929 lines
37 KiB
Nim
929 lines
37 KiB
Nim
# Nimbus
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# Copyright (c) 2018 Status Research & Development GmbH
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# Licensed under either of
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# * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE) or
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# http://www.apache.org/licenses/LICENSE-2.0)
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# * MIT license ([LICENSE-MIT](LICENSE-MIT) or
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# http://opensource.org/licenses/MIT)
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# at your option. This file may not be copied, modified, or distributed except
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# according to those terms.
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## TODO:
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## =====
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## * No uncles are handled by this pool
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##
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## * Impose a size limit to the bucket database. Which items would be removed?
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##
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## * There is a conceivable problem with the per-account optimisation. The
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## algorithm chooses an account and does not stop packing until all txs
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## of the account are packed or the block is full. In the latter case,
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## there might be some txs left unpacked from the account which might be
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## the most lucrative ones. Should this be tackled (see also next item)?
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##
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## * The classifier throws out all txs with negative gas tips. This implies
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## that all subsequent txs must also be suspended for this account even
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## though these following txs might be extraordinarily profitable so that
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## packing the whole account might be woth wile. Should this be considered,
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## somehow (see also previous item)?
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##
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##
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## Transaction Pool
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## ================
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##
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## The transaction pool collects transactions and holds them in a database.
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## This database consists of the three buckets *pending*, *staged*, and
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## *packed* and a *waste basket*. These database entities are discussed in
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## more detail, below.
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##
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## At some point, there will be some transactions in the *staged* bucket.
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## Upon request, the pool will pack as many of those transactions as possible
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## into to *packed* bucket which will subsequently be used to generate a
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## new Ethereum block.
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##
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## When packing transactions from *staged* into *packed* bucked, the staged
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## transactions are sorted by *sender account* and *nonce*. The *sender
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## account* values are ordered by a *ranking* function (highest ranking first)
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## and the *nonce* values by their natural integer order. Then, transactions
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## are greedily picked from the ordered set until there are enough
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## transactions in the *packed* bucket. Some boundary condition applies which
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## roughly says that for a given account, all the transactions packed must
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## leave no gaps between nonce values when sorted.
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##
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## The rank function applied to the *sender account* sorting is chosen as a
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## guess for higher profitability which goes with a higher rank account.
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##
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##
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## Rank calculator
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## ---------------
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## Let *tx()* denote the mapping
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## ::
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## tx: (account,nonce) -> tx
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##
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## from an index pair *(account,nonce)* to a transaction *tx*. Also, for some
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## external parameter *baseFee*, let
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## ::
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## maxProfit: (tx,baseFee) -> tx.effectiveGasTip(baseFee) * tx.gasLimit
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##
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## be the maximal tip a single transation can achieve (where unit of the
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## *effectiveGasTip()* is a *price* and *gasLimit* is a *commodity value*.).
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## Then the rank function
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## ::
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## rank(account) = Σ maxProfit(tx(account,ν),baseFee) / Σ tx(account,ν).gasLimit
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## ν ν
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##
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## is a *price* estimate of the maximal avarage tip per gas unit over all
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## transactions for the given account. The nonces `ν` for the summation
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## run over all transactions from the *staged* and *packed* bucket.
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##
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##
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##
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##
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## Pool database:
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## --------------
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## ::
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## <Transactions> . <Status buckets> . <Terminal state>
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## . .
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## . . +----------+
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## add() ----+---------------------------------> | |
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## | . +-----------+ . | disposed |
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## +-----------> | pending | ------> | |
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## . +-----------+ . | |
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## . | ^ ^ . | waste |
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## . v | | . | basket |
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## . +----------+ | . | |
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## . | staged | | . | |
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## . +----------+ | . | |
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## . | | ^ | . | |
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## . | v | | . | |
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## . | +----------+ . | |
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## . | | packed | -------> | |
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## . | +----------+ . | |
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## . +----------------------> | |
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## . . +----------+
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##
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## The three columns *Batch queue*, *State bucket*, and *Terminal state*
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## represent three different accounting (or database) systems. The pool
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## database is continuosly updated while new transactions are added.
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## Transactions are bundled with meta data which holds the full datanbase
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## state in addition to other cached information like the sender account.
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##
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##
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## New transactions
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## ----------------
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## When entering the pool, new transactions are bundled with meta data and
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## appended to the batch queue. These bundles are called *items* which are
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## forwarded to one of the following entites:
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##
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## * the *staged* bucket if the transaction is valid and match some constraints
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## on expected minimum mining fees (or a semblance of that for *non-PoW*
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## networks)
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## * the *pending* bucket if the transaction is valid but is not subject to be
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## held in the *staged* bucket
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## * the *waste basket* if the transaction is invalid
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##
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## If a valid transaction item supersedes an existing one, the existing
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## item is moved to the waste basket and the new transaction replaces the
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## existing one in the current bucket if the gas price of the transaction is
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## at least `priceBump` per cent higher (see adjustable parameters, below.)
