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Constants ¶
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const ( ConsensusFaultDoubleForkMining = runtime0.ConsensusFaultDoubleForkMining ConsensusFaultParentGrinding = runtime0.ConsensusFaultParentGrinding ConsensusFaultTimeOffsetMining = runtime0.ConsensusFaultTimeOffsetMining )
Variables ¶
This section is empty.
Functions ¶
This section is empty.
Types ¶
type ConsensusFault ¶
type ConsensusFault = runtime0.ConsensusFault
Result of checking two headers for a consensus fault.
type ConsensusFaultType ¶
type ConsensusFaultType = runtime0.ConsensusFaultType
type Message ¶
type Message interface {
// The address of the immediate calling actor. Always an ID-address.
// If an actor invokes its own method, Caller() == Receiver().
Caller() addr.Address
// The address of the actor receiving the message. Always an ID-address.
Receiver() addr.Address
// The value attached to the message being processed, implicitly added to CurrentBalance()
// of Receiver() before method invocation.
// This value came from Caller().
ValueReceived() abi.TokenAmount
}
Message contains information available to the actor about the executing message. These values are fixed for the duration of an invocation.
type Runtime ¶
type Runtime interface {
// Information related to the current message being executed.
// When an actor invokes a method on another actor as a sub-call, these values reflect
// the sub-call context, rather than the top-level context.
Message
// Provides a handle for the actor's state object.
StateHandle
// Provides IPLD storage for actor state
Store
// Provides the system call interface.
Syscalls
// The network protocol version number at the current epoch.
NetworkVersion() network.Version
// The current chain epoch number. The genesis block has epoch zero.
CurrEpoch() abi.ChainEpoch
// Satisfies the requirement that every exported actor method must invoke at least one caller validation
// method before returning, without making any assertions about the caller.
ValidateImmediateCallerAcceptAny()
// Validates that the immediate caller's address exactly matches one of a set of expected addresses,
// aborting if it does not.
// The caller address is always normalized to an ID address, so expected addresses must be
// ID addresses to have any expectation of passing validation.
ValidateImmediateCallerIs(addrs ...addr.Address)
// Validates that the immediate caller is an actor with code CID matching one of a set of
// expected CIDs, aborting if it does not.
ValidateImmediateCallerType(types ...cid.Cid)
// The balance of the receiver. Always >= zero.
CurrentBalance() abi.TokenAmount
// Resolves an address of any protocol to an ID address (via the Init actor's table).
// This allows resolution of externally-provided SECP, BLS, or actor addresses to the canonical form.
// If the argument is an ID address it is returned directly.
ResolveAddress(address addr.Address) (addr.Address, bool)
// Look up the code ID at an actor address.
// The address will be resolved as if via ResolveAddress, if necessary, so need not be an ID-address.
GetActorCodeCID(addr addr.Address) (ret cid.Cid, ok bool)
// GetRandomnessFromBeacon returns a (pseudo)random byte array drawing from a random beacon at a prior epoch.
// The beacon value is combined with the personalization tag, epoch number, and explicitly provided entropy.
// The personalization tag may be any int64 value.
// The epoch must be less than the current epoch. The epoch may be negative, in which case
// it addresses the beacon value from genesis block.
// The entropy may be any byte array, or nil.
GetRandomnessFromBeacon(personalization crypto.DomainSeparationTag, randEpoch abi.ChainEpoch, entropy []byte) abi.Randomness
// GetRandomnessFromTickets samples randomness from the ticket chain. Randomess
// sampled through this method is unique per potential fork, and as a
// result, processes relying on this randomness are tied to whichever fork
// they choose.
// See GetRandomnessFromBeacon for notes about the personalization tag, epoch, and entropy.
GetRandomnessFromTickets(personalization crypto.DomainSeparationTag, randEpoch abi.ChainEpoch, entropy []byte) abi.Randomness
// Sends a message to another actor, returning the exit code and return value envelope.
// If the invoked method does not return successfully, its state changes (and that of any messages it sent in turn)
// will be rolled back.
Send(toAddr addr.Address, methodNum abi.MethodNum, params cbor.Marshaler, value abi.TokenAmount, out cbor.Er) exitcode.ExitCode
// Halts execution upon an error from which the receiver cannot recover. The caller will receive the exitcode and
// an empty return value. State changes made within this call will be rolled back.
// This method does not return.
// The provided exit code must be >= exitcode.FirstActorExitCode.
// The message and args are for diagnostic purposes and do not persist on chain. They should be suitable for
// passing to fmt.Errorf(msg, args...).
Abortf(errExitCode exitcode.ExitCode, msg string, args ...interface{})
// Computes an address for a new actor. The returned address is intended to uniquely refer to
// the actor even in the event of a chain re-org (whereas an ID-address might refer to a
// different actor after messages are re-ordered).
// Always an ActorExec address.
NewActorAddress() addr.Address
// Creates an actor with code `codeID` and address `address`, with empty state.
// May only be called by Init actor.
