tasm_lib/verifier/master_table/zerofiers_inverse.rs
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use strum::EnumCount;
use triton_vm::prelude::*;
use triton_vm::table::ConstraintType;
use twenty_first::math::x_field_element::EXTENSION_DEGREE;
use crate::arithmetic::xfe::to_the_power_of_power_of_2::ToThePowerOfPowerOf2;
use crate::prelude::*;
/// Calculate all inverses of the zerofiers. It is the caller's responsibility
/// to statically allocate memory for the array where the result is stored.
#[derive(Debug, Copy, Clone)]
pub struct ZerofiersInverse {
pub zerofiers_inverse_write_address: BFieldElement,
}
impl ZerofiersInverse {
pub(super) fn array_size() -> usize {
EXTENSION_DEGREE * ConstraintType::COUNT
}
/// Return the address needed to write to the inverted zerofiers array
fn zerofier_inv_write_address(&self, constraint_type: ConstraintType) -> BFieldElement {
let constraint_type_offset =
u64::try_from(EXTENSION_DEGREE * constraint_type as usize).unwrap();
self.zerofiers_inverse_write_address + bfe!(constraint_type_offset)
}
/// Return the address needed to read from the inverted zerofiers array
pub(super) fn zerofier_inv_read_address(
&self,
constraint_type: ConstraintType,
) -> BFieldElement {
self.zerofier_inv_write_address(constraint_type)
+ BFieldElement::new((EXTENSION_DEGREE - 1).try_into().unwrap())
}
}
impl BasicSnippet for ZerofiersInverse {
fn inputs(&self) -> Vec<(DataType, String)> {
vec![
(
DataType::Xfe,
"out_of_domain_point_curr_row_point".to_owned(),
),
(DataType::U32, "padded_height".to_owned()),
(DataType::Bfe, "trace_domain_generator".to_owned()),
]
}
fn outputs(&self) -> Vec<(DataType, String)> {
vec![]
}
fn entrypoint(&self) -> String {
"tasmlib_verifier_master_table_zerofiers_inverse".to_owned()
}
fn code(&self, library: &mut Library) -> Vec<LabelledInstruction> {
let xfe_mod_pow_pow_2 = library.import(Box::new(ToThePowerOfPowerOf2));
let calculate_initial_zerofier_inverse = triton_asm!(
// _ [out_of_domain_point_curr_row] padded_height trace_domain_generator
dup 4
dup 4
dup 4
push -1
add
x_invert
// _ [out_of_domain_point_curr_row] padded_height trace_domain_generator [initial_zerofier_inv]
);
let calculate_consistency_zerofier_inv = triton_asm!(
// _ [out_of_domain_point_curr_row] padded_height trace_domain_generator
swap 1
// _ [out_of_domain_point_curr_row] trace_domain_generator padded_height
log_2_floor
dup 4
dup 4
dup 4
// _ [out_of_domain_point_curr_row] trace_domain_generator log2_padded_height [out_of_domain_point_curr_row]
call {xfe_mod_pow_pow_2}
// _ [out_of_domain_point_curr_row] trace_domain_generator [out_of_domain_point_curr_row^{padded_height}]
push -1
add
x_invert
// _ [out_of_domain_point_curr_row] trace_domain_generator [consistency_zerofier_inv]
);
let calculate_except_last_row = triton_asm!(
// _ [out_of_domain_point_curr_row] trace_domain_generator
invert
// _ [out_of_domain_point_curr_row] (1 / trace_domain_generator)
push -1
mul
add
// _ [except_last_row]
);
let calculate_transition_zerofier_inv = triton_asm!(
// _ [except_last_row]
dup 2
dup 2
dup 2
// _ [except_last_row] [except_last_row]
push {self.zerofier_inv_read_address(ConstraintType::Consistency)}
read_mem {EXTENSION_DEGREE}
pop 1
// _ [except_last_row] [except_last_row] [consistency_zerofier_inv]
xx_mul
// _ [except_last_row] [transition_zerofier_inv]
);
let calculate_terminal_zerofier_inv = triton_asm!(
// _ [except_last_row]
