apply.ml
(*****************************************************************************)
(* *)
(* Open Source License *)
(* Copyright (c) 2018 Dynamic Ledger Solutions, Inc. <contact@tezos.com> *)
(* Copyright (c) 2019-2022 Nomadic Labs <contact@nomadic-labs.com> *)
(* Copyright (c) 2022 Trili Tech, <contact@trili.tech> *)
(* *)
(* Permission is hereby granted, free of charge, to any person obtaining a *)
(* copy of this software and associated documentation files (the "Software"),*)
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(* Software is furnished to do so, subject to the following conditions: *)
(* *)
(* The above copyright notice and this permission notice shall be included *)
(* in all copies or substantial portions of the Software. *)
(* *)
(* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR*)
(* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, *)
(* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL *)
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(*****************************************************************************)
(** Tezos Protocol Implementation - Main Entry Points *)
open Alpha_context
type error +=
| Not_enough_endorsements of {required : int; provided : int}
| Faulty_validation_wrong_slot
| Set_deposits_limit_on_unregistered_delegate of Signature.Public_key_hash.t
| Set_deposits_limit_too_high of {limit : Tez.t; max_limit : Tez.t}
| Error_while_taking_fees
| Empty_transaction of Contract.t
| Tx_rollup_feature_disabled
| Tx_rollup_invalid_transaction_ticket_amount
| Cannot_transfer_ticket_to_implicit
| Sc_rollup_feature_disabled
| Internal_operation_replay of
Apply_internal_results.packed_internal_operation
| Multiple_revelation
| Zero_frozen_deposits of Signature.Public_key_hash.t
| Invalid_transfer_to_sc_rollup_from_implicit_account
let () =
register_error_kind
`Permanent
~id:"operation.not_enough_endorsements"
~title:"Not enough endorsements"
~description:
"The block being validated does not include the required minimum number \
of endorsements."
~pp:(fun ppf (required, provided) ->
Format.fprintf
ppf
"Wrong number of endorsements (%i), at least %i are expected"
provided
required)
Data_encoding.(obj2 (req "required" int31) (req "provided" int31))
(function
| Not_enough_endorsements {required; provided} -> Some (required, provided)
| _ -> None)
(fun (required, provided) -> Not_enough_endorsements {required; provided}) ;
let description =
"The consensus operation uses an invalid slot. This error should not \
happen: the operation validation should have failed earlier."
in
register_error_kind
`Permanent
~id:"operation.faulty_validation_wrong_slot"
~title:"Faulty validation (wrong slot for consensus operation)"
~description
~pp:(fun ppf () -> Format.fprintf ppf "%s" description)
Data_encoding.empty
(function Faulty_validation_wrong_slot -> Some () | _ -> None)
(fun () -> Faulty_validation_wrong_slot) ;
register_error_kind
`Temporary
~id:"operation.set_deposits_limit_on_unregistered_delegate"
~title:"Set deposits limit on an unregistered delegate"
~description:"Cannot set deposits limit on an unregistered delegate."
~pp:(fun ppf c ->
Format.fprintf
ppf
"Cannot set a deposits limit on the unregistered delegate %a."
Signature.Public_key_hash.pp
c)
Data_encoding.(obj1 (req "delegate" Signature.Public_key_hash.encoding))
(function
| Set_deposits_limit_on_unregistered_delegate c -> Some c | _ -> None)
(fun c -> Set_deposits_limit_on_unregistered_delegate c) ;
register_error_kind
`Permanent
~id:"operation.set_deposits_limit_too_high"
~title:"Set deposits limit to a too high value"
~description:
"Cannot set deposits limit such that the active stake overflows."
~pp:(fun ppf (limit, max_limit) ->
Format.fprintf
ppf
"Cannot set deposits limit to %a as it is higher the allowed maximum \
%a."
Tez.pp
limit
Tez.pp
max_limit)
Data_encoding.(
obj2 (req "limit" Tez.encoding) (req "max_limit" Tez.encoding))
(function
| Set_deposits_limit_too_high {limit; max_limit} -> Some (limit, max_limit)
| _ -> None)
(fun (limit, max_limit) -> Set_deposits_limit_too_high {limit; max_limit}) ;
let error_while_taking_fees_description =
"There was an error while taking the fees, which should not happen and \
means that the operation's validation was faulty."
in
register_error_kind
`Permanent
~id:"operation.error_while_taking_fees"
~title:"Error while taking the fees of a manager operation"
~description:error_while_taking_fees_description
~pp:(fun ppf () ->
Format.fprintf ppf "%s" error_while_taking_fees_description)
Data_encoding.unit
(function Error_while_taking_fees -> Some () | _ -> None)
(fun () -> Error_while_taking_fees) ;
register_error_kind
`Branch
~id:"contract.empty_transaction"
~title:"Empty transaction"
~description:"Forbidden to credit 0ꜩ to a contract without code."
~pp:(fun ppf contract ->
Format.fprintf
ppf
"Transactions of 0ꜩ towards a contract without code are forbidden (%a)."
Contract.pp
contract)
Data_encoding.(obj1 (req "contract" Contract.encoding))
(function Empty_transaction c -> Some c | _ -> None)
(fun c -> Empty_transaction c) ;
register_error_kind
`Permanent
~id:"operation.tx_rollup_is_disabled"
~title:"Tx rollup is disabled"
~description:"Cannot originate a tx rollup as it is disabled."
~pp:(fun ppf () ->
Format.fprintf
ppf
"Cannot apply a tx rollup operation as it is disabled. This feature \
will be enabled in a future proposal")
Data_encoding.unit
(function Tx_rollup_feature_disabled -> Some () | _ -> None)
(fun () -> Tx_rollup_feature_disabled) ;
register_error_kind
`Permanent
~id:"operation.tx_rollup_invalid_transaction_ticket_amount"
~title:"Amount of transferred ticket is too high"
~description:
"The ticket amount of a rollup transaction must fit in a signed 64-bit \
integer."
~pp:(fun ppf () ->
Format.fprintf ppf "Amount of transferred ticket is too high.")
Data_encoding.unit
(function
| Tx_rollup_invalid_transaction_ticket_amount -> Some () | _ -> None)
(fun () -> Tx_rollup_invalid_transaction_ticket_amount) ;
register_error_kind
`Permanent
~id:"operation.cannot_transfer_ticket_to_implicit"
~title:"Cannot transfer ticket to implicit account"
~description:"Cannot transfer ticket to implicit account"
Data_encoding.unit
(function Cannot_transfer_ticket_to_implicit -> Some () | _ -> None)
(fun () -> Cannot_transfer_ticket_to_implicit) ;
let description =
"Smart contract rollups will be enabled in a future proposal."
in
register_error_kind
`Permanent
~id:"operation.sc_rollup_disabled"
~title:"Smart contract rollups are disabled"
~description
~pp:(fun ppf () -> Format.fprintf ppf "%s" description)
Data_encoding.unit
(function Sc_rollup_feature_disabled -> Some () | _ -> None)
(fun () -> Sc_rollup_feature_disabled) ;
register_error_kind
`Permanent
~id:"internal_operation_replay"
~title:"Internal operation replay"
~description:"An internal operation was emitted twice by a script"
~pp:(fun ppf (Apply_internal_results.Internal_operation {nonce; _}) ->
Format.fprintf
ppf
"Internal operation %d was emitted twice by a script"
nonce)
Apply_internal_results.internal_operation_encoding
(function Internal_operation_replay op -> Some op | _ -> None)
(fun op -> Internal_operation_replay op) ;
register_error_kind
`Permanent
~id:"block.multiple_revelation"
~title:"Multiple revelations were included in a manager operation"
~description:
"A manager operation should not contain more than one revelation"
~pp:(fun ppf () ->
Format.fprintf
ppf
"Multiple revelations were included in a manager operation")
Data_encoding.empty
(function Multiple_revelation -> Some () | _ -> None)
(fun () -> Multiple_revelation) ;
register_error_kind
`Permanent
~id:"delegate.zero_frozen_deposits"
~title:"Zero frozen deposits"
~description:"The delegate has zero frozen deposits."
~pp:(fun ppf delegate ->
Format.fprintf
ppf
"Delegate %a has zero frozen deposits; it is not allowed to \
bake/preendorse/endorse."
Signature.Public_key_hash.pp
delegate)
Data_encoding.(obj1 (req "delegate" Signature.Public_key_hash.encoding))
(function Zero_frozen_deposits delegate -> Some delegate | _ -> None)
(fun delegate -> Zero_frozen_deposits delegate) ;
register_error_kind
`Permanent
~id:"operations.invalid_transfer_to_sc_rollup_from_implicit_account"
~title:"Invalid transfer to sc rollup"
~description:"Invalid transfer to sc rollup from implicit account"
~pp:(fun ppf () ->
Format.fprintf
ppf
"Invalid source for transfer operation to smart-contract rollup. Only \
originated accounts are allowed")
Data_encoding.empty
(function
| Invalid_transfer_to_sc_rollup_from_implicit_account -> Some ()
| _ -> None)
(fun () -> Invalid_transfer_to_sc_rollup_from_implicit_account)
open Apply_results
open Apply_operation_result
open Apply_internal_results
let assert_tx_rollup_feature_enabled ctxt =
let open Result_syntax in
let level = (Level.current ctxt).level in
let* sunset = Raw_level.of_int32 @@ Constants.tx_rollup_sunset_level ctxt in
let* () = error_when Raw_level.(sunset <= level) Tx_rollup_feature_disabled in
error_unless (Constants.tx_rollup_enable ctxt) Tx_rollup_feature_disabled
let assert_sc_rollup_feature_enabled ctxt =
error_unless (Constants.sc_rollup_enable ctxt) Sc_rollup_feature_disabled
let update_script_storage_and_ticket_balances ctxt ~self storage
lazy_storage_diff ticket_diffs operations =
Contract.update_script_storage ctxt self storage lazy_storage_diff
>>=? fun ctxt ->
Ticket_accounting.update_ticket_balances ctxt ~self ~ticket_diffs operations
let apply_delegation ~ctxt ~source ~delegate ~before_operation =
Delegate.set ctxt source delegate >|=? fun ctxt ->
(ctxt, Gas.consumed ~since:before_operation ~until:ctxt, [])
type 'loc execution_arg =
| Typed_arg : 'loc * ('a, _) Script_typed_ir.ty * 'a -> 'loc execution_arg
| Untyped_arg : Script.expr -> _ execution_arg
let apply_transaction_to_implicit ~ctxt ~source ~amount ~pkh ~before_operation =
let contract = Contract.Implicit pkh in
(* Transfers of zero to implicit accounts are forbidden. *)
error_when Tez.(amount = zero) (Empty_transaction contract) >>?= fun () ->
(* If the implicit contract is not yet allocated at this point then
the next transfer of tokens will allocate it. *)
Contract.allocated ctxt contract >>= fun already_allocated ->
Token.transfer ctxt (`Contract source) (`Contract contract) amount
>>=? fun (ctxt, balance_updates) ->
let result =
Transaction_to_contract_result
{
storage = None;
lazy_storage_diff = None;
balance_updates;
originated_contracts = [];
consumed_gas = Gas.consumed ~since:before_operation ~until:ctxt;
storage_size = Z.zero;
paid_storage_size_diff = Z.zero;
allocated_destination_contract = not already_allocated;
}
in
return (ctxt, result, [])
let apply_transaction_to_smart_contract ~ctxt ~source ~contract_hash ~amount
~entrypoint ~before_operation ~payer ~chain_id ~internal ~parameter =
let contract = Contract.Originated contract_hash in
(* Since the contract is originated, nothing will be allocated or this
transfer of tokens will fail. [Token.transfer] will succeed even on
non-existing contracts, if the amount is zero. Then if the destination
does not exist, [Script_cache.find] will signal that by returning [None]
and we'll fail.
