tasm_lib/hashing/absorb_multiple.rs
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use std::collections::HashMap;
use triton_vm::prelude::*;
use crate::prelude::*;
use crate::traits::basic_snippet::Reviewer;
use crate::traits::basic_snippet::SignOffFingerprint;
/// Absorb a sequence of field elements stored in memory, into the Sponge.
///
/// ### Behavior
///
/// ```text
/// BEFORE: _ *sequence [len: u32]
/// AFTER: _
/// ```
///
/// ### Preconditions
///
/// - all input arguments are properly [`BFieldCodec`] encoded
///
/// ### Postconditions
///
/// None.
#[derive(Debug, Copy, Clone, Eq, PartialEq, Hash)]
pub struct AbsorbMultiple;
impl BasicSnippet for AbsorbMultiple {
fn inputs(&self) -> Vec<(DataType, String)> {
vec![
(DataType::VoidPointer, "*sequence".to_string()),
(DataType::U32, "len".to_string()),
]
}
fn outputs(&self) -> Vec<(DataType, String)> {
vec![]
}
fn entrypoint(&self) -> String {
"tasmlib_hashing_absorb_multiple".to_string()
}
fn code(&self, _: &mut Library) -> Vec<LabelledInstruction> {
let entrypoint = self.entrypoint();
let absorb_all_full_chunks = format!("{entrypoint}_absorb_all_full_chunks");
let pad_varnum_zeros = format!("{entrypoint}_pad_varnum_zeros");
let read_remainder = format!("{entrypoint}_read_remainder");
triton_asm! {
// BEFORE: _ *bfe_sequence length
// AFTER: _
{entrypoint}:
push 10
dup 1
div_mod // _ *bfe_sequence length (length/10) (length%10)
place 2
pop 1 // _ *bfe_sequence (length%10) length
dup 1 // _ *bfe_sequence (length%10) length (length%10)
push -1
mul // _ *bfe_sequence (length%10) length (-length%10)
dup 3
add
add // _ *bfe_sequence (length%10) (*bfe_sequence + length - length%10)
// _ *bfe_sequence (length%10) *remainder
push 0
push 0
push 0
push 0 // _ *bfe_sequence (length%10) *remainder 0 0 0 0
pick 6 // _ (length%10) *remainder 0 0 0 0 *bfe_sequence
call {absorb_all_full_chunks}
// _ (length%10) *remainder e f g h *remainder
pop 5 // _ (length%10) *remainder
/* Calculate stop condition for reading remainder */
addi -1 // _ (length%10) (*remainder - 1)
dup 1 // _ (length%10) (*remainder - 1) (length%10)
push -1 // _ (length%10) (*remainder - 1) (length%10) -1
mul // _ (length%10) (*remainder - 1) (-length%10)
addi 9 // _ (length%10) (*remainder - 1) (9-length%10)
call {pad_varnum_zeros}
// _ [0; 9-length%10] (length%10) (*remainder - 1) 0
pop 1 // _ [0; 9-length%10] (length%10) (*remainder - 1)
push 1 // _ [0; 9-length%10] (length%10) (*remainder - 1) 1
swap 2 // _ [0; 9-length%10] 1 (*remainder - 1) (length%10)
dup 1
add // _ [0; 9-length%10] 1 (*remainder - 1) *last_word
call {read_remainder}
// _ [last_chunk_padded; 10] (*remainder - 1) (*remainder - 1)
pop 2
sponge_absorb
return
// BEFORE: _ *remainder 0 0 0 0 *bfe_sequence
// INVARIANT: _ *remainder a b c d *bfe_sequence'
// AFTER: _ *remainder e f g h *remainder
{absorb_all_full_chunks}:
dup 5 dup 1 eq
skiz return
// _ *remainder a b c d *bfe_sequence
sponge_absorb_mem
// _ *remainder e f g h *bfe_sequence'
recurse
// BEFORE: _ (length%10) (*remainder - 1) num_zeros
// INVARIANT: _ [0; i] (length%10) (*remainder - 1) (num_zeros - i)
// AFTER: _ [0; num_zeros] (length%10) (*remainder - 1) 0
