemoryKind( format!("{:?}", alloc_kind), format!("{:?}", kind), )) } if let Some((size, align)) = old_size_and_align { if size != alloc.size || align != alloc.align { let bytes = alloc.size; throw_unsup!(IncorrectAllocationInformation(size, bytes, align, alloc.align)) } } // Let the machine take some extra action let size = alloc.size; AllocationExtra::memory_deallocated(&mut alloc, ptr, size)?; // Don't forget to remember size and align of this now-dead allocation let old = self.dead_alloc_map.insert( ptr.alloc_id, (alloc.size, alloc.align) ); if old.is_some() { bug!("Nothing can be deallocated twice"); } Ok(()) } /// Check if the given scalar is allowed to do a memory access of given `size` /// and `align`. On success, returns `None` for zero-sized accesses (where /// nothing else is left to do) and a `Pointer` to use for the actual access otherwise. /// Crucially, if the input is a `Pointer`, we will test it for liveness /// *even if* the size is 0. /// /// Everyone accessing memory based on a `Scalar` should use this method to get the /// `Pointer` they need. And even if you already have a `Pointer`, call this method /// to make sure it is sufficiently aligned and not dangling. Not doing that may /// cause ICEs. /// /// Most of the time you should use `check_mplace_access`, but when you just have a pointer, /// this method is still appropriate. #[inline(always)] pub fn check_ptr_access( &self, sptr: Scalar, size: Size, align: Align, ) -> InterpResult<'tcx, Option>> { let align = if M::CHECK_ALIGN { Some(align) } else { None }; self.check_ptr_access_align(sptr, size, align) } /// Like `check_ptr_access`, but *definitely* checks alignment when `align` /// is `Some` (overriding `M::CHECK_ALIGN`). pub(super) fn check_ptr_access_align( &self, sptr: Scalar, size: Size, align: Option, ) -> InterpResult<'tcx, Option>> { fn check_offset_align(offset: u64, align: Align) -> InterpResult<'static> { if offset % align.bytes() == 0 { Ok(()) } else { // The biggest power of two through which `offset` is divisible. let offset_pow2 = 1 << offset.trailing_zeros(); throw_unsup!(AlignmentCheckFailed { has: Align::from_bytes(offset_pow2).unwrap(), required: align, }) } } // Normalize to a `Pointer` if we definitely need one. let normalized = if size.bytes() == 0 { // Can be an integer, just take what we got. We do NOT `force_bits` here; // if this is already a `Pointer` we want to do the bounds checks! sptr } else { // A "real" access, we must get a pointer. Scalar::Ptr(self.force_ptr(sptr)?) }; Ok(match normalized.to_bits_or_ptr(self.pointer_size(), self) { Ok(bits) => { let bits = bits as u64; // it's ptr-sized assert!(size.bytes() == 0); // Must be non-NULL. if bits == 0 { throw_unsup!(InvalidNullPointerUsage) } // Must be aligned. if let Some(align) = align { check_offset_align(bits, align)?; } None } Err(ptr) => { let (allocation_size, alloc_align) = self.get_size_and_align(ptr.alloc_id, AllocCheck::Dereferencable)?; // Test bounds. This also ensures non-NULL. // It is sufficient to check this for the end pointer. The addition // checks for overflow. let end_ptr = ptr.offset(size, self)?; end_ptr.check_inbounds_alloc(allocation_size, CheckInAllocMsg::MemoryAccessTest)?; // Test align. Check this last; if both bounds and alignment are violated // we want the error to be about the bounds. if let Some(align) = align { if alloc_align.bytes() < align.bytes() { // The allocation itself is not aligned enough. // FIXME: Alignment check is too strict, depending on the base address that // got picked we might be aligned even if this check fails. // We instead have to fall back to converting to an integer and checking // the "real" alignment. throw_unsup!