*)
Token.transfer ctxt (`Contract source) (`Contract contract) amount
>>=? fun (ctxt, balance_updates) ->
Script_cache.find ctxt contract_hash >>=? fun (ctxt, cache_key, script) ->
match script with
| None -> fail (Contract.Non_existing_contract contract)
| Some (script, script_ir) ->
(* Token.transfer which is being called before already loads this value into
the Irmin cache, so no need to burn gas for it. *)
Contract.get_balance ctxt contract >>=? fun balance ->
let now = Script_timestamp.now ctxt in
let level =
(Level.current ctxt).level |> Raw_level.to_int32 |> Script_int.of_int32
|> Script_int.abs
in
let step_constants =
let open Script_interpreter in
{
source;
payer;
self = contract_hash;
amount;
chain_id;
balance;
now;
level;
}
in
let execute =
match parameter with
| Untyped_arg parameter -> Script_interpreter.execute ~parameter
| Typed_arg (location, parameter_ty, parameter) ->
Script_interpreter.execute_with_typed_parameter
~location
~parameter_ty
~parameter
in
let cached_script = Some script_ir in
execute
ctxt
~cached_script
Optimized
step_constants
~script
~entrypoint
~internal
>>=? fun ( {
script = updated_cached_script;
code_size = updated_size;
storage;
lazy_storage_diff;
operations;
ticket_diffs;
},
ctxt ) ->
update_script_storage_and_ticket_balances
ctxt
~self:contract
storage
lazy_storage_diff
ticket_diffs
operations
>>=? fun (ticket_table_size_diff, ctxt) ->
Ticket_balance.adjust_storage_space
ctxt
~storage_diff:ticket_table_size_diff
>>=? fun (ticket_paid_storage_diff, ctxt) ->
Fees.record_paid_storage_space ctxt contract
>>=? fun (ctxt, new_size, contract_paid_storage_size_diff) ->
Contract.originated_from_current_nonce ~since:before_operation ~until:ctxt
>>=? fun originated_contracts ->
Lwt.return
( Script_cache.update
ctxt
cache_key
( {script with storage = Script.lazy_expr storage},
updated_cached_script )
updated_size
>|? fun ctxt ->
let result =
Transaction_to_contract_result
{
storage = Some storage;
lazy_storage_diff;
balance_updates;
originated_contracts;
consumed_gas = Gas.consumed ~since:before_operation ~until:ctxt;
storage_size = new_size;
paid_storage_size_diff =
Z.add contract_paid_storage_size_diff ticket_paid_storage_diff;
allocated_destination_contract = false;
}
in
(ctxt, result, operations) )
let ex_ticket_size :
context -> Ticket_scanner.ex_ticket -> (context * int) tzresult Lwt.t =
fun ctxt (Ex_ticket (ty, ticket)) ->
(* type *)
Script_typed_ir.ticket_t Micheline.dummy_location ty >>?= fun ty ->
Script_ir_unparser.unparse_ty ~loc:Micheline.dummy_location ctxt ty
>>?= fun (ty', ctxt) ->
let ty_nodes, ty_size = Script_typed_ir_size.node_size ty' in
let ty_size = Saturation_repr.to_int ty_size in
let ty_size_cost = Script_typed_ir_size_costs.nodes_cost ~nodes:ty_nodes in
Gas.consume ctxt ty_size_cost >>?= fun ctxt ->
(* contents *)
let val_nodes, val_size = Script_typed_ir_size.value_size ty ticket in
let val_size = Saturation_repr.to_int val_size in
let val_size_cost = Script_typed_ir_size_costs.nodes_cost ~nodes:val_nodes in
Gas.consume ctxt val_size_cost >>?= fun ctxt ->
(* gas *)
return (ctxt, ty_size + val_size)
let apply_transaction_to_tx_rollup ~ctxt ~parameters_ty ~parameters ~payer
~dst_rollup ~since =
assert_tx_rollup_feature_enabled ctxt >>?= fun () ->
(* If the ticket deposit fails on L2 for some reason
(e.g. [Balance_overflow] in the recipient), then it is
returned to [payer]. As [payer] is implicit, it cannot own
tickets directly. Therefore, erroneous deposits are
returned using the L2 withdrawal mechanism: a failing
deposit emits a withdrawal that can be executed by
[payer]. *)
let Tx_rollup_parameters.{ex_ticket; l2_destination} =
Tx_rollup_parameters.get_deposit_parameters parameters_ty parameters
in
ex_ticket_size ctxt ex_ticket >>=? fun (ctxt, ticket_size) ->
let limit = Constants.tx_rollup_max_ticket_payload_size ctxt in
fail_when
Compare.Int.(ticket_size > limit)
(Tx_rollup_errors_repr.Ticket_payload_size_limit_exceeded
{payload_size = ticket_size; limit})
>>=? fun () ->
let ex_token, ticket_amount =
Ticket_token.token_and_amount_of_ex_ticket ex_ticket
in
Ticket_balance_key.of_ex_token ctxt ~owner:(Tx_rollup dst_rollup) ex_token
>>=? fun (ticket_hash, ctxt) ->
Option.value_e
~error:
(Error_monad.trace_of_error Tx_rollup_invalid_transaction_ticket_amount)
(Option.bind (Script_int.to_int64 ticket_amount) Tx_rollup_l2_qty.of_int64)
>>?= fun ticket_amount ->
error_when
Tx_rollup_l2_qty.(ticket_amount <= zero)
Ticket_scanner.Forbidden_zero_ticket_quantity
>>?= fun () ->
let deposit, message_size =
Tx_rollup_message.make_deposit
payer
l2_destination
ticket_hash
ticket_amount
in
Tx_rollup_state.get ctxt dst_rollup >>=? fun (ctxt, state) ->
Tx_rollup_state.burn_cost ~limit:None state message_size >>?= fun cost ->
Token.transfer ctxt (`Contract (Contract.Implicit payer)) `Burned cost
>>=? fun (ctxt, balance_updates) ->
Tx_rollup_inbox.append_message ctxt dst_rollup state deposit
>>=? fun (ctxt, state, paid_storage_size_diff) ->
Tx_rollup_state.update ctxt dst_rollup state >>=? fun ctxt ->
let result =
ITransaction_result
(Transaction_to_tx_rollup_result
{
balance_updates;
consumed_gas = Gas.consumed ~since ~until:ctxt;
ticket_hash;
paid_storage_size_diff;
})
in
return (ctxt, result, [])
let apply_origination ~ctxt ~storage_type ~storage ~unparsed_code
~contract:contract_hash ~delegate ~source ~credit ~before_operation =
Script_ir_translator.collect_lazy_storage ctxt storage_type storage
>>?= fun (to_duplicate, ctxt) ->
let to_update = Script_ir_translator.no_lazy_storage_id in
Script_ir_translator.extract_lazy_storage_diff
ctxt
Optimized
storage_type
storage
~to_duplicate
~to_update
~temporary:false
>>=? fun (storage, lazy_storage_diff, ctxt) ->
Script_ir_translator.unparse_data ctxt Optimized storage_type storage
>>=? fun (storage, ctxt) ->
Gas.consume ctxt (Script.strip_locations_cost storage) >>?= fun ctxt ->
let storage = Script.lazy_expr (Micheline.strip_locations storage) in
(* Normalize code to avoid #843 *)
Script_ir_translator.unparse_code
ctxt
Optimized
(Micheline.root unparsed_code)
>>=? fun (code, ctxt) ->
Gas.consume ctxt (Script.strip_locations_cost code) >>?= fun ctxt ->
let code = Script.lazy_expr (Micheline.strip_locations code) in
let script = {Script.code; storage} in
Contract.raw_originate
ctxt
~prepaid_bootstrap_storage:false
contract_hash
~script:(script, lazy_storage_diff)
>>=? fun ctxt ->
let contract = Contract.Originated contract_hash in
(match delegate with
| None -> return ctxt
| Some delegate -> Delegate.init ctxt contract delegate)
>>=? fun ctxt ->
Token.transfer ctxt (`Contract source) (`Contract contract) credit
>>=? fun (ctxt, balance_updates) ->
Fees.record_paid_storage_space ctxt contract
>|=? fun (ctxt, size, paid_storage_size_diff) ->
let result =
{
lazy_storage_diff;
balance_updates;
originated_contracts = [contract_hash];
consumed_gas = Gas.consumed ~since:before_operation ~until:ctxt;
storage_size = size;
paid_storage_size_diff;
}
in
(ctxt, result, [])
(**
Retrieving the source code of a contract from its address is costly
because it requires I/Os. For this reason, we put the corresponding
Micheline expression in the cache.
Elaborating a Micheline node into the well-typed script abstract
syntax tree is also a costly operation. The result of this operation
is cached as well.
*)
let apply_internal_operation_contents :
type kind.
context ->
payer:public_key_hash ->
source:Contract.t ->
chain_id:Chain_id.t ->
kind Script_typed_ir.internal_operation_contents ->
(context
* kind successful_internal_operation_result
* Script_typed_ir.packed_internal_operation list)
tzresult
Lwt.t =
fun ctxt_before_op ~payer ~source ~chain_id operation ->
Contract.must_exist ctxt_before_op source >>=? fun () ->
Gas.consume ctxt_before_op Michelson_v1_gas.Cost_of.manager_operation
>>?= fun ctxt ->
(* Note that [ctxt_before_op] will be used again later to compute
gas consumption and originations for the operation result (by
comparing it with the [ctxt] we will have at the end of the
application). *)
match operation with
| Transaction_to_implicit {destination = pkh; amount} ->
apply_transaction_to_implicit
~ctxt
~source
~amount
~pkh
~before_operation:ctxt_before_op
>|=? fun (ctxt, res, ops) ->
( ctxt,
(ITransaction_result res : kind successful_internal_operation_result),
ops )
| Transaction_to_smart_contract
{
amount;
destination = contract_hash;
entrypoint;
location;
parameters_ty;
parameters = typed_parameters;
unparsed_parameters = _;
} ->
apply_transaction_to_smart_contract
~ctxt
~source
~contract_hash
~amount
~entrypoint
~before_operation:ctxt_before_op
~payer
~chain_id
~internal:true
~parameter:(Typed_arg (location, parameters_ty, typed_parameters))
>|=? fun (ctxt, res, ops) -> (ctxt, ITransaction_result res, ops)
| Transaction_to_tx_rollup
{destination; unparsed_parameters = _; parameters_ty; parameters} ->
apply_transaction_to_tx_rollup
~ctxt
~parameters_ty
~parameters
~payer
~dst_rollup:destination
~since:ctxt_before_op
| Transaction_to_sc_rollup
{
destination;
entrypoint = _;
parameters_ty = _;
parameters = _;
unparsed_parameters = payload;
} ->
assert_sc_rollup_feature_enabled ctxt >>?= fun () ->
(* TODO: #3242
We could rather change the type of [source] in
{!Script_type_ir.internal_operation}. Only originated accounts should
be allowed anyway for internal operations.
*)
(match source with
| Contract.Implicit _ ->
error Invalid_transfer_to_sc_rollup_from_implicit_account
| Originated hash -> ok hash)
>>?= fun sender ->
(* Adding the message to the inbox. Note that it is safe to ignore the
size diff since only its hash and meta data are stored in the context.