{pad_varnum_zeros}:
dup 0
push 0 eq
skiz return
// _ [0; i] (length%10) (*remainder - 1) (num_zeros - i)
push 0
place 3 // _ [0; i+1] (length%10) (*remainder - 1) (num_zeros - i)
addi -1
recurse
// BEFORE: _ (*remainder - 1) *last_word
// INVARIANT: _ [elements; num_elements_read] (*remainder - 1) *some_addr
// AFTER: _ [elements; remainder_length] (*remainder - 1) (*remainder - 1)
{read_remainder}:
dup 1 dup 1 eq
skiz return
// _ [elements; num_elements_read] (*remainder - 1) *some_addr
read_mem 1 // _ [elements; num_elements_read] (*remainder - 1) element (*addr-1)
pick 1 // _ [elements; num_elements_read] (*remainder - 1) (*addr-1) element
place 2 // _ [elements; num_elements_read+1] (*remainder - 1) (*addr-1)
recurse
}
}
fn sign_offs(&self) -> HashMap<Reviewer, SignOffFingerprint> {
let mut sign_offs = HashMap::new();
sign_offs.insert(Reviewer("ferdinand"), 0x66d806516fc1be22.into());
sign_offs
}
}
#[cfg(test)]
mod tests {
use std::collections::VecDeque;
use twenty_first::prelude::Sponge;
use super::*;
use crate::empty_stack;
use crate::rust_shadowing_helper_functions::array::array_from_memory;
use crate::test_prelude::*;
impl MemPreserver for AbsorbMultiple {
fn rust_shadow(
&self,
stack: &mut Vec<BFieldElement>,
memory: &HashMap<BFieldElement, BFieldElement>,
_: VecDeque<BFieldElement>,
_: VecDeque<Digest>,
_: VecDeque<BFieldElement>,
sponge: &mut Option<Tip5>,
) -> Vec<BFieldElement> {
let length = pop_encodable::<u32>(stack).try_into().unwrap();
let address = stack.pop().unwrap();
let sponge = sponge.as_mut().expect("sponge must be initialized");
sponge.pad_and_absorb_all(&array_from_memory::<BFieldElement>(address, length, memory));
vec![]
}
fn pseudorandom_initial_state(
&self,
seed: [u8; 32],
bench_case: Option<BenchmarkCase>,
) -> MemPreserverInitialState {
let mut rng = StdRng::from_seed(seed);
let address = rng.random::<BFieldElement>();
let length = match bench_case {
Some(BenchmarkCase::CommonCase) => 102,
Some(BenchmarkCase::WorstCase) => 2002,
None => rng.random_range(0..=29),
};
let memory: HashMap<_, _> = (0..length)
.map(|i| (address + bfe!(i), rng.random()))
.collect();
MemPreserverInitialState {
stack: [empty_stack(), bfe_vec![address, length]].concat(),
nondeterminism: NonDeterminism::default().with_ram(memory),
public_input: VecDeque::new(),
sponge_state: Some(Tip5 {
state: rng.random(),
}),
}
}
fn corner_case_initial_states(&self) -> Vec<MemPreserverInitialState> {
let mut states = vec![];
// (all remainders) x {0, 1, 2 full absorptions}
for num_words in 0..=29 {
// populate RAM with 2s because padding consists of 0s and 1s
let ram: HashMap<_, _> = (0..num_words).map(|i| (bfe!(i), bfe!(2))).collect();
states.push(MemPreserverInitialState {
stack: [empty_stack(), bfe_vec![0, num_words]].concat(),
nondeterminism: NonDeterminism::default().with_ram(ram),
public_input: VecDeque::new(),
sponge_state: Some(Tip5::default()),
});
}
states
}
}
#[test]
fn test() {
ShadowedMemPreserver::new(AbsorbMultiple).test();
}
}
#[cfg(test)]
mod benches {
use super::*;
use crate::test_prelude::*;
#[test]
fn benchmark() {
ShadowedMemPreserver::new(AbsorbMultiple).bench();
}
}