(AlignmentCheckFailed { has: alloc_align, required: align, }); } check_offset_align(ptr.offset.bytes(), align)?; } // We can still be zero-sized in this branch, in which case we have to // return `None`. if size.bytes() == 0 { None } else { Some(ptr) } } }) } /// Test if the pointer might be NULL. pub fn ptr_may_be_null( &self, ptr: Pointer, ) -> bool { let (size, _align) = self.get_size_and_align(ptr.alloc_id, AllocCheck::MaybeDead) .expect("alloc info with MaybeDead cannot fail"); ptr.check_inbounds_alloc(size, CheckInAllocMsg::NullPointerTest).is_err() } } /// Allocation accessors impl<'mir, 'tcx, M: Machine<'mir, 'tcx>> Memory<'mir, 'tcx, M> { /// Helper function to obtain the global (tcx) allocation for a static. /// This attempts to return a reference to an existing allocation if /// one can be found in `tcx`. That, however, is only possible if `tcx` and /// this machine use the same pointer tag, so it is indirected through /// `M::tag_allocation`. /// /// Notice that every static has two `AllocId` that will resolve to the same /// thing here: one maps to `GlobalAlloc::Static`, this is the "lazy" ID, /// and the other one is maps to `GlobalAlloc::Memory`, this is returned by /// `const_eval_raw` and it is the "resolved" ID. /// The resolved ID is never used by the interpreted progrma, it is hidden. /// The `GlobalAlloc::Memory` branch here is still reachable though; when a static /// contains a reference to memory that was created during its evaluation (i.e., not to /// another static), those inner references only exist in "resolved" form. fn get_static_alloc( memory_extra: &M::MemoryExtra, tcx: TyCtxtAt<'tcx>, id: AllocId, ) -> InterpResult<'tcx, Cow<'tcx, Allocation>> { let alloc = tcx.alloc_map.lock().get(id); let alloc = match alloc { Some(GlobalAlloc::Memory(mem)) => Cow::Borrowed(mem), Some(GlobalAlloc::Function(..)) => throw_unsup!(DerefFunctionPointer), None => throw_unsup!(DanglingPointerDeref), Some(GlobalAlloc::Static(def_id)) => { // We got a "lazy" static that has not been computed yet. if tcx.is_foreign_item(def_id) { trace!("static_alloc: foreign item {:?}", def_id); M::find_foreign_static(tcx.tcx, def_id)? } else { trace!("static_alloc: Need to compute {:?}", def_id); let instance = Instance::mono(tcx.tcx, def_id); let gid = GlobalId { instance, promoted: None, }; // use the raw query here to break validation cycles. Later uses of the static // will call the full query anyway let raw_const = tcx.const_eval_raw(ty::ParamEnv::reveal_all().and(gid)) .map_err(|err| { // no need to report anything, the const_eval call takes care of that // for statics assert!(tcx.is_static(def_id)); match err { ErrorHandled::Reported => err_inval!(ReferencedConstant), ErrorHandled::TooGeneric => err_inval!(TooGeneric), } })?; // Make sure we use the ID of the resolved memory, not the lazy one! let id = raw_const.alloc_id; let allocation = tcx.alloc_map.lock().unwrap_memory(id); M::before_access_static(allocation)?; Cow::Borrowed(allocation) } } }; // We got tcx memory. Let the machine figure out whether and how to // turn that into memory with the right pointer tag. Ok(M::tag_allocation( memory_extra, id, // always use the ID we got as input, not the "hidden" one. alloc, M::STATIC_KIND.map(MemoryKind::Machine), ).0) } pub fn get( &self, id: AllocId, ) -> InterpResult<'tcx, &Allocation> { // The error type of the inner closure here is somewhat funny. We have two // ways of "erroring": An actual error, or because we got a reference from // `get_static_alloc` that we can actually use directly without inserting anything anywhere. // So the error type is `InterpResult<'tcx, &Allocation>`. let a = self.alloc_map.get_or(id, || { let alloc = Self::get_static_alloc(&self.extra, self.tcx, id).map_err(Err)?; match alloc { Cow::Borrowed(alloc) => { // We got a ref, cheaply return that as an "error" so that the // map does not get mutated. Err(Ok(alloc)) } Cow::Owned(alloc) => { // Need to put it into the map and return a ref to that let kind = M::STATIC_KIND.expect( "I got an owned allocation that I have to copy but the machine does \ not expect that to happen" ); Ok((MemoryKind::Machine(kind), alloc)) } } }); // Now unpack that funny error type match a { Ok(a) => Ok(&a.1), Err(a) => a } } pub fn get_mut( &mut self, id: AllocId, ) -> InterpResult<'tcx, &mut Allocation> { let tcx = self.tcx; let memory_extra = &self.extra; let a = self.alloc_map.get_mut_or(id, || { // Need to make a copy, even if `get_static_alloc` is able // to give us a cheap reference. let alloc = Self::get_static_alloc(memory_extra, tcx, id)?; if alloc.mutability == Mutability::Immutable { throw_unsup!