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rust/compiler/rustc_codegen_llvm/src/context.rs
bors bb587b1a17 Auto merge of #80652 - calebzulawski:simd-lanes, r=nagisa 
Improve SIMD type element count validation

Resolves rust-lang/stdsimd#53.

These changes are motivated by `stdsimd` moving in the direction of const generic vectors, e.g.:
```rust
#[repr(simd)]
struct SimdF32<const N: usize>([f32; N]);
```

This makes a few changes:
* Establishes a maximum SIMD lane count of 2^16 (65536).  This value is arbitrary, but attempts to validate lane count before hitting potential errors in the backend.  It's not clear what LLVM's maximum lane count is, but cranelift's appears to be much less than `usize::MAX`, at least.
* Expands some SIMD intrinsics to support arbitrary lane counts.  This resolves the ICE in the linked issue.
* Attempts to catch invalid-sized vectors during typeck when possible.

Unresolved questions:
* Generic-length vectors can't be validated in typeck and are only validated after monomorphization while computing layout.  This "works", but the errors simply bail out with no context beyond the name of the type.  Should these errors instead return `LayoutError` or otherwise provide context in some way?  As it stands, users of `stdsimd` could trivially produce monomorphization errors by making zero-length vectors.

cc `@bjorn3`
2021-02-07 22:25:14 +00:00

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use crate::attributes;
use crate::callee::get_fn;
use crate::coverageinfo;
use crate::debuginfo;
use crate::llvm;
use crate::llvm_util;
use crate::type_::Type;
use crate::value::Value;
use rustc_codegen_ssa::base::wants_msvc_seh;
use rustc_codegen_ssa::traits::*;
use rustc_data_structures::base_n;
use rustc_data_structures::const_cstr;
use rustc_data_structures::fx::FxHashMap;
use rustc_data_structures::small_c_str::SmallCStr;
use rustc_middle::bug;
use rustc_middle::mir::mono::CodegenUnit;
use rustc_middle::ty::layout::{HasParamEnv, LayoutError, TyAndLayout};
use rustc_middle::ty::{self, Instance, Ty, TyCtxt};
use rustc_session::config::{CFGuard, CrateType, DebugInfo};
use rustc_session::Session;
use rustc_span::source_map::{Span, DUMMY_SP};
use rustc_span::symbol::Symbol;
use rustc_target::abi::{HasDataLayout, LayoutOf, PointeeInfo, Size, TargetDataLayout, VariantIdx};
use rustc_target::spec::{HasTargetSpec, RelocModel, Target, TlsModel};
use std::cell::{Cell, RefCell};
use std::ffi::CStr;
use std::str;
/// There is one `CodegenCx` per compilation unit. Each one has its own LLVM
/// `llvm::Context` so that several compilation units may be optimized in parallel.
/// All other LLVM data structures in the `CodegenCx` are tied to that `llvm::Context`.
pub struct CodegenCx<'ll, 'tcx> {
pub tcx: TyCtxt<'tcx>,
pub check_overflow: bool,
pub use_dll_storage_attrs: bool,
pub tls_model: llvm::ThreadLocalMode,
pub llmod: &'ll llvm::Module,
pub llcx: &'ll llvm::Context,
pub codegen_unit: &'tcx CodegenUnit<'tcx>,
/// Cache instances of monomorphic and polymorphic items
pub instances: RefCell<FxHashMap<Instance<'tcx>, &'ll Value>>,
/// Cache generated vtables
pub vtables:
RefCell<FxHashMap<(Ty<'tcx>, Option<ty::PolyExistentialTraitRef<'tcx>>), &'ll Value>>,
/// Cache of constant strings,
pub const_cstr_cache: RefCell<FxHashMap<Symbol, &'ll Value>>,
/// Reverse-direction for const ptrs cast from globals.
///
/// Key is a Value holding a `*T`,
/// Val is a Value holding a `*[T]`.
///
/// Needed because LLVM loses pointer->pointee association
/// when we ptrcast, and we have to ptrcast during codegen
/// of a `[T]` const because we form a slice, a `(*T,usize)` pair, not
/// a pointer to an LLVM array type. Similar for trait objects.
pub const_unsized: RefCell<FxHashMap<&'ll Value, &'ll Value>>,
/// Cache of emitted const globals (value -> global)
pub const_globals: RefCell<FxHashMap<&'ll Value, &'ll Value>>,
/// List of globals for static variables which need to be passed to the
/// LLVM function ReplaceAllUsesWith (RAUW) when codegen is complete.
