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#[llvm_versions(..=16)]
use llvm_sys::core::LLVMGetGlobalPassRegistry;
use llvm_sys::core::{
LLVMCreateFunctionPassManagerForModule, LLVMCreatePassManager, LLVMDisposePassManager,
LLVMFinalizeFunctionPassManager, LLVMInitializeFunctionPassManager, LLVMRunFunctionPassManager, LLVMRunPassManager,
};
#[llvm_versions(..=16)]
use llvm_sys::initialization::{
LLVMInitializeAnalysis, LLVMInitializeCodeGen, LLVMInitializeCore, LLVMInitializeIPA, LLVMInitializeIPO,
LLVMInitializeInstCombine, LLVMInitializeScalarOpts, LLVMInitializeTarget, LLVMInitializeTransformUtils,
LLVMInitializeVectorization,
};
#[llvm_versions(..=15)]
use llvm_sys::initialization::{LLVMInitializeInstrumentation, LLVMInitializeObjCARCOpts};
use llvm_sys::prelude::LLVMPassManagerRef;
#[llvm_versions(..=16)]
use llvm_sys::prelude::LLVMPassRegistryRef;
#[llvm_versions(10..=16)]
use llvm_sys::transforms::ipo::LLVMAddMergeFunctionsPass;
#[llvm_versions(..=15)]
use llvm_sys::transforms::ipo::LLVMAddPruneEHPass;
#[llvm_versions(..=16)]
use llvm_sys::transforms::ipo::{
LLVMAddAlwaysInlinerPass, LLVMAddConstantMergePass, LLVMAddDeadArgEliminationPass, LLVMAddFunctionAttrsPass,
LLVMAddFunctionInliningPass, LLVMAddGlobalDCEPass, LLVMAddGlobalOptimizerPass, LLVMAddIPSCCPPass,
LLVMAddInternalizePass, LLVMAddStripDeadPrototypesPass, LLVMAddStripSymbolsPass,
};
#[llvm_versions(..=16)]
use llvm_sys::transforms::pass_manager_builder::{
LLVMPassManagerBuilderCreate, LLVMPassManagerBuilderDispose, LLVMPassManagerBuilderPopulateFunctionPassManager,
LLVMPassManagerBuilderPopulateModulePassManager, LLVMPassManagerBuilderRef,
LLVMPassManagerBuilderSetDisableSimplifyLibCalls, LLVMPassManagerBuilderSetDisableUnitAtATime,
LLVMPassManagerBuilderSetDisableUnrollLoops, LLVMPassManagerBuilderSetOptLevel, LLVMPassManagerBuilderSetSizeLevel,
LLVMPassManagerBuilderUseInlinerWithThreshold,
};
#[llvm_versions(..=16)]
use llvm_sys::transforms::scalar::{
LLVMAddAggressiveDCEPass, LLVMAddAlignmentFromAssumptionsPass, LLVMAddBasicAliasAnalysisPass,
LLVMAddBitTrackingDCEPass, LLVMAddCFGSimplificationPass, LLVMAddCorrelatedValuePropagationPass,
LLVMAddDeadStoreEliminationPass, LLVMAddDemoteMemoryToRegisterPass, LLVMAddEarlyCSEPass, LLVMAddGVNPass,
LLVMAddIndVarSimplifyPass, LLVMAddInstructionCombiningPass, LLVMAddJumpThreadingPass, LLVMAddLICMPass,
LLVMAddLoopDeletionPass, LLVMAddLoopIdiomPass, LLVMAddLoopRerollPass, LLVMAddLoopRotatePass, LLVMAddLoopUnrollPass,
LLVMAddLowerExpectIntrinsicPass, LLVMAddMemCpyOptPass, LLVMAddMergedLoadStoreMotionPass,
LLVMAddPartiallyInlineLibCallsPass, LLVMAddReassociatePass, LLVMAddSCCPPass, LLVMAddScalarReplAggregatesPass,
LLVMAddScalarReplAggregatesPassSSA, LLVMAddScalarReplAggregatesPassWithThreshold, LLVMAddScalarizerPass,
LLVMAddScopedNoAliasAAPass, LLVMAddSimplifyLibCallsPass, LLVMAddTailCallEliminationPass,
LLVMAddTypeBasedAliasAnalysisPass, LLVMAddVerifierPass,
};
#[llvm_versions(..=16)]
use llvm_sys::transforms::vectorize::{LLVMAddLoopVectorizePass, LLVMAddSLPVectorizePass};
// LLVM12 removes the ConstantPropagation pass
// Users should use the InstSimplify pass instead.
#[llvm_versions(..=11)]
use llvm_sys::transforms::ipo::LLVMAddIPConstantPropagationPass;
#[llvm_versions(..=11)]
use llvm_sys::transforms::scalar::LLVMAddConstantPropagationPass;
#[llvm_versions(13..)]
use llvm_sys::transforms::pass_builder::{
LLVMCreatePassBuilderOptions, LLVMDisposePassBuilderOptions, LLVMPassBuilderOptionsRef,
LLVMPassBuilderOptionsSetCallGraphProfile, LLVMPassBuilderOptionsSetDebugLogging,
LLVMPassBuilderOptionsSetForgetAllSCEVInLoopUnroll, LLVMPassBuilderOptionsSetLicmMssaNoAccForPromotionCap,
LLVMPassBuilderOptionsSetLicmMssaOptCap, LLVMPassBuilderOptionsSetLoopInterleaving,
LLVMPassBuilderOptionsSetLoopUnrolling, LLVMPassBuilderOptionsSetLoopVectorization,
LLVMPassBuilderOptionsSetMergeFunctions, LLVMPassBuilderOptionsSetSLPVectorization,
LLVMPassBuilderOptionsSetVerifyEach,
};
#[llvm_versions(12..=16)]
use llvm_sys::transforms::scalar::LLVMAddInstructionSimplifyPass;
use crate::module::Module;
use crate::values::{AsValueRef, FunctionValue};
#[llvm_versions(..=16)]
use crate::OptimizationLevel;
use std::borrow::Borrow;
use std::marker::PhantomData;
// REVIEW: Opt Level might be identical to targets::Option<CodeGenOptLevel>
#[llvm_versions(..=16)]
#[derive(Debug)]
pub struct PassManagerBuilder {
pass_manager_builder: LLVMPassManagerBuilderRef,
}
#[llvm_versions(..=16)]
impl PassManagerBuilder {
pub unsafe fn new(pass_manager_builder: LLVMPassManagerBuilderRef) -> Self {
assert!(!pass_manager_builder.is_null());
PassManagerBuilder { pass_manager_builder }
}
/// Acquires the underlying raw pointer belonging to this `PassManagerBuilder` type.
