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fuchsia / third_party / rust / 682c5f485b4cc55ce16315e0d76a5a16ab3064f5 / . / compiler / rustc_codegen_llvm / src / context.rs
blob: 73c2c15717fc14a9c1dfc3ceeeec81e18c75d5ee [file] [log] [blame]
use std::borrow::Borrow;
use std::cell::{Cell, RefCell};
use std::ffi::CStr;
use std::str;
use libc::c_uint;
use rustc_codegen_ssa::base::{wants_msvc_seh, wants_wasm_eh};
use rustc_codegen_ssa::errors as ssa_errors;
use rustc_codegen_ssa::traits::*;
use rustc_data_structures::base_n::{ToBaseN, ALPHANUMERIC_ONLY};
use rustc_data_structures::fx::FxHashMap;
use rustc_data_structures::small_c_str::SmallCStr;
use rustc_hir::def_id::DefId;
use rustc_middle::middle::codegen_fn_attrs::PatchableFunctionEntry;
use rustc_middle::mir::mono::CodegenUnit;
use rustc_middle::ty::layout::{
FnAbiError, FnAbiOfHelpers, FnAbiRequest, HasParamEnv, LayoutError, LayoutOfHelpers,
TyAndLayout,
};
use rustc_middle::ty::{self, Instance, Ty, TyCtxt};
use rustc_middle::{bug, span_bug};
use rustc_session::config::{
BranchProtection, CFGuard, CFProtection, CrateType, DebugInfo, PAuthKey, PacRet,
};
use rustc_session::Session;
use rustc_span::source_map::Spanned;
use rustc_span::{Span, DUMMY_SP};
use rustc_target::abi::call::FnAbi;
use rustc_target::abi::{HasDataLayout, TargetDataLayout, VariantIdx};
use rustc_target::spec::{HasTargetSpec, RelocModel, SmallDataThresholdSupport, Target, TlsModel};
use smallvec::SmallVec;
use crate::back::write::to_llvm_code_model;
use crate::callee::get_fn;
use crate::debuginfo::metadata::apply_vcall_visibility_metadata;
use crate::type_::Type;
use crate::value::Value;
use crate::{attributes, coverageinfo, debuginfo, llvm, llvm_util};
/// 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(crate) struct CodegenCx<'ll, 'tcx> {
pub tcx: TyCtxt<'tcx>,
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_str_cache: RefCell<FxHashMap<String, &'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 <https://llvm.org/docs/LangRef.html#the-llvm-used-global-variable> for details
pub used_statics: RefCell<Vec<&'ll Value>>,
/// Statics that will be placed in the llvm.compiler.used variable
/// See <https://llvm.org/docs/LangRef.html#the-llvm-compiler-used-global-variable> for details
pub compiler_used_statics: RefCell<Vec<&'ll Value>>,
/// Mapping of non-scalar types to llvm types.
pub type_lowering: RefCell<FxHashMap<(Ty<'tcx>, Option<VariantIdx>), &'ll Type>>,
/// Mapping of scalar types to llvm types.
pub scalar_lltypes: RefCell<FxHashMap<Ty<'tcx>, &'ll Type>>,
pub isize_ty: &'ll Type,
pub coverage_cx: Option<coverageinfo::CrateCoverageContext<'ll, 'tcx>>,
pub dbg_cx: Option<debuginfo::CodegenUnitDebugContext<'ll, 'tcx>>,
eh_personality: Cell<Option<&'ll Value>>,
eh_catch_typeinfo: Cell<Option<&'ll Value>>,
pub rust_try_fn: Cell<Option<(&'ll Type, &'ll Value)>>,
intrinsics: RefCell<FxHashMap<&'static str, (&'ll Type, &'ll Value)>>,
/// A counter that is used for generating local symbol names
local_gen_sym_counter: Cell<usize>,
/// `codegen_static` will sometimes create a second global variable with a
/// different type and clear the symbol name of the original global.
/// `global_asm!` needs to be able to find this new global so that it can
/// compute the correct mangled symbol name to insert into the asm.
pub renamed_statics: RefCell<FxHashMap<DefId, &'ll Value>>,
}
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,
TlsModel::Emulated => llvm::ThreadLocalMode::GeneralDynamic,
}
}
pub(crate) unsafe fn create_module<'ll>(
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 = unsafe { llvm::LLVMModuleCreateWithNameInContext(mod_name.as_ptr(), llcx) };
let mut target_data_layout = sess.target.data_layout.to_string();
let llvm_version = llvm_util::get_version();
if llvm_version < (18, 0, 0) {
if sess.target.arch == "x86" || sess.target.arch == "x86_64" {
// LLVM 18 adjusts i128 to be 128-bit aligned on x86 variants.
