compiler/rustc_mir_transform/src/patch.rs - rust - Git at Google

 use rustc_index::{Idx, IndexVec};
 use rustc_middle::mir::*;
 use rustc_middle::ty::Ty;
 use rustc_span::Span;
 use tracing::debug;

 /// This struct lets you "patch" a MIR body, i.e. modify it. You can queue up
 /// various changes, such as the addition of new statements and basic blocks
 /// and replacement of terminators, and then apply the queued changes all at
 /// once with `apply`. This is useful for MIR transformation passes.
 pub(crate) struct MirPatch<'tcx> {
     term_patch_map: IndexVec<BasicBlock, Option<TerminatorKind<'tcx>>>,
     new_blocks: Vec<BasicBlockData<'tcx>>,
     new_statements: Vec<(Location, StatementKind<'tcx>)>,
     new_locals: Vec<LocalDecl<'tcx>>,
     resume_block: Option<BasicBlock>,
     // Only for unreachable in cleanup path.
     unreachable_cleanup_block: Option<BasicBlock>,
     // Only for unreachable not in cleanup path.
     unreachable_no_cleanup_block: Option<BasicBlock>,
     // Cached block for UnwindTerminate (with reason)
     terminate_block: Option<(BasicBlock, UnwindTerminateReason)>,
     body_span: Span,
     next_local: usize,
 }

 impl<'tcx> MirPatch<'tcx> {
     /// Creates a new, empty patch.
     pub(crate) fn new(body: &Body<'tcx>) -> Self {
         let mut result = MirPatch {
             term_patch_map: IndexVec::from_elem(None, &body.basic_blocks),
             new_blocks: vec![],
             new_statements: vec![],
             new_locals: vec![],
             next_local: body.local_decls.len(),
             resume_block: None,
             unreachable_cleanup_block: None,
             unreachable_no_cleanup_block: None,
             terminate_block: None,
             body_span: body.span,
         };

         for (bb, block) in body.basic_blocks.iter_enumerated() {
             // Check if we already have a resume block
             if matches!(block.terminator().kind, TerminatorKind::UnwindResume)
                 && block.statements.is_empty()
             {
                 result.resume_block = Some(bb);
                 continue;
             }

             // Check if we already have an unreachable block
             if matches!(block.terminator().kind, TerminatorKind::Unreachable)
                 && block.statements.is_empty()
             {
                 if block.is_cleanup {
                     result.unreachable_cleanup_block = Some(bb);
                 } else {
                     result.unreachable_no_cleanup_block = Some(bb);
                 }
                 continue;
             }

             // Check if we already have a terminate block
             if let TerminatorKind::UnwindTerminate(reason) = block.terminator().kind
                 && block.statements.is_empty()
             {
                 result.terminate_block = Some((bb, reason));
                 continue;
             }
         }

         result
     }

     pub(crate) fn resume_block(&mut self) -> BasicBlock {
         if let Some(bb) = self.resume_block {
             return bb;
         }

         let bb = self.new_block(BasicBlockData {
             statements: vec![],
             terminator: Some(Terminator {
                 source_info: SourceInfo::outermost(self.body_span),
                 kind: TerminatorKind::UnwindResume,
             }),
             is_cleanup: true,
         });
         self.resume_block = Some(bb);
         bb
     }

     pub(crate) fn unreachable_cleanup_block(&mut self) -> BasicBlock {
         if let Some(bb) = self.unreachable_cleanup_block {
             return bb;
         }

         let bb = self.new_block(BasicBlockData {
             statements: vec![],
             terminator: Some(Terminator {
                 source_info: SourceInfo::outermost(self.body_span),
                 kind: TerminatorKind::Unreachable,
             }),
             is_cleanup: true,
         });
         self.unreachable_cleanup_block = Some(bb);
         bb
     }

     pub(crate) fn unreachable_no_cleanup_block(&mut self) -> BasicBlock {
         if let Some(bb) = self.unreachable_no_cleanup_block {
             return bb;
         }

         let bb = self.new_block(BasicBlockData {
             statements: vec![],
             terminator: Some(Terminator {
                 source_info: SourceInfo::outermost(self.body_span),
                 kind: TerminatorKind::Unreachable,
             }),
             is_cleanup: false,
         });
         self.unreachable_no_cleanup_block = Some(bb);
         bb
     }

     pub(crate) fn terminate_block(&mut self, reason: UnwindTerminateReason) -> BasicBlock {
         if let Some((cached_bb, cached_reason)) = self.terminate_block
             && reason == cached_reason
         {
             return cached_bb;
         }

         let bb = self.new_block(BasicBlockData {
             statements: vec![],
             terminator: Some(Terminator {
                 source_info: SourceInfo::outermost(self.body_span),
                 kind: TerminatorKind::UnwindTerminate(reason),
             }),
             is_cleanup: true,
         });
         self.terminate_block = Some((bb, reason));
         bb
     }

