fork.py (in diffs/osaka/bpo1)

ethereum.forks.osaka.forkethereum.forks.bpo1.fork

Ethereum Specification.

.. contents:: Table of Contents :backlinks: none :local:

Introduction

Entry point for the Ethereum specification.

BASE_FEE_MAX_CHANGE_DENOMINATOR ¶

98	BASE_FEE_MAX_CHANGE_DENOMINATOR = Uint(8)

ELASTICITY_MULTIPLIER ¶

99	ELASTICITY_MULTIPLIER = Uint(2)

EMPTY_OMMER_HASH ¶

100	EMPTY_OMMER_HASH = keccak256(rlp.encode([]))

SYSTEM_ADDRESS ¶

101	SYSTEM_ADDRESS = hex_to_address("0xfffffffffffffffffffffffffffffffffffffffe")

BEACON_ROOTS_ADDRESS ¶

102	BEACON_ROOTS_ADDRESS = hex_to_address(
103	"0x000F3df6D732807Ef1319fB7B8bB8522d0Beac02"
104	)

SYSTEM_TRANSACTION_GAS ¶

105	SYSTEM_TRANSACTION_GAS = Uint(30000000)

MAX_BLOB_GAS_PER_BLOCK ¶

106	MAX_BLOB_GAS_PER_BLOCK: Final[U64] = (
107	GasCosts.BLOB_SCHEDULE_MAX * GasCosts.PER_BLOB
108	)

VERSIONED_HASH_VERSION_KZG ¶

109	VERSIONED_HASH_VERSION_KZG = b"\x01"

WITHDRAWAL_REQUEST_PREDEPLOY_ADDRESS ¶

111	WITHDRAWAL_REQUEST_PREDEPLOY_ADDRESS = hex_to_address(
112	"0x00000961Ef480Eb55e80D19ad83579A64c007002"
113	)

CONSOLIDATION_REQUEST_PREDEPLOY_ADDRESS ¶

114	CONSOLIDATION_REQUEST_PREDEPLOY_ADDRESS = hex_to_address(
115	"0x0000BBdDc7CE488642fb579F8B00f3a590007251"
116	)

HISTORY_STORAGE_ADDRESS ¶

117	HISTORY_STORAGE_ADDRESS = hex_to_address(
118	"0x0000F90827F1C53a10cb7A02335B175320002935"
119	)

MAX_BLOCK_SIZE ¶

120	MAX_BLOCK_SIZE = 10_485_760

SAFETY_MARGIN ¶

121	SAFETY_MARGIN = 2_097_152

MAX_RLP_BLOCK_SIZE ¶

122	MAX_RLP_BLOCK_SIZE = MAX_BLOCK_SIZE - SAFETY_MARGIN

BLOB_COUNT_LIMIT ¶

123	BLOB_COUNT_LIMIT = 6

BlockChain ¶

History and current state of the block chain.

126	@dataclass

class BlockChain:

blocks ¶

132	blocks: List[Block]

state ¶

133	state: State

chain_id ¶

134	chain_id: U64

apply_fork ¶

Transforms the state from the previous hard fork (old) into the block chain object for this hard fork and returns it.

When forks need to implement an irregular state transition, this function is used to handle the irregularity. See the :ref:DAO Fork <dao-fork> for an example.

Parameters

old : Previous block chain object.

Returns

new : BlockChain Upgraded block chain object for this hard fork.

def apply_fork(old: BlockChain) -> BlockChain:

138	<snip>
157	return old

get_last_256_block_hashes ¶

Obtain the list of hashes of the previous 256 blocks in order of increasing block number.

This function will return less hashes for the first 256 blocks.

The BLOCKHASH opcode needs to access the latest hashes on the chain, therefore this function retrieves them.

Parameters

chain : History and current state.