(ModifiedConstantMemory) } match M::STATIC_KIND { Some(kind) => Ok((MemoryKind::Machine(kind), alloc.into_owned())), None => throw_unsup!(ModifiedStatic), } }); // Unpack the error type manually because type inference doesn't // work otherwise (and we cannot help it because `impl Trait`) match a { Err(e) => Err(e), Ok(a) => { let a = &mut a.1; if a.mutability == Mutability::Immutable { throw_unsup!(ModifiedConstantMemory) } Ok(a) } } } /// Obtain the size and alignment of an allocation, even if that allocation has /// been deallocated. /// /// If `liveness` is `AllocCheck::MaybeDead`, this function always returns `Ok`. pub fn get_size_and_align( &self, id: AllocId, liveness: AllocCheck, ) -> InterpResult<'static, (Size, Align)> { // # Regular allocations // Don't use `self.get` here as that will // a) cause cycles in case `id` refers to a static // b) duplicate a static's allocation in miri if let Some((_, alloc)) = self.alloc_map.get(id) { return Ok((alloc.size, alloc.align)); } // # Function pointers // (both global from `alloc_map` and local from `extra_fn_ptr_map`) if let Ok(_) = self.get_fn_alloc(id) { return if let AllocCheck::Dereferencable = liveness { // The caller requested no function pointers. throw_unsup!(DerefFunctionPointer) } else { Ok((Size::ZERO, Align::from_bytes(1).unwrap())) }; } // # Statics // Can't do this in the match argument, we may get cycle errors since the lock would // be held throughout the match. let alloc = self.tcx.alloc_map.lock().get(id); match alloc { Some(GlobalAlloc::Static(did)) => { // Use size and align of the type. let ty = self.tcx.type_of(did); let layout = self.tcx.layout_of(ParamEnv::empty().and(ty)).unwrap(); Ok((layout.size, layout.align.abi)) }, Some(GlobalAlloc::Memory(alloc)) => // Need to duplicate the logic here, because the global allocations have // different associated types than the interpreter-local ones. Ok((alloc.size, alloc.align)), Some(GlobalAlloc::Function(_)) => bug!("We already checked function pointers above"), // The rest must be dead. None => if let AllocCheck::MaybeDead = liveness { // Deallocated pointers are allowed, we should be able to find // them in the map. Ok(*self.dead_alloc_map.get(&id) .expect("deallocated pointers should all be recorded in \ `dead_alloc_map`")) } else { throw_unsup!(DanglingPointerDeref) }, } } fn get_fn_alloc(&self, id: AllocId) -> InterpResult<'tcx, FnVal<'tcx, M::ExtraFnVal>> { trace!("reading fn ptr: {}", id); if let Some(extra) = self.extra_fn_ptr_map.get(&id) { Ok(FnVal::Other(*extra)) } else { match self.tcx.alloc_map.lock().get(id) { Some(GlobalAlloc::Function(instance)) => Ok(FnVal::Instance(instance)), _ => throw_unsup!(ExecuteMemory), } } } pub fn get_fn( &self, ptr: Scalar, ) -> InterpResult<'tcx, FnVal<'tcx, M::ExtraFnVal>> { let ptr = self.force_ptr(ptr)?; // We definitely need a pointer value. if ptr.offset.bytes() != 0 { throw_unsup!