pub fn as_mut_ptr(&self) -> LLVMPassManagerBuilderRef {
self.pass_manager_builder
}
pub fn create() -> Self {
let pass_manager_builder = unsafe { LLVMPassManagerBuilderCreate() };
unsafe { PassManagerBuilder::new(pass_manager_builder) }
}
pub fn set_optimization_level(&self, opt_level: OptimizationLevel) {
unsafe { LLVMPassManagerBuilderSetOptLevel(self.pass_manager_builder, opt_level as u32) }
}
// REVIEW: Valid input 0-2 according to llvmlite. Maybe better as an enum?
pub fn set_size_level(&self, size_level: u32) {
unsafe { LLVMPassManagerBuilderSetSizeLevel(self.pass_manager_builder, size_level) }
}
pub fn set_disable_unit_at_a_time(&self, disable: bool) {
unsafe { LLVMPassManagerBuilderSetDisableUnitAtATime(self.pass_manager_builder, disable as i32) }
}
pub fn set_disable_unroll_loops(&self, disable: bool) {
unsafe { LLVMPassManagerBuilderSetDisableUnrollLoops(self.pass_manager_builder, disable as i32) }
}
pub fn set_disable_simplify_lib_calls(&self, disable: bool) {
unsafe { LLVMPassManagerBuilderSetDisableSimplifyLibCalls(self.pass_manager_builder, disable as i32) }
}
pub fn set_inliner_with_threshold(&self, threshold: u32) {
unsafe { LLVMPassManagerBuilderUseInlinerWithThreshold(self.pass_manager_builder, threshold) }
}
/// Populates a PassManager<FunctionValue> with the expectation of function
/// transformations.
///
/// # Example
///
/// ```no_run
/// use inkwell::context::Context;
/// use inkwell::OptimizationLevel::Aggressive;
/// use inkwell::passes::{PassManager, PassManagerBuilder};
///
/// let context = Context::create();
/// let module = context.create_module("mod");
/// let pass_manager_builder = PassManagerBuilder::create();
///
/// pass_manager_builder.set_optimization_level(Aggressive);
///
/// let fpm = PassManager::create(&module);
///
/// pass_manager_builder.populate_function_pass_manager(&fpm);
/// ```
pub fn populate_function_pass_manager(&self, pass_manager: &PassManager<FunctionValue>) {
unsafe {
LLVMPassManagerBuilderPopulateFunctionPassManager(self.pass_manager_builder, pass_manager.pass_manager)
}
}
/// Populates a PassManager<Module> with the expectation of whole module
/// transformations.
///
/// # Example
///
/// ```no_run
/// use inkwell::OptimizationLevel::Aggressive;
/// use inkwell::passes::{PassManager, PassManagerBuilder};
/// use inkwell::targets::{InitializationConfig, Target};
///
/// let config = InitializationConfig::default();
/// Target::initialize_native(&config).unwrap();
/// let pass_manager_builder = PassManagerBuilder::create();
///
/// pass_manager_builder.set_optimization_level(Aggressive);
///
/// let fpm = PassManager::create(());
///
/// pass_manager_builder.populate_module_pass_manager(&fpm);
/// ```
pub fn populate_module_pass_manager(&self, pass_manager: &PassManager<Module>) {
unsafe { LLVMPassManagerBuilderPopulateModulePassManager(self.pass_manager_builder, pass_manager.pass_manager) }
}
/// Populates a PassManager<Module> with the expectation of link time
/// optimization transformations.
///
/// # Example
///
/// ```no_run
/// use inkwell::OptimizationLevel::Aggressive;
/// use inkwell::passes::{PassManager, PassManagerBuilder};
/// use inkwell::targets::{InitializationConfig, Target};
///
/// let config = InitializationConfig::default();
/// Target::initialize_native(&config).unwrap();
/// let pass_manager_builder = PassManagerBuilder::create();
///
/// pass_manager_builder.set_optimization_level(Aggressive);
///
/// let lpm = PassManager::create(());
///
/// pass_manager_builder.populate_lto_pass_manager(&lpm, false, false);
/// ```
#[llvm_versions(..=14)]
pub fn populate_lto_pass_manager(&self, pass_manager: &PassManager<Module>, internalize: bool, run_inliner: bool) {
use llvm_sys::transforms::pass_manager_builder::LLVMPassManagerBuilderPopulateLTOPassManager;
unsafe {
LLVMPassManagerBuilderPopulateLTOPassManager(
self.pass_manager_builder,
pass_manager.pass_manager,
internalize as i32,
run_inliner as i32,
)
}
}
}
#[llvm_versions(..=16)]
impl Drop for PassManagerBuilder {
fn drop(&mut self) {
unsafe { LLVMPassManagerBuilderDispose(self.pass_manager_builder) }
}
}
// This is an ugly privacy hack so that PassManagerSubType can stay private
// to this module and so that super traits using this trait will be not be
// implementable outside this library
pub trait PassManagerSubType {
type Input;
unsafe fn create<I: Borrow<Self::Input>>(input: I) -> LLVMPassManagerRef;
unsafe fn run_in_pass_manager(&self, pass_manager: &PassManager<Self>) -> bool
where
Self: Sized;
}
impl PassManagerSubType for Module<'_> {
type Input = ();
unsafe fn create<I: Borrow<Self::Input>>(_: I) -> LLVMPassManagerRef {
LLVMCreatePassManager()
}
unsafe fn run_in_pass_manager(&self, pass_manager: &PassManager<Self>) -> bool {
LLVMRunPassManager(pass_manager.pass_manager, self.module.get()) == 1
}
}
// With GATs https://github.com/rust-lang/rust/issues/44265 this could be
// type Input<'a> = &'a Module;
impl<'ctx> PassManagerSubType for FunctionValue<'ctx> {
type Input = Module<'ctx>;
unsafe fn create<I: Borrow<Self::Input>>(input: I) -> LLVMPassManagerRef {
LLVMCreateFunctionPassManagerForModule(input.borrow().module.get())
}
unsafe fn run_in_pass_manager(&self, pass_manager: &PassManager<Self>) -> bool {
LLVMRunFunctionPassManager(pass_manager.pass_manager, self.as_value_ref()) == 1
}
}
// SubTypes: PassManager<Module>, PassManager<FunctionValue>
/// A manager for running optimization and simplification passes. Much of the
/// documentation for specific passes is directly from the [LLVM
/// documentation](https://llvm.org/docs/Passes.html).