Returns

recent_block_hashes : List[Hash32] Hashes of the recent 256 blocks in order of increasing block number.

def get_last_256_block_hashes(chain: BlockChain) -> List[Hash32]:

161	<snip>
181	recent_blocks = chain.blocks[-255:]
182	# TODO: This function has not been tested rigorously
183	if len(recent_blocks) == 0:
184	return []
185
186	recent_block_hashes = []
187
188	for block in recent_blocks:
189	prev_block_hash = block.header.parent_hash
190	recent_block_hashes.append(prev_block_hash)
191
192	# We are computing the hash only for the most recent block and not for
193	# the rest of the blocks as they have successors which have the hash of
194	# the current block as parent hash.
195	most_recent_block_hash = keccak256(rlp.encode(recent_blocks[-1].header))
196	recent_block_hashes.append(most_recent_block_hash)
197
198	return recent_block_hashes

state_transition ¶

Attempts to apply a block to an existing block chain.

All parts of the block's contents need to be verified before being added to the chain. Blocks are verified by ensuring that the contents of the block make logical sense with the contents of the parent block. The information in the block's header must also match the corresponding information in the block.

To implement Ethereum, in theory clients are only required to store the most recent 255 blocks of the chain since as far as execution is concerned, only those blocks are accessed. Practically, however, clients should store more blocks to handle reorgs.

Parameters

chain : History and current state. block : Block to apply to chain.

def state_transition(chain: BlockChain, block: Block) -> None:

202	<snip>
224	if len(rlp.encode(block)) > MAX_RLP_BLOCK_SIZE:
225	raise InvalidBlock("Block rlp size exceeds MAX_RLP_BLOCK_SIZE")
226
227	validate_header(chain, block.header)
228	if block.ommers != ():
229	raise InvalidBlock
230
231	block_state = BlockState(pre_state=chain.state)
232
233	block_env = vm.BlockEnvironment(
234	chain_id=chain.chain_id,
235	state=block_state,
236	block_gas_limit=block.header.gas_limit,
237	block_hashes=get_last_256_block_hashes(chain),
238	coinbase=block.header.coinbase,
239	number=block.header.number,
240	base_fee_per_gas=block.header.base_fee_per_gas,
241	time=block.header.timestamp,
242	prev_randao=block.header.prev_randao,
243	excess_blob_gas=block.header.excess_blob_gas,
244	parent_beacon_block_root=block.header.parent_beacon_block_root,
245	)
246
247	block_output = apply_body(
248	block_env=block_env,
249	transactions=block.transactions,
250	withdrawals=block.withdrawals,
251	)
252	block_diff = extract_block_diff(block_state)
253	block_state_root, _ = chain.state.compute_state_root_and_trie_changes(
254	block_diff.account_changes, block_diff.storage_changes
255	)
256	transactions_root = root(block_output.transactions_trie)
257	receipt_root = root(block_output.receipts_trie)
258	block_logs_bloom = logs_bloom(block_output.block_logs)
259	withdrawals_root = root(block_output.withdrawals_trie)
260	requests_hash = compute_requests_hash(block_output.requests)
261
262	if block_output.block_gas_used != block.header.gas_used:
263	raise InvalidBlock(
264	f"{block_output.block_gas_used} != {block.header.gas_used}"
265	)
266	if transactions_root != block.header.transactions_root:
267	raise InvalidBlock
268	if block_state_root != block.header.state_root:
269	raise InvalidBlock
270	if receipt_root != block.header.receipt_root:
271	raise InvalidBlock
272	if block_logs_bloom != block.header.bloom:
273	raise InvalidBlock
274	if withdrawals_root != block.header.withdrawals_root:
275	raise InvalidBlock
276	if block_output.blob_gas_used != block.header.blob_gas_used:
277	raise InvalidBlock
278	if requests_hash != block.header.requests_hash:
279	raise InvalidBlock
280
281	apply_changes_to_state(chain.state, block_diff)
282	chain.blocks.append(block)
283	if len(chain.blocks) > 255:
284	# Real clients have to store more blocks to deal with reorgs, but the
285	# protocol only requires the last 255
286	chain.blocks = chain.blocks[-255:]

calculate_base_fee_per_gas ¶

Calculates the base fee per gas for the block.