     /// Has a replacement of this block's terminator been queued in this patch?
     pub(crate) fn is_term_patched(&self, bb: BasicBlock) -> bool {
         self.term_patch_map[bb].is_some()
     }

     /// Universal getter for block data, either it is in 'old' blocks or in patched ones
     pub(crate) fn block<'a>(
         &'a self,
         body: &'a Body<'tcx>,
         bb: BasicBlock,
     ) -> &'a BasicBlockData<'tcx> {
         match bb.index().checked_sub(body.basic_blocks.len()) {
             Some(new) => &self.new_blocks[new],
             None => &body[bb],
         }
     }

     pub(crate) fn terminator_loc(&self, body: &Body<'tcx>, bb: BasicBlock) -> Location {
         let offset = self.block(body, bb).statements.len();
         Location { block: bb, statement_index: offset }
     }

     /// Queues the addition of a new temporary with additional local info.
     pub(crate) fn new_local_with_info(
         &mut self,
         ty: Ty<'tcx>,
         span: Span,
         local_info: LocalInfo<'tcx>,
     ) -> Local {
         let index = self.next_local;
         self.next_local += 1;
         let mut new_decl = LocalDecl::new(ty, span);
         **new_decl.local_info.as_mut().unwrap_crate_local() = local_info;
         self.new_locals.push(new_decl);
         Local::new(index)
     }

     /// Queues the addition of a new temporary.
     pub(crate) fn new_temp(&mut self, ty: Ty<'tcx>, span: Span) -> Local {
         let index = self.next_local;
         self.next_local += 1;
         self.new_locals.push(LocalDecl::new(ty, span));
         Local::new(index)
     }

     /// Returns the type of a local that's newly-added in the patch.
     pub(crate) fn local_ty(&self, local: Local) -> Ty<'tcx> {
         let local = local.as_usize();
         assert!(local < self.next_local);
         let new_local_idx = self.new_locals.len() - (self.next_local - local);
         self.new_locals[new_local_idx].ty
     }

     /// Queues the addition of a new basic block.
     pub(crate) fn new_block(&mut self, data: BasicBlockData<'tcx>) -> BasicBlock {
         let block = self.term_patch_map.next_index();
         debug!("MirPatch: new_block: {:?}: {:?}", block, data);
         self.new_blocks.push(data);
         self.term_patch_map.push(None);
         block
     }

     /// Queues the replacement of a block's terminator.
     pub(crate) fn patch_terminator(&mut self, block: BasicBlock, new: TerminatorKind<'tcx>) {
         assert!(self.term_patch_map[block].is_none());
         debug!("MirPatch: patch_terminator({:?}, {:?})", block, new);
         self.term_patch_map[block] = Some(new);
     }

     /// Queues the insertion of a statement at a given location. The statement
     /// currently at that location, and all statements that follow, are shifted
     /// down. If multiple statements are queued for addition at the same
     /// location, the final statement order after calling `apply` will match
     /// the queue insertion order.
     ///
     /// E.g. if we have `s0` at location `loc` and do these calls:
     ///
     ///   p.add_statement(loc, s1);
     ///   p.add_statement(loc, s2);
     ///   p.apply(body);
     ///
     /// then the final order will be `s1, s2, s0`, with `s1` at `loc`.
     pub(crate) fn add_statement(&mut self, loc: Location, stmt: StatementKind<'tcx>) {
         debug!("MirPatch: add_statement({:?}, {:?})", loc, stmt);
         self.new_statements.push((loc, stmt));
     }

     /// Like `add_statement`, but specialized for assignments.
     pub(crate) fn add_assign(&mut self, loc: Location, place: Place<'tcx>, rv: Rvalue<'tcx>) {
         self.add_statement(loc, StatementKind::Assign(Box::new((place, rv))));
     }