#[derive(Debug)]
pub struct PassManager<T> {
pub(crate) pass_manager: LLVMPassManagerRef,
sub_type: PhantomData<T>,
}
impl PassManager<FunctionValue<'_>> {
/// Acquires the underlying raw pointer belonging to this `PassManager<T>` type.
pub fn as_mut_ptr(&self) -> LLVMPassManagerRef {
self.pass_manager
}
// return true means some pass modified the module, not an error occurred
pub fn initialize(&self) -> bool {
unsafe { LLVMInitializeFunctionPassManager(self.pass_manager) == 1 }
}
pub fn finalize(&self) -> bool {
unsafe { LLVMFinalizeFunctionPassManager(self.pass_manager) == 1 }
}
}
impl<T: PassManagerSubType> PassManager<T> {
pub unsafe fn new(pass_manager: LLVMPassManagerRef) -> Self {
assert!(!pass_manager.is_null());
PassManager {
pass_manager,
sub_type: PhantomData,
}
}
pub fn create<I: Borrow<T::Input>>(input: I) -> PassManager<T> {
let pass_manager = unsafe { T::create(input) };
unsafe { PassManager::new(pass_manager) }
}
/// This method returns true if any of the passes modified the function or module
/// and false otherwise.
pub fn run_on(&self, input: &T) -> bool {
unsafe { input.run_in_pass_manager(self) }
}
/// This pass promotes "by reference" arguments to be "by value" arguments.
/// In practice, this means looking for internal functions that have pointer
/// arguments. If it can prove, through the use of alias analysis, that an
/// argument is only loaded, then it can pass the value into the function
/// instead of the address of the value. This can cause recursive simplification
/// of code and lead to the elimination of allocas (especially in C++ template
/// code like the STL).
///
/// This pass also handles aggregate arguments that are passed into a function,
/// scalarizing them if the elements of the aggregate are only loaded. Note that
/// it refuses to scalarize aggregates which would require passing in more than
/// three operands to the function, because passing thousands of operands for a
/// large array or structure is unprofitable!
///
/// Note that this transformation could also be done for arguments that are
/// only stored to (returning the value instead), but does not currently.
/// This case would be best handled when and if LLVM starts supporting multiple
/// return values from functions.
#[llvm_versions(..=14)]
pub fn add_argument_promotion_pass(&self) {
use llvm_sys::transforms::ipo::LLVMAddArgumentPromotionPass;
unsafe { LLVMAddArgumentPromotionPass(self.pass_manager) }
}
/// Merges duplicate global constants together into a single constant that is
/// shared. This is useful because some passes (i.e., TraceValues) insert a lot
/// of string constants into the program, regardless of whether or not an existing
/// string is available.
#[llvm_versions(..=16)]
pub fn add_constant_merge_pass(&self) {
unsafe { LLVMAddConstantMergePass(self.pass_manager) }
}
/// Discovers identical functions and collapses them.
#[llvm_versions(10..=16)]
pub fn add_merge_functions_pass(&self) {
unsafe { LLVMAddMergeFunctionsPass(self.pass_manager) }
}
/// This pass deletes dead arguments from internal functions. Dead argument
/// elimination removes arguments which are directly dead, as well as arguments
/// only passed into function calls as dead arguments of other functions. This
/// pass also deletes dead arguments in a similar way.
///
/// This pass is often useful as a cleanup pass to run after aggressive
/// interprocedural passes, which add possibly-dead arguments.
#[llvm_versions(..=16)]
pub fn add_dead_arg_elimination_pass(&self) {
unsafe { LLVMAddDeadArgEliminationPass(self.pass_manager) }
}
/// A simple interprocedural pass which walks the call-graph, looking for
/// functions which do not access or only read non-local memory, and marking
/// them readnone/readonly. In addition, it marks function arguments (of
/// pointer type) “nocapture” if a call to the function does not create
/// any copies of the pointer value that outlive the call. This more or
/// less means that the pointer is only dereferenced, and not returned
/// from the function or stored in a global. This pass is implemented
/// as a bottom-up traversal of the call-graph.
#[llvm_versions(..=16)]
pub fn add_function_attrs_pass(&self) {
unsafe { LLVMAddFunctionAttrsPass(self.pass_manager) }
}
/// Bottom-up inlining of functions into callees.
#[llvm_versions(..=16)]
pub fn add_function_inlining_pass(&self) {
unsafe { LLVMAddFunctionInliningPass(self.pass_manager) }
}
/// A custom inliner that handles only functions that are marked as “always inline”.
#[llvm_versions(..=16)]
pub fn add_always_inliner_pass(&self) {
unsafe { LLVMAddAlwaysInlinerPass(self.pass_manager) }
}
/// This transform is designed to eliminate unreachable internal
/// globals from the program. It uses an aggressive algorithm,
/// searching out globals that are known to be alive. After it
/// finds all of the globals which are needed, it deletes
/// whatever is left over. This allows it to delete recursive
/// chunks of the program which are unreachable.
#[llvm_versions(..=16)]
pub fn add_global_dce_pass(&self) {
unsafe { LLVMAddGlobalDCEPass(self.pass_manager) }
}
/// This pass transforms simple global variables that never have
/// their address taken. If obviously true, it marks read/write
/// globals as constant, deletes variables only stored to, etc.