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##
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## Status buckets
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## --------------
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## The term *bucket* is a nickname for a set of *items* (i.e. transactions
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## bundled with meta data as mentioned earlier) all labelled with the same
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## `status` symbol and not marked *waste*. In particular, bucket membership
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## for an item is encoded as
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##
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## * the `status` field indicates the particular *bucket* membership
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## * the `reject` field is reset/unset and has zero-equivalent value
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##
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## The following boundary conditions hold for the union of all buckets:
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##
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## * *Unique index:*
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## Let **T** be the union of all buckets and **Q** be the
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## set of *(sender,nonce)* pairs derived from the items of **T**. Then
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## **T** and **Q** are isomorphic, i.e. for each pair *(sender,nonce)*
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## from **Q** there is exactly one item from **T**, and vice versa.
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##
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## * *Consecutive nonces:*
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## For each *(sender0,nonce0)* of **Q**, either
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## *(sender0,nonce0-1)* is in **Q** or *nonce0* is the current nonce as
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## registered with the *sender account* (implied by the block chain),
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##
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## The *consecutive nonces* requirement involves the *sender account*
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## which depends on the current state of the block chain as represented by the
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## internally cached head (i.e. insertion point where a new block is to be
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## appended.)
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##
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## The following notation describes sets of *(sender,nonce)* pairs for
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## per-bucket items. It will be used for boundary conditions similar to the
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## ones above.
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##
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## * **Pending** denotes the set of *(sender,nonce)* pairs for the
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## *pending* bucket
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##
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## * **Staged** denotes the set of *(sender,nonce)* pairs for the
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## *staged* bucket
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##
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## * **Packed** denotes the set of *(sender,nonce)* pairs for the
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## *packed* bucket
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##
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## The pending bucket
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## ^^^^^^^^^^^^^^^^^^
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## Items in this bucket hold valid transactions that are not in any of the
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## other buckets. All itmes might be promoted form here into other buckets if
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## the current state of the block chain as represented by the internally cached
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## head changes.
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##
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## The staged bucket
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## ^^^^^^^^^^^^^^^^^
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## Items in this bucket are ready to be added to a new block. They typycally
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## imply some expected minimum reward when mined on PoW networks. Some
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## boundary condition holds:
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##
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## * *Consecutive nonces:*
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## For any *(sender0,nonce0)* pair from **Staged**, the pair
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## *(sender0,nonce0-1)* is not in **Pending**.
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##
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## Considering the respective boundary condition on the union of buckets
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## **T**, this condition here implies that a *staged* per sender nonce has a
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## predecessor in the *staged* or *packed* bucket or is a nonce as registered
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## with the *sender account*.
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##
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## The packed bucket
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## ^^^^^^^^^^^^^^^^^
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## All items from this bucket have been selected from the *staged* bucket, the
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## transactions of which (i.e. unwrapped items) can go right away into a new
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## ethernet block. How these items are selected was described at the beginning
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## of this chapter. The following boundary conditions holds:
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##
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## * *Consecutive nonces:*
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## For any *(sender0,nonce0)* pair from **Packed**, the pair
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## *(sender0,nonce0-1)* is neither in **Pending**, nor in **Staged**.
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##
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## Considering the respective boundary condition on the union of buckets
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## **T**, this condition here implies that a *packed* per-sender nonce has a
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## predecessor in the very *packed* bucket or is a nonce as registered with the
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## *sender account*.
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##
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##
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## Terminal state
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## --------------
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## After use, items are disposed into a waste basket *FIFO* queue which has a
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## maximal length. If the length is exceeded, the oldest items are deleted.
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## The waste basket is used as a cache for discarded transactions that need to
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## re-enter the system. Recovering from the waste basket saves the effort of
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## recovering the sender account from the signature. An item is identified
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## *waste* if
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##
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## * the `reject` field is explicitely set and has a value different
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## from a zero-equivalent.
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##
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## So a *waste* item is clearly distinguishable from any active one as a
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## member of one of the *status buckets*.
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##
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##
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##
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## Pool coding
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## ===========
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## A piece of code using this pool architecture could look like as follows:
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## ::
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## # see also unit test examples, e.g. "Block packer tests"
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## var db: CoreDbRef # to be initialised
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## var txs: seq[Transaction] # to be initialised
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##
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## proc mineThatBlock(blk: EthBlock) # external function
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##
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## ..
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##
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## var xq = TxPoolRef.new(db) # initialise tx-pool
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## ..
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##
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## xq.add(txs) # add transactions ..
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## .. # .. into the buckets
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##
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## let newBlock = xq.ethBlock # fetch current mining block
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##
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## ..
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## mineThatBlock(newBlock) ... # external mining & signing process
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## ..
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##
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## xp.smartHead(newBlock.header) # update pool, new insertion point
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##
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##
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## Discussion of example
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## ---------------------
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## In the example, transactions are processed into buckets via `add()`.
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##
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## The `ethBlock()` directive assembles and retrieves a new block for mining
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## derived from the current pool state. It invokes the block packer which
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## accumulates txs from the `pending` buscket into the `packed` bucket which
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## then go into the block.
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##
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## Then mining and signing takes place ...
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##
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## After mining and signing, the view of the block chain as seen by the pool
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## must be updated to be ready for a new mining process. In the best case, the
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## canonical head is just moved to the currently mined block which would imply
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## just to discard the contents of the *packed* bucket with some additional
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## transactions from the *staged* bucket. A more general block chain state
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## head update would be more complex, though.