     /// Applies the queued changes.
     pub(crate) fn apply(self, body: &mut Body<'tcx>) {
         debug!(
             "MirPatch: {:?} new temps, starting from index {}: {:?}",
             self.new_locals.len(),
             body.local_decls.len(),
             self.new_locals
         );
         debug!(
             "MirPatch: {} new blocks, starting from index {}",
             self.new_blocks.len(),
             body.basic_blocks.len()
         );
         let bbs = if self.term_patch_map.is_empty() && self.new_blocks.is_empty() {
             body.basic_blocks.as_mut_preserves_cfg()
         } else {
             body.basic_blocks.as_mut()
         };
         bbs.extend(self.new_blocks);
         body.local_decls.extend(self.new_locals);
         for (src, patch) in self.term_patch_map.into_iter_enumerated() {
             if let Some(patch) = patch {
                 debug!("MirPatch: patching block {:?}", src);
                 bbs[src].terminator_mut().kind = patch;
             }
         }

         let mut new_statements = self.new_statements;

         // This must be a stable sort to provide the ordering described in the
         // comment for `add_statement`.
         new_statements.sort_by_key(|s| s.0);

         let mut delta = 0;
         let mut last_bb = START_BLOCK;
         for (mut loc, stmt) in new_statements {
             if loc.block != last_bb {
                 delta = 0;
                 last_bb = loc.block;
             }
             debug!("MirPatch: adding statement {:?} at loc {:?}+{}", stmt, loc, delta);
             loc.statement_index += delta;
             let source_info = Self::source_info_for_index(&body[loc.block], loc);
             body[loc.block]
                 .statements
                 .insert(loc.statement_index, Statement { source_info, kind: stmt });
             delta += 1;
         }
     }

     fn source_info_for_index(data: &BasicBlockData<'_>, loc: Location) -> SourceInfo {
         match data.statements.get(loc.statement_index) {
             Some(stmt) => stmt.source_info,
             None => data.terminator().source_info,
         }
     }

     pub(crate) fn source_info_for_location(&self, body: &Body<'tcx>, loc: Location) -> SourceInfo {
         let data = self.block(body, loc.block);
         Self::source_info_for_index(data, loc)
     }
 }
	use rustc_index::{Idx, IndexVec};
	use rustc_middle::mir::*;
	use rustc_middle::ty::Ty;
	use rustc_span::Span;
	use tracing::debug;

	/// This struct lets you "patch" a MIR body, i.e. modify it. You can queue up
	/// various changes, such as the addition of new statements and basic blocks
	/// and replacement of terminators, and then apply the queued changes all at
	/// once with `apply`. This is useful for MIR transformation passes.
	pub(crate) struct MirPatch<'tcx> {
	term_patch_map: IndexVec<BasicBlock, Option<TerminatorKind<'tcx>>>,
	new_blocks: Vec<BasicBlockData<'tcx>>,
	new_statements: Vec<(Location, StatementKind<'tcx>)>,
	new_locals: Vec<LocalDecl<'tcx>>,
	resume_block: Option<BasicBlock>,
	// Only for unreachable in cleanup path.
	unreachable_cleanup_block: Option<BasicBlock>,
	// Only for unreachable not in cleanup path.
	unreachable_no_cleanup_block: Option<BasicBlock>,
	// Cached block for UnwindTerminate (with reason)
	terminate_block: Option<(BasicBlock, UnwindTerminateReason)>,
	body_span: Span,
	next_local: usize,
	}

	impl<'tcx> MirPatch<'tcx> {
	/// Creates a new, empty patch.
	pub(crate) fn new(body: &Body<'tcx>) -> Self {
	let mut result = MirPatch {
	term_patch_map: IndexVec::from_elem(None, &body.basic_blocks),
	new_blocks: vec![],
	new_statements: vec![],
	new_locals: vec![],
	next_local: body.local_decls.len(),
	resume_block: None,
	unreachable_cleanup_block: None,
	unreachable_no_cleanup_block: None,
	terminate_block: None,
	body_span: body.span,
	};

	for (bb, block) in body.basic_blocks.iter_enumerated() {
	// Check if we already have a resume block
	if matches!(block.terminator().kind, TerminatorKind::UnwindResume)
	&& block.statements.is_empty()
	{
	result.resume_block = Some(bb);
	continue;
	}