See #3232. *)
Sc_rollup.Inbox.add_internal_message
ctxt
destination
~payload
~sender
~source:payer
>|=? fun (inbox_after, _size, ctxt) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Transaction_to_sc_rollup_result {consumed_gas; inbox_after}
in
(ctxt, ITransaction_result result, [])
| Event {ty = _; unparsed_data = _; tag = _} ->
return
( ctxt,
IEvent_result
{consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt},
[] )
| Origination
{
delegate;
code = unparsed_code;
unparsed_storage = _;
credit;
preorigination;
storage_type;
storage;
} ->
apply_origination
~ctxt
~storage_type
~storage
~unparsed_code
~contract:preorigination
~delegate
~source
~credit
~before_operation:ctxt_before_op
>|=? fun (ctxt, origination_result, ops) ->
(ctxt, IOrigination_result origination_result, ops)
| Delegation delegate ->
apply_delegation ~ctxt ~source ~delegate ~before_operation:ctxt_before_op
>|=? fun (ctxt, consumed_gas, ops) ->
(ctxt, IDelegation_result {consumed_gas}, ops)
let apply_manager_operation :
type kind.
context ->
source:public_key_hash ->
chain_id:Chain_id.t ->
kind manager_operation ->
(context
* kind successful_manager_operation_result
* Script_typed_ir.packed_internal_operation list)
tzresult
Lwt.t =
fun ctxt_before_op ~source ~chain_id operation ->
let source_contract = Contract.Implicit source in
Contract.must_exist ctxt_before_op source_contract >>=? fun () ->
Gas.consume ctxt_before_op Michelson_v1_gas.Cost_of.manager_operation
>>?= fun ctxt ->
(* Note that [ctxt_before_op] will be used again later to compute
gas consumption and originations for the operation result (by
comparing it with the [ctxt] we will have at the end of the
application). *)
let consume_deserialization_gas =
(* Note that we used to set this to [Script.When_needed] because
the deserialization gas was accounted for in the gas consumed
by precheck. However, we no longer have access to this precheck
gas, so we want to always consume the deserialization gas
again, independently of the internal state of the lazy_exprs in
the arguments. *)
Script.Always
in
match operation with
| Reveal pk ->
(* TODO #2603
Even if [precheck_manager_contents] has already asserted that
the implicit contract is allocated, we must re-do this check in
case the manager has been emptied while collecting fees. This
should be solved by forking out [validate_operation] from
[apply_operation]. *)
Contract.must_be_allocated ctxt source_contract >>=? fun () ->
(* TODO tezos/tezos#3070
We have already asserted the consistency of the supplied public
key during precheck, so we avoid re-checking that precondition
with [?check_consistency=false]. This optional parameter is
temporary, to avoid breaking compatibility with external legacy
usage of [Contract.reveal_manager_key]. However, the pattern of
using [Contract.check_public_key] and this usage of
[Contract.reveal_manager_key] should become the standard. *)
Contract.reveal_manager_key ~check_consistency:false ctxt source pk
>>=? fun ctxt ->
return
( ctxt,
(Reveal_result
{consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt}
: kind successful_manager_operation_result),
[] )
| Transaction {amount; parameters; destination = Implicit pkh; entrypoint} ->
Script.force_decode_in_context
~consume_deserialization_gas
ctxt
parameters
>>?= fun (parameters, ctxt) ->
(* Only allow [Unit] parameter to implicit accounts. *)
(match Micheline.root parameters with
| Prim (_, Michelson_v1_primitives.D_Unit, [], _) -> Result.return_unit
| _ -> error (Script_interpreter.Bad_contract_parameter source_contract))
>>?= fun () ->
(if Entrypoint.is_default entrypoint then Result.return_unit
else error (Script_tc_errors.No_such_entrypoint entrypoint))
>>?= fun () ->
apply_transaction_to_implicit
~ctxt
~source:source_contract
~amount
~pkh
~before_operation:ctxt_before_op
>|=? fun (ctxt, res, ops) -> (ctxt, Transaction_result res, ops)
| Transaction
{amount; parameters; destination = Originated contract_hash; entrypoint}
->
Script.force_decode_in_context
~consume_deserialization_gas
ctxt
parameters
>>?= fun (parameters, ctxt) ->
apply_transaction_to_smart_contract
~ctxt
~source:source_contract
~contract_hash
~amount
~entrypoint
~before_operation:ctxt_before_op
~payer:source
~chain_id
~internal:false
~parameter:(Untyped_arg parameters)
>|=? fun (ctxt, res, ops) -> (ctxt, Transaction_result res, ops)
| Tx_rollup_dispatch_tickets
{
tx_rollup;
level;
context_hash;
message_index;
message_result_path;
tickets_info;
} ->
Tx_rollup_state.get ctxt tx_rollup >>=? fun (ctxt, state) ->
Tx_rollup_commitment.get_finalized ctxt tx_rollup state level
>>=? fun (ctxt, commitment) ->
Tx_rollup_reveal.mem ctxt tx_rollup level ~message_position:message_index
>>=? fun (ctxt, already_revealed) ->
error_when
already_revealed
Tx_rollup_errors.Withdrawals_already_dispatched
>>?= fun () ->
(* The size of the list [tickets_info] is bounded by a
parametric constant, and checked in precheck. *)
List.fold_left_es
(fun (acc_withdraw, acc, ctxt)
Tx_rollup_reveal.{contents; ty; ticketer; amount; claimer} ->
error_when
Tx_rollup_l2_qty.(amount <= zero)
Ticket_scanner.Forbidden_zero_ticket_quantity
>>?= fun () ->
Tx_rollup_ticket.parse_ticket
~consume_deserialization_gas
~ticketer
~contents
~ty
ctxt
>>=? fun (ctxt, ticket_token) ->
Tx_rollup_ticket.make_withdraw_order
ctxt
tx_rollup
ticket_token
claimer
amount
>>=? fun (ctxt, withdrawal) ->
return
(withdrawal :: acc_withdraw, (withdrawal, ticket_token) :: acc, ctxt))
([], [], ctxt)
tickets_info
>>=? fun (rev_withdraw_list, rev_ex_token_and_hash_list, ctxt) ->
Tx_rollup_hash.withdraw_list ctxt (List.rev rev_withdraw_list)
>>?= fun (ctxt, withdraw_list_hash) ->
Tx_rollup_commitment.check_message_result
ctxt
commitment.commitment
(`Result {context_hash; withdraw_list_hash})
~path:message_result_path
~index:message_index
>>?= fun ctxt ->
Tx_rollup_reveal.record
ctxt
tx_rollup
level
~message_position:message_index
>>=? fun ctxt ->
let adjust_ticket_balance (ctxt, acc_diff)
( Tx_rollup_withdraw.
{claimer; amount; ticket_hash = tx_rollup_ticket_hash},
ticket_token ) =
let amount = Tx_rollup_l2_qty.to_z amount in
Ticket_balance_key.of_ex_token
ctxt
~owner:(Contract (Contract.Implicit claimer))
ticket_token
>>=? fun (claimer_ticket_hash, ctxt) ->
Tx_rollup_ticket.transfer_ticket_with_hashes
ctxt
~src_hash:tx_rollup_ticket_hash
~dst_hash:claimer_ticket_hash
amount
>>=? fun (ctxt, diff) -> return (ctxt, Z.(add acc_diff diff))
in
List.fold_left_es
adjust_ticket_balance
(ctxt, Z.zero)
rev_ex_token_and_hash_list
>>=? fun (ctxt, paid_storage_size_diff) ->
let result =
Tx_rollup_dispatch_tickets_result
{
balance_updates = [];
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
paid_storage_size_diff;
}
in
return (ctxt, result, [])
| Transfer_ticket {contents; ty; ticketer; amount; destination; entrypoint}
-> (
(* The encoding ensures that the amount is in a natural number. Here is
mainly to check that it is non-zero.*)
error_when
Compare.Z.(amount <= Z.zero)
Ticket_scanner.Forbidden_zero_ticket_quantity
>>?= fun () ->
match destination with
| Implicit _ -> fail Cannot_transfer_ticket_to_implicit
| Originated destination_hash ->
Tx_rollup_ticket.parse_ticket_and_operation
~consume_deserialization_gas
~ticketer
~contents
~ty
~source:source_contract
~destination:destination_hash
~entrypoint
~amount
ctxt
>>=? fun (ctxt, ticket_token, op) ->
Tx_rollup_ticket.transfer_ticket
ctxt
~src:(Contract source_contract)
~dst:(Contract destination)
ticket_token
amount
>>=? fun (ctxt, paid_storage_size_diff) ->
let result =
Transfer_ticket_result
{
balance_updates = [];
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
paid_storage_size_diff;
}
in
return (ctxt, result, [op]))
| Origination {delegate; script; credit} ->
(* Internal originations have their address generated in the interpreter
so that the script can use it immediately.
The address of external originations is generated here. *)
Contract.fresh_contract_from_current_nonce ctxt
>>?= fun (ctxt, contract) ->
Script.force_decode_in_context
~consume_deserialization_gas
ctxt
script.Script.storage
>>?= fun (_unparsed_storage, ctxt) ->
Script.force_decode_in_context
~consume_deserialization_gas
ctxt
script.Script.code
>>?= fun (unparsed_code, ctxt) ->
Script_ir_translator.parse_script
ctxt
~elab_conf:Script_ir_translator_config.(make ~legacy:false ())
~allow_forged_in_storage:false
script
>>=? fun (Ex_script parsed_script, ctxt) ->
let (Script {storage_type; views; storage; _}) = parsed_script in
let views_result =
Script_ir_translator.parse_views
ctxt
~elab_conf:Script_ir_translator_config.(make ~legacy:false ())
storage_type
views
in
trace
(Script_tc_errors.Ill_typed_contract (unparsed_code, []))
views_result
>>=? fun (_typed_views, ctxt) ->
apply_origination
~ctxt
~storage_type
~storage
~unparsed_code
~contract
~delegate
~source:source_contract
~credit
~before_operation:ctxt_before_op
>|=? fun (ctxt, origination_result, ops) ->
(ctxt, Origination_result origination_result, ops)
| Delegation delegate ->
apply_delegation
~ctxt
~source:source_contract
~delegate
~before_operation:ctxt_before_op
>|=? fun (ctxt, consumed_gas, ops) ->
(ctxt, Delegation_result {consumed_gas}, ops)
| Register_global_constant {value} ->
(* Decode the value and consume gas appropriately *)
Script.force_decode_in_context ~consume_deserialization_gas ctxt value
>>?= fun (expr, ctxt) ->
(* Set the key to the value in storage. *)
Global_constants_storage.register ctxt expr
>>=? fun (ctxt, address, size) ->
(* The burn and the reporting of the burn are calculated differently.
[Fees.record_global_constant_storage_space] does the actual burn
based on the size of the constant registered, and this causes a
change in account balance.
On the other hand, the receipt is calculated
with the help of [Fees.cost_of_bytes], and is included in block metadata
and the client output. The receipt is also used during simulation,
letting the client automatically set an appropriate storage limit.