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##
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## In the most complex case, the newly mined block was added to some block
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## chain branch which has become an uncle to the new canonical head retrieved
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## by `getCanonicalHead()`. In order to update the pool to the very state
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## one would have arrived if worked on the retrieved canonical head branch
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## in the first place, the directive `smartHead()` calculates the actions of
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## what is needed to get just there from the locally cached head state of the
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## pool. These actions are applied by `smartHead()` after the internal head
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## position was moved.
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##
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## The *setter* behind the internal head position adjustment also caches
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## updated internal parameters as base fee, state, fork, etc.
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##
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##
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## Adjustable Parameters
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## ---------------------
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##
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## flags
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## The `flags` parameter holds a set of strategy symbols for how to process
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## items and buckets.
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##
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## *stageItems1559MinFee*
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## Stage tx items with `tx.maxFee` at least `minFeePrice`. Other items are
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## left or set pending. This symbol affects post-London tx items, only.
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##
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## *stageItems1559MinTip*
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## Stage tx items with `tx.effectiveGasTip(baseFee)` at least
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## `minTipPrice`. Other items are considered underpriced and left or set
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## pending. This symbol affects post-London tx items, only.
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##
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## *stageItemsPlMinPrice*
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## Stage tx items with `tx.gasPrice` at least `minPreLondonGasPrice`.
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## Other items are considered underpriced and left or set pending. This
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## symbol affects pre-London tx items, only.
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##
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## *packItemsMaxGasLimit*
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## It set, the *packer* will execute and collect additional items from
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## the `staged` bucket while accumulating `gasUsed` as long as
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## `maxGasLimit` is not exceeded. If `packItemsTryHarder` flag is also
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## set, the *packer* will not stop until at least `hwmGasLimit` is
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## reached.
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##
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## Otherwise the *packer* will accumulate up until `trgGasLimit` is
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## not exceeded, and not stop until at least `lwmGasLimit` is reached
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## in case `packItemsTryHarder` is also set,
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##
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## *packItemsTryHarder*
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## It set, the *packer* will *not* stop accumulaing transactions up until
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## the `lwmGasLimit` or `hwmGasLimit` is reached, depending on whether
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## the `packItemsMaxGasLimit` is set. Otherwise, accumulating stops
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## immediately before the next transaction exceeds `trgGasLimit`, or
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## `maxGasLimit` depending on `packItemsMaxGasLimit`.
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##
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## *autoUpdateBucketsDB*
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## Automatically update the state buckets after running batch jobs if the
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## `dirtyBuckets` flag is also set.
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##
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## *autoZombifyUnpacked*
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## Automatically dispose *pending* or *staged* tx items that were added to
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## the state buckets database at least `lifeTime` ago.
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##
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## *autoZombifyPacked*
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## Automatically dispose *packed* tx itemss that were added to
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## the state buckets database at least `lifeTime` ago.
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##
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## *..there might be more strategy symbols..*
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##
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## hwmTrgPercent
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## This parameter implies the size of `hwmGasLimit` which is calculated
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## as `max(trgGasLimit, maxGasLimit * lwmTrgPercent / 100)`.
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##
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## lifeTime
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## Txs that stay longer in one of the buckets will be moved to a waste
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## basket. From there they will be eventually deleted oldest first when
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## the maximum size would be exceeded.
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##
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## lwmMaxPercent
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## This parameter implies the size of `lwmGasLimit` which is calculated
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## as `max(minGasLimit, trgGasLimit * lwmTrgPercent / 100)`.
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##
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## minFeePrice
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## Applies no EIP-1559 txs only. Txs are packed if `maxFee` is at least
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## that value.
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##
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## minTipPrice
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## For EIP-1559, txs are packed if the expected tip (see `estimatedGasTip()`)
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## is at least that value. In compatibility mode for legacy txs, this
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## degenerates to `gasPrice - baseFee`.
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##
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## minPreLondonGasPrice
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## For pre-London or legacy txs, this parameter has precedence over
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## `minTipPrice`. Txs are packed if the `gasPrice` is at least that value.
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##
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## priceBump
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## There can be only one transaction in the database for the same `sender`
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## account and `nonce` value. When adding a transaction with the same
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## (`sender`, `nonce`) pair, the new transaction will replace the current one
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## if it has a gas price which is at least `priceBump` per cent higher.
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##
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||
##
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## Read-Only Parameters
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## --------------------
|
||
##
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## baseFee
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## This parameter is derived from the internally cached block chain state.