#[llvm_versions(..=16)]
pub fn add_global_optimizer_pass(&self) {
unsafe { LLVMAddGlobalOptimizerPass(self.pass_manager) }
}
/// This pass implements an extremely simple interprocedural
/// constant propagation pass. It could certainly be improved
/// in many different ways, like using a worklist. This pass
/// makes arguments dead, but does not remove them. The existing
/// dead argument elimination pass should be run after this to
/// clean up the mess.
///
/// In LLVM 12 and later, this instruction is replaced by the
/// [`add_instruction_simplify_pass`].
#[llvm_versions(..=11)]
pub fn add_ip_constant_propagation_pass(&self) {
unsafe { LLVMAddIPConstantPropagationPass(self.pass_manager) }
}
/// This file implements a simple interprocedural pass which
/// walks the call-graph, turning invoke instructions into
/// call instructions if and only if the callee cannot throw
/// an exception. It implements this as a bottom-up traversal
/// of the call-graph.
#[llvm_versions(..=15)]
pub fn add_prune_eh_pass(&self) {
unsafe { LLVMAddPruneEHPass(self.pass_manager) }
}
/// An interprocedural variant of [Sparse Conditional Constant
/// Propagation](https://llvm.org/docs/Passes.html#passes-sccp).
#[llvm_versions(..=16)]
pub fn add_ipsccp_pass(&self) {
unsafe { LLVMAddIPSCCPPass(self.pass_manager) }
}
/// This pass loops over all of the functions in the input module,
/// looking for a main function. If a main function is found, all
/// other functions and all global variables with initializers are
/// marked as internal.
#[llvm_versions(..=16)]
pub fn add_internalize_pass(&self, all_but_main: bool) {
unsafe { LLVMAddInternalizePass(self.pass_manager, all_but_main as u32) }
}
/// This pass loops over all of the functions in the input module,
/// looking for dead declarations and removes them. Dead declarations
/// are declarations of functions for which no implementation is available
/// (i.e., declarations for unused library functions).
#[llvm_versions(..=16)]
pub fn add_strip_dead_prototypes_pass(&self) {
unsafe { LLVMAddStripDeadPrototypesPass(self.pass_manager) }
}
/// Performs code stripping. This transformation can delete:
///
/// * Names for virtual registers
/// * Symbols for internal globals and functions
/// * Debug information
///
/// Note that this transformation makes code much less readable,
/// so it should only be used in situations where the strip utility
/// would be used, such as reducing code size or making it harder
/// to reverse engineer code.
#[llvm_versions(..=16)]
pub fn add_strip_symbol_pass(&self) {
unsafe { LLVMAddStripSymbolsPass(self.pass_manager) }
}
/// This pass combines instructions inside basic blocks to form
/// vector instructions. It iterates over each basic block,
/// attempting to pair compatible instructions, repeating this
/// process until no additional pairs are selected for vectorization.
/// When the outputs of some pair of compatible instructions are
/// used as inputs by some other pair of compatible instructions,
/// those pairs are part of a potential vectorization chain.
/// Instruction pairs are only fused into vector instructions when
/// they are part of a chain longer than some threshold length.
/// Moreover, the pass attempts to find the best possible chain
/// for each pair of compatible instructions. These heuristics
/// are intended to prevent vectorization in cases where it would
/// not yield a performance increase of the resulting code.
#[cfg(feature = "llvm4-0")]
pub fn add_bb_vectorize_pass(&self) {
use llvm_sys::transforms::vectorize::LLVMAddBBVectorizePass;
unsafe { LLVMAddBBVectorizePass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_loop_vectorize_pass(&self) {
unsafe { LLVMAddLoopVectorizePass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_slp_vectorize_pass(&self) {
unsafe { LLVMAddSLPVectorizePass(self.pass_manager) }
}
/// ADCE aggressively tries to eliminate code. This pass is similar
/// to [DCE](https://llvm.org/docs/Passes.html#passes-dce) but it
/// assumes that values are dead until proven otherwise. This is
/// similar to [SCCP](https://llvm.org/docs/Passes.html#passes-sccp),
/// except applied to the liveness of values.
#[llvm_versions(..=16)]
pub fn add_aggressive_dce_pass(&self) {
unsafe { LLVMAddAggressiveDCEPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_bit_tracking_dce_pass(&self) {
unsafe { LLVMAddBitTrackingDCEPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_alignment_from_assumptions_pass(&self) {
unsafe { LLVMAddAlignmentFromAssumptionsPass(self.pass_manager) }
}
/// Performs dead code elimination and basic block merging. Specifically:
///
/// * Removes basic blocks with no predecessors.
/// * Merges a basic block into its predecessor if there is only one and the predecessor only has one successor.
/// * Eliminates PHI nodes for basic blocks with a single predecessor.
/// * Eliminates a basic block that only contains an unconditional branch.
#[llvm_versions(..=16)]
pub fn add_cfg_simplification_pass(&self) {
unsafe { LLVMAddCFGSimplificationPass(self.pass_manager) }
}
/// A trivial dead store elimination that only considers basic-block local redundant stores.
#[llvm_versions(..=16)]
pub fn add_dead_store_elimination_pass(&self) {
unsafe { LLVMAddDeadStoreEliminationPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_scalarizer_pass(&self) {
unsafe { LLVMAddScalarizerPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_merged_load_store_motion_pass(&self) {
unsafe { LLVMAddMergedLoadStoreMotionPass(self.pass_manager) }
}
/// This pass performs global value numbering to eliminate
/// fully and partially redundant instructions. It also
/// performs redundant load elimination.
#[llvm_versions(..=16)]
pub fn add_gvn_pass(&self) {
unsafe { LLVMAddGVNPass(self.pass_manager) }
}
/// This pass performs global value numbering to eliminate
/// fully and partially redundant instructions. It also
/// performs redundant load elimination.
// REVIEW: Is `LLVMAddGVNPass` deprecated? Should we just seamlessly replace
// the old one with this one in 4.0+?
#[llvm_versions(..=16)]
pub fn add_new_gvn_pass(&self) {
use llvm_sys::transforms::scalar::LLVMAddNewGVNPass;
unsafe { LLVMAddNewGVNPass(self.pass_manager) }
}
/// This transformation analyzes and transforms the induction variables (and
/// computations derived from them) into simpler forms suitable for subsequent
/// analysis and transformation.