// Earlier LLVMs leave this as default alignment, so remove it.
// See https://reviews.llvm.org/D86310
target_data_layout = target_data_layout.replace("-i128:128", "");
}
}
if llvm_version < (19, 0, 0) {
if sess.target.arch == "aarch64" || sess.target.arch.starts_with("arm64") {
// LLVM 19 sets -Fn32 in its data layout string for 64-bit ARM
// Earlier LLVMs leave this default, so remove it.
// See https://github.com/llvm/llvm-project/pull/90702
target_data_layout = target_data_layout.replace("-Fn32", "");
}
}
if llvm_version < (19, 0, 0) {
if sess.target.arch == "loongarch64" {
// LLVM 19 updates the LoongArch64 data layout.
// See https://github.com/llvm/llvm-project/pull/93814
target_data_layout = target_data_layout.replace("-n32:64", "-n64");
}
}
// Ensure the data-layout values hardcoded remain the defaults.
{
let tm = crate::back::write::create_informational_target_machine(tcx.sess, false);
unsafe {
llvm::LLVMRustSetDataLayoutFromTargetMachine(llmod, &tm);
}
let llvm_data_layout = unsafe { llvm::LLVMGetDataLayoutStr(llmod) };
let llvm_data_layout =
str::from_utf8(unsafe { CStr::from_ptr(llvm_data_layout) }.to_bytes())
.expect("got a non-UTF8 data-layout from LLVM");
if target_data_layout != llvm_data_layout {
tcx.dcx().emit_err(crate::errors::MismatchedDataLayout {
rustc_target: sess.opts.target_triple.to_string().as_str(),
rustc_layout: target_data_layout.as_str(),
llvm_target: sess.target.llvm_target.borrow(),
llvm_layout: llvm_data_layout,
});
}
}
let data_layout = SmallCStr::new(&target_data_layout);
unsafe {
llvm::LLVMSetDataLayout(llmod, data_layout.as_ptr());
}
let llvm_target = SmallCStr::new(&sess.target.llvm_target);
unsafe {
llvm::LLVMRustSetNormalizedTarget(llmod, llvm_target.as_ptr());
}
let reloc_model = sess.relocation_model();
if matches!(reloc_model, RelocModel::Pic | RelocModel::Pie) {
unsafe {
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 reloc_model == RelocModel::Pie
|| tcx.crate_types().iter().all(|ty| *ty == CrateType::Executable)
{
unsafe {
llvm::LLVMRustSetModulePIELevel(llmod);
}
}
}
// Linking object files with different code models is undefined behavior
// because the compiler would have to generate additional code (to span
// longer jumps) if a larger code model is used with a smaller one.
//
// See https://reviews.llvm.org/D52322 and https://reviews.llvm.org/D52323.
unsafe {
llvm::LLVMRustSetModuleCodeModel(llmod, to_llvm_code_model(sess.code_model()));
}
// 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 = c"RtLibUseGOT".as_ptr();
unsafe {
llvm::LLVMRustAddModuleFlagU32(llmod, llvm::LLVMModFlagBehavior::Warning, avoid_plt, 1);
}
}
// Enable canonical jump tables if CFI is enabled. (See https://reviews.llvm.org/D65629.)
if sess.is_sanitizer_cfi_canonical_jump_tables_enabled() && sess.is_sanitizer_cfi_enabled() {
let canonical_jump_tables = c"CFI Canonical Jump Tables".as_ptr();
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Override,
canonical_jump_tables,
1,
);
}
}
// If we're normalizing integers with CFI, ensure LLVM generated functions do the same.
