#[cfg(not(feature = "std"))]
pub use alloc::borrow::ToOwned;
#[cfg(not(feature = "std"))]
use alloc::{string::String, vec, vec::Vec};
#[cfg(feature = "std")]
pub use std::borrow::ToOwned;
use cairo_lang_utils::casts::IntoOrPanic;
use cairo_lang_utils::extract_matches;
use cairo_lang_utils::ordered_hash_map::OrderedHashMap;
use cairo_lang_utils::unordered_hash_map::{Entry, UnorderedHashMap};
use cairo_lang_utils::unordered_hash_set::UnorderedHashSet;
use num_bigint::BigInt;
use num_traits::{One, Zero};
use crate::ap_change::ApplyApChange;
use crate::cell_expression::{CellExpression, CellOperator};
use crate::deref_or_immediate;
use crate::hints::Hint;
use crate::instructions::{
AddApInstruction, AssertEqInstruction, CallInstruction, Instruction, InstructionBody,
JnzInstruction, JumpInstruction, RetInstruction,
};
use crate::operand::{BinOpOperand, CellRef, DerefOrImmediate, Operation, Register, ResOperand};
#[cfg(test)]
#[path = "builder_test.rs"]
mod test;
#[derive(Copy, Clone, Debug, Eq, PartialEq, Hash)]
pub struct Var(usize);
#[derive(Clone, Debug, Default, Eq, PartialEq)]
pub struct State {
vars: OrderedHashMap<Var, CellExpression>,
allocated: i16,
pub ap_change: usize,
pub steps: usize,
}
impl State {
fn get_value(&self, var: Var) -> CellExpression {
self.vars[&var].clone()
}
pub fn get_adjusted(&self, var: Var) -> CellExpression {
self.get_value(var).unchecked_apply_known_ap_change(self.ap_change)
}
pub fn get_adjusted_as_cell_ref(&self, var: Var) -> CellRef {
extract_matches!(self.get_adjusted(var), CellExpression::Deref)
}
fn validate_finality(&self) {
assert!(
self.ap_change >= self.allocated.into_or_panic(),
"Not enough instructions to update ap. Add an `ap += *` instruction. ap_change: {}, \
allocated: {}",
self.ap_change,
self.allocated,
);
}
fn intersect(&mut self, other: &Self, read_only: bool) {
assert_eq!(self.ap_change, other.ap_change, "Merged branches not aligned on AP change.");
assert_eq!(
self.allocated, other.allocated,
"Merged branches not aligned on number of allocations."
);
if read_only {
assert!(self.steps >= other.steps, "Finalized branch cannot be updated.");
} else {
self.steps = self.steps.max(other.steps);
}
self.vars.retain(|var, value| {
other
.vars
.get(var)
.map(|x| assert_eq!(x, value, "Var mismatch between branches."))
.is_some()
});
}
}
enum Statement {
Final(Instruction),
Jump(String, Instruction),
Label(String, usize),
}
pub struct CasmBuildResult<const BRANCH_COUNT: usize> {
pub instructions: Vec<Instruction>,
pub branches: [(State, Vec<usize>); BRANCH_COUNT],
}
pub struct CasmBuilder {
label_state: UnorderedHashMap<String, State>,
read_labels: UnorderedHashSet<String>,
main_state: State,
statements: Vec<Statement>,
current_hints: Vec<Hint>,
var_count: usize,
reachable: bool,
}
impl CasmBuilder {
pub fn build<const BRANCH_COUNT: usize>(
mut self,
branch_names: [&str; BRANCH_COUNT],
) -> CasmBuildResult<BRANCH_COUNT> {
assert!(
self.current_hints.is_empty(),
"Build cannot be called with hints as the last addition."
);
let label_offsets = self.compute_label_offsets();
if self.reachable {
self.label_state.insert("Fallthrough".to_owned(), self.main_state);
}
let mut instructions = vec![];
let mut branch_relocations = UnorderedHashMap::<String, Vec<usize>>::default();
let mut offset = 0;
for statement in self.statements {
match statement {
Statement::Final(inst) => {
offset += inst.body.op_size();
instructions.push(inst);
}
Statement::Jump(label, mut inst) => {
match label_offsets.get(&label) {
Some(label_offset) => match &mut inst.body {
InstructionBody::Jnz(JnzInstruction {
jump_offset: DerefOrImmediate::Immediate(value),
..