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## The base fee parameter modifies/determines the expected gain when packing
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## a new block (is set to *zero* for *pre-London* blocks.)
|
||
##
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## dirtyBuckets
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## If `true`, the state buckets database is ready for re-org if the
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## `autoUpdateBucketsDB` flag is also set.
|
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##
|
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## gasLimit
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## Taken or derived from the current block chain head, incoming txs that
|
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## exceed this gas limit are stored into the *pending* bucket (maybe
|
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## eligible for staging at the next cycle when the internally cached block
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## chain state is updated.)
|
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##
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## head
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## Cached block chain insertion point, not necessarily the same header as
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## retrieved by the `getCanonicalHead()`. This insertion point can be
|
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## adjusted with the `smartHead()` function.
|
||
##
|
||
## hwmGasLimit
|
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## This parameter is at least `trgGasLimit` and does not exceed
|
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## `maxGasLimit` and can be adjusted by means of setting `hwmMaxPercent`. It
|
||
## is used by the packer as a minimum block size if both flags
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## `packItemsTryHarder` and `packItemsMaxGasLimit` are set.
|
||
##
|
||
## lwmGasLimit
|
||
## This parameter is at least `minGasLimit` and does not exceed
|
||
## `trgGasLimit` and can be adjusted by means of setting `lwmTrgPercent`. It
|
||
## is used by the packer as a minimum block size if the flag
|
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## `packItemsTryHarder` is set and `packItemsMaxGasLimit` is unset.
|
||
##
|
||
## maxGasLimit
|
||
## This parameter is at least `hwmGasLimit`. It is calculated considering
|
||
## the current state of the block chain as represented by the internally
|
||
## cached head. This parameter is used by the *packer* as a size limit if
|
||
## `packItemsMaxGasLimit` is set.
|
||
##
|
||
## minGasLimit
|
||
## This parameter is calculated considering the current state of the block
|
||
## chain as represented by the internally cached head. It can be used for
|
||
## verifying that a generated block does not underflow minimum size.
|
||
## Underflow can only be happen if there are not enough transaction available
|
||
## in the pool.
|
||
##
|
||
## trgGasLimit
|
||
## This parameter is at least `lwmGasLimit` and does not exceed
|
||
## `maxGasLimit`. It is calculated considering the current state of the block
|
||
## chain as represented by the internally cached head. This parameter is
|
||
## used by the *packer* as a size limit if `packItemsMaxGasLimit` is unset.
|
||
##
|
||
|
||
import
|
||
std/[sequtils, tables],
|
||
./tx_pool/[tx_chain, tx_desc, tx_info, tx_item],
|
||
./tx_pool/tx_tabs,
|
||
./tx_pool/tx_tasks/[
|
||
tx_add,
|
||
tx_bucket,
|
||
tx_head,
|
||
tx_dispose,
|
||
tx_packer,
|
||
tx_recover],
|
||
chronicles,
|
||
eth/keys,
|
||
stew/[keyed_queue, results],
|
||
../common/common
|
||
|
||
export
|
||
TxItemRef,
|
||
TxItemStatus,
|
||
TxPoolFlags,
|
||
TxPoolRef,
|
||
TxTabsGasTotals,
|
||
TxTabsItemsCount,
|
||
results,
|
||
tx_desc.startDate,
|
||
tx_info,
|
||
tx_item.GasPrice,
|
||
tx_item.`<=`,
|
||
tx_item.`<`,
|
||
tx_item.effectiveGasTip,
|
||
tx_item.info,
|
||
tx_item.itemID,
|
||
tx_item.sender,
|
||
tx_item.status,
|
||
tx_item.timeStamp,
|
||
tx_item.tx,
|
||
tx_tabs.local,
|
||
tx_tabs.remote
|
||
|
||
{.push raises: [].}
|
||
|
||
logScope:
|
||
topics = "tx-pool"
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Private functions: tasks processor
|
||
# ------------------------------------------------------------------------------
|
||
|
||
proc maintenanceProcessing(xp: TxPoolRef)
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Tasks to be done after add/del txs processing
|
||
|
||
# Purge expired items
|
||
if autoZombifyUnpacked in xp.pFlags or
|
||
autoZombifyPacked in xp.pFlags:
|
||
# Move transactions older than `xp.lifeTime` to the waste basket.
|
||
xp.disposeExpiredItems
|
||
|
||
# Update buckets
|
||
if autoUpdateBucketsDB in xp.pFlags:
|
||
if xp.pDirtyBuckets:
|
||
# For all items, re-calculate item status values (aka bucket labels).
|
||
# If the `force` flag is set, re-calculation is done even though the
|
||
# change flag has remained unset.
|
||
discard xp.bucketUpdateAll
|
||
xp.pDirtyBuckets = false
|
||
|
||
proc setHead(xp: TxPoolRef; val: BlockHeader)
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Update cached block chain insertion point. This will also update the
|
||
## internally cached `baseFee` (depends on the block chain state.)
|
||
if xp.chain.head != val:
|
||
xp.chain.head = val # calculates the new baseFee
|
||
xp.txDB.baseFee = xp.chain.baseFee
|
||
xp.pDirtyBuckets = true
|
||
xp.bucketFlushPacked
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Public constructor/destructor
|
||
# ------------------------------------------------------------------------------
|
||
|
||
proc new*(T: type TxPoolRef; com: CommonRef; miner: EthAddress): T
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Constructor, returns a new tx-pool descriptor. The `miner` argument is
|
||
## the fee beneficiary for informational purposes only.
|
||
new result
|
||
result.init(com, miner)
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Public functions, task manager, pool actions serialiser
