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cranelift: CLIF Fuzzer generate brz/brnz/bricmp instructions

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This commit is contained in:
Afonso Bordado
2021-07-06 10:09:19 +01:00
parent f4bd7d17a3
commit f0f2efba26
2 changed files with 199 additions and 88 deletions
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259
cranelift/fuzzgen/src/function_generator.rs
View File

@@ -1,13 +1,13 @@
use crate::config::Config; use crate::config::Config;
use anyhow::Result; use anyhow::Result;
use arbitrary::Unstructured; use arbitrary::{Arbitrary, Unstructured};
use cranelift::codegen::ir::types::*; use cranelift::codegen::ir::types::*;
use cranelift::codegen::ir::{ use cranelift::codegen::ir::{
AbiParam, Block, ExternalName, Function, Opcode, Signature, Type, Value, AbiParam, Block, ExternalName, Function, Opcode, Signature, Type, Value,
}; };
use cranelift::codegen::isa::CallConv; use cranelift::codegen::isa::CallConv;
use cranelift::frontend::{FunctionBuilder, FunctionBuilderContext, Variable}; use cranelift::frontend::{FunctionBuilder, FunctionBuilderContext, Variable};
use cranelift::prelude::{EntityRef, InstBuilder}; use cranelift::prelude::{EntityRef, InstBuilder, IntCC};
type BlockSignature = Vec<Type>; type BlockSignature = Vec<Type>;
@@ -117,11 +117,30 @@ where
Ok(CallConv::SystemV) Ok(CallConv::SystemV)
} }
fn generate_intcc(&mut self) -> Result<IntCC> {
Ok(*self.u.choose(
&[
IntCC::Equal,
IntCC::NotEqual,
IntCC::SignedLessThan,
IntCC::SignedGreaterThanOrEqual,
IntCC::SignedGreaterThan,
IntCC::SignedLessThanOrEqual,
IntCC::UnsignedLessThan,
IntCC::UnsignedGreaterThanOrEqual,
IntCC::UnsignedGreaterThan,
IntCC::UnsignedLessThanOrEqual,
IntCC::Overflow,
IntCC::NotOverflow,
][..],
)?)
}
fn generate_type(&mut self) -> Result<Type> { fn generate_type(&mut self) -> Result<Type> {
// TODO: It would be nice if we could get these directly from cranelift // TODO: It would be nice if we could get these directly from cranelift
let scalars = [ let scalars = [
// IFLAGS, FFLAGS, // IFLAGS, FFLAGS,
// B1, B8, B16, B32, B64, B128, B1, // B8, B16, B32, B64, B128,
I8, I16, I32, I64, I8, I16, I32, I64,
// I128, // I128,
// F32, F64, // F32, F64,
@@ -180,60 +199,140 @@ where
/// Generates an instruction(`iconst`/`fconst`/etc...) to introduce a constant value /// Generates an instruction(`iconst`/`fconst`/etc...) to introduce a constant value
fn generate_const(&mut self, builder: &mut FunctionBuilder, ty: Type) -> Result<Value> { fn generate_const(&mut self, builder: &mut FunctionBuilder, ty: Type) -> Result<Value> {
let imm64 = match ty { Ok(match ty {
I8 => self.u.arbitrary::<i8>()? as i64, ty if ty.is_int() => {
I16 => self.u.arbitrary::<i16>()? as i64, let imm64 = match ty {
I32 => self.u.arbitrary::<i32>()? as i64, I8 => self.u.arbitrary::<i8>()? as i64,
I64 => self.u.arbitrary::<i64>()?, I16 => self.u.arbitrary::<i16>()? as i64,
_ => unreachable!(), I32 => self.u.arbitrary::<i32>()? as i64,
}; I64 => self.u.arbitrary::<i64>()?,
let val = builder.ins().iconst(ty, imm64); _ => unreachable!(),
};
builder.ins().iconst(ty, imm64)
}
ty if ty.is_bool() => builder.ins().bconst(B1, bool::arbitrary(self.u)?),
_ => unimplemented!(),
})
}
Ok(val) /// Chooses a random block which can be targeted by a jump / branch.
/// This means any block that is not the first block.