TODO : is this concern still honored by the token management
refactoring ? *)
let ctxt, paid_size =
Fees.record_global_constant_storage_space ctxt size
in
let result =
Register_global_constant_result
{
balance_updates = [];
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
size_of_constant = paid_size;
global_address = address;
}
in
return (ctxt, result, [])
| Set_deposits_limit limit ->
(match limit with
| None -> Result.return_unit
| Some limit ->
let frozen_deposits_percentage =
Constants.frozen_deposits_percentage ctxt
in
let max_limit =
Tez.of_mutez_exn
Int64.(
mul (of_int frozen_deposits_percentage) Int64.(div max_int 100L))
in
error_when
Tez.(limit > max_limit)
(Set_deposits_limit_too_high {limit; max_limit}))
>>?= fun () ->
Delegate.registered ctxt source >>=? fun is_registered ->
error_unless
is_registered
(Set_deposits_limit_on_unregistered_delegate source)
>>?= fun () ->
Delegate.set_frozen_deposits_limit ctxt source limit >>= fun ctxt ->
return
( ctxt,
Set_deposits_limit_result
{consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt},
[] )
| Increase_paid_storage {amount_in_bytes; destination} ->
let contract = Contract.Originated destination in
Contract.increase_paid_storage ctxt contract ~amount_in_bytes
>>=? fun ctxt ->
let payer = `Contract (Contract.Implicit source) in
Fees.burn_storage_increase_fees ctxt ~payer amount_in_bytes
>|=? fun (ctxt, storage_bus) ->
let result =
Increase_paid_storage_result
{
balance_updates = storage_bus;
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
}
in
(ctxt, result, [])
| Tx_rollup_origination ->
Tx_rollup.originate ctxt >>=? fun (ctxt, originated_tx_rollup) ->
let result =
Tx_rollup_origination_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
originated_tx_rollup;
balance_updates = [];
}
in
return (ctxt, result, [])
| Tx_rollup_submit_batch {tx_rollup; content; burn_limit} ->
let message, message_size = Tx_rollup_message.make_batch content in
Tx_rollup_gas.hash_cost message_size >>?= fun cost ->
Gas.consume ctxt cost >>?= fun ctxt ->
Tx_rollup_state.get ctxt tx_rollup >>=? fun (ctxt, state) ->
Tx_rollup_inbox.append_message ctxt tx_rollup state message
>>=? fun (ctxt, state, paid_storage_size_diff) ->
Tx_rollup_state.burn_cost ~limit:burn_limit state message_size
>>?= fun cost ->
Token.transfer ctxt (`Contract source_contract) `Burned cost
>>=? fun (ctxt, balance_updates) ->
Tx_rollup_state.update ctxt tx_rollup state >>=? fun ctxt ->
let result =
Tx_rollup_submit_batch_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates;
paid_storage_size_diff;
}
in
return (ctxt, result, [])
| Tx_rollup_commit {tx_rollup; commitment} ->
Tx_rollup_state.get ctxt tx_rollup >>=? fun (ctxt, state) ->
( Tx_rollup_commitment.has_bond ctxt tx_rollup source
>>=? fun (ctxt, pending) ->
if not pending then
let bond_id = Bond_id.Tx_rollup_bond_id tx_rollup in
Token.transfer
ctxt
(`Contract source_contract)
(`Frozen_bonds (source_contract, bond_id))
(Constants.tx_rollup_commitment_bond ctxt)
else return (ctxt, []) )
>>=? fun (ctxt, balance_updates) ->
Tx_rollup_commitment.add_commitment ctxt tx_rollup state source commitment
>>=? fun (ctxt, state, to_slash) ->
(match to_slash with
| Some pkh ->
let committer = Contract.Implicit pkh in
Tx_rollup_commitment.slash_bond ctxt tx_rollup pkh
>>=? fun (ctxt, slashed) ->
if slashed then
let bid = Bond_id.Tx_rollup_bond_id tx_rollup in
Token.balance ctxt (`Frozen_bonds (committer, bid))
>>=? fun (ctxt, burn) ->
Token.transfer
ctxt
(`Frozen_bonds (committer, bid))
`Tx_rollup_rejection_punishments
burn
else return (ctxt, [])
| None -> return (ctxt, []))
>>=? fun (ctxt, burn_update) ->
Tx_rollup_state.update ctxt tx_rollup state >>=? fun ctxt ->
let result =
Tx_rollup_commit_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates = burn_update @ balance_updates;
}
in
return (ctxt, result, [])
| Tx_rollup_return_bond {tx_rollup} ->
Tx_rollup_commitment.remove_bond ctxt tx_rollup source >>=? fun ctxt ->
let bond_id = Bond_id.Tx_rollup_bond_id tx_rollup in
Token.balance ctxt (`Frozen_bonds (source_contract, bond_id))
>>=? fun (ctxt, bond) ->
Token.transfer
ctxt
(`Frozen_bonds (source_contract, bond_id))
(`Contract source_contract)
bond
>>=? fun (ctxt, balance_updates) ->
let result =
Tx_rollup_return_bond_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates;
}
in
return (ctxt, result, [])
| Tx_rollup_finalize_commitment {tx_rollup} ->
Tx_rollup_state.get ctxt tx_rollup >>=? fun (ctxt, state) ->
Tx_rollup_commitment.finalize_commitment ctxt tx_rollup state
>>=? fun (ctxt, state, level) ->
Tx_rollup_state.update ctxt tx_rollup state >>=? fun ctxt ->
let result =
Tx_rollup_finalize_commitment_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates = [];
level;
}
in
return (ctxt, result, [])
| Tx_rollup_remove_commitment {tx_rollup} ->
Tx_rollup_state.get ctxt tx_rollup >>=? fun (ctxt, state) ->
Tx_rollup_commitment.remove_commitment ctxt tx_rollup state
>>=? fun (ctxt, state, level) ->
Tx_rollup_state.update ctxt tx_rollup state >>=? fun ctxt ->
let result =
Tx_rollup_remove_commitment_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates = [];
level;
}
in
return (ctxt, result, [])
| Tx_rollup_rejection
{
proof;
tx_rollup;
level;
message;
message_position;
message_path;
message_result_hash;
message_result_path;
previous_message_result;
previous_message_result_path;
} ->
Tx_rollup_state.get ctxt tx_rollup >>=? fun (ctxt, state) ->
(* Check [level] *)
Tx_rollup_state.check_level_can_be_rejected state level >>?= fun () ->
Tx_rollup_commitment.get ctxt tx_rollup state level
>>=? fun (ctxt, commitment) ->
(* Check [message] *)
error_when
Compare.Int.(
message_position < 0
|| commitment.commitment.messages.count <= message_position)
(Tx_rollup_errors.Wrong_message_position
{
level = commitment.commitment.level;
position = message_position;
length = commitment.commitment.messages.count;
})
>>?= fun () ->
Tx_rollup_inbox.check_message_hash
ctxt
level
tx_rollup
~position:message_position
message
message_path
>>=? fun ctxt ->
(* Check message result paths *)
Tx_rollup_commitment.check_agreed_and_disputed_results
ctxt
tx_rollup
state
commitment
~agreed_result:previous_message_result
~agreed_result_path:previous_message_result_path
~disputed_result:message_result_hash
~disputed_result_path:message_result_path
~disputed_position:message_position
>>=? fun ctxt ->
(* Check [proof] *)
let parameters =
Tx_rollup_l2_apply.
{
tx_rollup_max_withdrawals_per_batch =
Constants.tx_rollup_max_withdrawals_per_batch ctxt;
}
in
Tx_rollup_l2_verifier.verify_proof
ctxt
parameters
message
proof
~agreed:previous_message_result
~rejected:message_result_hash
~max_proof_size:
(Alpha_context.Constants.tx_rollup_rejection_max_proof_size ctxt)
>>=? fun ctxt ->
(* Proof is correct, removing *)
Tx_rollup_commitment.reject_commitment ctxt tx_rollup state level
>>=? fun (ctxt, state) ->
(* Bond slashing, and removing *)
Tx_rollup_commitment.slash_bond ctxt tx_rollup commitment.committer
>>=? fun (ctxt, slashed) ->
(if slashed then
let committer = Contract.Implicit commitment.committer in
let bid = Bond_id.Tx_rollup_bond_id tx_rollup in
Token.balance ctxt (`Frozen_bonds (committer, bid))
>>=? fun (ctxt, burn) ->
Tez.(burn /? 2L) >>?= fun reward ->
Token.transfer
ctxt
(`Frozen_bonds (committer, bid))
`Tx_rollup_rejection_punishments
burn
>>=? fun (ctxt, burn_update) ->
Token.transfer
ctxt
`Tx_rollup_rejection_rewards
(`Contract source_contract)
reward
>>=? fun (ctxt, reward_update) ->
return (ctxt, burn_update @ reward_update)
else return (ctxt, []))
>>=? fun (ctxt, balance_updates) ->
(* Update state and conclude *)
Tx_rollup_state.update ctxt tx_rollup state >>=? fun ctxt ->
let result =
Tx_rollup_rejection_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates;
}
in
return (ctxt, result, [])
| Dal_publish_slot_header {slot} ->
Dal_apply.apply_publish_slot_header ctxt slot >>?= fun ctxt ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result = Dal_publish_slot_header_result {consumed_gas} in
return (ctxt, result, [])
| Sc_rollup_originate {kind; boot_sector; origination_proof; parameters_ty} ->
Sc_rollup_operations.originate
ctxt
~kind
~boot_sector
~origination_proof
~parameters_ty
>>=? fun ({address; size; genesis_commitment_hash}, ctxt) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_originate_result
{
address;
genesis_commitment_hash;
consumed_gas;
size;
balance_updates = [];
}
in
return (ctxt, result, [])
| Sc_rollup_add_messages {rollup; messages} ->
Sc_rollup.Inbox.add_external_messages ctxt rollup messages
>>=? fun (inbox_after, _size, ctxt) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result = Sc_rollup_add_messages_result {consumed_gas; inbox_after} in
return (ctxt, result, [])
| Sc_rollup_cement {rollup; commitment} ->
Sc_rollup.Stake_storage.cement_commitment ctxt rollup commitment
>>=? fun (ctxt, commitment) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_cement_result
{consumed_gas; inbox_level = commitment.inbox_level}
in
return (ctxt, result, [])
| Sc_rollup_publish {rollup; commitment} ->
Sc_rollup.Stake_storage.publish_commitment ctxt rollup source commitment
>>=? fun (staked_hash, published_at_level, ctxt, balance_updates) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_publish_result
{staked_hash; consumed_gas; published_at_level; balance_updates}
in
return (ctxt, result, [])
| Sc_rollup_refute {rollup; opponent; refutation} ->
let open Sc_rollup.Refutation_storage in
let player = source in
(match refutation with
| None ->
start_game ctxt rollup ~player ~opponent >>=? fun ctxt ->
return (None, ctxt)
| Some refutation -> game_move ctxt rollup ~player ~opponent refutation)
>>=? fun (outcome, ctxt) ->
(match outcome with
| None -> return (Sc_rollup.Game.Ongoing, ctxt, [])
| Some o ->
let stakers = Sc_rollup.Game.Index.make source opponent in
Sc_rollup.Refutation_storage.apply_outcome ctxt rollup stakers o)
>>=? fun (game_status, ctxt, balance_updates) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_refute_result {game_status; consumed_gas; balance_updates}
in
return (ctxt, result, [])
| Sc_rollup_timeout {rollup; stakers} ->
Sc_rollup.Refutation_storage.timeout ctxt rollup stakers
>>=? fun (outcome, ctxt) ->
Sc_rollup.Refutation_storage.apply_outcome ctxt rollup stakers outcome
>>=? fun (game_status, ctxt, balance_updates) ->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_timeout_result {game_status; consumed_gas; balance_updates}
in
return (ctxt, result, [])
| Sc_rollup_execute_outbox_message {rollup; cemented_commitment; output_proof}
->
Sc_rollup_operations.execute_outbox_message
ctxt
rollup
~cemented_commitment
~source
~output_proof
>|=? fun ({Sc_rollup_operations.paid_storage_size_diff; operations}, ctxt)
->
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_execute_outbox_message_result
{paid_storage_size_diff; balance_updates = []; consumed_gas}
in
(ctxt, result, operations)
| Sc_rollup_recover_bond {sc_rollup} ->
Sc_rollup.Stake_storage.withdraw_stake ctxt sc_rollup source
>>=? fun (ctxt, balance_updates) ->
let result =
Sc_rollup_recover_bond_result
{
consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt;
balance_updates;
}
in
return (ctxt, result, [])
| Sc_rollup_dal_slot_subscribe {rollup; slot_index} ->
let open Lwt_tzresult_syntax in
let+ slot_index, level, ctxt =
Sc_rollup.Dal_slot.subscribe ctxt rollup ~slot_index
in
let consumed_gas = Gas.consumed ~since:ctxt_before_op ~until:ctxt in
let result =
Sc_rollup_dal_slot_subscribe_result {consumed_gas; slot_index; level}
in
(ctxt, result, [])
| Zk_rollup_origination {public_parameters; circuits_info; init_state; nb_ops}
->