})
| InstructionBody::Jump(JumpInstruction {
target: DerefOrImmediate::Immediate(value),
..
})
| InstructionBody::Call(CallInstruction {
target: DerefOrImmediate::Immediate(value),
..
}) => {
value.value += *label_offset as i128 - offset as i128;
}
_ => unreachable!("Only jump or call statements should be here."),
},
None => {
branch_relocations.entry(label).or_default().push(instructions.len())
}
}
offset += inst.body.op_size();
instructions.push(inst);
}
Statement::Label(name, _) => {
self.label_state.remove(&name);
}
}
}
let branches = branch_names.map(|label| {
let state = self
.label_state
.remove(label)
.unwrap_or_else(|| panic!("Requested a non existing final label: {label:?}."));
state.validate_finality();
(state, branch_relocations.remove(label).unwrap_or_default())
});
assert!(self.label_state.is_empty(), "Did not use all branches.");
assert!(branch_relocations.is_empty(), "Did not use all branch relocations.");
CasmBuildResult { instructions, branches }
}
pub fn curr_ap_change(&self) -> usize {
self.main_state.ap_change
}
fn compute_label_offsets(&self) -> UnorderedHashMap<String, usize> {
let mut label_offsets = UnorderedHashMap::default();
let mut offset = 0;
for statement in &self.statements {
match statement {
Statement::Final(inst) | Statement::Jump(_, inst) => {
offset += inst.body.op_size();
}
Statement::Label(name, extra_offset) => {
label_offsets.insert(name.clone(), offset + extra_offset);
}
}
}
label_offsets
}
pub fn add_var(&mut self, value: CellExpression) -> Var {
let var = Var(self.var_count);
self.var_count += 1;
self.main_state.vars.insert(var, value);
var
}
pub fn alloc_var(&mut self, local_var: bool) -> Var {
let var = self.add_var(CellExpression::Deref(CellRef {
offset: self.main_state.allocated,
register: if local_var { Register::FP } else { Register::AP },
}));
self.main_state.allocated += 1;
var
}
pub fn duplicate_var(&mut self, var: Var) -> Var {
self.add_var(self.get_value(var, false))
}
pub fn add_hint<
const INPUTS_COUNT: usize,
const OUTPUTS_COUNT: usize,
THint: Into<Hint>,
F: FnOnce([ResOperand; INPUTS_COUNT], [CellRef; OUTPUTS_COUNT]) -> THint,
>(
&mut self,
f: F,
inputs: [Var; INPUTS_COUNT],
outputs: [Var; OUTPUTS_COUNT],
) {
self.current_hints.push(
f(
inputs.map(|v| match self.get_value(v, true) {
CellExpression::Deref(cell) => ResOperand::Deref(cell),
CellExpression::DoubleDeref(cell, offset) => {
ResOperand::DoubleDeref(cell, offset)
}
CellExpression::Immediate(imm) => imm.into(),
CellExpression::BinOp { op, a: other, b } => match op {
CellOperator::Add => {
ResOperand::BinOp(BinOpOperand { op: Operation::Add, a: other, b })
}
CellOperator::Mul => {
ResOperand::BinOp(BinOpOperand { op: Operation::Mul, a: other, b })
}
CellOperator::Sub | CellOperator::Div => {
panic!("hints to non ResOperand references are not supported.")