// Aborts if the provided address has previously been created.
CreateActor(codeId cid.Cid, address addr.Address)
// Deletes the executing actor from the state tree, transferring any balance to beneficiary.
// Aborts if the beneficiary does not exist or is the calling actor.
// May only be called by the actor itself.
DeleteActor(beneficiary addr.Address)
// Returns the total token supply in circulation at the beginning of the current epoch.
// The circulating supply is the sum of:
// - rewards emitted by the reward actor,
// - funds vested from lock-ups in the genesis state,
// less the sum of:
// - funds burnt,
// - pledge collateral locked in storage miner actors (recorded in the storage power actor)
// - deal collateral locked by the storage market actor
TotalFilCircSupply() abi.TokenAmount
// Provides a Go context for use by HAMT, etc.
// The VM is intended to provide an idealised machine abstraction, with infinite storage etc, so this context
// should not be used by actor code directly.
Context() context.Context
// Starts a new tracing span. The span must be End()ed explicitly by invoking or deferring EndSpan
StartSpan(name string) (EndSpan func())
// ChargeGas charges specified amount of `gas` for execution.
// `name` provides information about gas charging point
// `virtual` sets virtual amount of gas to charge, this amount is not counted
// toward execution cost. This functionality is used for observing global changes
// in total gas charged if amount of gas charged was to be changed.
ChargeGas(name string, gas int64, virtual int64)
// Note events that may make debugging easier
Log(level rt.LogLevel, msg string, args ...interface{})
// BaseFee returns the basefee value in attoFIL per unit gas for the currently exectuting tipset.
BaseFee() abi.TokenAmount
}
Runtime is the interface to the execution environment for actor methods.. This is everything that is accessible to actors, beyond parameters.
type StateHandle ¶
type StateHandle interface {
// Create initializes the state object.
// This is only valid in a constructor function and when the state has not yet been initialized.
StateCreate(obj cbor.Marshaler)
// Readonly loads a readonly copy of the state into the argument.
//
// Any modification to the state is illegal and will result in an abort.
StateReadonly(obj cbor.Unmarshaler)
// Transaction loads a mutable version of the state into the `obj` argument and protects
// the execution from side effects (including message send).
//
// The second argument is a function which allows the caller to mutate the state.
//
// If the state is modified after this function returns, execution will abort.
//
// The gas cost of this method is that of a Store.Put of the mutated state object.
//
// Note: the Go signature is not ideal due to lack of type system power.
//
// # Usage
// “`go
// var state SomeState
// rt.StateTransaction(&state, func() {
// // make some changes
// state.ImLoaded = true
// })
// // state.ImLoaded = false // BAD!! state is readonly outside the lambda, it will panic
// “`
StateTransaction(obj cbor.Er, f func())
}
StateHandle provides mutable, exclusive access to actor state.
type Store ¶
type Store interface {
// Retrieves and deserializes an object from the store into `o`. Returns whether successful.
StoreGet(c cid.Cid, o cbor.Unmarshaler) bool
// Serializes and stores an object, returning its CID.
StorePut(x cbor.Marshaler) cid.Cid
}
Store defines the storage module exposed to actors.
type Syscalls ¶
type Syscalls interface {
// Verifies that a signature is valid for an address and plaintext.
// If the address is a public-key type address, it is used directly.
// If it's an ID-address, the actor is looked up in state. It must be an account actor, and the
// public key is obtained from its state.
VerifySignature(signature crypto.Signature, signer addr.Address, plaintext []byte) error
// Hashes input data using blake2b with 256 bit output.
HashBlake2b(data []byte) [32]byte
// Computes an unsealed sector CID (CommD) from its constituent piece CIDs (CommPs) and sizes.
ComputeUnsealedSectorCID(reg abi.RegisteredSealProof, pieces []abi.PieceInfo) (cid.Cid, error)
// Verifies a sector seal proof.
// Deprecated and un-used.
VerifySeal(vi proof.SealVerifyInfo) error
BatchVerifySeals(vis map[addr.Address][]proof.SealVerifyInfo) (map[addr.Address][]bool, error)
VerifyAggregateSeals(aggregate proof.AggregateSealVerifyProofAndInfos) error
VerifyReplicaUpdate(replicaInfo proof.ReplicaUpdateInfo) error
// Verifies a proof of spacetime.
VerifyPoSt(vi proof5.WindowPoStVerifyInfo) error
// Verifies that two block headers provide proof of a consensus fault:
// - both headers mined by the same actor
// - headers are different
// - first header is of the same or lower epoch as the second
// - the headers provide evidence of a fault (see the spec for the different fault types).
// The parameters are all serialized block headers. The third "extra" parameter is consulted only for
// the "parent grinding fault", in which case it must be the sibling of h1 (same parent tipset) and one of the
// blocks in an ancestor of h2.
// Returns nil and an error if the headers don't prove a fault.
VerifyConsensusFault(h1, h2, extra []byte) (*ConsensusFault, error)
}
Pure functions implemented as primitives by the runtime.
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