/// (We have to make sure we don't invalidate any Values referring
/// to constants.)
pub statics_to_rauw: RefCell<Vec<(&'ll Value, &'ll Value)>>,
/// Statics that will be placed in the llvm.used variable
/// See <http://llvm.org/docs/LangRef.html#the-llvm-used-global-variable> for details
pub used_statics: RefCell<Vec<&'ll Value>>,
pub lltypes: RefCell<FxHashMap<(Ty<'tcx>, Option<VariantIdx>), &'ll Type>>,
pub scalar_lltypes: RefCell<FxHashMap<Ty<'tcx>, &'ll Type>>,
pub pointee_infos: RefCell<FxHashMap<(Ty<'tcx>, Size), Option<PointeeInfo>>>,
pub isize_ty: &'ll Type,
pub coverage_cx: Option<coverageinfo::CrateCoverageContext<'tcx>>,
pub dbg_cx: Option<debuginfo::CrateDebugContext<'ll, 'tcx>>,
eh_personality: Cell<Option<&'ll Value>>,
eh_catch_typeinfo: Cell<Option<&'ll Value>>,
pub rust_try_fn: Cell<Option<&'ll Value>>,
intrinsics: RefCell<FxHashMap<&'static str, &'ll Value>>,
/// A counter that is used for generating local symbol names
local_gen_sym_counter: Cell<usize>,
}
fn to_llvm_tls_model(tls_model: TlsModel) -> llvm::ThreadLocalMode {
match tls_model {
TlsModel::GeneralDynamic => llvm::ThreadLocalMode::GeneralDynamic,
TlsModel::LocalDynamic => llvm::ThreadLocalMode::LocalDynamic,
TlsModel::InitialExec => llvm::ThreadLocalMode::InitialExec,
TlsModel::LocalExec => llvm::ThreadLocalMode::LocalExec,
}
}
fn strip_x86_address_spaces(data_layout: String) -> String {
data_layout.replace("-p270:32:32-p271:32:32-p272:64:64-", "-")
}
pub unsafe fn create_module(
tcx: TyCtxt<'_>,
llcx: &'ll llvm::Context,
mod_name: &str,
) -> &'ll llvm::Module {
let sess = tcx.sess;
let mod_name = SmallCStr::new(mod_name);
let llmod = llvm::LLVMModuleCreateWithNameInContext(mod_name.as_ptr(), llcx);
let mut target_data_layout = sess.target.data_layout.clone();
if llvm_util::get_version() < (10, 0, 0)
&& (sess.target.arch == "x86" || sess.target.arch == "x86_64")
{
target_data_layout = strip_x86_address_spaces(target_data_layout);
}
// Ensure the data-layout values hardcoded remain the defaults.
if sess.target.is_builtin {
let tm = crate::back::write::create_informational_target_machine(tcx.sess);
llvm::LLVMRustSetDataLayoutFromTargetMachine(llmod, tm);
llvm::LLVMRustDisposeTargetMachine(tm);
let llvm_data_layout = llvm::LLVMGetDataLayoutStr(llmod);
let llvm_data_layout = str::from_utf8(CStr::from_ptr(llvm_data_layout).to_bytes())
.expect("got a non-UTF8 data-layout from LLVM");
// Unfortunately LLVM target specs change over time, and right now we
// don't have proper support to work with any more than one
// `data_layout` than the one that is in the rust-lang/rust repo. If
// this compiler is configured against a custom LLVM, we may have a
// differing data layout, even though we should update our own to use
// that one.
//
// As an interim hack, if CFG_LLVM_ROOT is not an empty string then we
// disable this check entirely as we may be configured with something
// that has a different target layout.
//
// Unsure if this will actually cause breakage when rustc is configured
// as such.
//
// FIXME(#34960)
let cfg_llvm_root = option_env!("CFG_LLVM_ROOT").unwrap_or("");
let custom_llvm_used = cfg_llvm_root.trim() != "";
if !custom_llvm_used && target_data_layout != llvm_data_layout {
bug!(
"data-layout for builtin `{}` target, `{}`, \
differs from LLVM default, `{}`",
sess.target.llvm_target,
target_data_layout,
llvm_data_layout
);
}
}
let data_layout = SmallCStr::new(&target_data_layout);
llvm::LLVMSetDataLayout(llmod, data_layout.as_ptr());
let llvm_target = SmallCStr::new(&sess.target.llvm_target);
llvm::LLVMRustSetNormalizedTarget(llmod, llvm_target.as_ptr());
if sess.relocation_model() == RelocModel::Pic {
llvm::LLVMRustSetModulePICLevel(llmod);
// PIE is potentially more effective than PIC, but can only be used in executables.