}
},
}),
outputs.map(|v| self.as_cell_ref(v, true)),
)
.into(),
);
}
pub fn assert_vars_eq(&mut self, dst: Var, res: Var) {
let a = self.as_cell_ref(dst, true);
let b = self.get_value(res, true);
let (a, b) = match b {
CellExpression::Deref(cell) => (a, ResOperand::Deref(cell)),
CellExpression::DoubleDeref(cell, offset) => (a, ResOperand::DoubleDeref(cell, offset)),
CellExpression::Immediate(imm) => (a, imm.into()),
CellExpression::BinOp { op, a: other, b } => match op {
CellOperator::Add => {
(a, ResOperand::BinOp(BinOpOperand { op: Operation::Add, a: other, b }))
}
CellOperator::Mul => {
(a, ResOperand::BinOp(BinOpOperand { op: Operation::Mul, a: other, b }))
}
CellOperator::Sub => {
(other, ResOperand::BinOp(BinOpOperand { op: Operation::Add, a, b }))
}
CellOperator::Div => {
(other, ResOperand::BinOp(BinOpOperand { op: Operation::Mul, a, b }))
}
},
};
let instruction =
self.next_instruction(InstructionBody::AssertEq(AssertEqInstruction { a, b }), true);
self.statements.push(Statement::Final(instruction));
}
pub fn buffer_write_and_inc(&mut self, buffer: Var, value: Var) {
let (cell, offset) = self.buffer_get_and_inc(buffer);
let location = self.add_var(CellExpression::DoubleDeref(cell, offset));
self.assert_vars_eq(value, location);
}
pub fn maybe_add_tempvar(&mut self, var: Var) -> Var {
self.add_var(CellExpression::Deref(match self.get_value(var, false) {
CellExpression::Deref(cell) => cell,
CellExpression::BinOp {
op: CellOperator::Add | CellOperator::Sub,
a,
b: DerefOrImmediate::Immediate(imm),
} if imm.value.is_zero() => a,
CellExpression::BinOp {
op: CellOperator::Mul | CellOperator::Div,
a,
b: DerefOrImmediate::Immediate(imm),
} if imm.value.is_one() => a,
_ => {
let temp = self.alloc_var(false);
self.assert_vars_eq(temp, var);
return temp;
}
}))
}
pub fn get_ref_and_inc(&mut self, buffer: Var) -> Var {
let (cell, offset) = self.as_cell_ref_plus_const(buffer, 0, false);
self.main_state.vars.insert(buffer, CellExpression::BinOp {
op: CellOperator::Add,
a: cell,
b: deref_or_immediate!(BigInt::from(offset) + 1),
});
self.add_var(CellExpression::DoubleDeref(cell, offset))
}
fn buffer_get_and_inc(&mut self, buffer: Var) -> (CellRef, i16) {
let (base, offset) = match self.get_value(buffer, false) {
CellExpression::Deref(cell) => (cell, 0),
CellExpression::BinOp {
op: CellOperator::Add,
a,
b: DerefOrImmediate::Immediate(imm),
} => (a, imm.value.try_into().expect("Too many buffer writes.")),
_ => panic!("Not a valid buffer."),
};
self.main_state.vars.insert(buffer, CellExpression::BinOp {
op: CellOperator::Add,
a: base,
b: deref_or_immediate!(offset + 1),
});
(base, offset)
}
pub fn add_ap(&mut self, size: usize) {
let instruction = self.next_instruction(
InstructionBody::AddAp(AddApInstruction { operand: BigInt::from(size).into() }),
false,
);
self.statements.push(Statement::Final(instruction));
self.main_state.ap_change += size;
}
pub fn increase_ap_change(&mut self, amount: usize) {
self.main_state.ap_change += amount;
self.main_state.allocated += amount.into_or_panic::<i16>();
}
pub fn bin_op(&mut self, op: CellOperator, lhs: Var, rhs: Var) -> Var {
let (a, b) = match self.get_value(lhs, false) {
CellExpression::Deref(cell) => (cell, self.as_deref_or_imm(rhs, false)),
CellExpression::BinOp {
op: CellOperator::Add,
a,
b: DerefOrImmediate::Immediate(imm),
} if op == CellOperator::Add => (
a,
DerefOrImmediate::Immediate(
(imm.value
+ extract_matches!(self.get_value(rhs, false), CellExpression::Immediate))
.into(),
),
),
_ => panic!(
"`bin_op` is supported only between a `deref` and a `deref_or_imm`, or a \
`add_with_const` and `imm`."