|
||
# ------------------------------------------------------------------------------
|
||
|
||
# core/tx_pool.go(848): func (pool *TxPool) AddLocals(txs []..
|
||
# core/tx_pool.go(864): func (pool *TxPool) AddRemotes(txs []..
|
||
proc add*(xp: TxPoolRef; txs: openArray[Transaction]; info = "")
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Add a list of transactions to be processed and added to the buckets
|
||
## database. It is OK pass an empty list in which case some maintenance
|
||
## check can be forced.
|
||
##
|
||
## The argument Transactions `txs` may come in any order, they will be
|
||
## sorted by `<account,nonce>` before adding to the database with the
|
||
## least nonce first. For this reason, it is suggested to pass transactions
|
||
## in larger groups. Calling single transaction jobs, they must strictly be
|
||
## passed *smaller nonce* before *larger nonce*.
|
||
xp.pDoubleCheckAdd xp.addTxs(txs, info).topItems
|
||
xp.maintenanceProcessing
|
||
|
||
# core/tx_pool.go(854): func (pool *TxPool) AddLocals(txs []..
|
||
# core/tx_pool.go(883): func (pool *TxPool) AddRemotes(txs []..
|
||
proc add*(xp: TxPoolRef; tx: Transaction; info = "")
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Variant of `add()` for a single transaction.
|
||
xp.add(@[tx], info)
|
||
|
||
proc smartHead*(xp: TxPoolRef; pos: BlockHeader; blindMode = false): bool
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## This function moves the internal head cache (i.e. tx insertion point,
|
||
## vmState) and ponts it to a now block on the chain.
|
||
##
|
||
## In standard mode when argument `blindMode` is `false`, it calculates the
|
||
## txs that need to be added or deleted after moving the insertion point
|
||
## head so that the tx-pool will not fail to re-insert quered txs that are
|
||
## on the chain, already. Neither will it loose any txs. After updating the
|
||
## the internal head cache, the previously calculated actions will be
|
||
## applied.
|
||
##
|
||
## If the argument `blindMode` is passed `true`, the insertion head is
|
||
## simply set ignoring all changes. This mode makes sense only in very
|
||
## particular circumstances.
|
||
if blindMode:
|
||
xp.sethead(pos)
|
||
return true
|
||
|
||
let rcDiff = xp.headDiff(pos)
|
||
if rcDiff.isOk:
|
||
let changes = rcDiff.value
|
||
|
||
# Need to move head before adding txs which may rightly be rejected in
|
||
# `addTxs()` otherwise.
|
||
xp.sethead(pos)
|
||
|
||
# Re-inject transactions, do that via job queue
|
||
if 0 < changes.addTxs.len:
|
||
debug "queuing delta txs",
|
||
mode = "inject",
|
||
num = changes.addTxs.len
|
||
xp.pDoubleCheckAdd xp.addTxs(toSeq(changes.addTxs.nextValues)).topItems
|
||
|
||
# Delete already *mined* transactions
|
||
if 0 < changes.remTxs.len:
|
||
debug "queuing delta txs",
|
||
mode = "remove",
|
||
num = changes.remTxs.len
|
||
xp.disposeById(toSeq(changes.remTxs.keys), txInfoChainHeadUpdate)
|
||
|
||
xp.maintenanceProcessing
|
||
return true
|
||
|
||
proc triggerReorg*(xp: TxPoolRef)
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## This function triggers a tentative bucket re-org action by setting the
|
||
## `dirtyBuckets` parameter. This re-org action eventually happens only if
|
||
## the `autoUpdateBucketsDB` flag is also set.
|
||
xp.pDirtyBuckets = true
|
||
xp.maintenanceProcessing
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Public functions, getters
|
||
# ------------------------------------------------------------------------------
|
||
|
||
proc com*(xp: TxPoolRef): CommonRef =
|
||
## Getter
|
||
xp.chain.com
|
||
|
||
proc baseFee*(xp: TxPoolRef): GasPrice =
|
||
## Getter, this parameter modifies/determines the expected gain when packing
|
||
xp.chain.baseFee
|
||
|
||
proc dirtyBuckets*(xp: TxPoolRef): bool =
|
||
## Getter, bucket database is ready for re-org if the `autoUpdateBucketsDB`
|
||
## flag is also set.
|
||
xp.pDirtyBuckets
|
||
|
||
proc ethBlock*(xp: TxPoolRef, someBaseFee: bool = false): EthBlock
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Getter, retrieves a packed block ready for mining and signing depending
