Struct storage_proofs_porep::stacked::StackedCompound
source · pub struct StackedCompound<Tree: MerkleTreeTrait, G: Hasher> { /* private fields */ }
Trait Implementations§
source§impl<C: Circuit<Scalar>, P: ParameterSetMetadata, Tree: MerkleTreeTrait, G: Hasher> CacheableParameters<C, P> for StackedCompound<Tree, G>
impl<C: Circuit<Scalar>, P: ParameterSetMetadata, Tree: MerkleTreeTrait, G: Hasher> CacheableParameters<C, P> for StackedCompound<Tree, G>
fn cache_prefix() -> String
fn cache_meta(pub_params: &P) -> CacheEntryMetadata
fn cache_identifier(pub_params: &P) -> String
fn get_param_metadata( _circuit: C, pub_params: &P, ) -> Result<CacheEntryMetadata, Error>
source§fn get_groth_params<R>(
rng: Option<&mut R>,
circuit: C,
pub_params: &P,
) -> Result<MappedParameters<Bls12>, Error>where
R: RngCore,
fn get_groth_params<R>(
rng: Option<&mut R>,
circuit: C,
pub_params: &P,
) -> Result<MappedParameters<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
source§fn get_inner_product<R>(
rng: Option<&mut R>,
_circuit: C,
pub_params: &P,
num_proofs_to_aggregate: usize,
) -> Result<GenericSRS<Bls12>, Error>where
R: RngCore,
fn get_inner_product<R>(
rng: Option<&mut R>,
_circuit: C,
pub_params: &P,
num_proofs_to_aggregate: usize,
) -> Result<GenericSRS<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
source§fn get_verifying_key<R>(
rng: Option<&mut R>,
circuit: C,
pub_params: &P,
) -> Result<VerifyingKey<Bls12>, Error>where
R: RngCore,
fn get_verifying_key<R>(
rng: Option<&mut R>,
circuit: C,
pub_params: &P,
) -> Result<VerifyingKey<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
source§impl<'a, Tree: 'static + MerkleTreeTrait, G: 'static + Hasher> CompoundProof<'a, StackedDrg<'a, Tree, G>, StackedCircuit<Tree, G>> for StackedCompound<Tree, G>
impl<'a, Tree: 'static + MerkleTreeTrait, G: 'static + Hasher> CompoundProof<'a, StackedDrg<'a, Tree, G>, StackedCircuit<Tree, G>> for StackedCompound<Tree, G>
source§fn generate_public_inputs(
pub_in: &<StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicInputs,
pub_params: &<StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicParams,
k: Option<usize>,
) -> Result<Vec<Fr>>
fn generate_public_inputs( pub_in: &<StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicInputs, pub_params: &<StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicParams, k: Option<usize>, ) -> Result<Vec<Fr>>
generate_public_inputs generates public inputs suitable for use as input during verification
of a proof generated from this CompoundProof’s bellperson::Circuit (C). These inputs correspond
to those allocated when C is synthesized.
source§fn circuit<'b>(
public_inputs: &'b <StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicInputs,
_component_private_inputs: <StackedCircuit<Tree, G> as CircuitComponent>::ComponentPrivateInputs,
vanilla_proof: &'b <StackedDrg<'_, Tree, G> as ProofScheme<'_>>::Proof,
_public_params: &'b <StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicParams,
_partition_k: Option<usize>,
) -> Result<StackedCircuit<Tree, G>>
fn circuit<'b>( public_inputs: &'b <StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicInputs, _component_private_inputs: <StackedCircuit<Tree, G> as CircuitComponent>::ComponentPrivateInputs, vanilla_proof: &'b <StackedDrg<'_, Tree, G> as ProofScheme<'_>>::Proof, _public_params: &'b <StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicParams, _partition_k: Option<usize>, ) -> Result<StackedCircuit<Tree, G>>
circuit constructs an instance of this CompoundProof’s bellperson::Circuit.