// If all our outputs are executables, then we can relax PIC to PIE.
if sess.crate_types().iter().all(|ty| *ty == CrateType::Executable) {
llvm::LLVMRustSetModulePIELevel(llmod);
}
}
// If skipping the PLT is enabled, we need to add some module metadata
// to ensure intrinsic calls don't use it.
if !sess.needs_plt() {
let avoid_plt = "RtLibUseGOT\0".as_ptr().cast();
llvm::LLVMRustAddModuleFlag(llmod, avoid_plt, 1);
}
// Control Flow Guard is currently only supported by the MSVC linker on Windows.
if sess.target.is_like_msvc {
match sess.opts.cg.control_flow_guard {
CFGuard::Disabled => {}
CFGuard::NoChecks => {
// Set `cfguard=1` module flag to emit metadata only.
llvm::LLVMRustAddModuleFlag(llmod, "cfguard\0".as_ptr() as *const _, 1)
}
CFGuard::Checks => {
// Set `cfguard=2` module flag to emit metadata and checks.
llvm::LLVMRustAddModuleFlag(llmod, "cfguard\0".as_ptr() as *const _, 2)
}
}
}
llmod
}
impl<'ll, 'tcx> CodegenCx<'ll, 'tcx> {
crate fn new(
tcx: TyCtxt<'tcx>,
codegen_unit: &'tcx CodegenUnit<'tcx>,
llvm_module: &'ll crate::ModuleLlvm,
) -> Self {
// An interesting part of Windows which MSVC forces our hand on (and
// apparently MinGW didn't) is the usage of `dllimport` and `dllexport`
// attributes in LLVM IR as well as native dependencies (in C these
// correspond to `__declspec(dllimport)`).
//
// LD (BFD) in MinGW mode can often correctly guess `dllexport` but
// relying on that can result in issues like #50176.
// LLD won't support that and expects symbols with proper attributes.
// Because of that we make MinGW target emit dllexport just like MSVC.
// When it comes to dllimport we use it for constants but for functions
// rely on the linker to do the right thing. Opposed to dllexport this
// task is easy for them (both LD and LLD) and allows us to easily use
// symbols from static libraries in shared libraries.
//
// Whenever a dynamic library is built on Windows it must have its public
// interface specified by functions tagged with `dllexport` or otherwise
// they're not available to be linked against. This poses a few problems
// for the compiler, some of which are somewhat fundamental, but we use
// the `use_dll_storage_attrs` variable below to attach the `dllexport`
// attribute to all LLVM functions that are exported e.g., they're
// already tagged with external linkage). This is suboptimal for a few
// reasons:
//
// * If an object file will never be included in a dynamic library,
// there's no need to attach the dllexport attribute. Most object
// files in Rust are not destined to become part of a dll as binaries
// are statically linked by default.
// * If the compiler is emitting both an rlib and a dylib, the same
// source object file is currently used but with MSVC this may be less
// feasible. The compiler may be able to get around this, but it may
// involve some invasive changes to deal with this.
//
// The flipside of this situation is that whenever you link to a dll and
// you import a function from it, the import should be tagged with
// `dllimport`. At this time, however, the compiler does not emit
// `dllimport` for any declarations other than constants (where it is
// required), which is again suboptimal for even more reasons!
//
// * Calling a function imported from another dll without using
// `dllimport` causes the linker/compiler to have extra overhead (one
// `jmp` instruction on x86) when calling the function.
// * The same object file may be used in different circumstances, so a
// function may be imported from a dll if the object is linked into a
// dll, but it may be just linked against if linked into an rlib.
// * The compiler has no knowledge about whether native functions should
// be tagged dllimport or not.
//
// For now the compiler takes the perf hit (I do not have any numbers to
// this effect) by marking very little as `dllimport` and praying the
// linker will take care of everything. Fixing this problem will likely
// require adding a few attributes to Rust itself (feature gated at the
// start) and then strongly recommending static linkage on Windows!
let use_dll_storage_attrs = tcx.sess.target.is_like_windows;
let check_overflow = tcx.sess.overflow_checks();
let tls_model = to_llvm_tls_model(tcx.sess.tls_model());
let (llcx, llmod) = (&*llvm_module.llcx, llvm_module.llmod());
let coverage_cx = if tcx.sess.opts.debugging_opts.instrument_coverage {
let covctx = coverageinfo::CrateCoverageContext::new();
Some(covctx)
} else {
None
};
let dbg_cx = if tcx.sess.opts.debuginfo != DebugInfo::None {
let dctx = debuginfo::CrateDebugContext::new(llmod);
debuginfo::metadata::compile_unit_metadata(tcx, &codegen_unit.name().as_str(), &dctx);
Some(dctx)
} else {
None
};
let isize_ty = Type::ix_llcx(llcx, tcx.data_layout.pointer_size.bits());
CodegenCx {
tcx,
check_overflow,
use_dll_storage_attrs,
tls_model,
llmod,
llcx,
codegen_unit,
instances: Default::default(),
vtables: Default::default(),
const_cstr_cache: Default::default(),
const_unsized: Default::default(),
const_globals: Default::default(),
statics_to_rauw: RefCell::new(Vec::new()),
used_statics: RefCell::new(Vec::new()),
lltypes: Default::default(),
scalar_lltypes: Default::default(),
pointee_infos: Default::default(),
isize_ty,
coverage_cx,
dbg_cx,
eh_personality: Cell::new(None),
eh_catch_typeinfo: Cell::new(None),
rust_try_fn: Cell::new(None),
intrinsics: Default::default(),
local_gen_sym_counter: Cell::new(0),
}
}
crate fn statics_to_rauw(&self) -> &RefCell<Vec<(&'ll Value, &'ll Value)>> {
&self.statics_to_rauw
}
#[inline]
pub fn coverage_context(&'a self) -> Option<&'a coverageinfo::CrateCoverageContext<'tcx>> {
self.coverage_cx.as_ref()
}
}
impl MiscMethods<'tcx> for CodegenCx<'ll, 'tcx> {
fn vtables(
&self,
) -> &RefCell<FxHashMap<(Ty<'tcx>, Option<ty::PolyExistentialTraitRef<'tcx>>), &'ll Value>>
{
&self.vtables
}
fn get_fn(&self, instance: Instance<'tcx>) -> &'ll Value {
get_fn(self, instance)
}
fn get_fn_addr(&self, instance: Instance<'tcx>) -> &'ll Value {
get_fn(self, instance)
}
fn eh_personality(&self) -> &'ll Value {
// The exception handling personality function.