// See https://github.com/llvm/llvm-project/pull/104826
if sess.is_sanitizer_cfi_normalize_integers_enabled() {
let cfi_normalize_integers = c"cfi-normalize-integers".as_ptr().cast();
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Override,
cfi_normalize_integers,
1,
);
}
}
// Enable LTO unit splitting if specified or if CFI is enabled. (See https://reviews.llvm.org/D53891.)
if sess.is_split_lto_unit_enabled() || sess.is_sanitizer_cfi_enabled() {
let enable_split_lto_unit = c"EnableSplitLTOUnit".as_ptr();
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Override,
enable_split_lto_unit,
1,
);
}
}
// Add "kcfi" module flag if KCFI is enabled. (See https://reviews.llvm.org/D119296.)
if sess.is_sanitizer_kcfi_enabled() {
let kcfi = c"kcfi".as_ptr();
unsafe {
llvm::LLVMRustAddModuleFlagU32(llmod, llvm::LLVMModFlagBehavior::Override, kcfi, 1);
}
// Add "kcfi-offset" module flag with -Z patchable-function-entry (See
// https://reviews.llvm.org/D141172).
let pfe =
PatchableFunctionEntry::from_config(sess.opts.unstable_opts.patchable_function_entry);
if pfe.prefix() > 0 {
let kcfi_offset = c"kcfi-offset".as_ptr().cast();
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Override,
kcfi_offset,
pfe.prefix().into(),
);
}
}
}
// Control Flow Guard is currently only supported by the MSVC linker on Windows.
if sess.target.is_like_msvc {
unsafe {
match sess.opts.cg.control_flow_guard {
CFGuard::Disabled => {}
CFGuard::NoChecks => {
// Set `cfguard=1` module flag to emit metadata only.
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Warning,
c"cfguard".as_ptr() as *const _,
1,
)
}
CFGuard::Checks => {
// Set `cfguard=2` module flag to emit metadata and checks.
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Warning,
c"cfguard".as_ptr() as *const _,
2,
)
}
}
}
}
if let Some(BranchProtection { bti, pac_ret }) = sess.opts.unstable_opts.branch_protection {
if sess.target.arch == "aarch64" {
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Min,
c"branch-target-enforcement".as_ptr(),
bti.into(),
);
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Min,
c"sign-return-address".as_ptr(),
pac_ret.is_some().into(),
);
let pac_opts = pac_ret.unwrap_or(PacRet { leaf: false, key: PAuthKey::A });
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Min,
c"sign-return-address-all".as_ptr(),
pac_opts.leaf.into(),
);
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Min,
c"sign-return-address-with-bkey".as_ptr(),
u32::from(pac_opts.key == PAuthKey::B),
);
}
} else {
bug!(
"branch-protection used on non-AArch64 target; \
this should be checked in rustc_session."
);
}
}
// Pass on the control-flow protection flags to LLVM (equivalent to `-fcf-protection` in Clang).
if let CFProtection::Branch | CFProtection::Full = sess.opts.unstable_opts.cf_protection {
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Override,
c"cf-protection-branch".as_ptr(),
1,
);
}
}
if let CFProtection::Return | CFProtection::Full = sess.opts.unstable_opts.cf_protection {
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Override,
c"cf-protection-return".as_ptr(),
1,
);
}
}
if sess.opts.unstable_opts.virtual_function_elimination {
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Error,
c"Virtual Function Elim".as_ptr(),
1,
);
}
}
// Set module flag to enable Windows EHCont Guard (/guard:ehcont).
if sess.opts.unstable_opts.ehcont_guard {
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Warning,
c"ehcontguard".as_ptr() as *const _,
1,
)
}
}
match (sess.opts.unstable_opts.small_data_threshold, sess.target.small_data_threshold_support())
{
// Set up the small-data optimization limit for architectures that use
// an LLVM module flag to control this.
(Some(threshold), SmallDataThresholdSupport::LlvmModuleFlag(flag)) => {
let flag = SmallCStr::new(flag.as_ref());
unsafe {
llvm::LLVMRustAddModuleFlagU32(
llmod,
llvm::LLVMModFlagBehavior::Error,
flag.as_c_str().as_ptr(),
threshold as u32,
)
}
}
_ => (),
};
// Insert `llvm.ident` metadata.
//
// On the wasm targets it will get hooked up to the "producer" sections
// `processed-by` information.
#[allow(clippy::option_env_unwrap)]
let rustc_producer =
format!("rustc version {}", option_env!("CFG_VERSION").expect("CFG_VERSION"));
let name_metadata = unsafe {
llvm::LLVMMDStringInContext(
llcx,
rustc_producer.as_ptr().cast(),
rustc_producer.as_bytes().len() as c_uint,
)
};
unsafe {
llvm::LLVMAddNamedMetadataOperand(
llmod,
c"llvm.ident".as_ptr(),
llvm::LLVMMDNodeInContext(llcx, &name_metadata, 1),
);
}
// Emit RISC-V specific target-abi metadata
// to workaround lld as the LTO plugin not
// correctly setting target-abi for the LTO object
// FIXME: https://github.com/llvm/llvm-project/issues/50591
// If llvm_abiname is empty, emit nothing.