(InvalidFunctionPointer) } self.get_fn_alloc(ptr.alloc_id) } pub fn mark_immutable(&mut self, id: AllocId) -> InterpResult<'tcx> { self.get_mut(id)?.mutability = Mutability::Immutable; Ok(()) } /// For debugging, print an allocation and all allocations it points to, recursively. pub fn dump_alloc(&self, id: AllocId) { self.dump_allocs(vec![id]); } fn dump_alloc_helper( &self, allocs_seen: &mut FxHashSet, allocs_to_print: &mut VecDeque, mut msg: String, alloc: &Allocation, extra: String, ) { use std::fmt::Write; let prefix_len = msg.len(); let mut relocations = vec![]; for i in 0..alloc.size.bytes() { let i = Size::from_bytes(i); if let Some(&(_, target_id)) = alloc.relocations().get(&i) { if allocs_seen.insert(target_id) { allocs_to_print.push_back(target_id); } relocations.push((i, target_id)); } if alloc.undef_mask().is_range_defined(i, i + Size::from_bytes(1)).is_ok() { // this `as usize` is fine, since `i` came from a `usize` let i = i.bytes() as usize; // Checked definedness (and thus range) and relocations. This access also doesn't // influence interpreter execution but is only for debugging. let bytes = alloc.inspect_with_undef_and_ptr_outside_interpreter(i..i+1); write!(msg, "{:02x} ", bytes[0]).unwrap(); } else { msg.push_str("__ "); } } trace!( "{}({} bytes, alignment {}){}", msg, alloc.size.bytes(), alloc.align.bytes(), extra ); if !relocations.is_empty() { msg.clear(); write!(msg, "{:1$}", "", prefix_len).unwrap(); // Print spaces. let mut pos = Size::ZERO; let relocation_width = (self.pointer_size().bytes() - 1) * 3; for (i, target_id) in relocations { // this `as usize` is fine, since we can't print more chars than `usize::MAX` write!(msg, "{:1$}", "", ((i - pos) * 3).bytes() as usize).unwrap(); let target = format!("({})", target_id); // this `as usize` is fine, since we can't print more chars than `usize::MAX` write!(msg, "└{0:─^1$}┘ ", target, relocation_width as usize).unwrap(); pos = i + self.pointer_size(); } trace!("{}", msg); } } /// For debugging, print a list of allocations and all allocations they point to, recursively. pub fn dump_allocs(&self, mut allocs: Vec) { if !log_enabled!(::log::Level::Trace) { return; } allocs.sort(); allocs.dedup(); let mut allocs_to_print = VecDeque::from(allocs); let mut allocs_seen = FxHashSet::default(); while let Some(id) = allocs_to_print.pop_front() { let msg = format!("Alloc {:<5} ", format!("{}:", id)); // normal alloc? match self.alloc_map.get_or(id, || Err(())) { Ok((kind, alloc)) => { let extra = match kind { MemoryKind::Stack => " (stack)".to_owned(), MemoryKind::Vtable => " (vtable)".to_owned(), MemoryKind::Machine(m) => format!(" ({:?})", m), }; self.dump_alloc_helper( &mut allocs_seen, &mut allocs_to_print, msg, alloc, extra ); }, Err(()) => { // static alloc? match self.tcx.alloc_map.lock().get(id) { Some(GlobalAlloc::Memory(alloc)) => { self.dump_alloc_helper( &mut allocs_seen, &mut allocs_to_print, msg, alloc, " (immutable)".to_owned() ); } Some(GlobalAlloc::Function(func)) => { trace!("{} {}", msg, func); } Some(GlobalAlloc::Static(did)) => { trace!("{} {:?}", msg, did); } None => { trace!("{} (deallocated)", msg); } } }, }; } } pub fn leak_report(&self) -> usize { trace!("### LEAK REPORT ###"); let leaks: Vec<_> = self.alloc_map.filter_map_collect(|&id, &(kind, _)| { if kind.may_leak() { None } else { Some(id) } }); let n = leaks.len(); self.dump_allocs(leaks); n } /// This is used by [priroda](https://github.com/oli-obk/priroda) pub fn alloc_map(&self) -> &M::MemoryMap { &self.alloc_map } } /// Reading and writing. impl<'mir, 'tcx, M: Machine<'mir, 'tcx>> Memory<'mir, 'tcx, M> { /// Reads the given number of bytes from memory. Returns them as a slice. /// /// Performs appropriate bounds checks. pub fn read_bytes( &self, ptr: Scalar, size: Size, ) -> InterpResult<'tcx, &[u8]> { let ptr = match self.check_ptr_access(ptr, size, Align::from_bytes(1).unwrap())? { Some(ptr) => ptr, None => return Ok(&[]), // zero-sized access }; self.get(ptr.alloc_id)?.get_bytes(self, ptr, size) } /// Reads a 0-terminated sequence of bytes from memory. Returns them as a slice. /// /// Performs appropriate bounds checks. pub fn read_c_str(&self, ptr: Scalar) -> InterpResult<'tcx, &[u8]> { let ptr = self.force_ptr(ptr)?; // We need to read at least 1 byte, so we *need* a ptr. self.get(ptr.alloc_id)?.read_c_str(self, ptr) } /// Writes