///
/// This transformation makes the following changes to each loop with an
/// identifiable induction variable:
///
/// * All loops are transformed to have a single canonical induction variable
/// which starts at zero and steps by one.
///
/// * The canonical induction variable is guaranteed to be the first PHI node
/// in the loop header block.
///
/// * Any pointer arithmetic recurrences are raised to use array subscripts.
///
/// If the trip count of a loop is computable, this pass also makes the
/// following changes:
///
/// * The exit condition for the loop is canonicalized to compare the induction
/// value against the exit value. This turns loops like:
///
/// ```c
/// for (i = 7; i*i < 1000; ++i)
/// ```
/// into
/// ```c
/// for (i = 0; i != 25; ++i)
/// ```
///
/// * Any use outside of the loop of an expression derived from the indvar is
/// changed to compute the derived value outside of the loop, eliminating the
/// dependence on the exit value of the induction variable. If the only purpose
/// of the loop is to compute the exit value of some derived expression, this
/// transformation will make the loop dead.
///
/// This transformation should be followed by strength reduction after all of
/// the desired loop transformations have been performed. Additionally, on
/// targets where it is profitable, the loop could be transformed to count
/// down to zero (the "do loop" optimization).
#[llvm_versions(..=16)]
pub fn add_ind_var_simplify_pass(&self) {
unsafe { LLVMAddIndVarSimplifyPass(self.pass_manager) }
}
/// Combine instructions to form fewer, simple instructions. This pass
/// does not modify the CFG. This pass is where algebraic simplification happens.
///
/// This pass combines things like:
///
/// ```c
/// %Y = add i32 %X, 1
/// %Z = add i32 %Y, 1
/// ```
/// into:
/// ```c
/// %Z = add i32 %X, 2
/// ```
///
/// This is a simple worklist driven algorithm.
///
/// This pass guarantees that the following canonicalization are performed
/// on the program:
///
/// 1. If a binary operator has a constant operand, it is moved to the
/// right-hand side.
///
/// 2. Bitwise operators with constant operands are always grouped so that
/// shifts are performed first, then ors, then ands, then xors.
///
/// 3. Compare instructions are converted from <, >, ≤, or ≥ to = or ≠ if possible.
///
/// 4. All cmp instructions on boolean values are replaced with logical operations.
///
/// 5. add X, X is represented as mul X, 2 ⇒ shl X, 1
///
/// 6. Multiplies with a constant power-of-two argument are transformed into shifts.
///
/// 7. ... etc.
///
/// This pass can also simplify calls to specific well-known function calls
/// (e.g. runtime library functions). For example, a call exit(3) that occurs within
/// the main() function can be transformed into simply return 3. Whether or not library
/// calls are simplified is controlled by the [-functionattrs](https://llvm.org/docs/Passes.html#passes-functionattrs)
/// pass and LLVM’s knowledge of library calls on different targets.
#[llvm_versions(..=16)]
pub fn add_instruction_combining_pass(&self) {
unsafe { LLVMAddInstructionCombiningPass(self.pass_manager) }
}
/// Jump threading tries to find distinct threads of control flow
/// running through a basic block. This pass looks at blocks that
/// have multiple predecessors and multiple successors. If one or
/// more of the predecessors of the block can be proven to always
/// cause a jump to one of the successors, we forward the edge from
/// the predecessor to the successor by duplicating the contents of
/// this block.
///
/// An example of when this can occur is code like this:
///
/// ```c
/// if () { ...
/// X = 4;
/// }
/// if (X < 3) {
/// ```
///
/// In this case, the unconditional branch at the end of the first
/// if can be revectored to the false side of the second if.
#[llvm_versions(..=16)]
pub fn add_jump_threading_pass(&self) {
unsafe { LLVMAddJumpThreadingPass(self.pass_manager) }
}
/// This pass performs loop invariant code motion,
/// attempting to remove as much code from the body of
/// a loop as possible. It does this by either hoisting
/// code into the preheader block, or by sinking code to
/// the exit blocks if it is safe. This pass also promotes
/// must-aliased memory locations in the loop to live in
/// registers, thus hoisting and sinking “invariant” loads
/// and stores.
///
/// This pass uses alias analysis for two purposes:
///
/// 1. Moving loop invariant loads and calls out of loops.
/// If we can determine that a load or call inside of a
/// loop never aliases anything stored to, we can hoist
/// it or sink it like any other instruction.
///
/// 2. Scalar Promotion of Memory. If there is a store
/// instruction inside of the loop, we try to move the
/// store to happen AFTER the loop instead of inside of
/// the loop. This can only happen if a few conditions
/// are true:
///
/// 1. The pointer stored through is loop invariant.
///
/// 2. There are no stores or loads in the loop
/// which may alias the pointer. There are no calls in
/// the loop which mod/ref the pointer.
///
/// If these conditions are true, we can promote the loads
/// and stores in the loop of the pointer to use a temporary
/// alloca'd variable. We then use the mem2reg functionality
/// to construct the appropriate SSA form for the variable.
#[llvm_versions(..=16)]
pub fn add_licm_pass(&self) {
unsafe { LLVMAddLICMPass(self.pass_manager) }
}
/// This file implements the Dead Loop Deletion Pass.
/// This pass is responsible for eliminating loops with
/// non-infinite computable trip counts that have no side
/// effects or volatile instructions, and do not contribute
/// to the computation of the function’s return value.
#[llvm_versions(..=16)]
pub fn add_loop_deletion_pass(&self) {
unsafe { LLVMAddLoopDeletionPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_loop_idiom_pass(&self) {
unsafe { LLVMAddLoopIdiomPass(self.pass_manager) }
}
/// A simple loop rotation transformation.
#[llvm_versions(..=16)]
pub fn add_loop_rotate_pass(&self) {
unsafe { LLVMAddLoopRotatePass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_loop_reroll_pass(&self) {
unsafe { LLVMAddLoopRerollPass(self.pass_manager) }
}
/// This pass implements a simple loop unroller.
/// It works best when loops have been canonicalized
/// by the [indvars](https://llvm.org/docs/Passes.html#passes-indvars)
/// pass, allowing it to determine the trip counts
/// of loops easily.