x_invert // _ [terminal_zerofier_inv]
);
let entrypoint = self.entrypoint();
triton_asm!(
{entrypoint}:
// _ [out_of_domain_point_curr_row] padded_height trace_domain_generator
{&calculate_initial_zerofier_inverse}
// _ [out_of_domain_point_curr_row] padded_height trace_domain_generator [initial_zerofier_inv]
push {self.zerofier_inv_write_address(ConstraintType::Initial)}
write_mem {EXTENSION_DEGREE}
pop 1
// _ [out_of_domain_point_curr_row] padded_height trace_domain_generator
{&calculate_consistency_zerofier_inv}
// _ [out_of_domain_point_curr_row] trace_domain_generator [consistency_zerofier_inv]
push {self.zerofier_inv_write_address(ConstraintType::Consistency)}
write_mem {EXTENSION_DEGREE}
pop 1
// _ [out_of_domain_point_curr_row] trace_domain_generator
{&calculate_except_last_row}
// _ [except_last_row]
{&calculate_transition_zerofier_inv}
// _ [except_last_row] [transition_zerofier_inv]
push {self.zerofier_inv_write_address(ConstraintType::Transition)}
write_mem {EXTENSION_DEGREE}
pop 1
// _ [except_last_row]
{&calculate_terminal_zerofier_inv}
// _ [terminal_zerofier_inv]
push {self.zerofier_inv_write_address(ConstraintType::Terminal)}
write_mem {EXTENSION_DEGREE}
pop 1
// _
return
)
}
}
#[cfg(test)]
mod tests {
use num::One;
use twenty_first::math::traits::ModPowU32;
use twenty_first::math::traits::PrimitiveRootOfUnity;
use super::*;
use crate::rust_shadowing_helper_functions::array::insert_as_array;
use crate::test_prelude::*;
#[test]
fn zerofiers_inverse_pbt() {
let mem_address_if_first_static_malloc =
-BFieldElement::new(ZerofiersInverse::array_size() as u64) - BFieldElement::one();
ShadowedFunction::new(ZerofiersInverse {
zerofiers_inverse_write_address: mem_address_if_first_static_malloc,
})
.test()
}
impl Function for ZerofiersInverse {
fn rust_shadow(
&self,
stack: &mut Vec<BFieldElement>,
memory: &mut HashMap<BFieldElement, BFieldElement>,
) {
let trace_domain_generator = stack.pop().unwrap();
let padded_height: u32 = stack.pop().unwrap().value().try_into().unwrap();
let out_of_domain_point_curr_row = XFieldElement::new([
stack.pop().unwrap(),
stack.pop().unwrap(),
stack.pop().unwrap(),
]);
let initial_zerofier_inv =
(out_of_domain_point_curr_row - BFieldElement::one()).inverse();
let consistency_zerofier_inv =
(out_of_domain_point_curr_row.mod_pow_u32(padded_height) - BFieldElement::one())
.inverse();
let except_last_row = out_of_domain_point_curr_row - trace_domain_generator.inverse();
let transition_zerofier_inv = except_last_row * consistency_zerofier_inv;
let terminal_zerofier_inv = except_last_row.inverse();
insert_as_array(
self.zerofiers_inverse_write_address,
memory,
vec![
initial_zerofier_inv,
consistency_zerofier_inv,
transition_zerofier_inv,
terminal_zerofier_inv,
],
);
}
fn pseudorandom_initial_state(
&self,
seed: [u8; 32],
_bench_case: Option<BenchmarkCase>,
) -> FunctionInitialState {
let mut rng = StdRng::from_seed(seed);
let ood_current_row: XFieldElement = rng.random();
let log_2_padded_height: u32 = rng.random_range(8..32);
let padded_height = 2u32.pow(log_2_padded_height);
let trace_domain_generator =
BFieldElement::primitive_root_of_unity(padded_height as u64).unwrap();
FunctionInitialState {
stack: [
self.init_stack_for_isolated_run(),
ood_current_row.coefficients.into_iter().rev().collect_vec(),
vec![
BFieldElement::new(padded_height as u64),
trace_domain_generator,
],
]
.concat(),
memory: HashMap::default(),
}
}
}
}