//
// If our compilation unit has the `eh_personality` lang item somewhere
// within it, then we just need to codegen that. Otherwise, we're
// building an rlib which will depend on some upstream implementation of
// this function, so we just codegen a generic reference to it. We don't
// specify any of the types for the function, we just make it a symbol
// that LLVM can later use.
//
// Note that MSVC is a little special here in that we don't use the
// `eh_personality` lang item at all. Currently LLVM has support for
// both Dwarf and SEH unwind mechanisms for MSVC targets and uses the
// *name of the personality function* to decide what kind of unwind side
// tables/landing pads to emit. It looks like Dwarf is used by default,
// injecting a dependency on the `_Unwind_Resume` symbol for resuming
// an "exception", but for MSVC we want to force SEH. This means that we
// can't actually have the personality function be our standard
// `rust_eh_personality` function, but rather we wired it up to the
// CRT's custom personality function, which forces LLVM to consider
// landing pads as "landing pads for SEH".
if let Some(llpersonality) = self.eh_personality.get() {
return llpersonality;
}
let tcx = self.tcx;
let llfn = match tcx.lang_items().eh_personality() {
Some(def_id) if !wants_msvc_seh(self.sess()) => self.get_fn_addr(
ty::Instance::resolve(
tcx,
ty::ParamEnv::reveal_all(),
def_id,
tcx.intern_substs(&[]),
)
.unwrap()
.unwrap(),
),
_ => {
let name = if wants_msvc_seh(self.sess()) {
"__CxxFrameHandler3"
} else {
"rust_eh_personality"
};
let fty = self.type_variadic_func(&[], self.type_i32());
self.declare_cfn(name, llvm::UnnamedAddr::Global, fty)
}
};
attributes::apply_target_cpu_attr(self, llfn);
self.eh_personality.set(Some(llfn));
llfn
}
fn sess(&self) -> &Session {
&self.tcx.sess
}
fn check_overflow(&self) -> bool {
self.check_overflow
}
fn codegen_unit(&self) -> &'tcx CodegenUnit<'tcx> {
self.codegen_unit
}
fn used_statics(&self) -> &RefCell<Vec<&'ll Value>> {
&self.used_statics
}
fn set_frame_pointer_elimination(&self, llfn: &'ll Value) {
attributes::set_frame_pointer_elimination(self, llfn)
}
fn apply_target_cpu_attr(&self, llfn: &'ll Value) {
attributes::apply_target_cpu_attr(self, llfn);
attributes::apply_tune_cpu_attr(self, llfn);
}
fn create_used_variable(&self) {
let name = const_cstr!("llvm.used");
let section = const_cstr!("llvm.metadata");
let array =
self.const_array(&self.type_ptr_to(self.type_i8()), &*self.used_statics.borrow());
unsafe {
let g = llvm::LLVMAddGlobal(self.llmod, self.val_ty(array), name.as_ptr());
llvm::LLVMSetInitializer(g, array);
llvm::LLVMRustSetLinkage(g, llvm::Linkage::AppendingLinkage);
llvm::LLVMSetSection(g, section.as_ptr());
}
}
fn declare_c_main(&self, fn_type: Self::Type) -> Option<Self::Function> {
if self.get_declared_value("main").is_none() {
Some(self.declare_cfn("main", llvm::UnnamedAddr::Global, fn_type))
} else {
// If the symbol already exists, it is an error: for example, the user wrote
// #[no_mangle] extern "C" fn main(..) {..}
// instead of #[start]
None
}
}
}
impl CodegenCx<'b, 'tcx> {
crate fn get_intrinsic(&self, key: &str) -> &'b Value {
if let Some(v) = self.intrinsics.borrow().get(key).cloned() {