let llvm_abiname = &sess.target.options.llvm_abiname;
if matches!(sess.target.arch.as_ref(), "riscv32" | "riscv64") && !llvm_abiname.is_empty() {
unsafe {
llvm::LLVMRustAddModuleFlagString(
llmod,
llvm::LLVMModFlagBehavior::Error,
c"target-abi".as_ptr(),
llvm_abiname.as_ptr().cast(),
llvm_abiname.len(),
);
}
}
// Add module flags specified via -Z llvm_module_flag
for (key, value, behavior) in &sess.opts.unstable_opts.llvm_module_flag {
let key = format!("{key}\0");
let behavior = match behavior.as_str() {
"error" => llvm::LLVMModFlagBehavior::Error,
"warning" => llvm::LLVMModFlagBehavior::Warning,
"require" => llvm::LLVMModFlagBehavior::Require,
"override" => llvm::LLVMModFlagBehavior::Override,
"append" => llvm::LLVMModFlagBehavior::Append,
"appendunique" => llvm::LLVMModFlagBehavior::AppendUnique,
"max" => llvm::LLVMModFlagBehavior::Max,
"min" => llvm::LLVMModFlagBehavior::Min,
// We already checked this during option parsing
_ => unreachable!(),
};
unsafe { llvm::LLVMRustAddModuleFlagU32(llmod, behavior, key.as_ptr().cast(), *value) }
}
llmod
}
impl<'ll, 'tcx> CodegenCx<'ll, 'tcx> {
pub(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 flip side 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 tls_model = to_llvm_tls_model(tcx.sess.tls_model());
let (llcx, llmod) = (&*llvm_module.llcx, llvm_module.llmod());
let coverage_cx =
tcx.sess.instrument_coverage().then(coverageinfo::CrateCoverageContext::new);
let dbg_cx = if tcx.sess.opts.debuginfo != DebugInfo::None {
let dctx = debuginfo::CodegenUnitDebugContext::new(llmod);
debuginfo::metadata::build_compile_unit_di_node(
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,
use_dll_storage_attrs,
tls_model,
llmod,
llcx,
codegen_unit,
instances: Default::default(),
vtables: Default::default(),
const_str_cache: Default::default(),
const_globals: Default::default(),
statics_to_rauw: RefCell::new(Vec::new()),
used_statics: RefCell::new(Vec::new()),
compiler_used_statics: RefCell::new(Vec::new()),
type_lowering: Default::default(),
scalar_lltypes: 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),
renamed_statics: Default::default(),
}
}
pub(crate) fn statics_to_rauw(&self) -> &RefCell<Vec<(&'ll Value, &'ll Value)>> {
&self.statics_to_rauw
}
#[inline]
pub(crate) fn coverage_context(
&self,
) -> Option<&coverageinfo::CrateCoverageContext<'ll, 'tcx>> {
self.coverage_cx.as_ref()
}
pub(crate) fn create_used_variable_impl(&self, name: &'static CStr, values: &[&'ll Value]) {
let array = self.const_array(self.type_ptr(), values);
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, c"llvm.metadata".as_ptr());
}
}
}
impl<'ll, 'tcx> MiscMethods<'tcx> for CodegenCx<'ll, 'tcx> {
fn vtables(
&self,
) -> &RefCell<FxHashMap<(Ty<'tcx>, Option<ty::PolyExistentialTraitRef<'tcx>>), &'ll Value>>
{
&self.vtables
}
fn apply_vcall_visibility_metadata(
&self,
ty: Ty<'tcx>,
poly_trait_ref: Option<ty::PolyExistentialTraitRef<'tcx>>,
vtable: &'ll Value,
) {
apply_vcall_visibility_metadata(self, ty, poly_trait_ref, vtable);
}
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 name = if wants_msvc_seh(self.sess()) {
Some("__CxxFrameHandler3")
} else if wants_wasm_eh(self.sess()) {
// LLVM specifically tests for the name of the personality function
// There is no need for this function to exist anywhere, it will
// not be called. However, its name has to be "__gxx_wasm_personality_v0"
// for native wasm exceptions.
