vendor/cranelift-codegen/src/isa/x64/inst/unwind/systemv.rs - toolchain/rustc - Git at Google

 //! Unwind information for System V ABI (x86-64).

 use crate::isa::unwind::systemv::RegisterMappingError;
 use crate::machinst::{Reg, RegClass};
 use gimli::{write::CommonInformationEntry, Encoding, Format, Register, X86_64};

 /// Creates a new x86-64 common information entry (CIE).
 pub fn create_cie() -> CommonInformationEntry {
     use gimli::write::CallFrameInstruction;

     let mut entry = CommonInformationEntry::new(
         Encoding {
             address_size: 8,
             format: Format::Dwarf32,
             version: 1,
         },
         1,  // Code alignment factor
         -8, // Data alignment factor
         X86_64::RA,
     );

     // Every frame will start with the call frame address (CFA) at RSP+8
     // It is +8 to account for the push of the return address by the call instruction
     entry.add_instruction(CallFrameInstruction::Cfa(X86_64::RSP, 8));

     // Every frame will start with the return address at RSP (CFA-8 = RSP+8-8 = RSP)
     entry.add_instruction(CallFrameInstruction::Offset(X86_64::RA, -8));

     entry
 }

 /// Map Cranelift registers to their corresponding Gimli registers.
 pub fn map_reg(reg: Reg) -> Result<Register, RegisterMappingError> {
     // Mapping from https://github.com/bytecodealliance/cranelift/pull/902 by @iximeow
     const X86_GP_REG_MAP: [gimli::Register; 16] = [
         X86_64::RAX,
         X86_64::RCX,
         X86_64::RDX,
         X86_64::RBX,
         X86_64::RSP,
         X86_64::RBP,
         X86_64::RSI,
         X86_64::RDI,
         X86_64::R8,
         X86_64::R9,
         X86_64::R10,
         X86_64::R11,
         X86_64::R12,
         X86_64::R13,
         X86_64::R14,
         X86_64::R15,
     ];
     const X86_XMM_REG_MAP: [gimli::Register; 16] = [
         X86_64::XMM0,
         X86_64::XMM1,
         X86_64::XMM2,
         X86_64::XMM3,
         X86_64::XMM4,
         X86_64::XMM5,
         X86_64::XMM6,
         X86_64::XMM7,
         X86_64::XMM8,
         X86_64::XMM9,
         X86_64::XMM10,
         X86_64::XMM11,
         X86_64::XMM12,
         X86_64::XMM13,
         X86_64::XMM14,
         X86_64::XMM15,
     ];

     match reg.class() {
         RegClass::Int => {
             // x86 GP registers have a weird mapping to DWARF registers, so we use a
             // lookup table.
             Ok(X86_GP_REG_MAP[reg.to_real_reg().unwrap().hw_enc() as usize])
         }
         RegClass::Float => Ok(X86_XMM_REG_MAP[reg.to_real_reg().unwrap().hw_enc() as usize]),
     }
 }

 pub(crate) struct RegisterMapper;

 impl crate::isa::unwind::systemv::RegisterMapper<Reg> for RegisterMapper {
     fn map(&self, reg: Reg) -> Result<u16, RegisterMappingError> {
         Ok(map_reg(reg)?.0)
     }
     fn sp(&self) -> u16 {
         X86_64::RSP.0
     }
     fn fp(&self) -> Option<u16> {
         Some(X86_64::RBP.0)
     }
 }

 #[cfg(test)]
 mod tests {
     use crate::cursor::{Cursor, FuncCursor};
     use crate::ir::{
         types, AbiParam, ExternalName, Function, InstBuilder, Signature, StackSlotData,
         StackSlotKind,
     };
     use crate::isa::{lookup, CallConv};
     use crate::settings::{builder, Flags};
     use crate::Context;
     use gimli::write::Address;
     use std::str::FromStr;
     use target_lexicon::triple;

     #[test]
     fn test_simple_func() {
         let isa = lookup(triple!("x86_64"))
             .expect("expect x86 ISA")
             .finish(Flags::new(builder()))
             .expect("expect backend creation to succeed");

         let mut context = Context::for_function(create_function(
             CallConv::SystemV,
             Some(StackSlotData::new(StackSlotKind::ExplicitSlot, 64)),
         ));

         context.compile(&*isa).expect("expected compilation");

         let fde = match context
             .create_unwind_info(isa.as_ref())
             .expect("can create unwind info")
         {
             Some(crate::isa::unwind::UnwindInfo::SystemV(info)) => {
                 info.to_fde(Address::Constant(1234))
             }
             _ => panic!("expected unwind information"),
         };