|
||
## on the internally cached block chain head, the txs in the pool and some
|
||
## tuning parameters. The following block header fields are left
|
||
## uninitialised:
|
||
##
|
||
## * *extraData*: Blob
|
||
## * *mixDigest*: Hash256
|
||
## * *nonce*: BlockNonce
|
||
##
|
||
## Note that this getter runs *ad hoc* all the txs through the VM in
|
||
## order to build the block.
|
||
|
||
xp.packerVmExec # updates vmState
|
||
result.header = xp.chain.getHeader # uses updated vmState
|
||
for (_,nonceList) in xp.txDB.packingOrderAccounts(txItemPacked):
|
||
result.txs.add toSeq(nonceList.incNonce).mapIt(it.tx)
|
||
|
||
let com = xp.chain.com
|
||
if com.forkGTE(Shanghai):
|
||
result.withdrawals = some(xp.chain.withdrawals)
|
||
|
||
if someBaseFee:
|
||
# make sure baseFee always has something
|
||
result.header.fee = some(result.header.fee.get(0.u256))
|
||
|
||
proc gasCumulative*(xp: TxPoolRef): GasInt =
|
||
## Getter, retrieves the gas that will be burned in the block after
|
||
## retrieving it via `ethBlock`.
|
||
xp.chain.gasUsed
|
||
|
||
proc gasTotals*(xp: TxPoolRef): TxTabsGasTotals =
|
||
## Getter, retrieves the current gas limit totals per bucket.
|
||
xp.txDB.gasTotals
|
||
|
||
proc lwmTrgPercent*(xp: TxPoolRef): int =
|
||
## Getter, `trgGasLimit` percentage for `lwmGasLimit` which is
|
||
## `max(minGasLimit, trgGasLimit * lwmTrgPercent / 100)`
|
||
xp.chain.lhwm.lwmTrg
|
||
|
||
proc flags*(xp: TxPoolRef): set[TxPoolFlags] =
|
||
## Getter, retrieves strategy symbols for how to process items and buckets.
|
||
xp.pFlags
|
||
|
||
proc head*(xp: TxPoolRef): BlockHeader =
|
||
## Getter, cached block chain insertion point. Typocally, this should be the
|
||
## the same header as retrieved by the `getCanonicalHead()` (unless in the
|
||
## middle of a mining update.)
|
||
xp.chain.head
|
||
|
||
proc hwmMaxPercent*(xp: TxPoolRef): int =
|
||
## Getter, `maxGasLimit` percentage for `hwmGasLimit` which is
|
||
## `max(trgGasLimit, maxGasLimit * hwmMaxPercent / 100)`
|
||
xp.chain.lhwm.hwmMax
|
||
|
||
proc maxGasLimit*(xp: TxPoolRef): GasInt =
|
||
## Getter, hard size limit when packing blocks (see also `trgGasLimit`.)
|
||
xp.chain.limits.maxLimit
|
||
|
||
# core/tx_pool.go(435): func (pool *TxPool) GasPrice() *big.Int {
|
||
proc minFeePrice*(xp: TxPoolRef): GasPrice =
|
||
## Getter, retrieves minimum for the current gas fee enforced by the
|
||
## transaction pool for txs to be packed. This is an EIP-1559 only
|
||
## parameter (see `stage1559MinFee` strategy.)
|
||
xp.pMinFeePrice
|
||
|
||
proc minPreLondonGasPrice*(xp: TxPoolRef): GasPrice =
|
||
## Getter. retrieves, the current gas price enforced by the transaction
|
||
## pool. This is a pre-London parameter (see `packedPlMinPrice` strategy.)
|
||
xp.pMinPlGasPrice
|
||
|
||
proc minTipPrice*(xp: TxPoolRef): GasPrice =
|
||
## Getter, retrieves minimum for the current gas tip (or priority fee)
|
||
## enforced by the transaction pool. This is an EIP-1559 parameter but it
|
||
## comes with a fall back interpretation (see `stage1559MinTip` strategy.)
|
||
## for legacy transactions.
|
||
xp.pMinTipPrice
|
||
|
||
# core/tx_pool.go(474): func (pool SetGasPrice,*TxPool) Stats() (int, int) {
|
||
# core/tx_pool.go(1728): func (t *txLookup) Count() int {
|
||
# core/tx_pool.go(1737): func (t *txLookup) LocalCount() int {
|
||
# core/tx_pool.go(1745): func (t *txLookup) RemoteCount() int {
|
||
proc nItems*(xp: TxPoolRef): TxTabsItemsCount =
|
||
## Getter, retrieves the current number of items per bucket and
|
||
## some totals.
|
||
xp.txDB.nItems
|
||
|
||
proc profitability*(xp: TxPoolRef): GasPrice =
|
||
## Getter, a calculation of the average *price* per gas to be rewarded after
|
||
## packing the last block (see `ethBlock`). This *price* is only based on
|
||
## execution transaction in the VM without *PoW* specific rewards. The net
|
||
## profit (as opposed to the *PoW/PoA* specifc *reward*) can be calculated
|
||
## as `gasCumulative * profitability`.
|
||
if 0 < xp.chain.gasUsed:
|
||
(xp.chain.profit div xp.chain.gasUsed.u256).truncate(uint64).GasPrice
|
||
else:
|
||
0.GasPrice
|
||
|
||
proc trgGasLimit*(xp: TxPoolRef): GasInt =
|
||
## Getter, soft size limit when packing blocks (might be extended to
|
||
## `maxGasLimit`)
|
||
xp.chain.limits.trgLimit
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Public functions, setters
|
||
# ------------------------------------------------------------------------------
|
||
|
||
proc `baseFee=`*(xp: TxPoolRef; val: GasPrice)