Parameters

block_gas_limit : Gas limit of the block for which the base fee is being calculated. parent_gas_limit : Gas limit of the parent block. parent_gas_used : Gas used in the parent block. parent_base_fee_per_gas : Base fee per gas of the parent block.

Returns

base_fee_per_gas : Uint Base fee per gas for the block.

def calculate_base_fee_per_gas(block_gas_limit: Uint, parent_gas_limit: Uint, parent_gas_used: Uint, parent_base_fee_per_gas: Uint) -> Uint:

295	<snip>
315	parent_gas_target = parent_gas_limit // ELASTICITY_MULTIPLIER
316	if not check_gas_limit(block_gas_limit, parent_gas_limit):
317	raise InvalidBlock
318
319	if parent_gas_used == parent_gas_target:
320	expected_base_fee_per_gas = parent_base_fee_per_gas
321	elif parent_gas_used > parent_gas_target:
322	gas_used_delta = parent_gas_used - parent_gas_target
323
324	parent_fee_gas_delta = parent_base_fee_per_gas * gas_used_delta
325	target_fee_gas_delta = parent_fee_gas_delta // parent_gas_target
326
327	base_fee_per_gas_delta = max(
328	target_fee_gas_delta // BASE_FEE_MAX_CHANGE_DENOMINATOR,
329	Uint(1),
330	)
331
332	expected_base_fee_per_gas = (
333	parent_base_fee_per_gas + base_fee_per_gas_delta
334	)
335	else:
336	gas_used_delta = parent_gas_target - parent_gas_used
337
338	parent_fee_gas_delta = parent_base_fee_per_gas * gas_used_delta
339	target_fee_gas_delta = parent_fee_gas_delta // parent_gas_target
340
341	base_fee_per_gas_delta = (
342	target_fee_gas_delta // BASE_FEE_MAX_CHANGE_DENOMINATOR
343	)
344
345	expected_base_fee_per_gas = (
346	parent_base_fee_per_gas - base_fee_per_gas_delta
347	)
348
349	return Uint(expected_base_fee_per_gas)

validate_header ¶

Verifies a block header.

In order to consider a block's header valid, the logic for the quantities in the header should match the logic for the block itself. For example the header timestamp should be greater than the block's parent timestamp because the block was created after the parent block. Additionally, the block's number should be directly following the parent block's number since it is the next block in the sequence.

Parameters

chain : History and current state. header : Header to check for correctness.

def validate_header(chain: BlockChain, header: Header) -> None:

353	<snip>
371	if header.number < Uint(1):
372	raise InvalidBlock
373
374	parent_header = chain.blocks[-1].header
375
376	excess_blob_gas = calculate_excess_blob_gas(parent_header)
377	if header.excess_blob_gas != excess_blob_gas:
378	raise InvalidBlock
379
380	if header.gas_used > header.gas_limit:
381	raise InvalidBlock
382
383	expected_base_fee_per_gas = calculate_base_fee_per_gas(
384	header.gas_limit,
385	parent_header.gas_limit,
386	parent_header.gas_used,
387	parent_header.base_fee_per_gas,
388	)
389	if expected_base_fee_per_gas != header.base_fee_per_gas:
390	raise InvalidBlock
391	if header.timestamp <= parent_header.timestamp:
392	raise InvalidBlock
393	if header.number != parent_header.number + Uint(1):
394	raise InvalidBlock
395	if len(header.extra_data) > 32:
396	raise InvalidBlock
397	if header.difficulty != 0:
398	raise InvalidBlock
399	if header.nonce != b"\x00\x00\x00\x00\x00\x00\x00\x00":
400	raise InvalidBlock
401	if header.ommers_hash != EMPTY_OMMER_HASH:
402	raise InvalidBlock
403
404	block_parent_hash = keccak256(rlp.encode(parent_header))
405	if header.parent_hash != block_parent_hash:
406	raise InvalidBlock

check_transaction ¶

Check if the transaction is includable in the block.

Parameters

block_env : The block scoped environment. block_output : The block output for the current block. tx : The transaction. tx_state : The transaction state tracker.