),
};
self.add_var(CellExpression::BinOp { op, a, b })
}
pub fn double_deref(&mut self, var: Var, offset: i16) -> Var {
let (cell, full_offset) = self.as_cell_ref_plus_const(var, offset, false);
self.add_var(CellExpression::DoubleDeref(cell, full_offset))
}
fn set_or_test_label_state(&mut self, label: String, state: State) {
match self.label_state.entry(label) {
Entry::Occupied(e) => {
let read_only = self.read_labels.contains(e.key());
e.into_mut().intersect(&state, read_only);
}
Entry::Vacant(e) => {
e.insert(state);
}
}
}
pub fn jump(&mut self, label: String) {
let instruction = self.next_instruction(
InstructionBody::Jump(JumpInstruction {
target: deref_or_immediate!(0),
relative: true,
}),
true,
);
self.statements.push(Statement::Jump(label.clone(), instruction));
let mut state = State::default();
core::mem::swap(&mut state, &mut self.main_state);
self.set_or_test_label_state(label, state);
self.reachable = false;
}
pub fn jump_nz(&mut self, condition: Var, label: String) {
let cell = self.as_cell_ref(condition, true);
let instruction = self.next_instruction(
InstructionBody::Jnz(JnzInstruction {
condition: cell,
jump_offset: deref_or_immediate!(0),
}),
true,
);
self.statements.push(Statement::Jump(label.clone(), instruction));
self.set_or_test_label_state(label, self.main_state.clone());
}
pub fn label(&mut self, name: String) {
if self.reachable {
self.set_or_test_label_state(name.clone(), self.main_state.clone());
}
self.read_labels.insert(name.clone());
self.main_state = self
.label_state
.get(&name)
.unwrap_or_else(|| panic!("No known value for state on reaching {name}."))
.clone();
self.statements.push(Statement::Label(name, 0));
self.reachable = true;
}
pub fn future_label(&mut self, name: String, offset: usize) {
self.statements.push(Statement::Label(name, offset));
}
pub fn rescope<const VAR_COUNT: usize>(&mut self, vars: [(Var, Var); VAR_COUNT]) {
self.main_state.validate_finality();
let values =
vars.map(|(new_var, value_var)| (new_var, self.main_state.get_adjusted(value_var)));
self.main_state.ap_change = 0;
self.main_state.allocated = 0;
self.main_state.vars.clear();
self.main_state.vars.extend(values);
}
pub fn call(&mut self, label: String) {
self.main_state.validate_finality();
let mut function_vars = OrderedHashMap::<Var, CellExpression>::default();
let mut main_vars = OrderedHashMap::<Var, CellExpression>::default();
let ap_change = self.main_state.ap_change;
let cell_to_var_flags = |cell: &CellRef| {
if cell.register == Register::AP { (true, false) } else { (false, true) }
};
for (var, value) in self.main_state.vars.iter() {
let (function_var, main_var) = match value {
CellExpression::DoubleDeref(cell, _) | CellExpression::Deref(cell) => {
cell_to_var_flags(cell)
}
CellExpression::Immediate(_) => (true, true),
CellExpression::BinOp { op: _, a, b } => match b {
DerefOrImmediate::Deref(cell) => {
if a.register == cell.register {
cell_to_var_flags(cell)
} else {
(false, false)
}
}
DerefOrImmediate::Immediate(_) => (true, true),
},
};
if function_var {
let mut value = value.clone().unchecked_apply_known_ap_change(ap_change + 2);
match &mut value {
CellExpression::DoubleDeref(cell, _) | CellExpression::Deref(cell) => {
cell.register = Register::FP
}
CellExpression::Immediate(_) => {}
CellExpression::BinOp { a, b, .. } => {
a.register = Register::FP;
match b {
DerefOrImmediate::Deref(cell) => cell.register = Register::FP,
DerefOrImmediate::Immediate(_) => {}
}
}
}
function_vars.insert(*var, value);
}
if main_var {
main_vars.insert(*var, value.clone());
}
}
let instruction = self.next_instruction(
InstructionBody::Call(CallInstruction {
relative: true,
target: deref_or_immediate!(0),
}),
false,
);
self.statements.push(Statement::Jump(label.clone(), instruction));
self.main_state.vars = main_vars;
self.main_state.allocated = 0;
self.main_state.ap_change = 0;
let function_state = State { vars: function_vars, ..Default::default() };
self.set_or_test_label_state(label, function_state);
}
pub fn ret(&mut self) {
self.main_state.validate_finality();
let instruction = self.next_instruction(InstructionBody::Ret(RetInstruction {}), false);
self.statements.push(Statement::Final(instruction));