#[llvm_versions(..=16)]
pub fn add_loop_unroll_pass(&self) {
unsafe { LLVMAddLoopUnrollPass(self.pass_manager) }
}
/// This pass transforms loops that contain branches on
/// loop-invariant conditions to have multiple loops.
/// For example, it turns the left into the right code:
///
/// ```c
/// for (...) if (lic)
/// A for (...)
/// if (lic) A; B; C
/// B else
/// C for (...)
/// A; C
/// ```
///
/// This can increase the size of the code exponentially
/// (doubling it every time a loop is unswitched) so we
/// only unswitch if the resultant code will be smaller
/// than a threshold.
///
/// This pass expects [LICM](https://llvm.org/docs/Passes.html#passes-licm)
/// to be run before it to hoist invariant conditions
/// out of the loop, to make the unswitching opportunity
/// obvious.
#[llvm_versions(..=14)]
pub fn add_loop_unswitch_pass(&self) {
use llvm_sys::transforms::scalar::LLVMAddLoopUnswitchPass;
unsafe { LLVMAddLoopUnswitchPass(self.pass_manager) }
}
/// This pass performs various transformations related
/// to eliminating memcpy calls, or transforming sets
/// of stores into memsets.
#[llvm_versions(..=16)]
pub fn add_memcpy_optimize_pass(&self) {
unsafe { LLVMAddMemCpyOptPass(self.pass_manager) }
}
/// This pass performs partial inlining, typically by inlining
/// an if statement that surrounds the body of the function.
#[llvm_versions(..=16)]
pub fn add_partially_inline_lib_calls_pass(&self) {
unsafe { LLVMAddPartiallyInlineLibCallsPass(self.pass_manager) }
}
/// Rewrites switch instructions with a sequence of branches,
/// which allows targets to get away with not implementing the
/// switch instruction until it is convenient.
#[llvm_versions(..=16)]
pub fn add_lower_switch_pass(&self) {
#[llvm_versions(..=6)]
use llvm_sys::transforms::scalar::LLVMAddLowerSwitchPass;
#[llvm_versions(7..=16)]
use llvm_sys::transforms::util::LLVMAddLowerSwitchPass;
unsafe { LLVMAddLowerSwitchPass(self.pass_manager) }
}
/// This file promotes memory references to be register references.
/// It promotes alloca instructions which only have loads and stores
/// as uses. An alloca is transformed by using dominator frontiers
/// to place phi nodes, then traversing the function in depth-first
/// order to rewrite loads and stores as appropriate. This is just
/// the standard SSA construction algorithm to construct "pruned" SSA form.
#[llvm_versions(..=16)]
pub fn add_promote_memory_to_register_pass(&self) {
#[llvm_versions(..=6)]
use llvm_sys::transforms::scalar::LLVMAddPromoteMemoryToRegisterPass;
#[llvm_versions(7..=16)]
use llvm_sys::transforms::util::LLVMAddPromoteMemoryToRegisterPass;
unsafe { LLVMAddPromoteMemoryToRegisterPass(self.pass_manager) }
}
/// This pass reassociates commutative expressions in an order that is designed
/// to promote better constant propagation, GCSE, LICM, PRE, etc.
///
/// For example: 4 + (x + 5) ⇒ x + (4 + 5)
///
/// In the implementation of this algorithm, constants are assigned rank = 0,
/// function arguments are rank = 1, and other values are assigned ranks
/// corresponding to the reverse post order traversal of current function
/// (starting at 2), which effectively gives values in deep loops higher
/// rank than values not in loops.
#[llvm_versions(..=16)]
pub fn add_reassociate_pass(&self) {
unsafe { LLVMAddReassociatePass(self.pass_manager) }
}
/// Sparse conditional constant propagation and merging, which can
/// be summarized as:
///
/// * Assumes values are constant unless proven otherwise
/// * Assumes BasicBlocks are dead unless proven otherwise
/// * Proves values to be constant, and replaces them with constants
/// * Proves conditional branches to be unconditional
///
/// Note that this pass has a habit of making definitions be dead.
/// It is a good idea to run a DCE pass sometime after running this pass.
#[llvm_versions(..=16)]
pub fn add_sccp_pass(&self) {
unsafe { LLVMAddSCCPPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_scalar_repl_aggregates_pass(&self) {
unsafe { LLVMAddScalarReplAggregatesPass(self.pass_manager) }
}
/// The well-known scalar replacement of aggregates transformation.
/// This transform breaks up alloca instructions of aggregate type
/// (structure or array) into individual alloca instructions for each
/// member if possible. Then, if possible, it transforms the individual
/// alloca instructions into nice clean scalar SSA form.
#[llvm_versions(..=16)]
pub fn add_scalar_repl_aggregates_pass_ssa(&self) {
unsafe { LLVMAddScalarReplAggregatesPassSSA(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_scalar_repl_aggregates_pass_with_threshold(&self, threshold: i32) {
unsafe { LLVMAddScalarReplAggregatesPassWithThreshold(self.pass_manager, threshold) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_simplify_lib_calls_pass(&self) {
unsafe { LLVMAddSimplifyLibCallsPass(self.pass_manager) }
}
/// This file transforms calls of the current function (self recursion) followed
/// by a return instruction with a branch to the entry of the function, creating
/// a loop. This pass also implements the following extensions to the basic algorithm:
///
/// 1. Trivial instructions between the call and return do not prevent the
/// transformation from taking place, though currently the analysis cannot support
/// moving any really useful instructions (only dead ones).
///
/// 2. This pass transforms functions that are prevented from being tail
/// recursive by an associative expression to use an accumulator variable, thus
/// compiling the typical naive factorial or fib implementation into efficient code.
///
/// 3. TRE is performed if the function returns void, if the return returns
/// the result returned by the call, or if the function returns a run-time constant
/// on all exits from the function. It is possible, though unlikely, that the return
/// returns something else (like constant 0), and can still be TRE’d. It can be
/// TRE'd if all other return instructions in the function return the exact same value.
///
/// 4. If it can prove that callees do not access theier caller stack frame,
/// they are marked as eligible for tail call elimination (by the code generator).