         assert_eq!(format!("{:?}", fde), "FrameDescriptionEntry { address: Constant(1234), length: 17, lsda: None, instructions: [(1, CfaOffset(16)), (1, Offset(Register(6), -16)), (4, CfaRegister(Register(6)))] }");
     }

     fn create_function(call_conv: CallConv, stack_slot: Option<StackSlotData>) -> Function {
         let mut func =
             Function::with_name_signature(ExternalName::user(0, 0), Signature::new(call_conv));

         let block0 = func.dfg.make_block();
         let mut pos = FuncCursor::new(&mut func);
         pos.insert_block(block0);
         pos.ins().return_(&[]);

         if let Some(stack_slot) = stack_slot {
             func.stack_slots.push(stack_slot);
         }

         func
     }

     #[test]
     fn test_multi_return_func() {
         let isa = lookup(triple!("x86_64"))
             .expect("expect x86 ISA")
             .finish(Flags::new(builder()))
             .expect("expect backend creation to succeed");

         let mut context = Context::for_function(create_multi_return_function(CallConv::SystemV));

         context.compile(&*isa).expect("expected compilation");

         let fde = match context
             .create_unwind_info(isa.as_ref())
             .expect("can create unwind info")
         {
             Some(crate::isa::unwind::UnwindInfo::SystemV(info)) => {
                 info.to_fde(Address::Constant(4321))
             }
             _ => panic!("expected unwind information"),
         };

         assert_eq!(format!("{:?}", fde), "FrameDescriptionEntry { address: Constant(4321), length: 22, lsda: None, instructions: [(1, CfaOffset(16)), (1, Offset(Register(6), -16)), (4, CfaRegister(Register(6)))] }");
     }

     fn create_multi_return_function(call_conv: CallConv) -> Function {
         let mut sig = Signature::new(call_conv);
         sig.params.push(AbiParam::new(types::I32));
         let mut func = Function::with_name_signature(ExternalName::user(0, 0), sig);

         let block0 = func.dfg.make_block();
         let v0 = func.dfg.append_block_param(block0, types::I32);
         let block1 = func.dfg.make_block();
         let block2 = func.dfg.make_block();

         let mut pos = FuncCursor::new(&mut func);
         pos.insert_block(block0);
         pos.ins().brnz(v0, block2, &[]);
         pos.ins().jump(block1, &[]);

         pos.insert_block(block1);
         pos.ins().return_(&[]);

         pos.insert_block(block2);
         pos.ins().return_(&[]);

         func
     }
 }
	//! Unwind information for System V ABI (x86-64).

	use crate::isa::unwind::systemv::RegisterMappingError;
	use crate::machinst::{Reg, RegClass};
	use gimli::{write::CommonInformationEntry, Encoding, Format, Register, X86_64};

	/// Creates a new x86-64 common information entry (CIE).
	pub fn create_cie() -> CommonInformationEntry {
	use gimli::write::CallFrameInstruction;

	let mut entry = CommonInformationEntry::new(
	Encoding {
	address_size: 8,
	format: Format::Dwarf32,
	version: 1,
	},
	1, // Code alignment factor
	-8, // Data alignment factor
	X86_64::RA,
	);

	// Every frame will start with the call frame address (CFA) at RSP+8
	// It is +8 to account for the push of the return address by the call instruction
	entry.add_instruction(CallFrameInstruction::Cfa(X86_64::RSP, 8));

	// Every frame will start with the return address at RSP (CFA-8 = RSP+8-8 = RSP)
	entry.add_instruction(CallFrameInstruction::Offset(X86_64::RA, -8));

	entry
	}

	/// Map Cranelift registers to their corresponding Gimli registers.
	pub fn map_reg(reg: Reg) -> Result<Register, RegisterMappingError> {
	// Mapping from https://github.com/bytecodealliance/cranelift/pull/902 by @iximeow
	const X86_GP_REG_MAP: [gimli::Register; 16] = [
	X86_64::RAX,
	X86_64::RCX,
	X86_64::RDX,
	X86_64::RBX,
	X86_64::RSP,
	X86_64::RBP,
	X86_64::RSI,
	X86_64::RDI,
	X86_64::R8,
	X86_64::R9,
	X86_64::R10,
	X86_64::R11,
	X86_64::R12,
	X86_64::R13,
	X86_64::R14,
	X86_64::R15,
	];
	const X86_XMM_REG_MAP: [gimli::Register; 16] = [
	X86_64::XMM0,
	X86_64::XMM1,
	X86_64::XMM2,
	X86_64::XMM3,
	X86_64::XMM4,
	X86_64::XMM5,
	X86_64::XMM6,
	X86_64::XMM7,
	X86_64::XMM8,
	X86_64::XMM9,
	X86_64::XMM10,
	X86_64::XMM11,
	X86_64::XMM12,
	X86_64::XMM13,
	X86_64::XMM14,
	X86_64::XMM15,
	];