Some("__gxx_wasm_personality_v0")
} else {
None
};
let tcx = self.tcx;
let llfn = match tcx.lang_items().eh_personality() {
Some(def_id) if name.is_none() => self.get_fn_addr(ty::Instance::expect_resolve(
tcx,
ty::ParamEnv::reveal_all(),
def_id,
ty::List::empty(),
DUMMY_SP,
)),
_ => {
let name = name.unwrap_or("rust_eh_personality");
if let Some(llfn) = self.get_declared_value(name) {
llfn
} else {
let fty = self.type_variadic_func(&[], self.type_i32());
let llfn = self.declare_cfn(name, llvm::UnnamedAddr::Global, fty);
let target_cpu = attributes::target_cpu_attr(self);
attributes::apply_to_llfn(llfn, llvm::AttributePlace::Function, &[target_cpu]);
llfn
}
}
};
self.eh_personality.set(Some(llfn));
llfn
}
fn sess(&self) -> &Session {
self.tcx.sess
}
fn codegen_unit(&self) -> &'tcx CodegenUnit<'tcx> {
self.codegen_unit
}
fn set_frame_pointer_type(&self, llfn: &'ll Value) {
if let Some(attr) = attributes::frame_pointer_type_attr(self) {
attributes::apply_to_llfn(llfn, llvm::AttributePlace::Function, &[attr]);
}
}
fn apply_target_cpu_attr(&self, llfn: &'ll Value) {
let mut attrs = SmallVec::<[_; 2]>::new();
attrs.push(attributes::target_cpu_attr(self));
attrs.extend(attributes::tune_cpu_attr(self));
attributes::apply_to_llfn(llfn, llvm::AttributePlace::Function, &attrs);
}
fn declare_c_main(&self, fn_type: Self::Type) -> Option<Self::Function> {
let entry_name = self.sess().target.entry_name.as_ref();
if self.get_declared_value(entry_name).is_none() {
Some(self.declare_entry_fn(
entry_name,
self.sess().target.entry_abi.into(),
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<'ll> CodegenCx<'ll, '_> {
pub(crate) fn get_intrinsic(&self, key: &str) -> (&'ll Type, &'ll 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<&[&'ll llvm::Type]>,
ret: &'ll llvm::Type,
) -> (&'ll llvm::Type, &'ll 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, (fn_ty, f));
(fn_ty, f)
}
fn declare_intrinsic(&self, key: &str) -> Option<(&'ll Type, &'ll 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 ptr = self.type_ptr();
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_isize = self.type_isize();
let t_f16 = self.type_f16();
let t_f32 = self.type_f32();
let t_f64 = self.type_f64();
let t_f128 = self.type_f128();
let t_metadata = self.type_metadata();
let t_token = self.type_token();
ifn!("llvm.wasm.get.exception", fn(t_token) -> ptr);
ifn!("llvm.wasm.get.ehselector", fn(t_token) -> t_i32);
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.fptosi.sat.i8.f32", fn(t_f32) -> t_i8);
ifn!("llvm.fptosi.sat.i16.f32", fn(t_f32) -> t_i16);
ifn!("llvm.fptosi.sat.i32.f32", fn(t_f32) -> t_i32);
ifn!("llvm.fptosi.sat.i64.f32", fn(t_f32) -> t_i64);
ifn!("llvm.fptosi.sat.i128.f32", fn(t_f32) -> t_i128);
ifn!("llvm.fptosi.sat.i8.f64", fn(t_f64) -> t_i8);
ifn!("llvm.fptosi.sat.i16.f64", fn(t_f64) -> t_i16);
ifn!("llvm.fptosi.sat.i32.f64", fn(t_f64) -> t_i32);
ifn!("llvm.fptosi.sat.i64.f64", fn(t_f64) -> t_i64);
ifn!("llvm.fptosi.sat.i128.f64", fn(t_f64) -> t_i128);
ifn!("llvm.fptoui.sat.i8.f32", fn(t_f32) -> t_i8);
ifn!("llvm.fptoui.sat.i16.f32", fn(t_f32) -> t_i16);