Zk_rollup_apply.originate
~ctxt_before_op
~ctxt
~public_parameters
~circuits_info
~init_state
~nb_ops
type success_or_failure = Success of context | Failure
let apply_internal_operations ctxt ~payer ~chain_id ops =
let rec apply ctxt applied worklist =
match worklist with
| [] -> Lwt.return (Success ctxt, List.rev applied)
| Script_typed_ir.Internal_operation ({source; operation; nonce} as op)
:: rest -> (
(if internal_nonce_already_recorded ctxt nonce then
let op_res = Apply_internal_results.internal_operation op in
fail (Internal_operation_replay (Internal_operation op_res))
else
let ctxt = record_internal_nonce ctxt nonce in
apply_internal_operation_contents
ctxt
~source
~payer
~chain_id
operation)
>>= function
| Error errors ->
let result =
pack_internal_operation_result
op
(Failed (Script_typed_ir.manager_kind op.operation, errors))
in
let skipped =
List.rev_map
(fun (Script_typed_ir.Internal_operation op) ->
pack_internal_operation_result
op
(Skipped (Script_typed_ir.manager_kind op.operation)))
rest
in
Lwt.return (Failure, List.rev (skipped @ (result :: applied)))
| Ok (ctxt, result, emitted) ->
apply
ctxt
(pack_internal_operation_result op (Applied result) :: applied)
(emitted @ rest))
in
apply ctxt [] ops
let burn_transaction_storage_fees ctxt trr ~storage_limit ~payer =
match trr with
| Transaction_to_contract_result payload ->
let consumed = payload.paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>>=? fun (ctxt, storage_limit, storage_bus) ->
(if payload.allocated_destination_contract then
Fees.burn_origination_fees ctxt ~storage_limit ~payer
else return (ctxt, storage_limit, []))
>>=? fun (ctxt, storage_limit, origination_bus) ->
let balance_updates =
storage_bus @ payload.balance_updates @ origination_bus
in
return
( ctxt,
storage_limit,
Transaction_to_contract_result
{
storage = payload.storage;
lazy_storage_diff = payload.lazy_storage_diff;
balance_updates;
originated_contracts = payload.originated_contracts;
consumed_gas = payload.consumed_gas;
storage_size = payload.storage_size;
paid_storage_size_diff = payload.paid_storage_size_diff;
allocated_destination_contract =
payload.allocated_destination_contract;
} )
| Transaction_to_tx_rollup_result payload ->
let consumed = payload.paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>>=? fun (ctxt, storage_limit, storage_bus) ->
let balance_updates = storage_bus @ payload.balance_updates in
return
( ctxt,
storage_limit,
Transaction_to_tx_rollup_result {payload with balance_updates} )
| Transaction_to_sc_rollup_result _ -> return (ctxt, storage_limit, trr)
let burn_origination_storage_fees ctxt
{
lazy_storage_diff;
balance_updates;
originated_contracts;
consumed_gas;
storage_size;
paid_storage_size_diff;
} ~storage_limit ~payer =
let consumed = paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>>=? fun (ctxt, storage_limit, storage_bus) ->
Fees.burn_origination_fees ctxt ~storage_limit ~payer
>>=? fun (ctxt, storage_limit, origination_bus) ->
let balance_updates = storage_bus @ origination_bus @ balance_updates in
return
( ctxt,
storage_limit,
{
lazy_storage_diff;
balance_updates;
originated_contracts;
consumed_gas;
storage_size;
paid_storage_size_diff;
} )
(** [burn_manager_storage_fees ctxt smopr storage_limit payer] burns the
storage fees associated to an external operation result [smopr].
Returns an updated context, an updated storage limit with the space consumed
by the operation subtracted, and [smopr] with the relevant balance updates
included. *)
let burn_manager_storage_fees :
type kind.
context ->
kind successful_manager_operation_result ->
storage_limit:Z.t ->
payer:public_key_hash ->
(context * Z.t * kind successful_manager_operation_result) tzresult Lwt.t =
fun ctxt smopr ~storage_limit ~payer ->
let payer = `Contract (Contract.Implicit payer) in
match smopr with
| Transaction_result transaction_result ->
burn_transaction_storage_fees
ctxt
transaction_result
~storage_limit
~payer
>>=? fun (ctxt, storage_limit, transaction_result) ->
return (ctxt, storage_limit, Transaction_result transaction_result)
| Origination_result origination_result ->
burn_origination_storage_fees
ctxt
origination_result
~storage_limit
~payer
>>=? fun (ctxt, storage_limit, origination_result) ->
return (ctxt, storage_limit, Origination_result origination_result)
| Reveal_result _ | Delegation_result _ -> return (ctxt, storage_limit, smopr)
| Register_global_constant_result payload ->
let consumed = payload.size_of_constant in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>|=? fun (ctxt, storage_limit, storage_bus) ->
let balance_updates = storage_bus @ payload.balance_updates in
( ctxt,
storage_limit,
Register_global_constant_result
{
balance_updates;
consumed_gas = payload.consumed_gas;
size_of_constant = payload.size_of_constant;
global_address = payload.global_address;
} )
| Set_deposits_limit_result _ -> return (ctxt, storage_limit, smopr)
| Increase_paid_storage_result _ -> return (ctxt, storage_limit, smopr)
| Tx_rollup_origination_result payload ->
Fees.burn_tx_rollup_origination_fees ctxt ~storage_limit ~payer
>|=? fun (ctxt, storage_limit, origination_bus) ->
let balance_updates = origination_bus @ payload.balance_updates in
( ctxt,
storage_limit,
Tx_rollup_origination_result {payload with balance_updates} )
| Tx_rollup_return_bond_result _ | Tx_rollup_remove_commitment_result _
| Tx_rollup_rejection_result _ | Tx_rollup_finalize_commitment_result _
| Tx_rollup_commit_result _ ->
return (ctxt, storage_limit, smopr)
| Transfer_ticket_result payload ->
let consumed = payload.paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>|=? fun (ctxt, storage_limit, storage_bus) ->
let balance_updates = payload.balance_updates @ storage_bus in
( ctxt,
storage_limit,
Transfer_ticket_result {payload with balance_updates} )
| Tx_rollup_submit_batch_result payload ->
let consumed = payload.paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>|=? fun (ctxt, storage_limit, storage_bus) ->
let balance_updates = storage_bus @ payload.balance_updates in
( ctxt,
storage_limit,
Tx_rollup_submit_batch_result {payload with balance_updates} )
| Tx_rollup_dispatch_tickets_result payload ->
let consumed = payload.paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>|=? fun (ctxt, storage_limit, storage_bus) ->
let balance_updates = storage_bus @ payload.balance_updates in
( ctxt,
storage_limit,
Tx_rollup_dispatch_tickets_result {payload with balance_updates} )
| Dal_publish_slot_header_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_originate_result payload ->
Fees.burn_sc_rollup_origination_fees
ctxt
~storage_limit
~payer
payload.size
>|=? fun (ctxt, storage_limit, balance_updates) ->
let result = Sc_rollup_originate_result {payload with balance_updates} in
(ctxt, storage_limit, result)
| Sc_rollup_add_messages_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_cement_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_publish_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_refute_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_timeout_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_execute_outbox_message_result
({paid_storage_size_diff; balance_updates; _} as payload) ->
let consumed = paid_storage_size_diff in
Fees.burn_storage_fees ctxt ~storage_limit ~payer consumed
>|=? fun (ctxt, storage_limit, storage_bus) ->
let balance_updates = storage_bus @ balance_updates in
( ctxt,
storage_limit,
Sc_rollup_execute_outbox_message_result {payload with balance_updates}
)
| Sc_rollup_recover_bond_result _ -> return (ctxt, storage_limit, smopr)
| Sc_rollup_dal_slot_subscribe_result _ -> return (ctxt, storage_limit, smopr)
| Zk_rollup_origination_result payload ->
Fees.burn_zk_rollup_origination_fees
ctxt
~storage_limit
~payer
payload.storage_size
>>=? fun (ctxt, storage_limit, balance_updates) ->
let result =
Zk_rollup_origination_result {payload with balance_updates}
in
return (ctxt, storage_limit, result)
(** [burn_internal_storage_fees ctxt smopr storage_limit payer] burns the
storage fees associated to an internal operation result [smopr].
Returns an updated context, an updated storage limit with the space consumed
by the operation subtracted, and [smopr] with the relevant balance updates
included. *)
let burn_internal_storage_fees :
type kind.
context ->
kind successful_internal_operation_result ->
storage_limit:Z.t ->
payer:public_key_hash ->
(context * Z.t * kind successful_internal_operation_result) tzresult Lwt.t =
fun ctxt smopr ~storage_limit ~payer ->
let payer = `Contract (Contract.Implicit payer) in
match smopr with
| ITransaction_result transaction_result ->
burn_transaction_storage_fees
ctxt
transaction_result
~storage_limit
~payer
>|=? fun (ctxt, storage_limit, transaction_result) ->
(ctxt, storage_limit, ITransaction_result transaction_result)
| IOrigination_result origination_result ->
burn_origination_storage_fees
ctxt
origination_result
~storage_limit
~payer
>|=? fun (ctxt, storage_limit, origination_result) ->
(ctxt, storage_limit, IOrigination_result origination_result)
| IDelegation_result _ -> return (ctxt, storage_limit, smopr)
| IEvent_result _ -> return (ctxt, storage_limit, smopr)
let apply_manager_contents (type kind) ctxt chain_id
(op : kind Kind.manager contents) :
(success_or_failure
* kind manager_operation_result
* packed_internal_operation_result list)
Lwt.t =
let (Manager_operation {source; operation; gas_limit; storage_limit; _}) =
op
in
(* We do not expose the internal scaling to the users. Instead, we multiply
the specified gas limit by the internal scaling. *)
let ctxt = Gas.set_limit ctxt gas_limit in
apply_manager_operation ctxt ~source ~chain_id operation >>= function
| Ok (ctxt, operation_results, internal_operations) -> (
apply_internal_operations ctxt ~payer:source ~chain_id internal_operations
>>= function
| Success ctxt, internal_operations_results -> (
burn_manager_storage_fees
ctxt
operation_results
~storage_limit
~payer:source
>>= function
| Ok (ctxt, storage_limit, operation_results) -> (
List.fold_left_es
(fun (ctxt, storage_limit, res) imopr ->
let (Internal_operation_result (op, mopr)) = imopr in
match mopr with
| Applied smopr ->
burn_internal_storage_fees
ctxt
smopr
~storage_limit
~payer:source
>>=? fun (ctxt, storage_limit, smopr) ->
let imopr =
Internal_operation_result (op, Applied smopr)
in
return (ctxt, storage_limit, imopr :: res)
| _ -> return (ctxt, storage_limit, imopr :: res))
(ctxt, storage_limit, [])
internal_operations_results
>|= function
| Ok (ctxt, _, internal_operations_results) ->
( Success ctxt,
Applied operation_results,
List.rev internal_operations_results )
| Error errors ->
( Failure,
Backtracked (operation_results, Some errors),
internal_operations_results ))
| Error errors ->
Lwt.return
( Failure,
Backtracked (operation_results, Some errors),
internal_operations_results ))
| Failure, internal_operations_results ->
Lwt.return
(Failure, Applied operation_results, internal_operations_results))
| Error errors ->
Lwt.return (Failure, Failed (manager_kind operation, errors), [])
(** An individual manager operation (either standalone or inside a
batch) together with the balance update corresponding to the
transfer of its fee. *)
type 'kind fees_updated_contents = {
contents : 'kind contents;
balance_updates : Receipt.balance_updates;
}
type _ fees_updated_contents_list =
| FeesUpdatedSingle :
'kind fees_updated_contents
-> 'kind fees_updated_contents_list
| FeesUpdatedCons :
'kind Kind.manager fees_updated_contents
* 'rest Kind.manager fees_updated_contents_list
-> ('kind * 'rest) Kind.manager fees_updated_contents_list
let rec mark_skipped :
type kind.