	match reg.class() {
	RegClass::Int => {
	// x86 GP registers have a weird mapping to DWARF registers, so we use a
	// lookup table.
	Ok(X86_GP_REG_MAP[reg.to_real_reg().unwrap().hw_enc() as usize])
	}
	RegClass::Float => Ok(X86_XMM_REG_MAP[reg.to_real_reg().unwrap().hw_enc() as usize]),
	}
	}

	pub(crate) struct RegisterMapper;

	impl crate::isa::unwind::systemv::RegisterMapper<Reg> for RegisterMapper {
	fn map(&self, reg: Reg) -> Result<u16, RegisterMappingError> {
	Ok(map_reg(reg)?.0)
	}
	fn sp(&self) -> u16 {
	X86_64::RSP.0
	}
	fn fp(&self) -> Option<u16> {
	Some(X86_64::RBP.0)
	}
	}

	#[cfg(test)]
	mod tests {
	use crate::cursor::{Cursor, FuncCursor};
	use crate::ir::{
	types, AbiParam, ExternalName, Function, InstBuilder, Signature, StackSlotData,
	StackSlotKind,
	};
	use crate::isa::{lookup, CallConv};
	use crate::settings::{builder, Flags};
	use crate::Context;
	use gimli::write::Address;
	use std::str::FromStr;
	use target_lexicon::triple;

	#[test]
	fn test_simple_func() {
	let isa = lookup(triple!("x86_64"))
	.expect("expect x86 ISA")
	.finish(Flags::new(builder()))
	.expect("expect backend creation to succeed");

	let mut context = Context::for_function(create_function(
	CallConv::SystemV,
	Some(StackSlotData::new(StackSlotKind::ExplicitSlot, 64)),
	));

	context.compile(&*isa).expect("expected compilation");

	let fde = match context
	.create_unwind_info(isa.as_ref())
	.expect("can create unwind info")
	{
	Some(crate::isa::unwind::UnwindInfo::SystemV(info)) => {
	info.to_fde(Address::Constant(1234))
	}
	_ => panic!("expected unwind information"),
	};

	assert_eq!(format!("{:?}", fde), "FrameDescriptionEntry { address: Constant(1234), length: 17, lsda: None, instructions: [(1, CfaOffset(16)), (1, Offset(Register(6), -16)), (4, CfaRegister(Register(6)))] }");
	}

	fn create_function(call_conv: CallConv, stack_slot: Option<StackSlotData>) -> Function {
	let mut func =
	Function::with_name_signature(ExternalName::user(0, 0), Signature::new(call_conv));

	let block0 = func.dfg.make_block();
	let mut pos = FuncCursor::new(&mut func);
	pos.insert_block(block0);
	pos.ins().return_(&[]);

	if let Some(stack_slot) = stack_slot {
	func.stack_slots.push(stack_slot);
	}

	func
	}

	#[test]
	fn test_multi_return_func() {
	let isa = lookup(triple!("x86_64"))
	.expect("expect x86 ISA")
	.finish(Flags::new(builder()))
	.expect("expect backend creation to succeed");

	let mut context = Context::for_function(create_multi_return_function(CallConv::SystemV));

	context.compile(&*isa).expect("expected compilation");

	let fde = match context
	.create_unwind_info(isa.as_ref())
	.expect("can create unwind info")
	{
	Some(crate::isa::unwind::UnwindInfo::SystemV(info)) => {
	info.to_fde(Address::Constant(4321))
	}
	_ => panic!("expected unwind information"),
	};

	assert_eq!(format!("{:?}", fde), "FrameDescriptionEntry { address: Constant(4321), length: 22, lsda: None, instructions: [(1, CfaOffset(16)), (1, Offset(Register(6), -16)), (4, CfaRegister(Register(6)))] }");
	}

	fn create_multi_return_function(call_conv: CallConv) -> Function {
	let mut sig = Signature::new(call_conv);
	sig.params.push(AbiParam::new(types::I32));
	let mut func = Function::with_name_signature(ExternalName::user(0, 0), sig);

	let block0 = func.dfg.make_block();
	let v0 = func.dfg.append_block_param(block0, types::I32);
	let block1 = func.dfg.make_block();
	let block2 = func.dfg.make_block();

	let mut pos = FuncCursor::new(&mut func);
	pos.insert_block(block0);
	pos.ins().brnz(v0, block2, &[]);
	pos.ins().jump(block1, &[]);

	pos.insert_block(block1);
	pos.ins().return_(&[]);

	pos.insert_block(block2);
	pos.ins().return_(&[]);

	func
	}
	}