self.reachable = false;
}
pub fn steps(&self) -> usize {
self.main_state.steps
}
pub fn reset_steps(&mut self) {
self.main_state.steps = 0;
}
pub fn fail(&mut self) {
let cell = CellRef { offset: -1, register: Register::FP };
let instruction = self.next_instruction(
InstructionBody::AssertEq(AssertEqInstruction {
a: cell,
b: ResOperand::BinOp(BinOpOperand {
op: Operation::Add,
a: cell,
b: DerefOrImmediate::Immediate(BigInt::one().into()),
}),
}),
false,
);
self.statements.push(Statement::Final(instruction));
self.mark_unreachable();
}
pub fn mark_unreachable(&mut self) {
self.reachable = false;
}
pub fn get_value(&self, var: Var, adjust_ap: bool) -> CellExpression {
if adjust_ap { self.main_state.get_adjusted(var) } else { self.main_state.get_value(var) }
}
fn as_cell_ref(&self, var: Var, adjust_ap: bool) -> CellRef {
extract_matches!(self.get_value(var, adjust_ap), CellExpression::Deref)
}
fn as_deref_or_imm(&self, var: Var, adjust_ap: bool) -> DerefOrImmediate {
match self.get_value(var, adjust_ap) {
CellExpression::Deref(cell) => DerefOrImmediate::Deref(cell),
CellExpression::Immediate(imm) => DerefOrImmediate::Immediate(imm.into()),
CellExpression::DoubleDeref(_, _) | CellExpression::BinOp { .. } => {
panic!("wrong usage.")
}
}
}
fn as_cell_ref_plus_const(
&self,
var: Var,
additional_offset: i16,
adjust_ap: bool,
) -> (CellRef, i16) {
match self.get_value(var, adjust_ap) {
CellExpression::Deref(cell) => (cell, additional_offset),
CellExpression::BinOp {
op: CellOperator::Add,
a,
b: DerefOrImmediate::Immediate(imm),
} => (
a,
(imm.value + additional_offset).try_into().expect("Offset too large for deref."),
),
_ => panic!("Not a valid ptr."),
}
}
fn next_instruction(&mut self, body: InstructionBody, inc_ap_supported: bool) -> Instruction {
assert!(self.reachable, "Cannot add instructions at unreachable code.");
let inc_ap =
inc_ap_supported && self.main_state.allocated as usize > self.main_state.ap_change;
if inc_ap {
self.main_state.ap_change += 1;
}
self.main_state.steps += 1;
let mut hints = vec![];
core::mem::swap(&mut hints, &mut self.current_hints);
Instruction { body, inc_ap, hints }
}
}
impl Default for CasmBuilder {
fn default() -> Self {
Self {
label_state: Default::default(),
read_labels: Default::default(),
main_state: Default::default(),
statements: Default::default(),
current_hints: Default::default(),
var_count: Default::default(),
reachable: true,
}
}
}
#[macro_export]
macro_rules! casm_build_extend {
($builder:ident,) => {};
($builder:ident, tempvar $var:ident; $($tok:tt)*) => {
let $var = $builder.alloc_var(false);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, localvar $var:ident; $($tok:tt)*) => {
let $var = $builder.alloc_var(true);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, ap += $value:expr; $($tok:tt)*) => {
$builder.add_ap($value);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, const $imm:ident = $value:expr; $($tok:tt)*) => {
let $imm = $builder.add_var($crate::cell_expression::CellExpression::Immediate(($value).into()));
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = $res:ident; $($tok:tt)*) => {
$builder.assert_vars_eq($dst, $res);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = $a:ident + $b:ident; $($tok:tt)*) => {
{
let __sum = $builder.bin_op($crate::cell_expression::CellOperator::Add, $a, $b);
$builder.assert_vars_eq($dst, __sum);
}
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = $a:ident * $b:ident; $($tok:tt)*) => {
{
let __product = $builder.bin_op($crate::cell_expression::CellOperator::Mul, $a, $b);
$builder.assert_vars_eq($dst, __product);
}
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = $a:ident - $b:ident; $($tok:tt)*) => {
{
let __diff = $builder.bin_op($crate::cell_expression::CellOperator::Sub, $a, $b);
$builder.assert_vars_eq($dst, __diff);
}
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = $a:ident / $b:ident; $($tok:tt)*) => {
{
let __division = $builder.bin_op($crate::cell_expression::CellOperator::Div, $a, $b);
$builder.assert_vars_eq($dst, __division);
}
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = $buffer:ident [ $offset:expr ] ; $($tok:tt)*) => {