|
||
{.gcsafe,raises: [KeyError].} =
|
||
## Setter, sets `baseFee` explicitely witout triggering a packer update.
|
||
## Stil a database update might take place when updating account ranks.
|
||
##
|
||
## Typically, this function would *not* be called but rather the `smartHead()`
|
||
## update would be employed to do the job figuring out the proper value
|
||
## for the `baseFee`.
|
||
xp.txDB.baseFee = val
|
||
xp.chain.baseFee = val
|
||
|
||
proc `lwmTrgPercent=`*(xp: TxPoolRef; val: int) =
|
||
## Setter, `val` arguments outside `0..100` are ignored
|
||
if 0 <= val and val <= 100:
|
||
xp.chain.lhwm = (
|
||
lwmTrg: val,
|
||
hwmMax: xp.chain.lhwm.hwmMax,
|
||
gasFloor: xp.chain.lhwm.gasFloor,
|
||
gasCeil: xp.chain.lhwm.gasCeil
|
||
)
|
||
|
||
proc `flags=`*(xp: TxPoolRef; val: set[TxPoolFlags]) =
|
||
## Setter, strategy symbols for how to process items and buckets.
|
||
xp.pFlags = val
|
||
|
||
proc `hwmMaxPercent=`*(xp: TxPoolRef; val: int) =
|
||
## Setter, `val` arguments outside `0..100` are ignored
|
||
if 0 <= val and val <= 100:
|
||
xp.chain.lhwm = (
|
||
lwmTrg: xp.chain.lhwm.lwmTrg,
|
||
hwmMax: val,
|
||
gasFloor: xp.chain.lhwm.gasFloor,
|
||
gasCeil: xp.chain.lhwm.gasCeil
|
||
)
|
||
|
||
proc `maxRejects=`*(xp: TxPoolRef; val: int) =
|
||
## Setter, the size of the waste basket. This setting becomes effective with
|
||
## the next move of an item into the waste basket.
|
||
xp.txDB.maxRejects = val
|
||
|
||
# core/tx_pool.go(444): func (pool *TxPool) SetGasPrice(price *big.Int) {
|
||
proc `minFeePrice=`*(xp: TxPoolRef; val: GasPrice) =
|
||
## Setter for `minFeePrice`. If there was a value change, this function
|
||
## implies `triggerReorg()`.
|
||
if xp.pMinFeePrice != val:
|
||
xp.pMinFeePrice = val
|
||
xp.pDirtyBuckets = true
|
||
|
||
# core/tx_pool.go(444): func (pool *TxPool) SetGasPrice(price *big.Int) {
|
||
proc `minPreLondonGasPrice=`*(xp: TxPoolRef; val: GasPrice) =
|
||
## Setter for `minPlGasPrice`. If there was a value change, this function
|
||
## implies `triggerReorg()`.
|
||
if xp.pMinPlGasPrice != val:
|
||
xp.pMinPlGasPrice = val
|
||
xp.pDirtyBuckets = true
|
||
|
||
# core/tx_pool.go(444): func (pool *TxPool) SetGasPrice(price *big.Int) {
|
||
proc `minTipPrice=`*(xp: TxPoolRef; val: GasPrice) =
|
||
## Setter for `minTipPrice`. If there was a value change, this function
|
||
## implies `triggerReorg()`.
|
||
if xp.pMinTipPrice != val:
|
||
xp.pMinTipPrice = val
|
||
xp.pDirtyBuckets = true
|
||
|
||
proc `withdrawals=`*(xp: TxPoolRef, val: sink seq[Withdrawal]) =
|
||
xp.chain.withdrawals = system.move(val)
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Public functions, per-tx-item operations
|
||
# ------------------------------------------------------------------------------
|
||
|
||
# core/tx_pool.go(979): func (pool *TxPool) Get(hash common.Hash) ..
|
||
# core/tx_pool.go(985): func (pool *TxPool) Has(hash common.Hash) bool {
|
||
proc getItem*(xp: TxPoolRef; hash: Hash256): Result[TxItemRef,void] =
|
||
## Returns a transaction if it is contained in the pool.
|
||
xp.txDB.byItemID.eq(hash)
|
||
|
||
proc disposeItems*(xp: TxPoolRef; item: TxItemRef;
|
||
reason = txInfoExplicitDisposal;
|
||
otherReason = txInfoImpliedDisposal): int
|
||
{.discardable,gcsafe,raises: [CatchableError].} =
|
||
## Move item to wastebasket. All items for the same sender with nonces
|
||
## greater than the current one are deleted, as well. The function returns
|
||
## the number of items eventally removed.
|
||
xp.disposeItemAndHigherNonces(item, reason, otherReason)
|
||
|
||
iterator txHashes*(xp: TxPoolRef): Hash256 =
|
||
for txHash in nextKeys(xp.txDB.byItemID):
|
||
yield txHash
|
||
|
||
iterator okPairs*(xp: TxPoolRef): (Hash256, TxItemRef) =
|
||
for x in nextPairs(xp.txDB.byItemID):
|
||
if x.data.reject == txInfoOk:
|
||
yield (x.key, x.data)
|
||
|
||
proc numTxs*(xp: TxPoolRef): int =
|
||
xp.txDB.byItemID.len
|
||
|
||
proc disposeAll*(xp: TxpoolRef) {.gcsafe,raises: [CatchableError].} =
|
||
let numTx = xp.numTxs
|
||
var list = newSeqOfCap[TxItemRef](numTx)
|
||
for x in nextPairs(xp.txDB.byItemID):
|
||
list.add x.data
|
||
for x in list:
|
||
xp.disposeItems(x)
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# Public functions, local/remote accounts