ifn!("llvm.fptoui.sat.i32.f32", fn(t_f32) -> t_i32);
ifn!("llvm.fptoui.sat.i64.f32", fn(t_f32) -> t_i64);
ifn!("llvm.fptoui.sat.i128.f32", fn(t_f32) -> t_i128);
ifn!("llvm.fptoui.sat.i8.f64", fn(t_f64) -> t_i8);
ifn!("llvm.fptoui.sat.i16.f64", fn(t_f64) -> t_i16);
ifn!("llvm.fptoui.sat.i32.f64", fn(t_f64) -> t_i32);
ifn!("llvm.fptoui.sat.i64.f64", fn(t_f64) -> t_i64);
ifn!("llvm.fptoui.sat.i128.f64", fn(t_f64) -> t_i128);
ifn!("llvm.trap", fn() -> void);
ifn!("llvm.debugtrap", fn() -> void);
ifn!("llvm.frameaddress", fn(t_i32) -> ptr);
ifn!("llvm.powi.f16.i32", fn(t_f16, t_i32) -> t_f16);
ifn!("llvm.powi.f32.i32", fn(t_f32, t_i32) -> t_f32);
ifn!("llvm.powi.f64.i32", fn(t_f64, t_i32) -> t_f64);
ifn!("llvm.powi.f128.i32", fn(t_f128, t_i32) -> t_f128);
ifn!("llvm.pow.f16", fn(t_f16, t_f16) -> t_f16);
ifn!("llvm.pow.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.pow.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.pow.f128", fn(t_f128, t_f128) -> t_f128);
ifn!("llvm.sqrt.f16", fn(t_f16) -> t_f16);
ifn!("llvm.sqrt.f32", fn(t_f32) -> t_f32);
ifn!("llvm.sqrt.f64", fn(t_f64) -> t_f64);
ifn!("llvm.sqrt.f128", fn(t_f128) -> t_f128);
ifn!("llvm.sin.f16", fn(t_f16) -> t_f16);
ifn!("llvm.sin.f32", fn(t_f32) -> t_f32);
ifn!("llvm.sin.f64", fn(t_f64) -> t_f64);
ifn!("llvm.sin.f128", fn(t_f128) -> t_f128);
ifn!("llvm.cos.f16", fn(t_f16) -> t_f16);
ifn!("llvm.cos.f32", fn(t_f32) -> t_f32);
ifn!("llvm.cos.f64", fn(t_f64) -> t_f64);
ifn!("llvm.cos.f128", fn(t_f128) -> t_f128);
ifn!("llvm.exp.f16", fn(t_f16) -> t_f16);
ifn!("llvm.exp.f32", fn(t_f32) -> t_f32);
ifn!("llvm.exp.f64", fn(t_f64) -> t_f64);
ifn!("llvm.exp.f128", fn(t_f128) -> t_f128);
ifn!("llvm.exp2.f16", fn(t_f16) -> t_f16);
ifn!("llvm.exp2.f32", fn(t_f32) -> t_f32);
ifn!("llvm.exp2.f64", fn(t_f64) -> t_f64);
ifn!("llvm.exp2.f128", fn(t_f128) -> t_f128);
ifn!("llvm.log.f16", fn(t_f16) -> t_f16);
ifn!("llvm.log.f32", fn(t_f32) -> t_f32);
ifn!("llvm.log.f64", fn(t_f64) -> t_f64);
ifn!("llvm.log.f128", fn(t_f128) -> t_f128);
ifn!("llvm.log10.f16", fn(t_f16) -> t_f16);
ifn!("llvm.log10.f32", fn(t_f32) -> t_f32);
ifn!("llvm.log10.f64", fn(t_f64) -> t_f64);
ifn!("llvm.log10.f128", fn(t_f128) -> t_f128);
ifn!("llvm.log2.f16", fn(t_f16) -> t_f16);
ifn!("llvm.log2.f32", fn(t_f32) -> t_f32);
ifn!("llvm.log2.f64", fn(t_f64) -> t_f64);
ifn!("llvm.log2.f128", fn(t_f128) -> t_f128);
ifn!("llvm.fma.f16", fn(t_f16, t_f16, t_f16) -> t_f16);
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.fma.f128", fn(t_f128, t_f128, t_f128) -> t_f128);
ifn!("llvm.fabs.f16", fn(t_f16) -> t_f16);
ifn!("llvm.fabs.f32", fn(t_f32) -> t_f32);
ifn!("llvm.fabs.f64", fn(t_f64) -> t_f64);
ifn!("llvm.fabs.f128", fn(t_f128) -> t_f128);
ifn!("llvm.minnum.f16", fn(t_f16, t_f16) -> t_f16);
ifn!("llvm.minnum.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.minnum.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.minnum.f128", fn(t_f128, t_f128) -> t_f128);
ifn!("llvm.maxnum.f16", fn(t_f16, t_f16) -> t_f16);