payload_producer:Signature.Public_key_hash.t ->
Level.t ->
kind Kind.manager fees_updated_contents_list ->
kind Kind.manager contents_result_list =
fun ~payload_producer level fees_updated_contents_list ->
match fees_updated_contents_list with
| FeesUpdatedSingle
{contents = Manager_operation {operation; _}; balance_updates} ->
Single_result
(Manager_operation_result
{
balance_updates;
operation_result = Skipped (manager_kind operation);
internal_operation_results = [];
})
| FeesUpdatedCons
({contents = Manager_operation {operation; _}; balance_updates}, rest) ->
Cons_result
( Manager_operation_result
{
balance_updates;
operation_result = Skipped (manager_kind operation);
internal_operation_results = [];
},
mark_skipped ~payload_producer level rest )
(** Return balance updates for fees, and an updated context that
accounts for:
- fees spending,
- counter incrementation,
- consumption of each operation's [gas_limit] from the available
block gas.
The {!type:Validate_operation.stamp} argument enforces that the
operation has already been validated by {!Validate_operation}. The
latter is responsible for ensuring that the operation is solvable,
i.e. its fees can be taken, i.e. [take_fees] cannot return an
error. *)
let take_fees ctxt (_ : Validate_operation.stamp) contents_list =
let open Lwt_tzresult_syntax in
let rec take_fees_rec :
type kind.
context ->
kind Kind.manager contents_list ->
(context * kind Kind.manager fees_updated_contents_list) tzresult Lwt.t =
fun ctxt contents_list ->
let contents_effects contents =
let (Manager_operation {source; fee; gas_limit; _}) = contents in
let*? ctxt = Gas.consume_limit_in_block ctxt gas_limit in
let* ctxt = Contract.increment_counter ctxt source in
let+ ctxt, balance_updates =
Token.transfer
ctxt
(`Contract (Contract.Implicit source))
`Block_fees
fee
in
(ctxt, {contents; balance_updates})
in
match contents_list with
| Single contents ->
let+ ctxt, fees_updated_contents = contents_effects contents in
(ctxt, FeesUpdatedSingle fees_updated_contents)
| Cons (contents, rest) ->
let* ctxt, fees_updated_contents = contents_effects contents in
let+ ctxt, result_rest = take_fees_rec ctxt rest in
(ctxt, FeesUpdatedCons (fees_updated_contents, result_rest))
in
let*! result = take_fees_rec ctxt contents_list in
Lwt.return (record_trace Error_while_taking_fees result)
let rec apply_manager_contents_list_rec :
type kind.
context ->
payload_producer:public_key_hash ->
Chain_id.t ->
kind Kind.manager fees_updated_contents_list ->
(success_or_failure * kind Kind.manager contents_result_list) Lwt.t =
fun ctxt ~payload_producer chain_id fees_updated_contents_list ->
let level = Level.current ctxt in
match fees_updated_contents_list with
| FeesUpdatedSingle {contents = Manager_operation _ as op; balance_updates} ->
apply_manager_contents ctxt chain_id op
>|= fun (ctxt_result, operation_result, internal_operation_results) ->
let result =
Manager_operation_result
{balance_updates; operation_result; internal_operation_results}
in
(ctxt_result, Single_result result)
| FeesUpdatedCons
({contents = Manager_operation _ as op; balance_updates}, rest) -> (
apply_manager_contents ctxt chain_id op >>= function
| Failure, operation_result, internal_operation_results ->
let result =
Manager_operation_result
{balance_updates; operation_result; internal_operation_results}
in
Lwt.return
( Failure,
Cons_result (result, mark_skipped ~payload_producer level rest) )
| Success ctxt, operation_result, internal_operation_results ->
let result =
Manager_operation_result
{balance_updates; operation_result; internal_operation_results}
in
apply_manager_contents_list_rec ctxt ~payload_producer chain_id rest
>|= fun (ctxt_result, results) ->
(ctxt_result, Cons_result (result, results)))
let mark_backtracked results =
let mark_results :
type kind.
kind Kind.manager contents_result -> kind Kind.manager contents_result =
fun results ->
let mark_manager_operation_result :
type kind.
kind manager_operation_result -> kind manager_operation_result =
function
| (Failed _ | Skipped _ | Backtracked _) as result -> result
| Applied result -> Backtracked (result, None)
in
let mark_internal_operation_result :
type kind.
kind internal_operation_result -> kind internal_operation_result =
function
| (Failed _ | Skipped _ | Backtracked _) as result -> result
| Applied result -> Backtracked (result, None)
in
let mark_internal_operation_results
(Internal_operation_result (kind, result)) =
Internal_operation_result (kind, mark_internal_operation_result result)
in
match results with
| Manager_operation_result op ->
Manager_operation_result
{
balance_updates = op.balance_updates;
operation_result = mark_manager_operation_result op.operation_result;
internal_operation_results =
List.map
mark_internal_operation_results
op.internal_operation_results;
}
in
let rec traverse_apply_results :
type kind.
kind Kind.manager contents_result_list ->
kind Kind.manager contents_result_list = function
| Single_result res -> Single_result (mark_results res)
| Cons_result (res, rest) ->
Cons_result (mark_results res, traverse_apply_results rest)
in
traverse_apply_results results
type apply_mode =
| Application (** Both partial and normal *)
| Full_construction
| Partial_construction of {predecessor_level : Level.t option}
(** This mode is intended to be used by a mempool. In this case,
[predecessor_level] has a value and is used to identify
grandparent endorsements (see [record_endorsement]
below). However, the [option] allows this mode to be hijacked in
other situations with no access to the predecessor level,
e.g. during an RPC call. *)
let record_operation (type kind) ctxt hash (operation : kind operation) :
context =
match operation.protocol_data.contents with
| Single (Preendorsement _) -> ctxt
| Single (Endorsement _) -> ctxt
| Single (Dal_slot_availability _) -> ctxt
| Single
( Failing_noop _ | Proposals _ | Ballot _ | Seed_nonce_revelation _
| Vdf_revelation _ | Double_endorsement_evidence _
| Double_preendorsement_evidence _ | Double_baking_evidence _
| Activate_account _ | Manager_operation _ )
| Cons (Manager_operation _, _) ->
record_non_consensus_operation_hash ctxt hash
let record_preendorsement ctxt (apply_mode : apply_mode)
(_ : Validate_operation.stamp) (content : consensus_content) :
(context * Kind.preendorsement contents_result_list) tzresult =
let open Tzresult_syntax in
let ctxt =
match apply_mode with
| Full_construction -> (
match Consensus.get_preendorsements_quorum_round ctxt with
| None -> Consensus.set_preendorsements_quorum_round ctxt content.round
| Some _ -> ctxt)
| Application | Partial_construction _ -> ctxt
in
match Slot.Map.find content.slot (Consensus.allowed_preendorsements ctxt) with
| None ->
(* This should not happen: operation validation should have failed. *)
error Faulty_validation_wrong_slot
| Some (_delegate_pk, delegate, preendorsement_power) ->
let* ctxt =
Consensus.record_preendorsement
ctxt
~initial_slot:content.slot
~power:preendorsement_power
content.round
in
return
( ctxt,
Single_result
(Preendorsement_result
{balance_updates = []; delegate; preendorsement_power}) )
let is_grandparent_endorsement apply_mode content =
match apply_mode with
| Partial_construction {predecessor_level = Some predecessor_level} ->
Raw_level.(succ content.level = predecessor_level.Level.level)
| _ -> false
let record_endorsement ctxt (apply_mode : apply_mode)
(_ : Validate_operation.stamp) (content : consensus_content) :
(context * Kind.endorsement contents_result_list) tzresult Lwt.t =
let open Lwt_tzresult_syntax in
let mk_endorsement_result delegate endorsement_power =
Single_result
(Endorsement_result {balance_updates = []; delegate; endorsement_power})
in
if is_grandparent_endorsement apply_mode content then
let level = Level.from_raw ctxt content.level in
let* ctxt, (_delegate_pk, delegate) =
Stake_distribution.slot_owner ctxt level content.slot
in
let*? ctxt = Consensus.record_grand_parent_endorsement ctxt delegate in
return (ctxt, mk_endorsement_result delegate 0)
else
match Slot.Map.find content.slot (Consensus.allowed_endorsements ctxt) with
| None ->
(* This should not happen: operation validation should have failed. *)
fail Faulty_validation_wrong_slot
| Some (_delegate_pk, delegate, power) ->
let*? ctxt =
Consensus.record_endorsement ctxt ~initial_slot:content.slot ~power
in
return (ctxt, mk_endorsement_result delegate power)
let apply_manager_contents_list ctxt ~payload_producer chain_id
fees_updated_contents_list =
apply_manager_contents_list_rec
ctxt
~payload_producer
chain_id
fees_updated_contents_list
>>= fun (ctxt_result, results) ->
match ctxt_result with
| Failure -> Lwt.return (ctxt (* backtracked *), mark_backtracked results)
| Success ctxt ->
Lazy_storage.cleanup_temporaries ctxt >|= fun ctxt -> (ctxt, results)
let apply_manager_operations ctxt ~payload_producer chain_id ~mempool_mode
op_validated_stamp contents_list =
let open Lwt_tzresult_syntax in
let ctxt = if mempool_mode then Gas.reset_block_gas ctxt else ctxt in
let* ctxt, fees_updated_contents_list =
take_fees ctxt op_validated_stamp contents_list
in
let*! ctxt, contents_result_list =
apply_manager_contents_list
ctxt
~payload_producer
chain_id
fees_updated_contents_list
in
return (ctxt, contents_result_list)
let punish_delegate ctxt delegate level mistake mk_result ~payload_producer =
let punish =
match mistake with
| `Double_baking -> Delegate.punish_double_baking