{
let __deref = $builder.double_deref($buffer, $offset);
$builder.assert_vars_eq($dst, __deref);
}
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $dst:ident = * $buffer:ident; $($tok:tt)*) => {
{
let __deref = $builder.double_deref($buffer, 0);
$builder.assert_vars_eq($dst, __deref);
}
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, assert $value:ident = * ( $buffer:ident ++ ); $($tok:tt)*) => {
$builder.buffer_write_and_inc($buffer, $value);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, tempvar $var:ident = $value:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = $value; $($tok)*);
};
($builder:ident, tempvar $var:ident = $lhs:ident + $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = $lhs + $rhs; $($tok)*);
};
($builder:ident, tempvar $var:ident = $lhs:ident * $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = $lhs * $rhs; $($tok)*);
};
($builder:ident, tempvar $var:ident = $lhs:ident - $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = $lhs - $rhs; $($tok)*);
};
($builder:ident, tempvar $var:ident = $lhs:ident / $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = $lhs / $rhs; $($tok)*);
};
($builder:ident, tempvar $var:ident = * ( $buffer:ident ++ ); $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = *($buffer++); $($tok)*);
};
($builder:ident, tempvar $var:ident = $buffer:ident [ $offset:expr ]; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = $buffer[$offset]; $($tok)*);
};
($builder:ident, tempvar $var:ident = * $buffer:ident ; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, tempvar $var; assert $var = *$buffer; $($tok)*);
};
($builder:ident, maybe_tempvar $var:ident = $value:ident; $($tok:tt)*) => {
let $var = $builder.maybe_add_tempvar($value);
$crate::casm_build_extend!($builder, $($tok)*);
};
($builder:ident, maybe_tempvar $var:ident = $lhs:ident + $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
let $var = $lhs + $rhs;
maybe_tempvar $var = $var;
$($tok)*
};
};
($builder:ident, maybe_tempvar $var:ident = $lhs:ident * $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
let $var = $lhs * $rhs;
maybe_tempvar $var = $var;
$($tok)*
};
};
($builder:ident, maybe_tempvar $var:ident = $lhs:ident - $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
let $var = $lhs - $rhs;
maybe_tempvar $var = $var;
$($tok)*
};
};
($builder:ident, maybe_tempvar $var:ident = $lhs:ident / $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
let $var = $lhs / $rhs;
maybe_tempvar $var = $var;
$($tok)*
};
};
($builder:ident, localvar $var:ident = $value:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = $value; $($tok)*);
};
($builder:ident, localvar $var:ident = $lhs:ident + $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = $lhs + $rhs; $($tok)*);
};
($builder:ident, localvar $var:ident = $lhs:ident * $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = $lhs * $rhs; $($tok)*);
};
($builder:ident, localvar $var:ident = $lhs:ident - $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = $lhs - $rhs; $($tok)*);
};
($builder:ident, localvar $var:ident = $lhs:ident / $rhs:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = $lhs / $rhs; $($tok)*);
};
($builder:ident, localvar $var:ident = * ( $buffer:ident ++ ); $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = *($buffer++); $($tok)*);
};
($builder:ident, localvar $var:ident = $buffer:ident [ $offset:expr ]; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = $buffer[$offset]; $($tok)*);
};
($builder:ident, localvar $var:ident = * $buffer:ident ; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, localvar $var; assert $var = *$buffer; $($tok)*);
};
($builder:ident, let $dst:ident = $a:ident + $b:ident; $($tok:tt)*) => {
let $dst = $builder.bin_op($crate::cell_expression::CellOperator::Add, $a, $b);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = $a:ident * $b:ident; $($tok:tt)*) => {
let $dst = $builder.bin_op($crate::cell_expression::CellOperator::Mul, $a, $b);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = $a:ident - $b:ident; $($tok:tt)*) => {