	// Check if we already have an unreachable block
	if matches!(block.terminator().kind, TerminatorKind::Unreachable)
	&& block.statements.is_empty()
	{
	if block.is_cleanup {
	result.unreachable_cleanup_block = Some(bb);
	} else {
	result.unreachable_no_cleanup_block = Some(bb);
	}
	continue;
	}

	// Check if we already have a terminate block
	if let TerminatorKind::UnwindTerminate(reason) = block.terminator().kind
	&& block.statements.is_empty()
	{
	result.terminate_block = Some((bb, reason));
	continue;
	}
	}

	result
	}

	pub(crate) fn resume_block(&mut self) -> BasicBlock {
	if let Some(bb) = self.resume_block {
	return bb;
	}

	let bb = self.new_block(BasicBlockData {
	statements: vec![],
	terminator: Some(Terminator {
	source_info: SourceInfo::outermost(self.body_span),
	kind: TerminatorKind::UnwindResume,
	}),
	is_cleanup: true,
	});
	self.resume_block = Some(bb);
	bb
	}

	pub(crate) fn unreachable_cleanup_block(&mut self) -> BasicBlock {
	if let Some(bb) = self.unreachable_cleanup_block {
	return bb;
	}

	let bb = self.new_block(BasicBlockData {
	statements: vec![],
	terminator: Some(Terminator {
	source_info: SourceInfo::outermost(self.body_span),
	kind: TerminatorKind::Unreachable,
	}),
	is_cleanup: true,
	});
	self.unreachable_cleanup_block = Some(bb);
	bb
	}

	pub(crate) fn unreachable_no_cleanup_block(&mut self) -> BasicBlock {
	if let Some(bb) = self.unreachable_no_cleanup_block {
	return bb;
	}

	let bb = self.new_block(BasicBlockData {
	statements: vec![],
	terminator: Some(Terminator {
	source_info: SourceInfo::outermost(self.body_span),
	kind: TerminatorKind::Unreachable,
	}),
	is_cleanup: false,
	});
	self.unreachable_no_cleanup_block = Some(bb);
	bb
	}

	pub(crate) fn terminate_block(&mut self, reason: UnwindTerminateReason) -> BasicBlock {
	if let Some((cached_bb, cached_reason)) = self.terminate_block
	&& reason == cached_reason
	{
	return cached_bb;
	}

	let bb = self.new_block(BasicBlockData {
	statements: vec![],
	terminator: Some(Terminator {
	source_info: SourceInfo::outermost(self.body_span),
	kind: TerminatorKind::UnwindTerminate(reason),
	}),
	is_cleanup: true,
	});
	self.terminate_block = Some((bb, reason));
	bb
	}

	/// Has a replacement of this block's terminator been queued in this patch?
	pub(crate) fn is_term_patched(&self, bb: BasicBlock) -> bool {
	self.term_patch_map[bb].is_some()
	}

	/// Universal getter for block data, either it is in 'old' blocks or in patched ones
	pub(crate) fn block<'a>(
	&'a self,
	body: &'a Body<'tcx>,
	bb: BasicBlock,
	) -> &'a BasicBlockData<'tcx> {
	match bb.index().checked_sub(body.basic_blocks.len()) {
	Some(new) => &self.new_blocks[new],
	None => &body[bb],
	}
	}

	pub(crate) fn terminator_loc(&self, body: &Body<'tcx>, bb: BasicBlock) -> Location {
	let offset = self.block(body, bb).statements.len();
	Location { block: bb, statement_index: offset }
	}

	/// Queues the addition of a new temporary with additional local info.
	pub(crate) fn new_local_with_info(
	&mut self,
	ty: Ty<'tcx>,
	span: Span,
	local_info: LocalInfo<'tcx>,
	) -> Local {
	let index = self.next_local;
	self.next_local += 1;
	let mut new_decl = LocalDecl::new(ty, span);
	**new_decl.local_info.as_mut().unwrap_crate_local() = local_info;
	self.new_locals.push(new_decl);
	Local::new(index)
	}

	/// Queues the addition of a new temporary.
	pub(crate) fn new_temp(&mut self, ty: Ty<'tcx>, span: Span) -> Local {
	let index = self.next_local;
	self.next_local += 1;
	self.new_locals.push(LocalDecl::new(ty, span));
	Local::new(index)
	}