ifn!("llvm.maxnum.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.maxnum.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.maxnum.f128", fn(t_f128, t_f128) -> t_f128);
ifn!("llvm.floor.f16", fn(t_f16) -> t_f16);
ifn!("llvm.floor.f32", fn(t_f32) -> t_f32);
ifn!("llvm.floor.f64", fn(t_f64) -> t_f64);
ifn!("llvm.floor.f128", fn(t_f128) -> t_f128);
ifn!("llvm.ceil.f16", fn(t_f16) -> t_f16);
ifn!("llvm.ceil.f32", fn(t_f32) -> t_f32);
ifn!("llvm.ceil.f64", fn(t_f64) -> t_f64);
ifn!("llvm.ceil.f128", fn(t_f128) -> t_f128);
ifn!("llvm.trunc.f16", fn(t_f16) -> t_f16);
ifn!("llvm.trunc.f32", fn(t_f32) -> t_f32);
ifn!("llvm.trunc.f64", fn(t_f64) -> t_f64);
ifn!("llvm.trunc.f128", fn(t_f128) -> t_f128);
ifn!("llvm.copysign.f16", fn(t_f16, t_f16) -> t_f16);
ifn!("llvm.copysign.f32", fn(t_f32, t_f32) -> t_f32);
ifn!("llvm.copysign.f64", fn(t_f64, t_f64) -> t_f64);
ifn!("llvm.copysign.f128", fn(t_f128, t_f128) -> t_f128);
ifn!("llvm.round.f16", fn(t_f16) -> t_f16);
ifn!("llvm.round.f32", fn(t_f32) -> t_f32);
ifn!("llvm.round.f64", fn(t_f64) -> t_f64);
ifn!("llvm.round.f128", fn(t_f128) -> t_f128);
ifn!("llvm.roundeven.f16", fn(t_f16) -> t_f16);
ifn!("llvm.roundeven.f32", fn(t_f32) -> t_f32);
ifn!("llvm.roundeven.f64", fn(t_f64) -> t_f64);
ifn!("llvm.roundeven.f128", fn(t_f128) -> t_f128);
ifn!("llvm.rint.f16", fn(t_f16) -> t_f16);
ifn!("llvm.rint.f32", fn(t_f32) -> t_f32);
ifn!("llvm.rint.f64", fn(t_f64) -> t_f64);
ifn!("llvm.rint.f128", fn(t_f128) -> t_f128);
ifn!("llvm.nearbyint.f16", fn(t_f16) -> t_f16);
ifn!("llvm.nearbyint.f32", fn(t_f32) -> t_f32);
ifn!("llvm.nearbyint.f64", fn(t_f64) -> t_f64);
ifn!("llvm.nearbyint.f128", fn(t_f128) -> t_f128);
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, ptr) -> void);
ifn!("llvm.lifetime.end.p0i8", fn(t_i64, ptr) -> void);
// FIXME: This is an infinitesimally small portion of the types you can
// pass to this intrinsic, if we can ever lazily register intrinsics we
// should register these when they're used, that way any type can be
// passed.
ifn!("llvm.is.constant.i1", fn(i1) -> i1);
ifn!("llvm.is.constant.i8", fn(t_i8) -> i1);
ifn!("llvm.is.constant.i16", fn(t_i16) -> i1);
ifn!("llvm.is.constant.i32", fn(t_i32) -> i1);
ifn!("llvm.is.constant.i64", fn(t_i64) -> i1);
ifn!("llvm.is.constant.i128", fn(t_i128) -> i1);
ifn!("llvm.is.constant.isize", fn(t_isize) -> i1);
ifn!("llvm.is.constant.f16", fn(t_f16) -> i1);
ifn!("llvm.is.constant.f32", fn(t_f32) -> i1);
ifn!("llvm.is.constant.f64", fn(t_f64) -> i1);
ifn!("llvm.is.constant.f128", fn(t_f128) -> i1);
ifn!("llvm.is.constant.ptr", fn(ptr) -> i1);
ifn!("llvm.expect.i1", fn(i1, i1) -> i1);
ifn!("llvm.eh.typeid.for", fn(ptr) -> t_i32);
ifn!("llvm.localescape", fn(...) -> void);
ifn!("llvm.localrecover", fn(ptr, ptr, t_i32) -> ptr);
ifn!("llvm.x86.seh.recoverfp", fn(ptr, ptr) -> ptr);
ifn!("llvm.assume", fn(i1) -> void);
ifn!("llvm.prefetch", fn(ptr, t_i32, t_i32, t_i32) -> void);
// This isn't an "LLVM intrinsic", but LLVM's optimization passes
// recognize it like one (including turning it into `bcmp` sometimes)
// and we use it to implement intrinsics like `raw_eq` and `compare_bytes`
match self.sess().target.arch.as_ref() {