Returns

sender_address : The sender of the transaction. effective_gas_price : The price to charge for gas when the transaction is executed. blob_versioned_hashes : The blob versioned hashes of the transaction. tx_blob_gas_used: The blob gas used by the transaction.

Raises

InvalidBlock : If the transaction is not includable. GasUsedExceedsLimitError : If the gas used by the transaction exceeds the block's gas limit. NonceMismatchError : If the nonce of the transaction is not equal to the sender's nonce. InsufficientBalanceError : If the sender's balance is not enough to pay for the transaction. InvalidSenderError : If the transaction is from an address that does not exist anymore. PriorityFeeGreaterThanMaxFeeError : If the priority fee is greater than the maximum fee per gas. InsufficientMaxFeePerGasError : If the maximum fee per gas is insufficient for the transaction. InsufficientMaxFeePerBlobGasError : If the maximum fee per blob gas is insufficient for the transaction. BlobGasLimitExceededError : If the blob gas used by the transaction exceeds the block's blob gas limit. InvalidBlobVersionedHashError : If the transaction contains a blob versioned hash with an invalid version. NoBlobDataError : If the transaction is a type 3 but has no blobs. BlobCountExceededError : If the transaction is a type 3 and has more blobs than the limit. TransactionTypeContractCreationError: If the transaction type is not allowed to create contracts. EmptyAuthorizationListError : If the transaction is a SetCodeTransaction and the authorization list is empty.

def check_transaction(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, block_output: ethereum.forks.osaka.vm.BlockOutputethereum.forks.bpo1.vm.BlockOutput, tx: Transaction, tx_state: TransactionState) -> Tuple[Address, Uint, Tuple[VersionedHash, ...], U64]:

415	<snip>
475	gas_available = block_env.block_gas_limit - block_output.block_gas_used
476	blob_gas_available = MAX_BLOB_GAS_PER_BLOCK - block_output.blob_gas_used
477
478	if tx.gas > gas_available:
479	raise GasUsedExceedsLimitError("gas used exceeds limit")
480
481	tx_blob_gas_used = calculate_total_blob_gas(tx)
482	if tx_blob_gas_used > blob_gas_available:
483	raise BlobGasLimitExceededError("blob gas limit exceeded")
484
485	sender_address = recover_sender(block_env.chain_id, tx)
486	sender_account = get_account(tx_state, sender_address)
487
488	if isinstance(
489	tx, (FeeMarketTransaction, BlobTransaction, SetCodeTransaction)
490	):
491	if tx.max_fee_per_gas < tx.max_priority_fee_per_gas:
492	raise PriorityFeeGreaterThanMaxFeeError(
493	"priority fee greater than max fee"
494	)
495	if tx.max_fee_per_gas < block_env.base_fee_per_gas:
496	raise InsufficientMaxFeePerGasError(
497	tx.max_fee_per_gas, block_env.base_fee_per_gas
498	)
499
500	priority_fee_per_gas = min(
501	tx.max_priority_fee_per_gas,
502	tx.max_fee_per_gas - block_env.base_fee_per_gas,
503	)
504	effective_gas_price = priority_fee_per_gas + block_env.base_fee_per_gas
505	max_gas_fee = tx.gas * tx.max_fee_per_gas
506	else:
507	if tx.gas_price < block_env.base_fee_per_gas:
508	raise InvalidBlock
509	effective_gas_price = tx.gas_price
510	max_gas_fee = tx.gas * tx.gas_price
511
512	if isinstance(tx, BlobTransaction):
513	blob_count = len(tx.blob_versioned_hashes)
514	if blob_count == 0:
515	raise NoBlobDataError("no blob data in transaction")
516	if blob_count > BLOB_COUNT_LIMIT:
517	raise BlobCountExceededError(
518	f"Tx has {blob_count} blobs. Max allowed: {BLOB_COUNT_LIMIT}"
519	)
520	for blob_versioned_hash in tx.blob_versioned_hashes:
521	if blob_versioned_hash[0:1] != VERSIONED_HASH_VERSION_KZG:
522	raise InvalidBlobVersionedHashError(
523	"invalid blob versioned hash"
524	)
525
526	blob_gas_price = calculate_blob_gas_price(block_env.excess_blob_gas)
527	if Uint(tx.max_fee_per_blob_gas) < blob_gas_price:
528	raise InsufficientMaxFeePerBlobGasError(
529	"insufficient max fee per blob gas"
530	)
531
532	max_gas_fee += Uint(calculate_total_blob_gas(tx)) * Uint(
533	tx.max_fee_per_blob_gas
534	)
535	blob_versioned_hashes = tx.blob_versioned_hashes
536	else:
537	blob_versioned_hashes = ()
538
539	if isinstance(tx, (BlobTransaction, SetCodeTransaction)):
540	if not isinstance(tx.to, Address):
541	raise TransactionTypeContractCreationError(tx)
542
543	if isinstance(tx, SetCodeTransaction):
544	if not any(tx.authorizations):
545	raise EmptyAuthorizationListError("empty authorization list")
546
547	if sender_account.nonce > Uint(tx.nonce):
548	raise NonceMismatchError("nonce too low")
549	elif sender_account.nonce < Uint(tx.nonce):
550	raise NonceMismatchError("nonce too high")
551
552	if Uint(sender_account.balance) < max_gas_fee + Uint(tx.value):
553	raise InsufficientBalanceError("insufficient sender balance")
554	sender_code = get_code(tx_state, sender_account.code_hash)
555	if sender_account.code_hash != EMPTY_CODE_HASH and not is_valid_delegation(
556	sender_code
557	):
558	raise InvalidSenderError("not EOA")
559
560	return (
561	sender_address,
562	effective_gas_price,
563	blob_versioned_hashes,
564	tx_blob_gas_used,
565	)