circuit takes PublicInputs, PublicParams, and Proof from this CompoundProof’s proof::ProofScheme (S)
and uses them to initialize Circuit fields which will be used to construct public and private
inputs during circuit synthesis.
fn blank_circuit( public_params: &<StackedDrg<'_, Tree, G> as ProofScheme<'_>>::PublicParams, ) -> StackedCircuit<Tree, G>
fn setup(sp: &SetupParams<'a, S>) -> Result<PublicParams<'a, S>, Error>
fn partition_count(public_params: &PublicParams<'a, S>) -> usize
source§fn prove(
pub_params: &PublicParams<'a, S>,
pub_in: &<S as ProofScheme<'a>>::PublicInputs,
priv_in: &<S as ProofScheme<'a>>::PrivateInputs,
groth_params: &MappedParameters<Bls12>,
) -> Result<Vec<Proof<Bls12>>, Error>
fn prove( pub_params: &PublicParams<'a, S>, pub_in: &<S as ProofScheme<'a>>::PublicInputs, priv_in: &<S as ProofScheme<'a>>::PrivateInputs, groth_params: &MappedParameters<Bls12>, ) -> Result<Vec<Proof<Bls12>>, Error>
prove is equivalent to ProofScheme::prove.
fn prove_with_vanilla( pub_params: &PublicParams<'a, S>, pub_in: &<S as ProofScheme<'a>>::PublicInputs, vanilla_proofs: Vec<<S as ProofScheme<'a>>::Proof>, groth_params: &MappedParameters<Bls12>, ) -> Result<Vec<Proof<Bls12>>, Error>
fn verify<'b>( public_params: &PublicParams<'a, S>, public_inputs: &<S as ProofScheme<'a>>::PublicInputs, multi_proof: &MultiProof<'b>, requirements: &<S as ProofScheme<'a>>::Requirements, ) -> Result<bool, Error>
source§fn batch_verify<'b>(
public_params: &PublicParams<'a, S>,
public_inputs: &[<S as ProofScheme<'a>>::PublicInputs],
multi_proofs: &[MultiProof<'b>],
requirements: &<S as ProofScheme<'a>>::Requirements,
) -> Result<bool, Error>
fn batch_verify<'b>( public_params: &PublicParams<'a, S>, public_inputs: &[<S as ProofScheme<'a>>::PublicInputs], multi_proofs: &[MultiProof<'b>], requirements: &<S as ProofScheme<'a>>::Requirements, ) -> Result<bool, Error>
Efficiently verify multiple proofs.
source§fn circuit_proofs(
pub_in: &<S as ProofScheme<'a>>::PublicInputs,
vanilla_proofs: Vec<<S as ProofScheme<'a>>::Proof>,
pub_params: &<S as ProofScheme<'a>>::PublicParams,
groth_params: &MappedParameters<Bls12>,
priority: bool,
) -> Result<Vec<Proof<Bls12>>, Error>
fn circuit_proofs( pub_in: &<S as ProofScheme<'a>>::PublicInputs, vanilla_proofs: Vec<<S as ProofScheme<'a>>::Proof>, pub_params: &<S as ProofScheme<'a>>::PublicParams, groth_params: &MappedParameters<Bls12>, priority: bool, ) -> Result<Vec<Proof<Bls12>>, Error>
circuit_proof creates and synthesizes a circuit from concrete params/inputs, then generates a
groth proof from it. It returns a groth proof.
circuit_proof is used internally and should neither be called nor implemented outside of
default trait methods.
source§fn aggregate_proofs(
prover_srs: &ProverSRS<Bls12>,
hashed_seeds_and_comm_rs: &[u8],
proofs: &[Proof<Bls12>],
version: AggregateVersion,
) -> Result<AggregateProof<Bls12>, Error>
fn aggregate_proofs( prover_srs: &ProverSRS<Bls12>, hashed_seeds_and_comm_rs: &[u8], proofs: &[Proof<Bls12>], version: AggregateVersion, ) -> Result<AggregateProof<Bls12>, Error>
Given a prover_srs key, a list of groth16 proofs, and an ordered list of seeds
(used to derive the PoRep challenges) hashed pair-wise with the comm_rs using sha256, aggregate them all into
an AggregateProof type.