the given stream of bytes into memory. /// /// Performs appropriate bounds checks. pub fn write_bytes( &mut self, ptr: Scalar, src: impl IntoIterator, ) -> InterpResult<'tcx> { let src = src.into_iter(); let size = Size::from_bytes(src.size_hint().0 as u64); // `write_bytes` checks that this lower bound matches the upper bound matches reality. let ptr = match self.check_ptr_access(ptr, size, Align::from_bytes(1).unwrap())? { Some(ptr) => ptr, None => return Ok(()), // zero-sized access }; let tcx = self.tcx.tcx; self.get_mut(ptr.alloc_id)?.write_bytes(&tcx, ptr, src) } /// Expects the caller to have checked bounds and alignment. pub fn copy( &mut self, src: Pointer, dest: Pointer, size: Size, nonoverlapping: bool, ) -> InterpResult<'tcx> { self.copy_repeatedly(src, dest, size, 1, nonoverlapping) } /// Expects the caller to have checked bounds and alignment. pub fn copy_repeatedly( &mut self, src: Pointer, dest: Pointer, size: Size, length: u64, nonoverlapping: bool, ) -> InterpResult<'tcx> { // first copy the relocations to a temporary buffer, because // `get_bytes_mut` will clear the relocations, which is correct, // since we don't want to keep any relocations at the target. // (`get_bytes_with_undef_and_ptr` below checks that there are no // relocations overlapping the edges; those would not be handled correctly). let relocations = self.get(src.alloc_id)? .prepare_relocation_copy(self, src, size, dest, length); let tcx = self.tcx.tcx; // This checks relocation edges on the src. let src_bytes = self.get(src.alloc_id)? .get_bytes_with_undef_and_ptr(&tcx, src, size)? .as_ptr(); let dest_bytes = self.get_mut(dest.alloc_id)? .get_bytes_mut(&tcx, dest, size * length)? .as_mut_ptr(); // SAFE: The above indexing would have panicked if there weren't at least `size` bytes // behind `src` and `dest`. Also, we use the overlapping-safe `ptr::copy` if `src` and // `dest` could possibly overlap. // The pointers above remain valid even if the `HashMap` table is moved around because they // point into the `Vec` storing the bytes. unsafe { assert_eq!(size.bytes() as usize as u64, size.bytes()); if src.alloc_id == dest.alloc_id { if nonoverlapping { if (src.offset <= dest.offset && src.offset + size > dest.offset) || (dest.offset <= src.offset && dest.offset + size > src.offset) { throw_ub_format!( "copy_nonoverlapping called on overlapping ranges" ) } } for i in 0..length { ptr::copy(src_bytes, dest_bytes.offset((size.bytes() * i) as isize), size.bytes() as usize); } } else { for i in 0..length { ptr::copy_nonoverlapping(src_bytes, dest_bytes.offset((size.bytes() * i) as isize), size.bytes() as usize); } } } // copy definedness to the destination self.copy_undef_mask(src, dest, size, length)?; // copy the relocations to the destination self.get_mut(dest.alloc_id)?.mark_relocation_range(relocations); Ok(()) } } /// Undefined bytes impl<'mir, 'tcx, M: Machine<'mir, 'tcx>> Memory<'mir, 'tcx, M> { // FIXME: Add a fast version for the common, nonoverlapping case fn copy_undef_mask( &mut self, src: Pointer, dest: Pointer, size: Size, repeat: u64, ) -> InterpResult<'tcx> { // The bits have to be saved locally before writing to dest in case src and dest overlap. assert_eq!(size.bytes() as usize as u64, size.bytes()); let src_alloc = self.get(src.alloc_id)?; let compressed = src_alloc.compress_undef_range(src, size); // now fill in all the data let dest_allocation = self.get_mut(dest.alloc_id)?; dest_allocation.mark_compressed_undef_range(&compressed, dest, size, repeat); Ok(()) } pub fn force_ptr( &self, scalar: Scalar, ) -> InterpResult<'tcx, Pointer> { match scalar { Scalar::Ptr(ptr) => Ok(ptr), _ => M::int_to_ptr(&self, scalar.to_usize(self)?) } } pub fn force_bits( &self, scalar: Scalar, size: Size ) -> InterpResult<'tcx, u128> { match scalar.to_bits_or_ptr(size, self) { Ok(bits) => Ok(bits), Err(ptr) => Ok(M::ptr_to_int(&self, ptr)? as u128) } } }