///
/// For convenience we also generate values that match the block's signature
fn generate_target_block(
&mut self,
builder: &mut FunctionBuilder,
) -> Result<(Block, Vec<Value>)> {
let block_targets = &self.blocks[1..];
let (block, signature) = self.u.choose(block_targets)?.clone();
let args = self.generate_values_for_signature(builder, signature.into_iter())?;
Ok((block, args))
}
fn generate_values_for_signature<I: Iterator<Item = Type>>(
&mut self,
builder: &mut FunctionBuilder,
signature: I,
) -> Result<Vec<Value>> {
signature
.map(|ty| {
let var = self.get_variable_of_type(ty)?;
let val = builder.use_var(var);
Ok(val)
})
.collect()
} }
fn generate_return(&mut self, builder: &mut FunctionBuilder) -> Result<()> { fn generate_return(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
let ret_params = builder.func.signature.returns.clone(); let types: Vec<Type> = {
let rets = &builder.func.signature.returns;
let vars = ret_params rets.iter().map(|p| p.value_type).collect()
.iter() };
.map(|p| self.get_variable_of_type(p.value_type)) let vals = self.generate_values_for_signature(builder, types.into_iter())?;
.collect::<Result<Vec<_>>>()?;
let vals = vars
.into_iter()
.map(|v| builder.use_var(v))
.collect::<Vec<_>>();
builder.ins().return_(&vals[..]); builder.ins().return_(&vals[..]);
Ok(()) Ok(())
} }
fn generate_jump(&mut self, builder: &mut FunctionBuilder) -> Result<()> { fn generate_jump(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
let (block, signature) = { let (block, args) = self.generate_target_block(builder)?;
let target = self.u.choose(&self.blocks[..])?; builder.ins().jump(block, &args[..]);
let target = target.clone();
target
};
let vars = signature
.iter()
.map(|ty| self.get_variable_of_type(*ty))
.collect::<Result<Vec<_>>>()?;
let vals = vars
.into_iter()
.map(|v| builder.use_var(v))
.collect::<Vec<_>>();
builder.ins().jump(*block, &vals[..]);
Ok(()) Ok(())
} }
/// Inserts a random instruction into the block /// Generates a brz/brnz into a random block
fn generate_instruction(&mut self, builder: &mut FunctionBuilder) -> Result<()> { fn generate_br(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
let (op, args, rets, inserter) = *self.u.choose(OPCODE_SIGNATURES)?; let (block, args) = self.generate_target_block(builder)?;
inserter(self, builder, op, args, rets)
let condbr_types = [
I8, I16, I32, I64, // TODO: I128
B1,
];
let _type = *self.u.choose(&condbr_types[..])?;
let var = self.get_variable_of_type(_type)?;
let val = builder.use_var(var);
if bool::arbitrary(self.u)? {
builder.ins().brz(val, block, &args[..]);
} else {
builder.ins().brnz(val, block, &args[..]);
}
// After brz/brnz we must generate a jump
self.generate_jump(builder)?;
Ok(())
}
fn generate_bricmp(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
let (block, args) = self.generate_target_block(builder)?;
let cond = self.generate_intcc()?;
let bricmp_types = [
I8, I16, I32, I64, // TODO: I128
];
let _type = *self.u.choose(&bricmp_types[..])?;
let lhs_var = self.get_variable_of_type(_type)?;
let lhs_val = builder.use_var(lhs_var);
let rhs_var = self.get_variable_of_type(_type)?;
let rhs_val = builder.use_var(rhs_var);
builder
.ins()
.br_icmp(cond, lhs_val, rhs_val, block, &args[..]);
// After bricmp's we must generate a jump
self.generate_jump(builder)?;
Ok(())
}
/// We always need to exit safely out of a block.
/// This either means a jump into another block or a return.
fn finalize_block(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
let gen = self.u.choose(
&[
Self::generate_bricmp,
Self::generate_br,
Self::generate_jump,
Self::generate_return,
][..],
)?;
gen(self, builder)
}
/// Fills the current block with random instructions
fn generate_instructions(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
for _ in 0..self
.u
.int_in_range(self.config.instructions_per_block.clone())?
{
let (op, args, rets, inserter) = *self.u.choose(OPCODE_SIGNATURES)?;
inserter(self, builder, op, args, rets)?;
}
Ok(())
} }
/// Creates a random amount of blocks in this function /// Creates a random amount of blocks in this function
@@ -260,7 +359,11 @@ where
builder.append_block_params_for_function_params(block); builder.append_block_params_for_function_params(block);
Ok((block, sig.params.iter().map(|a| a.value_type).collect())) Ok((block, sig.params.iter().map(|a| a.value_type).collect()))
} else { } else {
Ok((block, self.generate_block_signature()?)) let sig = self.generate_block_signature()?;
sig.iter().for_each(|ty| {
builder.append_block_param(block, *ty);
});
Ok((block, sig))
} }
}) })
.collect::<Result<Vec<_>>>()?; .collect::<Result<Vec<_>>>()?;
@@ -280,7 +383,29 @@ where
Ok(params) Ok(params)
} }
/// We generate a function in multiple stages: by first creating a random number of empty fn build_variable_pool(&mut self, builder: &mut FunctionBuilder) -> Result<()> {
let block = builder.current_block().unwrap();
let func_params = builder.func.signature.params.clone();
// Define variables for the function signature
for (i, param) in func_params.iter().enumerate() {
let var = self.create_var(builder, param.value_type)?;
let block_param = builder.block_params(block)[i];
builder.def_var(var, block_param);
}
// Create a pool of vars that are going to be used in this function
for _ in 0..self.u.int_in_range(self.config.vars_per_function.clone())? {
let ty = self.generate_type()?;
let var = self.create_var(builder, ty)?;
let value = self.generate_const(builder, ty)?;
builder.def_var(var, value);
}
Ok(())
}
/// We generate a function in multiple stages:
/// ///
/// * First we generate a random number of empty blocks /// * First we generate a random number of empty blocks
/// * Then we generate a random pool of variables to be used throughout the function /// * Then we generate a random pool of variables to be used throughout the function
@@ -299,27 +424,18 @@ where
self.blocks = self.generate_blocks(&mut builder, &sig)?; self.blocks = self.generate_blocks(&mut builder, &sig)?;
// Main instruction generation loop // Main instruction generation loop
for (i, (block, signature)) in self.blocks.clone().iter().enumerate() { for (i, (block, block_sig)) in self.blocks.clone().iter().enumerate() {
let is_block0 = i == 0;
builder.switch_to_block(*block); builder.switch_to_block(*block);
if i == 0 { if is_block0 {
// Define variables for the function signature // The first block is special because we must create variables both for the
for (i, param) in sig.params.iter().enumerate() { // block signature and for the variable pool. Additionally, we must also define
let var = self.create_var(&mut builder, param.value_type)?; // initial values for all variables that are not the function signature.