return v;
}
self.declare_intrinsic(key).unwrap_or_else(|| bug!("unknown intrinsic '{}'", key))
}
fn insert_intrinsic(
&self,
name: &'static str,
args: Option<&[&'b llvm::Type]>,
ret: &'b llvm::Type,
) -> &'b llvm::Value {
let fn_ty = if let Some(args) = args {
self.type_func(args, ret)
} else {
self.type_variadic_func(&[], ret)
};
let f = self.declare_cfn(name, llvm::UnnamedAddr::No, fn_ty);
self.intrinsics.borrow_mut().insert(name, f);
f
}
fn declare_intrinsic(&self, key: &str) -> Option<&'b Value> {
macro_rules! ifn {
($name:expr, fn() -> $ret:expr) => (
if key == $name {
return Some(self.insert_intrinsic($name, Some(&[]), $ret));
}
);
($name:expr, fn(...) -> $ret:expr) => (
if key == $name {
return Some(self.insert_intrinsic($name, None, $ret));
}
);
($name:expr, fn($($arg:expr),*) -> $ret:expr) => (
if key == $name {
return Some(self.insert_intrinsic($name, Some(&[$($arg),*]), $ret));
}
);
}
macro_rules! mk_struct {
($($field_ty:expr),*) => (self.type_struct( &[$($field_ty),*], false))
}
let i8p = self.type_i8p();
let void = self.type_void();
let i1 = self.type_i1();
let t_i8 = self.type_i8();
let t_i16 = self.type_i16();
let t_i32 = self.type_i32();
let t_i64 = self.type_i64();
let t_i128 = self.type_i128();
let t_f32 = self.type_f32();
let t_f64 = self.type_f64();
ifn!("llvm.wasm.trunc.saturate.unsigned.i32.f32", fn(t_f32) -> t_i32);
ifn!("llvm.wasm.trunc.saturate.unsigned.i32.f64", fn(t_f64) -> t_i32);
ifn!("llvm.wasm.trunc.saturate.unsigned.i64.f32", fn(t_f32) -> t_i64);
ifn!("llvm.wasm.trunc.saturate.unsigned.i64.f64", fn(t_f64) -> t_i64);
ifn!("llvm.wasm.trunc.saturate.signed.i32.f32", fn(t_f32) -> t_i32);
ifn!("llvm.wasm.trunc.saturate.signed.i32.f64", fn(t_f64) -> t_i32);
ifn!("llvm.wasm.trunc.saturate.signed.i64.f32", fn(t_f32) -> t_i64);
ifn!("llvm.wasm.trunc.saturate.signed.i64.f64", fn(t_f64) -> t_i64);
ifn!("llvm.wasm.trunc.unsigned.i32.f32", fn(t_f32) -> t_i32);
ifn!("llvm.wasm.trunc.unsigned.i32.f64", fn(t_f64) -> t_i32);
ifn!("llvm.wasm.trunc.unsigned.i64.f32", fn(t_f32) -> t_i64);
ifn!("llvm.wasm.trunc.unsigned.i64.f64", fn(t_f64) -> t_i64);
ifn!("llvm.wasm.trunc.signed.i32.f32", fn(t_f32) -> t_i32);
ifn!("llvm.wasm.trunc.signed.i32.f64", fn(t_f64) -> t_i32);
ifn!("llvm.wasm.trunc.signed.i64.f32", fn(t_f32) -> t_i64);
ifn!("llvm.wasm.trunc.signed.i64.f64", fn(t_f64) -> t_i64);
ifn!("llvm.trap", fn() -> void);
ifn!("llvm.debugtrap", fn() -> void);
ifn!("llvm.frameaddress", fn(t_i32) -> i8p);
ifn!("llvm.sideeffect", fn() -> void);
ifn!("llvm.powi.f32", fn(t_f32, t_i32) -> t_f32);
ifn!("llvm.powi.f64", fn(t_f64, t_i32) -> t_f64);
ifn!("llvm.pow.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.pow.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.sqrt.f32", fn(t_f32) -> t_f32);
ifn!("llvm.sqrt.f64", fn(t_f64) -> t_f64);
ifn!("llvm.sin.f32", fn(t_f32) -> t_f32);
ifn!("llvm.sin.f64", fn(t_f64) -> t_f64);
ifn!("llvm.cos.f32", fn(t_f32) -> t_f32);
ifn!("llvm.cos.f64", fn(t_f64) -> t_f64);
ifn!("llvm.exp.f32", fn(t_f32) -> t_f32);
ifn!("llvm.exp.f64", fn(t_f64) -> t_f64);
ifn!("llvm.exp2.f32", fn(t_f32) -> t_f32);
ifn!("llvm.exp2.f64", fn(t_f64) -> t_f64);
ifn!("llvm.log.f32", fn(t_f32) -> t_f32);
ifn!("llvm.log.f64", fn(t_f64) -> t_f64);