#[llvm_versions(..=16)]
pub fn add_tail_call_elimination_pass(&self) {
unsafe { LLVMAddTailCallEliminationPass(self.pass_manager) }
}
/// This pass implements constant propagation and merging. It looks for instructions
/// involving only constant operands and replaces them with a constant value instead
/// of an instruction. For example:
///
/// ```ir
/// add i32 1, 2
/// ```
///
/// becomes
///
/// ```ir
/// i32 3
/// ```
///
/// NOTE: this pass has a habit of making definitions be dead. It is a good idea to
/// run a Dead Instruction Elimination pass sometime after running this pass.
///
/// In LLVM 12 and later, this instruction is replaced by the
/// [`add_instruction_simplify_pass`].
#[llvm_versions(..=11)]
pub fn add_constant_propagation_pass(&self) {
unsafe { LLVMAddConstantPropagationPass(self.pass_manager) }
}
/// This pass implements constant propagation and merging. It looks for instructions
/// involving only constant operands and replaces them with a constant value instead
/// of an instruction. For example:
///
/// ```ir
/// add i32 1, 2
/// ```
///
/// becomes
///
/// ```ir
/// i32 3
/// ```
///
/// NOTE: this pass has a habit of making definitions be dead. It is a good idea to
/// run a Dead Instruction Elimination pass sometime after running this pass.
#[llvm_versions(12..=16)]
pub fn add_instruction_simplify_pass(&self) {
unsafe { LLVMAddInstructionSimplifyPass(self.pass_manager) }
}
/// This file promotes memory references to be register references.
/// It promotes alloca instructions which only have loads and stores
/// as uses. An alloca is transformed by using dominator frontiers to
/// place phi nodes, then traversing the function in depth-first order to
/// rewrite loads and stores as appropriate. This is just the standard SSA
/// construction algorithm to construct “pruned” SSA form.
#[llvm_versions(..=16)]
pub fn add_demote_memory_to_register_pass(&self) {
unsafe { LLVMAddDemoteMemoryToRegisterPass(self.pass_manager) }
}
/// Verifies an LLVM IR code. This is useful to run after an optimization
/// which is undergoing testing. Note that llvm-as verifies its input before
/// emitting bitcode, and also that malformed bitcode is likely to make
/// LLVM crash. All language front-ends are therefore encouraged to verify
/// their output before performing optimizing transformations.
///
/// 1. Both of a binary operator’s parameters are of the same type.
///
/// 2. Verify that the indices of mem access instructions match other operands.
///
/// 3. Verify that arithmetic and other things are only performed on
/// first-class types. Verify that shifts and logicals only happen on
/// integrals f.e.
///
/// 4. All of the constants in a switch statement are of the correct type.
///
/// 5. The code is in valid SSA form.
///
/// 6. It is illegal to put a label into any other type (like a structure)
/// or to return one.
///
/// 7. Only phi nodes can be self referential: %x = add i32 %x, %x is invalid.
///
/// 8. PHI nodes must have an entry for each predecessor, with no extras.
///
/// 9. PHI nodes must be the first thing in a basic block, all grouped together.
///
/// 10. PHI nodes must have at least one entry.
///
/// 11. All basic blocks should only end with terminator insts, not contain them.
///
/// 12. The entry node to a function must not have predecessors.
///
/// 13. All Instructions must be embedded into a basic block.
///
/// 14. Functions cannot take a void-typed parameter.
///
/// 15. Verify that a function’s argument list agrees with its declared type.
///
/// 16. It is illegal to specify a name for a void value.
///
/// 17. It is illegal to have an internal global value with no initializer.
///
/// 18. It is illegal to have a ret instruction that returns a value that does
/// not agree with the function return value type.
///
/// 19. Function call argument types match the function prototype.
///
/// 20. All other things that are tested by asserts spread about the code.
///
/// Note that this does not provide full security verification (like Java), but instead just tries to ensure that code is well-formed.
#[llvm_versions(..=16)]
pub fn add_verifier_pass(&self) {
unsafe { LLVMAddVerifierPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_correlated_value_propagation_pass(&self) {
unsafe { LLVMAddCorrelatedValuePropagationPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_early_cse_pass(&self) {
unsafe { LLVMAddEarlyCSEPass(self.pass_manager) }
}
#[llvm_versions(..=16)]
/// No LLVM documentation is available at this time.
pub fn add_early_cse_mem_ssa_pass(&self) {
use llvm_sys::transforms::scalar::LLVMAddEarlyCSEMemSSAPass;
unsafe { LLVMAddEarlyCSEMemSSAPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_lower_expect_intrinsic_pass(&self) {
unsafe { LLVMAddLowerExpectIntrinsicPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_type_based_alias_analysis_pass(&self) {
unsafe { LLVMAddTypeBasedAliasAnalysisPass(self.pass_manager) }
}
/// No LLVM documentation is available at this time.
#[llvm_versions(..=16)]
pub fn add_scoped_no_alias_aa_pass(&self) {
unsafe { LLVMAddScopedNoAliasAAPass(self.pass_manager) }
}
/// A basic alias analysis pass that implements identities
/// (two different globals cannot alias, etc), but does no
/// stateful analysis.