make_receipt ¶

Make the receipt for a transaction that was executed.

Parameters

tx : The executed transaction. error : Error in the top level frame of the transaction, if any. cumulative_gas_used : The total gas used so far in the block after the transaction was executed. logs : The logs produced by the transaction.

Returns

receipt : The receipt for the transaction.

def make_receipt(tx: Transaction, error: Optional[EthereumException], cumulative_gas_used: Uint, logs: Tuple[Log, ...]) -> Bytes | Receipt:

574	<snip>
595	receipt = Receipt(
596	succeeded=error is None,
597	cumulative_gas_used=cumulative_gas_used,
598	bloom=logs_bloom(logs),
599	logs=logs,
600	)
601
602	return encode_receipt(tx, receipt)

process_checked_system_transaction ¶

Process a system transaction and raise an error if the contract does not contain code or if the transaction fails.

Parameters

block_env : The block scoped environment. target_address : Address of the contract to call. data : Data to pass to the contract.

Returns

system_tx_output : MessageCallOutput Output of processing the system transaction.

def process_checked_system_transaction(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, target_address: Address, data: Bytes) -> MessageCallOutput:

610	<snip>
629	# Pre-check that the system contract has code. We use a throwaway
630	# TransactionState here that is never propagated back to BlockState
631	# (no incorporate_tx_into_block call); the same get_account / get_code
632	# lookups are performed and properly tracked by
633	# process_unchecked_system_transaction below, which this function
634	# always calls. Reading via a TransactionState (rather than directly
635	# against pre_state) lets us see system contracts deployed earlier in
636	# the same block — see EIP-7002 and EIP-7251 for this edge case.
637	untracked_state = TransactionState(parent=block_env.state)
638	system_contract_code = get_code(
639	untracked_state,
640	get_account(untracked_state, target_address).code_hash,
641	)
642
643	if len(system_contract_code) == 0:
644	raise InvalidBlock(
645	f"System contract address {target_address.hex()} does not "
646	"contain code"
647	)
648
649	system_tx_output = process_unchecked_system_transaction(
650	block_env,
651	target_address,
652	data,
653	)
654
655	if system_tx_output.error:
656	raise InvalidBlock(
657	f"System contract ({target_address.hex()}) call failed: "
658	f"{system_tx_output.error}"
659	)
660
661	return system_tx_output

process_unchecked_system_transaction ¶

Process a system transaction without checking if the contract contains code or if the transaction fails.