let block_param = builder.block_params(*block)[i]; self.build_variable_pool(&mut builder)?;
builder.def_var(var, block_param);
}
// Create a pool of vars that are going to be used in this function
for _ in 0..self.u.int_in_range(self.config.vars_per_function.clone())? {
let ty = self.generate_type()?;
let var = self.create_var(&mut builder, ty)?;
let value = self.generate_const(&mut builder, ty)?;
builder.def_var(var, value);
}
} else { } else {
// Define variables for the block params // Define variables for the block params
for (i, ty) in signature.iter().enumerate() { for (i, ty) in block_sig.iter().enumerate() {
let var = self.get_variable_of_type(*ty)?; let var = self.get_variable_of_type(*ty)?;
let block_param = builder.block_params(*block)[i]; let block_param = builder.block_params(*block)[i];
builder.def_var(var, block_param); builder.def_var(var, block_param);
@@ -327,22 +443,9 @@ where
} }
// Generate block instructions // Generate block instructions
for _ in 0..self self.generate_instructions(&mut builder)?;
.u
.int_in_range(self.config.instructions_per_block.clone())?
{
self.generate_instruction(&mut builder)?;
}
// We always need to exit safely out of a block. self.finalize_block(&mut builder)?;
// For block 0 this means a return, but for other block it is a jump into any other
// random block.
if i == 0 {
// TODO: We should make this, part of the regular instruction selection
self.generate_return(&mut builder)?;
} else {
self.generate_jump(&mut builder)?;
}
} }
builder.seal_all_blocks(); builder.seal_all_blocks();

28
cranelift/fuzzgen/src/lib.rs
View File

@@ -47,6 +47,23 @@ where
} }
} }
fn generate_datavalue(&mut self, ty: Type) -> Result<DataValue> {
Ok(match ty {
ty if ty.is_int() => {
let imm = match ty {
I8 => self.u.arbitrary::<i8>()? as i128,
I16 => self.u.arbitrary::<i16>()? as i128,
I32 => self.u.arbitrary::<i32>()? as i128,
I64 => self.u.arbitrary::<i64>()? as i128,
_ => unreachable!(),
};
DataValue::from_integer(imm, ty)?
}
ty if ty.is_bool() => DataValue::B(bool::arbitrary(self.u)?),
_ => unimplemented!(),
})
}
fn generate_test_inputs(&mut self, signature: &Signature) -> Result<Vec<TestCaseInput>> { fn generate_test_inputs(&mut self, signature: &Signature) -> Result<Vec<TestCaseInput>> {
let num_tests = self.u.int_in_range(self.config.test_case_inputs.clone())?; let num_tests = self.u.int_in_range(self.config.test_case_inputs.clone())?;
let mut inputs = Vec::with_capacity(num_tests); let mut inputs = Vec::with_capacity(num_tests);
@@ -55,16 +72,7 @@ where
let test_args = signature let test_args = signature
.params .params
.iter() .iter()
.map(|p| { .map(|p| self.generate_datavalue(p.value_type))
let imm = match p.value_type {
I8 => self.u.arbitrary::<i8>()? as i128,
I16 => self.u.arbitrary::<i16>()? as i128,
I32 => self.u.arbitrary::<i32>()? as i128,
I64 => self.u.arbitrary::<i64>()? as i128,
_ => unreachable!(),
};
Ok(DataValue::from_integer(imm, p.value_type)?)
})
.collect::<Result<TestCaseInput>>()?; .collect::<Result<TestCaseInput>>()?;
inputs.push(test_args); inputs.push(test_args);