let $dst = $builder.bin_op($crate::cell_expression::CellOperator::Sub, $a, $b);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = $a:ident / $b:ident; $($tok:tt)*) => {
let $dst = $builder.bin_op($crate::cell_expression::CellOperator::Div, $a, $b);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = * ( $buffer:ident ++ ); $($tok:tt)*) => {
let $dst = $builder.get_ref_and_inc($buffer);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = $buffer:ident [ $offset:expr ] ; $($tok:tt)*) => {
let $dst = $builder.double_deref($buffer, $offset);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = *$buffer:ident; $($tok:tt)*) => {
let $dst = $builder.double_deref($buffer, 0);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let $dst:ident = $src:ident; $($tok:tt)*) => {
let $dst = $builder.duplicate_var($src);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, jump $target:ident; $($tok:tt)*) => {
$builder.jump($crate::builder::ToOwned::to_owned(core::stringify!($target)));
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, jump $target:ident if $condition:ident != 0; $($tok:tt)*) => {
$builder.jump_nz($condition, $crate::builder::ToOwned::to_owned(core::stringify!($target)));
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, let ($($var_name:ident),*) = call $target:ident; $($tok:tt)*) => {
$builder.call($crate::builder::ToOwned::to_owned(core::stringify!($target)));
let __var_count = {0i16 $(+ (stringify!($var_name), 1i16).1)*};
let mut __var_index = 0;
$(
let $var_name = $builder.add_var($crate::cell_expression::CellExpression::Deref($crate::operand::CellRef {
offset: __var_index - __var_count,
register: $crate::operand::Register::AP,
}));
__var_index += 1;
)*
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, ret; $($tok:tt)*) => {
$builder.ret();
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, $label:ident: $($tok:tt)*) => {
$builder.label($crate::builder::ToOwned::to_owned(core::stringify!($label)));
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, fail; $($tok:tt)*) => {
$builder.fail();
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, unsatisfiable_assert $dst:ident = $res:ident; $($tok:tt)*) => {
$crate::casm_build_extend!($builder, assert $dst = $res;);
$builder.mark_unreachable();
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, hint $hint_head:ident$(::$hint_tail:ident)+ {
$($input_name:ident $(: $input_value:ident)?),*
} into {
$($output_name:ident $(: $output_value:ident)?),*
}; $($tok:tt)*) => {
$builder.add_hint(
|[$($input_name),*], [$($output_name),*]| $hint_head$(::$hint_tail)+ {
$($input_name,)* $($output_name,)*
},
[$($crate::casm_build_hint_param_value!($input_name $(: $input_value)?),)*],
[$($crate::casm_build_hint_param_value!($output_name $(: $output_value)?),)*],
);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, hint $hint_name:ident { $($inputs:tt)* } into { $($outputs:tt)* }; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
hint $crate::hints::CoreHint::$hint_name { $($inputs)* } into { $($outputs)* };
$($tok)*
}
};
($builder:ident, hint $hint_head:ident$(::$hint_tail:ident)* { $($inputs:tt)* }; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
hint $hint_head$(::$hint_tail)* { $($inputs)* } into {};
$($tok)*
}
};
($builder:ident, hint $hint_head:ident$(::$hint_tail:ident)* into { $($outputs:tt)* }; $($tok:tt)*) => {
$crate::casm_build_extend! {$builder,
hint $hint_head$(::$hint_tail)* {} into { $($outputs)* };
$($tok)*
}
};
($builder:ident, rescope { $($new_var:ident = $value_var:ident),* }; $($tok:tt)*) => {
$builder.rescope([$(($new_var, $value_var)),*]);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, #{ validate steps == $count:expr; } $($tok:tt)*) => {
assert_eq!($builder.steps(), $count);
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, #{ steps = 0; } $($tok:tt)*) => {
$builder.reset_steps();
$crate::casm_build_extend!($builder, $($tok)*)
};
($builder:ident, #{ $counter:ident += steps; steps = 0; } $($tok:tt)*) => {
$counter += $builder.steps() as i32;
$builder.reset_steps();
$crate::casm_build_extend!($builder, $($tok)*)
};
}
#[macro_export]
macro_rules! casm_build_hint_param_value {
($_name:ident : $value:ident) => {
$value
};
($name:ident) => {
$name
};
}