Parameters

block_env : The block scoped environment. target_address : Address of the contract to call. data : Data to pass to the contract.

Returns

system_tx_output : MessageCallOutput Output of processing the system transaction.

def process_unchecked_system_transaction(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, target_address: Address, data: Bytes) -> MessageCallOutput:

669	<snip>
688	system_tx_state = TransactionState(parent=block_env.state)
689	system_contract_code = get_code(
690	system_tx_state,
691	get_account(system_tx_state, target_address).code_hash,
692	)
693
694	tx_env = vm.TransactionEnvironment(
695	origin=SYSTEM_ADDRESS,
696	gas_price=block_env.base_fee_per_gas,
697	gas=SYSTEM_TRANSACTION_GAS,
698	access_list_addresses=set(),
699	access_list_storage_keys=set(),
700	state=system_tx_state,
701	blob_versioned_hashes=(),
702	authorizations=(),
703	index_in_block=None,
704	tx_hash=None,
705	)
706
707	system_tx_message = Message(
708	block_env=block_env,
709	tx_env=tx_env,
710	caller=SYSTEM_ADDRESS,
711	target=target_address,
712	gas=SYSTEM_TRANSACTION_GAS,
713	value=U256(0),
714	data=data,
715	code=system_contract_code,
716	depth=Uint(0),
717	current_target=target_address,
718	code_address=target_address,
719	should_transfer_value=False,
720	is_static=False,
721	accessed_addresses=set(),
722	accessed_storage_keys=set(),
723	disable_precompiles=False,
724	parent_evm=None,
725	)
726
727	system_tx_output = process_message_call(system_tx_message)
728
729	incorporate_tx_into_block(system_tx_state)
730
731	return system_tx_output

apply_body ¶

Executes a block.

Many of the contents of a block are stored in data structures called tries. There is a transactions trie which is similar to a ledger of the transactions stored in the current block. There is also a receipts trie which stores the results of executing a transaction, like the post state and gas used. This function creates and executes the block that is to be added to the chain.

Parameters

block_env : The block scoped environment. transactions : Transactions included in the block. withdrawals : Withdrawals to be processed in the current block.

Returns

block_output : The block output for the current block.

def apply_body(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, transactions: Tuple[LegacyTransaction | Bytes, ...], withdrawals: Tuple[Withdrawal, ...]) -> ethereum.forks.osaka.vm.BlockOutputethereum.forks.bpo1.vm.BlockOutput:

739	<snip>
764	block_output = vm.BlockOutput()
765
766	process_unchecked_system_transaction(
767	block_env=block_env,
768	target_address=BEACON_ROOTS_ADDRESS,
769	data=block_env.parent_beacon_block_root,
770	)
771
772	process_unchecked_system_transaction(
773	block_env=block_env,
774	target_address=HISTORY_STORAGE_ADDRESS,
775	data=block_env.block_hashes[-1], # The parent hash
776	)
777
778	for i, tx in enumerate(map(decode_transaction, transactions)):
779	process_transaction(block_env, block_output, tx, Uint(i))
780
781	process_withdrawals(block_env, block_output, withdrawals)
782
783	process_general_purpose_requests(
784	block_env=block_env,
785	block_output=block_output,
786	)
787
788	return block_output

process_general_purpose_requests ¶

Process all the requests in the block.

Parameters

block_env : The execution environment for the Block. block_output : The block output for the current block.

def process_general_purpose_requests(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, block_output: ethereum.forks.osaka.vm.BlockOutputethereum.forks.bpo1.vm.BlockOutput) -> None:

795	<snip>
806	# Requests are to be in ascending order of request type
807	deposit_requests = parse_deposit_requests(block_output)
808	requests_from_execution = block_output.requests
809	if len(deposit_requests) > 0:
810	requests_from_execution.append(DEPOSIT_REQUEST_TYPE + deposit_requests)
811
812	system_withdrawal_tx_output = process_checked_system_transaction(
813	block_env=block_env,
814	target_address=WITHDRAWAL_REQUEST_PREDEPLOY_ADDRESS,
815	data=b"",
816	)
817
818	if len(system_withdrawal_tx_output.return_data) > 0:
819	requests_from_execution.append(
820	WITHDRAWAL_REQUEST_TYPE + system_withdrawal_tx_output.return_data
821	)
822
823	system_consolidation_tx_output = process_checked_system_transaction(
824	block_env=block_env,
825	target_address=CONSOLIDATION_REQUEST_PREDEPLOY_ADDRESS,
826	data=b"",
827	)
828
829	if len(system_consolidation_tx_output.return_data) > 0:
830	requests_from_execution.append(
831	CONSOLIDATION_REQUEST_TYPE
832	+ system_consolidation_tx_output.return_data
833	)

process_transaction ¶

Execute a transaction against the provided environment.

This function processes the actions needed to execute a transaction. It decrements the sender's account balance after calculating the gas fee and refunds them the proper amount after execution. Calling contracts, deploying code, and incrementing nonces are all examples of actions that happen within this function or from a call made within this function.

Accounts that are marked for deletion are processed and destroyed after execution.

Parameters

block_env : Environment for the Ethereum Virtual Machine. block_output : The block output for the current block. tx : Transaction to execute. index: Index of the transaction in the block.

def process_transaction(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, block_output: ethereum.forks.osaka.vm.BlockOutputethereum.forks.bpo1.vm.BlockOutput, tx: Transaction, index: Uint) -> None:

842	<snip>
866	tx_state = TransactionState(parent=block_env.state)
867
868	trie_set(
869	block_output.transactions_trie,
870	rlp.encode(index),
871	encode_transaction(tx),
872	)
873
874	intrinsic_gas, calldata_floor_gas_cost = validate_transaction(tx)
875
876	(
877	sender,
878	effective_gas_price,
879	blob_versioned_hashes,
880	tx_blob_gas_used,
881	) = check_transaction(
882	block_env=block_env,
883	block_output=block_output,
884	tx=tx,
885	tx_state=tx_state,
886	)
887
888	sender_account = get_account(tx_state, sender)
889
890	if isinstance(tx, BlobTransaction):
891	blob_gas_fee = calculate_data_fee(block_env.excess_blob_gas, tx)
892	else:
893	blob_gas_fee = Uint(0)
894
895	effective_gas_fee = tx.gas * effective_gas_price
896
897	gas = tx.gas - intrinsic_gas
898	increment_nonce(tx_state, sender)
899
900	sender_balance_after_gas_fee = (
901	Uint(sender_account.balance) - effective_gas_fee - blob_gas_fee
902	)
903	set_account_balance(tx_state, sender, U256(sender_balance_after_gas_fee))
904
905	access_list_addresses = set()
906	access_list_storage_keys = set()
907	access_list_addresses.add(block_env.coinbase)
908	if has_access_list(tx):
909	for access in tx.access_list:
910	access_list_addresses.add(access.account)
911	for slot in access.slots:
912	access_list_storage_keys.add((access.account, slot))
913
914	authorizations: Tuple[Authorization, ...] = ()
915	if isinstance(tx, SetCodeTransaction):
916	authorizations = tx.authorizations
917
918	tx_env = vm.TransactionEnvironment(
919	origin=sender,
920	gas_price=effective_gas_price,
921	gas=gas,
922	access_list_addresses=access_list_addresses,
923	access_list_storage_keys=access_list_storage_keys,
924	state=tx_state,
925	blob_versioned_hashes=blob_versioned_hashes,
926	authorizations=authorizations,
927	index_in_block=index,
928	tx_hash=get_transaction_hash(encode_transaction(tx)),
929	)
930
931	message = prepare_message(block_env, tx_env, tx)
932
933	tx_output = process_message_call(message)
934
935	# For EIP-7623 we first calculate the execution_gas_used, which includes
936	# the execution gas refund.
937	tx_gas_used_before_refund = tx.gas - tx_output.gas_left
938	tx_gas_refund = min(
939	tx_gas_used_before_refund // Uint(5), Uint(tx_output.refund_counter)
940	)
941	tx_gas_used_after_refund = tx_gas_used_before_refund - tx_gas_refund
942
943	# Transactions with less execution_gas_used than the floor pay at the
944	# floor cost.
945	tx_gas_used_after_refund = max(
946	tx_gas_used_after_refund, calldata_floor_gas_cost
947	)
948
949	tx_gas_left = tx.gas - tx_gas_used_after_refund
950	gas_refund_amount = tx_gas_left * effective_gas_price
951
952	# For non-1559 transactions effective_gas_price == tx.gas_price
953	priority_fee_per_gas = effective_gas_price - block_env.base_fee_per_gas
954	transaction_fee = tx_gas_used_after_refund * priority_fee_per_gas
955
956	# refund gas
957	sender_balance_after_refund = get_account(tx_state, sender).balance + U256(
958	gas_refund_amount
959	)
960	set_account_balance(tx_state, sender, sender_balance_after_refund)
961
962	# transfer miner fees
963	coinbase_balance_after_mining_fee = get_account(
964	tx_state, block_env.coinbase
965	).balance + U256(transaction_fee)
966	set_account_balance(
967	tx_state, block_env.coinbase, coinbase_balance_after_mining_fee
968	)
969
970	for address in tx_output.accounts_to_delete:
971	destroy_account(tx_state, address)
972
973	block_output.block_gas_used += tx_gas_used_after_refund
974	block_output.blob_gas_used += tx_blob_gas_used
975
976	receipt = make_receipt(
977	tx, tx_output.error, block_output.block_gas_used, tx_output.logs
978	)
979
980	receipt_key = rlp.encode(Uint(index))
981	block_output.receipt_keys += (receipt_key,)
982
983	trie_set(
984	block_output.receipts_trie,
985	receipt_key,
986	receipt,
987	)
988
989	block_output.block_logs += tx_output.logs
990
991	incorporate_tx_into_block(tx_state)