#[llvm_versions(..=16)]
pub fn add_basic_alias_analysis_pass(&self) {
unsafe { LLVMAddBasicAliasAnalysisPass(self.pass_manager) }
}
#[llvm_versions(7..=15)]
pub fn add_aggressive_inst_combiner_pass(&self) {
#[cfg(not(feature = "llvm7-0"))]
use llvm_sys::transforms::aggressive_instcombine::LLVMAddAggressiveInstCombinerPass;
#[cfg(feature = "llvm7-0")]
use llvm_sys::transforms::scalar::LLVMAddAggressiveInstCombinerPass;
unsafe { LLVMAddAggressiveInstCombinerPass(self.pass_manager) }
}
#[llvm_versions(7..=16)]
pub fn add_loop_unroll_and_jam_pass(&self) {
use llvm_sys::transforms::scalar::LLVMAddLoopUnrollAndJamPass;
unsafe { LLVMAddLoopUnrollAndJamPass(self.pass_manager) }
}
#[llvm_versions(8..15)]
pub fn add_coroutine_early_pass(&self) {
use llvm_sys::transforms::coroutines::LLVMAddCoroEarlyPass;
unsafe { LLVMAddCoroEarlyPass(self.pass_manager) }
}
#[llvm_versions(8..15)]
pub fn add_coroutine_split_pass(&self) {
use llvm_sys::transforms::coroutines::LLVMAddCoroSplitPass;
unsafe { LLVMAddCoroSplitPass(self.pass_manager) }
}
#[llvm_versions(8..15)]
pub fn add_coroutine_elide_pass(&self) {
use llvm_sys::transforms::coroutines::LLVMAddCoroElidePass;
unsafe { LLVMAddCoroElidePass(self.pass_manager) }
}
#[llvm_versions(8..15)]
pub fn add_coroutine_cleanup_pass(&self) {
use llvm_sys::transforms::coroutines::LLVMAddCoroCleanupPass;
unsafe { LLVMAddCoroCleanupPass(self.pass_manager) }
}
}
impl<T> Drop for PassManager<T> {
fn drop(&mut self) {
unsafe { LLVMDisposePassManager(self.pass_manager) }
}
}
#[llvm_versions(..=16)]
#[derive(Debug)]
pub struct PassRegistry {
pass_registry: LLVMPassRegistryRef,
}
#[llvm_versions(..=16)]
impl PassRegistry {
pub unsafe fn new(pass_registry: LLVMPassRegistryRef) -> PassRegistry {
assert!(!pass_registry.is_null());
PassRegistry { pass_registry }
}
/// Acquires the underlying raw pointer belonging to this `PassRegistry` type.
pub fn as_mut_ptr(&self) -> LLVMPassRegistryRef {
self.pass_registry
}
pub fn get_global() -> PassRegistry {
let pass_registry = unsafe { LLVMGetGlobalPassRegistry() };
unsafe { PassRegistry::new(pass_registry) }
}
pub fn initialize_core(&self) {
unsafe { LLVMInitializeCore(self.pass_registry) }
}
pub fn initialize_transform_utils(&self) {
unsafe { LLVMInitializeTransformUtils(self.pass_registry) }
}
pub fn initialize_scalar_opts(&self) {
unsafe { LLVMInitializeScalarOpts(self.pass_registry) }
}
#[llvm_versions(..=15)]
pub fn initialize_obj_carc_opts(&self) {
unsafe { LLVMInitializeObjCARCOpts(self.pass_registry) }
}
pub fn initialize_vectorization(&self) {
unsafe { LLVMInitializeVectorization(self.pass_registry) }
}
pub fn initialize_inst_combine(&self) {
unsafe { LLVMInitializeInstCombine(self.pass_registry) }
}
// Let us begin our initial public offering
pub fn initialize_ipo(&self) {
unsafe { LLVMInitializeIPO(self.pass_registry) }
}
#[llvm_versions(..=15)]
pub fn initialize_instrumentation(&self) {
unsafe { LLVMInitializeInstrumentation(self.pass_registry) }
}
pub fn initialize_analysis(&self) {
unsafe { LLVMInitializeAnalysis(self.pass_registry) }
}
pub fn initialize_ipa(&self) {
unsafe { LLVMInitializeIPA(self.pass_registry) }
}
pub fn initialize_codegen(&self) {
unsafe { LLVMInitializeCodeGen(self.pass_registry) }
}
pub fn initialize_target(&self) {
unsafe { LLVMInitializeTarget(self.pass_registry) }
}
#[llvm_versions(7..=15)]
pub fn initialize_aggressive_inst_combiner(&self) {
use llvm_sys::initialization::LLVMInitializeAggressiveInstCombiner;
unsafe { LLVMInitializeAggressiveInstCombiner(self.pass_registry) }
}
}
#[llvm_versions(13..)]
#[derive(Debug)]
pub struct PassBuilderOptions {
pub(crate) options_ref: LLVMPassBuilderOptionsRef,
}
#[llvm_versions(13..)]
impl PassBuilderOptions {
/// Create a new set of options for a PassBuilder
pub fn create() -> Self {
unsafe {
PassBuilderOptions {
options_ref: LLVMCreatePassBuilderOptions(),
}
}
}
/// Acquires the underlying raw pointer belonging to this `PassBuilderOptions` type.
pub fn as_mut_ptr(&self) -> LLVMPassBuilderOptionsRef {
self.options_ref
}
///Toggle adding the VerifierPass for the PassBuilder, ensuring all functions inside the module is valid.
pub fn set_verify_each(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetVerifyEach(self.options_ref, value as i32);
}
}
///Toggle debug logging when running the PassBuilder.
pub fn set_debug_logging(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetDebugLogging(self.options_ref, value as i32);
}
}
pub fn set_loop_interleaving(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetLoopInterleaving(self.options_ref, value as i32);
}
}
pub fn set_loop_vectorization(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetLoopVectorization(self.options_ref, value as i32);
}
}
pub fn set_loop_slp_vectorization(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetSLPVectorization(self.options_ref, value as i32);
}
}
pub fn set_loop_unrolling(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetLoopUnrolling(self.options_ref, value as i32);
}
}
pub fn set_forget_all_scev_in_loop_unroll(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetForgetAllSCEVInLoopUnroll(self.options_ref, value as i32);
}
}
pub fn set_licm_mssa_opt_cap(&self, value: u32) {
unsafe {
LLVMPassBuilderOptionsSetLicmMssaOptCap(self.options_ref, value);
}
}
pub fn set_licm_mssa_no_acc_for_promotion_cap(&self, value: u32) {
unsafe {
LLVMPassBuilderOptionsSetLicmMssaNoAccForPromotionCap(self.options_ref, value);
}
}
pub fn set_call_graph_profile(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetCallGraphProfile(self.options_ref, value as i32);
}
}
pub fn set_merge_functions(&self, value: bool) {
unsafe {
LLVMPassBuilderOptionsSetMergeFunctions(self.options_ref, value as i32);
}
}
}
#[llvm_versions(13..)]
impl Drop for PassBuilderOptions {
fn drop(&mut self) {
unsafe {
LLVMDisposePassBuilderOptions(self.options_ref);
}
}
}