source§fn verify_aggregate_proofs(
ip_verifier_srs: &VerifierSRS<Bls12>,
pvk: &PreparedVerifyingKey<Bls12>,
hashed_seeds_and_comm_rs: &[u8],
public_inputs: &[Vec<Scalar>],
aggregate_proof: &AggregateProof<Bls12>,
version: AggregateVersion,
) -> Result<bool, Error>
fn verify_aggregate_proofs( ip_verifier_srs: &VerifierSRS<Bls12>, pvk: &PreparedVerifyingKey<Bls12>, hashed_seeds_and_comm_rs: &[u8], public_inputs: &[Vec<Scalar>], aggregate_proof: &AggregateProof<Bls12>, version: AggregateVersion, ) -> Result<bool, Error>
Verifies the aggregate proof, with respect to the flattened input list. Read more
source§fn groth_params<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
) -> Result<MappedParameters<Bls12>, Error>where
R: RngCore,
fn groth_params<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
) -> Result<MappedParameters<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
source§fn verifying_key<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
) -> Result<VerifyingKey<Bls12>, Error>where
R: RngCore,
fn verifying_key<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
) -> Result<VerifyingKey<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
source§fn srs_key<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
num_proofs_to_aggregate: usize,
) -> Result<ProverSRS<Bls12>, Error>where
R: RngCore,
fn srs_key<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
num_proofs_to_aggregate: usize,
) -> Result<ProverSRS<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
source§fn srs_verifier_key<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
num_proofs_to_aggregate: usize,
) -> Result<VerifierSRS<Bls12>, Error>where
R: RngCore,
fn srs_verifier_key<R>(
rng: Option<&mut R>,
public_params: &<S as ProofScheme<'a>>::PublicParams,
num_proofs_to_aggregate: usize,
) -> Result<VerifierSRS<Bls12>, Error>where
R: RngCore,
If the rng option argument is set, parameters will be
generated using it. This is used for testing only, or where
parameters are otherwise unavailable (e.g. benches). If rng
is not set, an error will result if parameters are not
present.
fn circuit_for_test( public_parameters: &PublicParams<'a, S>, public_inputs: &<S as ProofScheme<'a>>::PublicInputs, private_inputs: &<S as ProofScheme<'a>>::PrivateInputs, ) -> Result<(C, Vec<Scalar>), Error>
source§fn circuit_for_test_all(
public_parameters: &PublicParams<'a, S>,
public_inputs: &<S as ProofScheme<'a>>::PublicInputs,
private_inputs: &<S as ProofScheme<'a>>::PrivateInputs,
) -> Result<Vec<(C, Vec<Scalar>)>, Error>
fn circuit_for_test_all( public_parameters: &PublicParams<'a, S>, public_inputs: &<S as ProofScheme<'a>>::PublicInputs, private_inputs: &<S as ProofScheme<'a>>::PrivateInputs, ) -> Result<Vec<(C, Vec<Scalar>)>, Error>
Like circuit_for_test but returns values for all partitions.
Auto Trait Implementations§
impl<Tree, G> Freeze for StackedCompound<Tree, G>
impl<Tree, G> RefUnwindSafe for StackedCompound<Tree, G>where
Tree: RefUnwindSafe,
G: RefUnwindSafe,
impl<Tree, G> Send for StackedCompound<Tree, G>
impl<Tree, G> Sync for StackedCompound<Tree, G>
impl<Tree, G> Unpin for StackedCompound<Tree, G>
impl<Tree, G> UnwindSafe for StackedCompound<Tree, G>where
Tree: UnwindSafe,
G: UnwindSafe,
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