| `Double_endorsing -> Delegate.punish_double_endorsing
in
punish ctxt delegate level >>=? fun (ctxt, burned, punish_balance_updates) ->
(match Tez.(burned /? 2L) with
| Ok reward ->
Token.transfer
ctxt
`Double_signing_evidence_rewards
(`Contract (Contract.Implicit payload_producer))
reward
| Error _ -> (* reward is Tez.zero *) return (ctxt, []))
>|=? fun (ctxt, reward_balance_updates) ->
let balance_updates = reward_balance_updates @ punish_balance_updates in
(ctxt, Single_result (mk_result balance_updates))
let punish_double_endorsement_or_preendorsement (type kind) ctxt
~(op1 : kind Kind.consensus Operation.t) ~payload_producer :
(context
* kind Kind.double_consensus_operation_evidence contents_result_list)
tzresult
Lwt.t =
let mk_result (balance_updates : Receipt.balance_updates) :
kind Kind.double_consensus_operation_evidence contents_result =
match op1.protocol_data.contents with
| Single (Preendorsement _) ->
Double_preendorsement_evidence_result balance_updates
| Single (Endorsement _) ->
Double_endorsement_evidence_result balance_updates
in
match op1.protocol_data.contents with
| Single (Preendorsement e1) | Single (Endorsement e1) ->
let level = Level.from_raw ctxt e1.level in
Stake_distribution.slot_owner ctxt level e1.slot
>>=? fun (ctxt, (_delegate_pk, delegate)) ->
punish_delegate
ctxt
delegate
level
`Double_endorsing
mk_result
~payload_producer
let punish_double_baking ctxt (bh1 : Block_header.t) ~payload_producer =
Fitness.from_raw bh1.shell.fitness >>?= fun bh1_fitness ->
let round1 = Fitness.round bh1_fitness in
Raw_level.of_int32 bh1.shell.level >>?= fun raw_level ->
let level = Level.from_raw ctxt raw_level in
let committee_size = Constants.consensus_committee_size ctxt in
Round.to_slot round1 ~committee_size >>?= fun slot1 ->
Stake_distribution.slot_owner ctxt level slot1
>>=? fun (ctxt, (_delegate_pk, delegate)) ->
punish_delegate
ctxt
delegate
level
`Double_baking
~payload_producer
(fun balance_updates -> Double_baking_evidence_result balance_updates)
let apply_contents_list (type kind) ctxt chain_id (apply_mode : apply_mode)
~payload_producer op_validated_stamp (contents_list : kind contents_list) :
(context * kind contents_result_list) tzresult Lwt.t =
let mempool_mode =
match apply_mode with
| Partial_construction _ -> true
| Full_construction | Application -> false
in
match contents_list with
| Single (Preendorsement consensus_content) ->
record_preendorsement ctxt apply_mode op_validated_stamp consensus_content
|> Lwt.return
| Single (Endorsement consensus_content) ->
record_endorsement ctxt apply_mode op_validated_stamp consensus_content
| Single (Dal_slot_availability (endorser, slot_availability)) ->
(* DAL/FIXME https://gitlab.com/tezos/tezos/-/issues/3115
This is a temporary operation. We do no check for the
moment. In particular, this means we do not check the
signature. Consequently, it is really important to ensure this
operation cannot be included into a block when the feature flag
is not set. This is done in order to avoid modifying the
endorsement encoding. However, once the DAL will be ready, this
operation should be merged with an endorsement or at least
refined. *)
Dal_apply.apply_data_availability ctxt slot_availability ~endorser
>>=? fun ctxt ->
return
( ctxt,
Single_result (Dal_slot_availability_result {delegate = endorser}) )
| Single (Seed_nonce_revelation {level; nonce}) ->
let level = Level.from_raw ctxt level in
Nonce.reveal ctxt level nonce >>=? fun ctxt ->
let tip = Constants.seed_nonce_revelation_tip ctxt in
let contract = Contract.Implicit payload_producer in
Token.transfer ctxt `Revelation_rewards (`Contract contract) tip
>|=? fun (ctxt, balance_updates) ->
(ctxt, Single_result (Seed_nonce_revelation_result balance_updates))
| Single (Vdf_revelation {solution}) ->
Seed.update_seed ctxt solution >>=? fun ctxt ->
let tip = Constants.seed_nonce_revelation_tip ctxt in
let contract = Contract.Implicit payload_producer in
Token.transfer ctxt `Revelation_rewards (`Contract contract) tip
>|=? fun (ctxt, balance_updates) ->
(ctxt, Single_result (Vdf_revelation_result balance_updates))
| Single (Double_preendorsement_evidence {op1; op2 = _}) ->
punish_double_endorsement_or_preendorsement ctxt ~op1 ~payload_producer
| Single (Double_endorsement_evidence {op1; op2 = _}) ->
punish_double_endorsement_or_preendorsement ctxt ~op1 ~payload_producer
| Single (Double_baking_evidence {bh1; bh2 = _}) ->
punish_double_baking ctxt bh1 ~payload_producer
| Single (Activate_account {id = pkh; activation_code}) ->
let blinded_pkh =
Blinded_public_key_hash.of_ed25519_pkh activation_code pkh
in
let src = `Collected_commitments blinded_pkh in
let contract = Contract.Implicit (Signature.Ed25519 pkh) in
Token.balance ctxt src >>=? fun (ctxt, amount) ->
Token.transfer ctxt src (`Contract contract) amount
>>=? fun (ctxt, bupds) ->
return (ctxt, Single_result (Activate_account_result bupds))
| Single (Proposals _ as contents) ->
Amendment.apply_proposals ctxt chain_id contents
| Single (Ballot _ as contents) -> Amendment.apply_ballot ctxt contents
| Single (Failing_noop _) ->
(* This operation always fails. It should already have been
rejected by {!Validate_operation.validate_operation}. *)
fail Validate_errors.Failing_noop_error
| Single (Manager_operation _) ->
apply_manager_operations
ctxt
~payload_producer
chain_id
~mempool_mode
op_validated_stamp
contents_list
| Cons (Manager_operation _, _) ->
apply_manager_operations
ctxt
~payload_producer
chain_id
~mempool_mode
op_validated_stamp
contents_list
let apply_operation ctxt chain_id (apply_mode : apply_mode) ~payload_producer
op_validated_stamp hash operation =
let ctxt = Origination_nonce.init ctxt hash in
let ctxt = record_operation ctxt hash operation in
apply_contents_list
ctxt
chain_id
apply_mode
~payload_producer
op_validated_stamp
operation.protocol_data.contents
>|=? fun (ctxt, result) ->
let ctxt = Gas.set_unlimited ctxt in
let ctxt = Origination_nonce.unset ctxt in
(ctxt, {contents = result})
let may_start_new_cycle ctxt =
match Level.dawn_of_a_new_cycle ctxt with
| None -> return (ctxt, [], [])
| Some last_cycle ->
Seed.cycle_end ctxt last_cycle >>=? fun (ctxt, unrevealed) ->
Delegate.cycle_end ctxt last_cycle unrevealed
>>=? fun (ctxt, balance_updates, deactivated) ->
Bootstrap.cycle_end ctxt last_cycle >|=? fun ctxt ->
(ctxt, balance_updates, deactivated)
let init_allowed_consensus_operations ctxt ~endorsement_level
~preendorsement_level =
Delegate.prepare_stake_distribution ctxt >>=? fun ctxt ->
(if Level.(endorsement_level = preendorsement_level) then
Baking.endorsing_rights_by_first_slot ctxt endorsement_level
>>=? fun (ctxt, slots) ->
let consensus_operations = slots in
return (ctxt, consensus_operations, consensus_operations)
else
Baking.endorsing_rights_by_first_slot ctxt endorsement_level
>>=? fun (ctxt, endorsements_slots) ->
let endorsements = endorsements_slots in
Baking.endorsing_rights_by_first_slot ctxt preendorsement_level
>>=? fun (ctxt, preendorsements_slots) ->
let preendorsements = preendorsements_slots in
return (ctxt, endorsements, preendorsements))
>>=? fun (ctxt, allowed_endorsements, allowed_preendorsements) ->
return
(Consensus.initialize_consensus_operation
ctxt
~allowed_endorsements
~allowed_preendorsements)
let apply_liquidity_baking_subsidy ctxt ~toggle_vote =
Liquidity_baking.on_subsidy_allowed
ctxt
~toggle_vote
(fun ctxt liquidity_baking_cpmm_contract_hash ->
let liquidity_baking_cpmm_contract =
Contract.Originated liquidity_baking_cpmm_contract_hash
in
let ctxt =
(* We set a gas limit of 1/20th the block limit, which is ~10x
actual usage here in Granada. Gas consumed is reported in
the Transaction receipt, but not counted towards the block
limit. The gas limit is reset to unlimited at the end of
this function.*)
Gas.set_limit
ctxt
(Gas.Arith.integral_exn
(Z.div
(Gas.Arith.integral_to_z
(Constants.hard_gas_limit_per_block ctxt))
(Z.of_int 20)))
in
let backtracking_ctxt = ctxt in
(let liquidity_baking_subsidy = Constants.liquidity_baking_subsidy ctxt in
(* credit liquidity baking subsidy to CPMM contract *)
Token.transfer
~origin:Subsidy
ctxt
`Liquidity_baking_subsidies
(`Contract liquidity_baking_cpmm_contract)
liquidity_baking_subsidy
>>=? fun (ctxt, balance_updates) ->
Script_cache.find ctxt liquidity_baking_cpmm_contract_hash
>>=? fun (ctxt, cache_key, script) ->
match script with
| None -> fail (Script_tc_errors.No_such_entrypoint Entrypoint.default)
| Some (script, script_ir) -> (
(* Token.transfer which is being called above already loads this
value into the Irmin cache, so no need to burn gas for it. *)
Contract.get_balance ctxt liquidity_baking_cpmm_contract
>>=? fun balance ->
let now = Script_timestamp.now ctxt in
let level =
(Level.current ctxt).level |> Raw_level.to_int32
|> Script_int.of_int32 |> Script_int.abs
in
let step_constants =
let open Script_interpreter in
(* Using dummy values for source, payer, and chain_id
since they are not used within the CPMM default
entrypoint. *)
{
source = liquidity_baking_cpmm_contract;
payer = Signature.Public_key_hash.zero;
self = liquidity_baking_cpmm_contract_hash;
amount = liquidity_baking_subsidy;
balance;
chain_id = Chain_id.zero;
now;
level;
}
in
(*
Call CPPM default entrypoint with parameter Unit.
This is necessary for the CPMM's xtz_pool in storage to
increase since it cannot use BALANCE due to a transfer attack.
Mimicks a transaction.