"avr" | "msp430" => ifn!("memcmp", fn(ptr, ptr, t_isize) -> t_i16),
_ => ifn!("memcmp", fn(ptr, ptr, t_isize) -> t_i32),
}
// variadic intrinsics
ifn!("llvm.va_start", fn(ptr) -> void);
ifn!("llvm.va_end", fn(ptr) -> void);
ifn!("llvm.va_copy", fn(ptr, ptr) -> void);
if self.sess().instrument_coverage() {
ifn!("llvm.instrprof.increment", fn(ptr, t_i64, t_i32, t_i32) -> void);
}
ifn!("llvm.type.test", fn(ptr, t_metadata) -> i1);
ifn!("llvm.type.checked.load", fn(ptr, t_i32, t_metadata) -> mk_struct! {ptr, i1});
if self.sess().opts.debuginfo != DebugInfo::None {
ifn!("llvm.dbg.declare", fn(t_metadata, t_metadata) -> void);
ifn!("llvm.dbg.value", fn(t_metadata, t_i64, t_metadata) -> void);
}
ifn!("llvm.ptrmask", fn(ptr, t_isize) -> ptr);
None
}
pub(crate) fn eh_catch_typeinfo(&self) -> &'ll Value {
if let Some(eh_catch_typeinfo) = self.eh_catch_typeinfo.get() {
return eh_catch_typeinfo;
}
let tcx = self.tcx;
assert!(self.sess().target.os == "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(), self.type_ptr()], false);
self.declare_global("rust_eh_catch_typeinfo", ty)
}
};
self.eh_catch_typeinfo.set(Some(eh_catch_typeinfo));
eh_catch_typeinfo
}
}
impl CodegenCx<'_, '_> {
/// Generates a new symbol name with the given prefix. This symbol name must
/// only be used for definitions with `internal` or `private` linkage.
pub(crate) 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('.');
name.push_str(&(idx as u64).to_base(ALPHANUMERIC_ONLY));
name
}
}
impl HasDataLayout for CodegenCx<'_, '_> {
#[inline]
fn data_layout(&self) -> &TargetDataLayout {
&self.tcx.data_layout
}
}
impl HasTargetSpec for CodegenCx<'_, '_> {
#[inline]
fn target_spec(&self) -> &Target {
&self.tcx.sess.target
}
}
impl<'tcx> ty::layout::HasTyCtxt<'tcx> for CodegenCx<'_, 'tcx> {
#[inline]
fn tcx(&self) -> TyCtxt<'tcx> {
self.tcx
}
}
impl<'tcx, 'll> HasParamEnv<'tcx> for CodegenCx<'ll, 'tcx> {
fn param_env(&self) -> ty::ParamEnv<'tcx> {
ty::ParamEnv::reveal_all()
}
}
impl<'tcx> LayoutOfHelpers<'tcx> for CodegenCx<'_, 'tcx> {
type LayoutOfResult = TyAndLayout<'tcx>;
#[inline]
fn handle_layout_err(&self, err: LayoutError<'tcx>, span: Span, ty: Ty<'tcx>) -> ! {
if let LayoutError::SizeOverflow(_) | LayoutError::ReferencesError(_) = err {
self.tcx.dcx().emit_fatal(Spanned { span, node: err.into_diagnostic() })
} else {
self.tcx.dcx().emit_fatal(ssa_errors::FailedToGetLayout { span, ty, err })
}
}
}
impl<'tcx> FnAbiOfHelpers<'tcx> for CodegenCx<'_, 'tcx> {
type FnAbiOfResult = &'tcx FnAbi<'tcx, Ty<'tcx>>;
#[inline]
fn handle_fn_abi_err(
&self,
err: FnAbiError<'tcx>,
span: Span,
fn_abi_request: FnAbiRequest<'tcx>,
) -> ! {
if let FnAbiError::Layout(LayoutError::SizeOverflow(_)) = err {
self.tcx.dcx().emit_fatal(Spanned { span, node: err })
} else {
match fn_abi_request {
FnAbiRequest::OfFnPtr { sig, extra_args } => {
span_bug!(span, "`fn_abi_of_fn_ptr({sig}, {extra_args:?})` failed: {err:?}",);
}
FnAbiRequest::OfInstance { instance, extra_args } => {
span_bug!(
span,
"`fn_abi_of_instance({instance}, {extra_args:?})` failed: {err:?}",
);
}
}
}
}
}