ifn!("llvm.log10.f32", fn(t_f32) -> t_f32);
ifn!("llvm.log10.f64", fn(t_f64) -> t_f64);
ifn!("llvm.log2.f32", fn(t_f32) -> t_f32);
ifn!("llvm.log2.f64", fn(t_f64) -> t_f64);
ifn!("llvm.fma.f32", fn(t_f32, t_f32, t_f32) -> t_f32);
ifn!("llvm.fma.f64", fn(t_f64, t_f64, t_f64) -> t_f64);
ifn!("llvm.fabs.f32", fn(t_f32) -> t_f32);
ifn!("llvm.fabs.f64", fn(t_f64) -> t_f64);
ifn!("llvm.minnum.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.minnum.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.maxnum.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.maxnum.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.floor.f32", fn(t_f32) -> t_f32);
ifn!("llvm.floor.f64", fn(t_f64) -> t_f64);
ifn!("llvm.ceil.f32", fn(t_f32) -> t_f32);
ifn!("llvm.ceil.f64", fn(t_f64) -> t_f64);
ifn!("llvm.trunc.f32", fn(t_f32) -> t_f32);
ifn!("llvm.trunc.f64", fn(t_f64) -> t_f64);
ifn!("llvm.copysign.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.copysign.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.round.f32", fn(t_f32) -> t_f32);
ifn!("llvm.round.f64", fn(t_f64) -> t_f64);
ifn!("llvm.rint.f32", fn(t_f32) -> t_f32);
ifn!("llvm.rint.f64", fn(t_f64) -> t_f64);
ifn!("llvm.nearbyint.f32", fn(t_f32) -> t_f32);
ifn!("llvm.nearbyint.f64", fn(t_f64) -> t_f64);
ifn!("llvm.ctpop.i8", fn(t_i8) -> t_i8);
ifn!("llvm.ctpop.i16", fn(t_i16) -> t_i16);
ifn!("llvm.ctpop.i32", fn(t_i32) -> t_i32);
ifn!("llvm.ctpop.i64", fn(t_i64) -> t_i64);
ifn!("llvm.ctpop.i128", fn(t_i128) -> t_i128);
ifn!("llvm.ctlz.i8", fn(t_i8, i1) -> t_i8);
ifn!("llvm.ctlz.i16", fn(t_i16, i1) -> t_i16);
ifn!("llvm.ctlz.i32", fn(t_i32, i1) -> t_i32);
ifn!("llvm.ctlz.i64", fn(t_i64, i1) -> t_i64);
ifn!("llvm.ctlz.i128", fn(t_i128, i1) -> t_i128);
ifn!("llvm.cttz.i8", fn(t_i8, i1) -> t_i8);
ifn!("llvm.cttz.i16", fn(t_i16, i1) -> t_i16);
ifn!("llvm.cttz.i32", fn(t_i32, i1) -> t_i32);
ifn!("llvm.cttz.i64", fn(t_i64, i1) -> t_i64);
ifn!("llvm.cttz.i128", fn(t_i128, i1) -> t_i128);
ifn!("llvm.bswap.i16", fn(t_i16) -> t_i16);
ifn!("llvm.bswap.i32", fn(t_i32) -> t_i32);
ifn!("llvm.bswap.i64", fn(t_i64) -> t_i64);
ifn!("llvm.bswap.i128", fn(t_i128) -> t_i128);
ifn!("llvm.bitreverse.i8", fn(t_i8) -> t_i8);
ifn!("llvm.bitreverse.i16", fn(t_i16) -> t_i16);
ifn!("llvm.bitreverse.i32", fn(t_i32) -> t_i32);
ifn!("llvm.bitreverse.i64", fn(t_i64) -> t_i64);
ifn!("llvm.bitreverse.i128", fn(t_i128) -> t_i128);
ifn!("llvm.fshl.i8", fn(t_i8, t_i8, t_i8) -> t_i8);
ifn!("llvm.fshl.i16", fn(t_i16, t_i16, t_i16) -> t_i16);
ifn!("llvm.fshl.i32", fn(t_i32, t_i32, t_i32) -> t_i32);
ifn!("llvm.fshl.i64", fn(t_i64, t_i64, t_i64) -> t_i64);
ifn!("llvm.fshl.i128", fn(t_i128, t_i128, t_i128) -> t_i128);
ifn!("llvm.fshr.i8", fn(t_i8, t_i8, t_i8) -> t_i8);
ifn!("llvm.fshr.i16", fn(t_i16, t_i16, t_i16) -> t_i16);
ifn!("llvm.fshr.i32", fn(t_i32, t_i32, t_i32) -> t_i32);
ifn!("llvm.fshr.i64", fn(t_i64, t_i64, t_i64) -> t_i64);
ifn!("llvm.fshr.i128", fn(t_i128, t_i128, t_i128) -> t_i128);
ifn!("llvm.sadd.with.overflow.i8", fn(t_i8, t_i8) -> mk_struct! {t_i8, i1});
ifn!("llvm.sadd.with.overflow.i16", fn(t_i16, t_i16) -> mk_struct! {t_i16, i1});
ifn!("llvm.sadd.with.overflow.i32", fn(t_i32, t_i32) -> mk_struct! {t_i32, i1});