	/// Returns the type of a local that's newly-added in the patch.
	pub(crate) fn local_ty(&self, local: Local) -> Ty<'tcx> {
	let local = local.as_usize();
	assert!(local < self.next_local);
	let new_local_idx = self.new_locals.len() - (self.next_local - local);
	self.new_locals[new_local_idx].ty
	}

	/// Queues the addition of a new basic block.
	pub(crate) fn new_block(&mut self, data: BasicBlockData<'tcx>) -> BasicBlock {
	let block = self.term_patch_map.next_index();
	debug!("MirPatch: new_block: {:?}: {:?}", block, data);
	self.new_blocks.push(data);
	self.term_patch_map.push(None);
	block
	}

	/// Queues the replacement of a block's terminator.
	pub(crate) fn patch_terminator(&mut self, block: BasicBlock, new: TerminatorKind<'tcx>) {
	assert!(self.term_patch_map[block].is_none());
	debug!("MirPatch: patch_terminator({:?}, {:?})", block, new);
	self.term_patch_map[block] = Some(new);
	}

	/// Queues the insertion of a statement at a given location. The statement
	/// currently at that location, and all statements that follow, are shifted
	/// down. If multiple statements are queued for addition at the same
	/// location, the final statement order after calling `apply` will match
	/// the queue insertion order.
	///
	/// E.g. if we have `s0` at location `loc` and do these calls:
	///
	/// p.add_statement(loc, s1);
	/// p.add_statement(loc, s2);
	/// p.apply(body);
	///
	/// then the final order will be `s1, s2, s0`, with `s1` at `loc`.
	pub(crate) fn add_statement(&mut self, loc: Location, stmt: StatementKind<'tcx>) {
	debug!("MirPatch: add_statement({:?}, {:?})", loc, stmt);
	self.new_statements.push((loc, stmt));
	}

	/// Like `add_statement`, but specialized for assignments.
	pub(crate) fn add_assign(&mut self, loc: Location, place: Place<'tcx>, rv: Rvalue<'tcx>) {
	self.add_statement(loc, StatementKind::Assign(Box::new((place, rv))));
	}

	/// Applies the queued changes.
	pub(crate) fn apply(self, body: &mut Body<'tcx>) {
	debug!(
	"MirPatch: {:?} new temps, starting from index {}: {:?}",
	self.new_locals.len(),
	body.local_decls.len(),
	self.new_locals
	);
	debug!(
	"MirPatch: {} new blocks, starting from index {}",
	self.new_blocks.len(),
	body.basic_blocks.len()
	);
	let bbs = if self.term_patch_map.is_empty() && self.new_blocks.is_empty() {
	body.basic_blocks.as_mut_preserves_cfg()
	} else {
	body.basic_blocks.as_mut()
	};
	bbs.extend(self.new_blocks);
	body.local_decls.extend(self.new_locals);
	for (src, patch) in self.term_patch_map.into_iter_enumerated() {
	if let Some(patch) = patch {
	debug!("MirPatch: patching block {:?}", src);
	bbs[src].terminator_mut().kind = patch;
	}
	}

	let mut new_statements = self.new_statements;

	// This must be a stable sort to provide the ordering described in the
	// comment for `add_statement`.
	new_statements.sort_by_key(\|s\| s.0);

	let mut delta = 0;
	let mut last_bb = START_BLOCK;
	for (mut loc, stmt) in new_statements {
	if loc.block != last_bb {
	delta = 0;
	last_bb = loc.block;
	}
	debug!("MirPatch: adding statement {:?} at loc {:?}+{}", stmt, loc, delta);
	loc.statement_index += delta;
	let source_info = Self::source_info_for_index(&body[loc.block], loc);
	body[loc.block]
	.statements
	.insert(loc.statement_index, Statement { source_info, kind: stmt });
	delta += 1;
	}
	}

	fn source_info_for_index(data: &BasicBlockData<'_>, loc: Location) -> SourceInfo {
	match data.statements.get(loc.statement_index) {
	Some(stmt) => stmt.source_info,
	None => data.terminator().source_info,
	}
	}

	pub(crate) fn source_info_for_location(&self, body: &Body<'tcx>, loc: Location) -> SourceInfo {
	let data = self.block(body, loc.block);
	Self::source_info_for_index(data, loc)
	}
	}