|
||
# ------------------------------------------------------------------------------
|
||
|
||
proc isLocal*(xp: TxPoolRef; account: EthAddress): bool =
|
||
## This function returns `true` if argument `account` is tagged local.
|
||
xp.txDB.isLocal(account)
|
||
|
||
proc setLocal*(xp: TxPoolRef; account: EthAddress) =
|
||
## Tag argument `account` local which means that the transactions from this
|
||
## account -- together with all other local accounts -- will be considered
|
||
## first for packing.
|
||
xp.txDB.setLocal(account)
|
||
|
||
proc resLocal*(xp: TxPoolRef; account: EthAddress) =
|
||
## Untag argument `account` as local which means that the transactions from
|
||
## this account -- together with all other untagged accounts -- will be
|
||
## considered for packing after the locally tagged accounts.
|
||
xp.txDB.resLocal(account)
|
||
|
||
proc flushLocals*(xp: TxPoolRef) =
|
||
## Untag all *local* addresses on the system.
|
||
xp.txDB.flushLocals
|
||
|
||
proc accountRanks*(xp: TxPoolRef): TxTabsLocality =
|
||
## Returns two lists, one for local and the other for non-local accounts.
|
||
## Any of these lists is sorted by the highest rank first. This sorting
|
||
## means that the order may be out-dated after adding transactions.
|
||
xp.txDB.locality
|
||
|
||
proc addRemote*(xp: TxPoolRef;
|
||
tx: Transaction; force = false): Result[void,TxInfo]
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Adds the argument transaction `tx` to the buckets database.
|
||
##
|
||
## If the argument `force` is set `false` and the sender account of the
|
||
## argument transaction is tagged local, this function returns with an error.
|
||
## If the argument `force` is set `true`, the sender account will be untagged,
|
||
## i.e. made non-local.
|
||
##
|
||
## Note: This function is rather inefficient if there are more than one
|
||
## txs to be added for a known account. The preferable way to do this
|
||
## would be to use a combination of `xp.add()` and `xp.resLocal()` in any
|
||
## order.
|
||
# Create or recover new item. This will wrap the argument `tx` and cache
|
||
# the sender account and other derived data accessible.
|
||
let rc = xp.recoverItem(
|
||
tx, txItemPending, "remote tx peek", acceptExisting = true)
|
||
if rc.isErr:
|
||
return err(rc.error)
|
||
|
||
# Temporarily stash the item in the rubbish bin to be recovered, later
|
||
let sender = rc.value.sender
|
||
discard xp.txDB.dispose(rc.value, txInfoTxStashed)
|
||
|
||
# Verify local/remote account
|
||
if force:
|
||
xp.txDB.resLocal(sender)
|
||
elif xp.txDB.isLocal(sender):
|
||
return err(txInfoTxErrorRemoteExpected)
|
||
|
||
xp.add(tx, "remote tx")
|
||
ok()
|
||
|
||
proc addLocal*(xp: TxPoolRef;
|
||
tx: Transaction; force = false): Result[void,TxInfo]
|
||
{.gcsafe,raises: [CatchableError].} =
|
||
## Adds the argument transaction `tx` to the buckets database.
|
||
##
|
||
## If the argument `force` is set `false` and the sender account of the
|
||
## argument transaction is _not_ tagged local, this function returns with
|
||
## an error. If the argument `force` is set `true`, the sender account will
|
||
## be tagged local.
|
||
##
|
||
## Note: This function is rather inefficient if there are more than one
|
||
## txs to be added for a known account. The preferable way to do this
|
||
## would be to use a combination of `xp.add()` and `xp.setLocal()` in any
|
||
## order.
|
||
# Create or recover new item. This will wrap the argument `tx` and cache
|
||
# the sender account and other derived data accessible.
|
||
let rc = xp.recoverItem(
|
||
tx, txItemPending, "local tx peek", acceptExisting = true)
|
||
if rc.isErr:
|
||
return err(rc.error)
|
||
|
||
# Temporarily stash the item in the rubbish bin to be recovered, later
|
||
let sender = rc.value.sender
|
||
discard xp.txDB.dispose(rc.value, txInfoTxStashed)
|
||
|
||
# Verify local/remote account
|
||
if force:
|
||
xp.txDB.setLocal(sender)
|
||
elif not xp.txDB.isLocal(sender):
|
||
return err(txInfoTxErrorLocalExpected)
|
||
|
||
xp.add(tx, "local tx")
|
||
ok()
|
||
|
||
proc inPoolAndOk*(xp: TxPoolRef; txHash: Hash256): bool =
|
||
let res = xp.getItem(txHash)
|
||
if res.isErr: return false
|
||
res.get().reject == txInfoOk
|
||
|
||
# ------------------------------------------------------------------------------
|
||
# End
|
||
# ------------------------------------------------------------------------------
|