ifn!("llvm.sadd.with.overflow.i64", fn(t_i64, t_i64) -> mk_struct! {t_i64, i1});
ifn!("llvm.sadd.with.overflow.i128", fn(t_i128, t_i128) -> mk_struct! {t_i128, i1});
ifn!("llvm.uadd.with.overflow.i8", fn(t_i8, t_i8) -> mk_struct! {t_i8, i1});
ifn!("llvm.uadd.with.overflow.i16", fn(t_i16, t_i16) -> mk_struct! {t_i16, i1});
ifn!("llvm.uadd.with.overflow.i32", fn(t_i32, t_i32) -> mk_struct! {t_i32, i1});
ifn!("llvm.uadd.with.overflow.i64", fn(t_i64, t_i64) -> mk_struct! {t_i64, i1});
ifn!("llvm.uadd.with.overflow.i128", fn(t_i128, t_i128) -> mk_struct! {t_i128, i1});
ifn!("llvm.ssub.with.overflow.i8", fn(t_i8, t_i8) -> mk_struct! {t_i8, i1});
ifn!("llvm.ssub.with.overflow.i16", fn(t_i16, t_i16) -> mk_struct! {t_i16, i1});
ifn!("llvm.ssub.with.overflow.i32", fn(t_i32, t_i32) -> mk_struct! {t_i32, i1});
ifn!("llvm.ssub.with.overflow.i64", fn(t_i64, t_i64) -> mk_struct! {t_i64, i1});
ifn!("llvm.ssub.with.overflow.i128", fn(t_i128, t_i128) -> mk_struct! {t_i128, i1});
ifn!("llvm.usub.with.overflow.i8", fn(t_i8, t_i8) -> mk_struct! {t_i8, i1});
ifn!("llvm.usub.with.overflow.i16", fn(t_i16, t_i16) -> mk_struct! {t_i16, i1});
ifn!("llvm.usub.with.overflow.i32", fn(t_i32, t_i32) -> mk_struct! {t_i32, i1});
ifn!("llvm.usub.with.overflow.i64", fn(t_i64, t_i64) -> mk_struct! {t_i64, i1});
ifn!("llvm.usub.with.overflow.i128", fn(t_i128, t_i128) -> mk_struct! {t_i128, i1});
ifn!("llvm.smul.with.overflow.i8", fn(t_i8, t_i8) -> mk_struct! {t_i8, i1});
ifn!("llvm.smul.with.overflow.i16", fn(t_i16, t_i16) -> mk_struct! {t_i16, i1});
ifn!("llvm.smul.with.overflow.i32", fn(t_i32, t_i32) -> mk_struct! {t_i32, i1});
ifn!("llvm.smul.with.overflow.i64", fn(t_i64, t_i64) -> mk_struct! {t_i64, i1});
ifn!("llvm.smul.with.overflow.i128", fn(t_i128, t_i128) -> mk_struct! {t_i128, i1});
ifn!("llvm.umul.with.overflow.i8", fn(t_i8, t_i8) -> mk_struct! {t_i8, i1});
ifn!("llvm.umul.with.overflow.i16", fn(t_i16, t_i16) -> mk_struct! {t_i16, i1});
ifn!("llvm.umul.with.overflow.i32", fn(t_i32, t_i32) -> mk_struct! {t_i32, i1});
ifn!("llvm.umul.with.overflow.i64", fn(t_i64, t_i64) -> mk_struct! {t_i64, i1});
ifn!("llvm.umul.with.overflow.i128", fn(t_i128, t_i128) -> mk_struct! {t_i128, i1});
ifn!("llvm.sadd.sat.i8", fn(t_i8, t_i8) -> t_i8);
ifn!("llvm.sadd.sat.i16", fn(t_i16, t_i16) -> t_i16);
ifn!("llvm.sadd.sat.i32", fn(t_i32, t_i32) -> t_i32);
ifn!("llvm.sadd.sat.i64", fn(t_i64, t_i64) -> t_i64);
ifn!("llvm.sadd.sat.i128", fn(t_i128, t_i128) -> t_i128);
ifn!("llvm.uadd.sat.i8", fn(t_i8, t_i8) -> t_i8);
ifn!("llvm.uadd.sat.i16", fn(t_i16, t_i16) -> t_i16);
ifn!("llvm.uadd.sat.i32", fn(t_i32, t_i32) -> t_i32);
ifn!("llvm.uadd.sat.i64", fn(t_i64, t_i64) -> t_i64);
ifn!("llvm.uadd.sat.i128", fn(t_i128, t_i128) -> t_i128);
ifn!("llvm.ssub.sat.i8", fn(t_i8, t_i8) -> t_i8);
ifn!("llvm.ssub.sat.i16", fn(t_i16, t_i16) -> t_i16);
ifn!("llvm.ssub.sat.i32", fn(t_i32, t_i32) -> t_i32);
ifn!("llvm.ssub.sat.i64", fn(t_i64, t_i64) -> t_i64);
ifn!("llvm.ssub.sat.i128", fn(t_i128, t_i128) -> t_i128);
ifn!("llvm.usub.sat.i8", fn(t_i8, t_i8) -> t_i8);
ifn!("llvm.usub.sat.i16", fn(t_i16, t_i16) -> t_i16);
ifn!("llvm.usub.sat.i32", fn(t_i32, t_i32) -> t_i32);
ifn!("llvm.usub.sat.i64", fn(t_i64, t_i64) -> t_i64);
ifn!("llvm.usub.sat.i128", fn(t_i128, t_i128) -> t_i128);