There is no:
- storage burn (extra storage is free)
- fees (the operation is mandatory)
*)
Script_interpreter.execute_with_typed_parameter
ctxt
Optimized
step_constants
~script
~parameter:()
~parameter_ty:Unit_t
~cached_script:(Some script_ir)
~location:Micheline.dummy_location
~entrypoint:Entrypoint.default
~internal:false
>>=? fun ( {
script = updated_cached_script;
code_size = updated_size;
storage;
lazy_storage_diff;
operations;
ticket_diffs;
},
ctxt ) ->
match operations with
| _ :: _ ->
(* No internal operations are expected here. Something bad may be happening. *)
return (backtracking_ctxt, [])
| [] ->
(* update CPMM storage *)
update_script_storage_and_ticket_balances
ctxt
~self:liquidity_baking_cpmm_contract
storage
lazy_storage_diff
ticket_diffs
operations
>>=? fun (ticket_table_size_diff, ctxt) ->
Fees.record_paid_storage_space
ctxt
liquidity_baking_cpmm_contract
>>=? fun (ctxt, new_size, paid_storage_size_diff) ->
Ticket_balance.adjust_storage_space
ctxt
~storage_diff:ticket_table_size_diff
>>=? fun (ticket_paid_storage_diff, ctxt) ->
let consumed_gas =
Gas.consumed ~since:backtracking_ctxt ~until:ctxt
in
Script_cache.update
ctxt
cache_key
( {script with storage = Script.lazy_expr storage},
updated_cached_script )
updated_size
>>?= fun ctxt ->
let result =
Transaction_result
(Transaction_to_contract_result
{
storage = Some storage;
lazy_storage_diff;
balance_updates;
(* At this point in application the
origination nonce has not been initialized
so it's not possible to originate new
contracts. We've checked above that none
were originated. *)
originated_contracts = [];
consumed_gas;
storage_size = new_size;
paid_storage_size_diff =
Z.add paid_storage_size_diff ticket_paid_storage_diff;
allocated_destination_contract = false;
})
in
let ctxt = Gas.set_unlimited ctxt in
return (ctxt, [Successful_manager_result result])))
>|= function
| Ok (ctxt, results) -> Ok (ctxt, results)
| Error _ ->
(* Do not fail if something bad happens during CPMM contract call. *)
let ctxt = Gas.set_unlimited backtracking_ctxt in
Ok (ctxt, []))
type 'a full_construction = {
ctxt : t;
protocol_data : 'a;
payload_producer : Signature.public_key_hash;
block_producer : Signature.public_key_hash;
round : Round.t;
implicit_operations_results : packed_successful_manager_operation_result list;
liquidity_baking_toggle_ema : Liquidity_baking.Toggle_EMA.t;
}
let begin_full_construction ctxt ~predecessor_timestamp ~predecessor_level
~predecessor_round ~round protocol_data =
let round_durations = Constants.round_durations ctxt in
let timestamp = Timestamp.current ctxt in
Block_header.check_timestamp
round_durations
~timestamp
~round
~predecessor_timestamp
~predecessor_round
>>?= fun () ->
let current_level = Level.current ctxt in
Stake_distribution.baking_rights_owner ctxt current_level ~round
>>=? fun (ctxt, _slot, (_block_producer_pk, block_producer)) ->
Delegate.frozen_deposits ctxt block_producer >>=? fun frozen_deposits ->
fail_unless
Tez.(frozen_deposits.current_amount > zero)
(Zero_frozen_deposits block_producer)
>>=? fun () ->
Stake_distribution.baking_rights_owner
ctxt
current_level
~round:protocol_data.Block_header.payload_round
>>=? fun (ctxt, _slot, (_payload_producer_pk, payload_producer)) ->
init_allowed_consensus_operations
ctxt
~endorsement_level:predecessor_level
~preendorsement_level:current_level
>>=? fun ctxt ->
let toggle_vote = protocol_data.liquidity_baking_toggle_vote in
apply_liquidity_baking_subsidy ctxt ~toggle_vote
>|=? fun ( ctxt,
liquidity_baking_operations_results,
liquidity_baking_toggle_ema ) ->
{
ctxt;
protocol_data;
payload_producer;
block_producer;
round;
implicit_operations_results = liquidity_baking_operations_results;
liquidity_baking_toggle_ema;
}
let begin_partial_construction ctxt ~predecessor_level ~toggle_vote =
(* In the mempool, only consensus operations for [predecessor_level]
(that is, head's level) are allowed, contrary to block validation
where endorsements are for the previous level and
preendorsements, if any, for the block's level. *)
init_allowed_consensus_operations
ctxt
~endorsement_level:predecessor_level
~preendorsement_level:predecessor_level
>>=? fun ctxt -> apply_liquidity_baking_subsidy ctxt ~toggle_vote
let begin_application ctxt chain_id (block_header : Block_header.t) fitness
~predecessor_timestamp ~predecessor_level ~predecessor_round =
let round = Fitness.round fitness in
let current_level = Level.current ctxt in
Stake_distribution.baking_rights_owner ctxt current_level ~round
>>=? fun (ctxt, _slot, (block_producer_pk, block_producer)) ->
let timestamp = block_header.shell.timestamp in
Block_header.begin_validate_block_header
~block_header
~chain_id
~predecessor_timestamp
~predecessor_round
~fitness
~timestamp
~delegate_pk:block_producer_pk
~round_durations:(Constants.round_durations ctxt)
~proof_of_work_threshold:(Constants.proof_of_work_threshold ctxt)
~expected_commitment:current_level.expected_commitment
>>?= fun () ->
Delegate.frozen_deposits ctxt block_producer >>=? fun frozen_deposits ->
fail_unless
Tez.(frozen_deposits.current_amount > zero)
(Zero_frozen_deposits block_producer)
>>=? fun () ->
Stake_distribution.baking_rights_owner
ctxt
current_level
~round:block_header.protocol_data.contents.payload_round
>>=? fun (ctxt, _slot, (payload_producer_pk, _payload_producer)) ->
init_allowed_consensus_operations
ctxt
~endorsement_level:predecessor_level
~preendorsement_level:current_level
>>=? fun ctxt ->
let toggle_vote =
block_header.Block_header.protocol_data.contents
.liquidity_baking_toggle_vote
in
apply_liquidity_baking_subsidy ctxt ~toggle_vote
>|=? fun ( ctxt,
liquidity_baking_operations_results,
liquidity_baking_toggle_ema ) ->
( ctxt,
payload_producer_pk,
block_producer,
liquidity_baking_operations_results,
liquidity_baking_toggle_ema )
type finalize_application_mode =
| Finalize_full_construction of {
level : Raw_level.t;
predecessor_round : Round.t;
}
| Finalize_application of Fitness.t
let compute_payload_hash (ctxt : context) ~(predecessor : Block_hash.t)
~(payload_round : Round.t) : Block_payload_hash.t =
let non_consensus_operations = non_consensus_operations ctxt in
let operations_hash = Operation_list_hash.compute non_consensus_operations in
Block_payload.hash ~predecessor payload_round operations_hash
let are_endorsements_required ctxt ~level =
First_level_of_protocol.get ctxt >|=? fun first_level ->
(* NB: the first level is the level of the migration block. There
are no endorsements for this block. Therefore the block at the
next level cannot contain endorsements. *)
let level_position_in_protocol = Raw_level.diff level first_level in
Compare.Int32.(level_position_in_protocol > 1l)
let check_minimum_endorsements ~endorsing_power ~minimum =
error_when
Compare.Int.(endorsing_power < minimum)
(Not_enough_endorsements {required = minimum; provided = endorsing_power})
let finalize_application_check_validity ctxt (mode : finalize_application_mode)
protocol_data ~round ~predecessor ~endorsing_power ~consensus_threshold
~required_endorsements =
(if required_endorsements then
check_minimum_endorsements ~endorsing_power ~minimum:consensus_threshold
else Result.return_unit)
>>?= fun () ->
let block_payload_hash =
compute_payload_hash
ctxt
~predecessor
~payload_round:protocol_data.Block_header.payload_round
in
let locked_round_evidence =
Option.map
(fun (preendorsement_round, preendorsement_count) ->
Block_header.{preendorsement_round; preendorsement_count})
(Consensus.locked_round_evidence ctxt)
in
(match mode with
| Finalize_application fitness -> ok fitness
| Finalize_full_construction {level; predecessor_round} ->
let locked_round =
match locked_round_evidence with
| None -> None
| Some {preendorsement_round; _} -> Some preendorsement_round
in
Fitness.create ~level ~round ~predecessor_round ~locked_round)
>>?= fun fitness ->
let checkable_payload_hash : Block_header.checkable_payload_hash =
match mode with
| Finalize_application _ -> Expected_payload_hash block_payload_hash
| Finalize_full_construction _ -> (
match locked_round_evidence with
| Some _ -> Expected_payload_hash block_payload_hash
| None ->
(* In full construction, when there is no locked round
evidence (and thus no preendorsements), the baker cannot
know the payload hash before selecting the operations. We
may dismiss checking the initially given
payload_hash. However, to be valid, the baker must patch
the resulting block header with the actual payload
hash. *)
No_check)
in
Block_header.finalize_validate_block_header
~block_header_contents:protocol_data
~round
~fitness
~checkable_payload_hash
~locked_round_evidence
~consensus_threshold
>>?= fun () -> return (fitness, block_payload_hash)
let record_endorsing_participation ctxt =
let validators = Consensus.allowed_endorsements ctxt in
Slot.Map.fold_es
(fun initial_slot (_delegate_pk, delegate, power) ctxt ->
let participation =
if Slot.Set.mem initial_slot (Consensus.endorsements_seen ctxt) then
Delegate.Participated
else Delegate.Didn't_participate
in
Delegate.record_endorsing_participation
ctxt
~delegate
~participation
~endorsing_power:power)
validators
ctxt
let finalize_application ctxt (mode : finalize_application_mode) protocol_data
~payload_producer ~block_producer liquidity_baking_toggle_ema
implicit_operations_results ~round ~predecessor ~migration_balance_updates =
(* Then we finalize the consensus. *)
let level = Level.current ctxt in
let block_endorsing_power = Consensus.current_endorsement_power ctxt in
let consensus_threshold = Constants.consensus_threshold ctxt in
are_endorsements_required ctxt ~level:level.level
>>=? fun required_endorsements ->
finalize_application_check_validity
ctxt
mode
protocol_data
~round
~predecessor
~endorsing_power:block_endorsing_power
~consensus_threshold
~required_endorsements
>>=? fun (fitness, block_payload_hash) ->
(* from this point nothing should fail *)
(* We mark the endorsement branch as the grand parent branch when
accessible. This will not be present before the first two blocks
of tenderbake. *)
(match Consensus.endorsement_branch ctxt with
| Some predecessor_branch ->
Consensus.store_grand_parent_branch ctxt predecessor_branch >>= return
| None -> return ctxt)
>>=? fun ctxt ->
(* We mark the current payload hash as the predecessor one => this
will only be accessed by the successor block now. *)
Consensus.store_endorsement_branch ctxt (predecessor, block_payload_hash)
>>= fun ctxt ->
Round.update ctxt round >>=? fun ctxt ->
(* end of level *)
(match protocol_data.Block_header.seed_nonce_hash with
| None -> return ctxt
| Some nonce_hash ->
Nonce.record_hash ctxt {nonce_hash; delegate = block_producer})
>>=? fun ctxt ->
(if required_endorsements then
record_endorsing_participation ctxt >>=? fun ctxt ->
Baking.bonus_baking_reward ctxt ~endorsing_power:block_endorsing_power
>>?= fun rewards_bonus -> return (ctxt, Some rewards_bonus)
else return (ctxt, None))
>>=? fun (ctxt, reward_bonus) ->
let baking_reward = Constants.baking_reward_fixed_portion ctxt in
Delegate.record_baking_activity_and_pay_rewards_and_fees
ctxt
~payload_producer
~block_producer
~baking_reward
~reward_bonus
>>=? fun (ctxt, baking_receipts) ->
(* if end of nonce revelation period, compute seed *)
(if Level.may_compute_randao ctxt then Seed.compute_randao ctxt
else return ctxt)
>>=? fun ctxt ->
(if Level.may_snapshot_stake_distribution ctxt then
Stake_distribution.snapshot ctxt
else return ctxt)
>>=? fun ctxt ->
may_start_new_cycle ctxt
>>=? fun (ctxt, cycle_end_balance_updates, deactivated) ->
Amendment.may_start_new_voting_period ctxt >>=? fun ctxt ->
Dal_apply.dal_finalisation ctxt >>=? fun (ctxt, dal_slot_availability) ->
let balance_updates =
migration_balance_updates @ baking_receipts @ cycle_end_balance_updates
in
let consumed_gas =
Gas.Arith.sub
(Gas.Arith.fp @@ Constants.hard_gas_limit_per_block ctxt)
(Gas.block_level ctxt)
in
Voting_period.get_rpc_current_info ctxt >|=? fun voting_period_info ->
let receipt =
Apply_results.
{
proposer = payload_producer;
baker = block_producer;
level_info = level;
voting_period_info;
nonce_hash = protocol_data.seed_nonce_hash;
consumed_gas;
deactivated;
balance_updates;
liquidity_baking_toggle_ema;
implicit_operations_results;
dal_slot_availability;
}
in
(ctxt, fitness, receipt)
let value_of_key ctxt k = Cache.Admin.value_of_key ctxt k