process_withdrawals ¶

Increase the balance of the withdrawing account.

def process_withdrawals(block_env: ethereum.forks.osaka.vm.BlockEnvironmentethereum.forks.bpo1.vm.BlockEnvironment, block_output: ethereum.forks.osaka.vm.BlockOutputethereum.forks.bpo1.vm.BlockOutput, withdrawals: Tuple[Withdrawal, ...]) -> None:

999	<snip>
1002	wd_state = TransactionState(parent=block_env.state)
1003
1004	for i, wd in enumerate(withdrawals):
1005	trie_set(
1006	block_output.withdrawals_trie,
1007	rlp.encode(Uint(i)),
1008	rlp.encode(wd),
1009	)
1010
1011	create_ether(wd_state, wd.address, wd.amount * U256(10**9))
1012
1013	incorporate_tx_into_block(wd_state)

check_gas_limit ¶

Validates the gas limit for a block.

The bounds of the gas limit, max_adjustment_delta, is set as the quotient of the parent block's gas limit and the LIMIT_ADJUSTMENT_FACTOR. Therefore, if the gas limit that is passed through as a parameter is greater than or equal to the sum of the parent's gas and the adjustment delta then the limit for gas is too high and fails this function's check. Similarly, if the limit is less than or equal to the difference of the parent's gas and the adjustment delta or the predefined LIMIT_MINIMUM then this function's check fails because the gas limit doesn't allow for a sufficient or reasonable amount of gas to be used on a block.

Parameters

gas_limit : Gas limit to validate.

parent_gas_limit : Gas limit of the parent block.

Returns

check : bool True if gas limit constraints are satisfied, False otherwise.

def check_gas_limit(gas_limit: Uint, parent_gas_limit: Uint) -> bool:

1017	<snip>
1045	max_adjustment_delta = parent_gas_limit // GasCosts.LIMIT_ADJUSTMENT_FACTOR
1046	if gas_limit >= parent_gas_limit + max_adjustment_delta:
1047	return False
1048	if gas_limit <= parent_gas_limit - max_adjustment_delta:
1049	return False
1050	if gas_limit < GasCosts.LIMIT_MINIMUM:
1051	return False
1052
1053	return True

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