ifn!("llvm.lifetime.start.p0i8", fn(t_i64, i8p) -> void);
ifn!("llvm.lifetime.end.p0i8", fn(t_i64, i8p) -> void);
ifn!("llvm.expect.i1", fn(i1, i1) -> i1);
ifn!("llvm.eh.typeid.for", fn(i8p) -> t_i32);
ifn!("llvm.localescape", fn(...) -> void);
ifn!("llvm.localrecover", fn(i8p, i8p, t_i32) -> i8p);
ifn!("llvm.x86.seh.recoverfp", fn(i8p, i8p) -> i8p);
ifn!("llvm.assume", fn(i1) -> void);
ifn!("llvm.prefetch", fn(i8p, t_i32, t_i32, t_i32) -> void);
// variadic intrinsics
ifn!("llvm.va_start", fn(i8p) -> void);
ifn!("llvm.va_end", fn(i8p) -> void);
ifn!("llvm.va_copy", fn(i8p, i8p) -> void);
if self.sess().opts.debugging_opts.instrument_coverage {
ifn!("llvm.instrprof.increment", fn(i8p, t_i64, t_i32, t_i32) -> void);
}
if self.sess().opts.debuginfo != DebugInfo::None {
ifn!("llvm.dbg.declare", fn(self.type_metadata(), self.type_metadata()) -> void);
ifn!("llvm.dbg.value", fn(self.type_metadata(), t_i64, self.type_metadata()) -> void);
}
None
}
crate fn eh_catch_typeinfo(&self) -> &'b Value {
if let Some(eh_catch_typeinfo) = self.eh_catch_typeinfo.get() {
return eh_catch_typeinfo;
}
let tcx = self.tcx;
assert!(self.sess().target.is_like_emscripten);
let eh_catch_typeinfo = match tcx.lang_items().eh_catch_typeinfo() {
Some(def_id) => self.get_static(def_id),
_ => {
let ty = self
.type_struct(&[self.type_ptr_to(self.type_isize()), self.type_i8p()], false);
self.declare_global("rust_eh_catch_typeinfo", ty)
}
};
let eh_catch_typeinfo = self.const_bitcast(eh_catch_typeinfo, self.type_i8p());
self.eh_catch_typeinfo.set(Some(eh_catch_typeinfo));
eh_catch_typeinfo
}
}
impl<'b, 'tcx> CodegenCx<'b, 'tcx> {
/// Generates a new symbol name with the given prefix. This symbol name must
/// only be used for definitions with `internal` or `private` linkage.
pub fn generate_local_symbol_name(&self, prefix: &str) -> String {
let idx = self.local_gen_sym_counter.get();
self.local_gen_sym_counter.set(idx + 1);
// Include a '.' character, so there can be no accidental conflicts with
// user defined names
let mut name = String::with_capacity(prefix.len() + 6);
name.push_str(prefix);
name.push('.');
base_n::push_str(idx as u128, base_n::ALPHANUMERIC_ONLY, &mut name);
name
}
}
impl HasDataLayout for CodegenCx<'ll, 'tcx> {
fn data_layout(&self) -> &TargetDataLayout {
&self.tcx.data_layout
}
}
impl HasTargetSpec for CodegenCx<'ll, 'tcx> {
fn target_spec(&self) -> &Target {
&self.tcx.sess.target
}
}
impl ty::layout::HasTyCtxt<'tcx> for CodegenCx<'ll, 'tcx> {
fn tcx(&self) -> TyCtxt<'tcx> {
self.tcx
}
}
impl LayoutOf for CodegenCx<'ll, 'tcx> {
type Ty = Ty<'tcx>;
type TyAndLayout = TyAndLayout<'tcx>;
fn layout_of(&self, ty: Ty<'tcx>) -> Self::TyAndLayout {
self.spanned_layout_of(ty, DUMMY_SP)
}
fn spanned_layout_of(&self, ty: Ty<'tcx>, span: Span) -> Self::TyAndLayout {
self.tcx.layout_of(ty::ParamEnv::reveal_all().and(ty)).unwrap_or_else(|e| {
if let LayoutError::SizeOverflow(_) = e {
self.sess().span_fatal(span, &e.to_string())
} else {
bug!("failed to get layout for `{}`: {}", ty, e)
}
})
}
}
impl<'tcx, 'll> HasParamEnv<'tcx> for CodegenCx<'ll, 'tcx> {
fn param_env(&self) -> ty::ParamEnv<'tcx> {
ty::ParamEnv::reveal_all()
}
}
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