Source file raw_context.ml
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module Int_set = Set.Make (Compare.Int)
type consensus_pk = {
delegate : Signature.Public_key_hash.t;
consensus_pk : Signature.Public_key.t;
consensus_pkh : Signature.Public_key_hash.t;
}
let consensus_pk_encoding =
let open Data_encoding in
conv
(fun {delegate; consensus_pk; consensus_pkh} ->
if Signature.Public_key_hash.equal consensus_pkh delegate then
(consensus_pk, None)
else (consensus_pk, Some delegate))
(fun (consensus_pk, delegate) ->
let consensus_pkh = Signature.Public_key.hash consensus_pk in
let delegate =
match delegate with None -> consensus_pkh | Some del -> del
in
{delegate; consensus_pk; consensus_pkh})
(obj2
(req "consensus_pk" Signature.Public_key.encoding)
(opt "delegate" Signature.Public_key_hash.encoding))
module Raw_consensus = struct
(** Consensus operations are indexed by their [initial slots]. Given
a delegate, the [initial slot] is the lowest slot assigned to
this delegate. *)
type t = {
current_endorsement_power : int;
(** Number of endorsement slots recorded for the current block. *)
allowed_endorsements : (consensus_pk * int) Slot_repr.Map.t;
(** Endorsements rights for the current block. Only an endorsement
for the lowest slot in the block can be recorded. The map
associates to each initial slot the [pkh] associated to this
slot with its power. *)
allowed_preendorsements : (consensus_pk * int) Slot_repr.Map.t;
(** Preendorsements rights for the current block. Only a preendorsement
for the lowest slot in the block can be recorded. The map
associates to each initial slot the [pkh] associated to this
slot with its power. *)
grand_parent_endorsements_seen : Signature.Public_key_hash.Set.t;
(** Record the endorsements already seen for the grand
parent. This only useful for the partial construction mode. *)
endorsements_seen : Slot_repr.Set.t;
(** Record the endorsements already seen. Only initial slots are indexed. *)
preendorsements_seen : Slot_repr.Set.t;
(** Record the preendorsements already seen. Only initial slots
are indexed. *)
locked_round_evidence : (Round_repr.t * int) option;
(** Record the preendorsement power for a locked round. *)
preendorsements_quorum_round : Round_repr.t option;
(** in block construction mode, record the round of preendorsements
included in a block. *)
endorsement_branch : (Block_hash.t * Block_payload_hash.t) option;
grand_parent_branch : (Block_hash.t * Block_payload_hash.t) option;
}
(** Invariant:
- [slot \in endorsements_seen => Int_map.mem slot allowed_endorsements]
- [slot \in preendorsements_seen => Int_map.mem slot allowed_preendorsements]
- [ |endorsements_seen| > 0 => |included endorsements| > 0]
*)
let empty : t =
{
current_endorsement_power = 0;
allowed_endorsements = Slot_repr.Map.empty;
allowed_preendorsements = Slot_repr.Map.empty;
grand_parent_endorsements_seen = Signature.Public_key_hash.Set.empty;
endorsements_seen = Slot_repr.Set.empty;
preendorsements_seen = Slot_repr.Set.empty;
locked_round_evidence = None;
preendorsements_quorum_round = None;
endorsement_branch = None;
grand_parent_branch = None;
}
type error += Double_inclusion_of_consensus_operation
let () =
register_error_kind
`Branch
~id:"operation.double_inclusion_of_consensus_operation"
~title:"Double inclusion of consensus operation"
~description:"double inclusion of consensus operation"
~pp:(fun ppf () ->
Format.fprintf ppf "Double inclusion of consensus operation")
Data_encoding.empty
(function
| Double_inclusion_of_consensus_operation -> Some () | _ -> None)
(fun () -> Double_inclusion_of_consensus_operation)
let record_grand_parent_endorsement t pkh =
error_when
(Signature.Public_key_hash.Set.mem pkh t.grand_parent_endorsements_seen)
Double_inclusion_of_consensus_operation
>|? fun () ->
{
t with
grand_parent_endorsements_seen =
Signature.Public_key_hash.Set.add pkh t.grand_parent_endorsements_seen;
}
let record_endorsement t ~initial_slot ~power =
error_when
(Slot_repr.Set.mem initial_slot t.endorsements_seen)
Double_inclusion_of_consensus_operation
>|? fun () ->
{
t with
current_endorsement_power = t.current_endorsement_power + power;
endorsements_seen = Slot_repr.Set.add initial_slot t.endorsements_seen;
}
let record_preendorsement ~initial_slot ~power round t =
error_when
(Slot_repr.Set.mem initial_slot t.preendorsements_seen)
Double_inclusion_of_consensus_operation
>|? fun () ->
let locked_round_evidence =
match t.locked_round_evidence with
| None -> Some (round, power)
| Some (_stored_round, evidences) ->
Some (round, evidences + power)
in
{
t with
locked_round_evidence;
preendorsements_seen =
Slot_repr.Set.add initial_slot t.preendorsements_seen;
}
let set_preendorsements_quorum_round round t =
match t.preendorsements_quorum_round with
| Some round' ->
assert (Round_repr.equal round round') ;
t
| None -> {t with preendorsements_quorum_round = Some round}
let initialize_with_endorsements_and_preendorsements ~allowed_endorsements
~allowed_preendorsements t =
{t with allowed_endorsements; allowed_preendorsements}
let locked_round_evidence t = t.locked_round_evidence
let endorsement_branch t = t.endorsement_branch
let grand_parent_branch t = t.grand_parent_branch
let set_endorsement_branch t endorsement_branch =
{t with endorsement_branch = Some endorsement_branch}
let set_grand_parent_branch t grand_parent_branch =
{t with grand_parent_branch = Some grand_parent_branch}
end
type dal_committee = {
pkh_to_shards :
(Dal_attestation_repr.shard_index * int) Signature.Public_key_hash.Map.t;
shard_to_pkh : Signature.Public_key_hash.t Dal_attestation_repr.Shard_map.t;
}
let empty_dal_committee =
{
pkh_to_shards = Signature.Public_key_hash.Map.empty;
shard_to_pkh = Dal_attestation_repr.Shard_map.empty;
}
type back = {
context : Context.t;
constants : Constants_parametric_repr.t;
round_durations : Round_repr.Durations.t;
cycle_eras : Level_repr.cycle_eras;
level : Level_repr.t;
predecessor_timestamp : Time.t;
timestamp : Time.t;
fees : Tez_repr.t;
origination_nonce : Origination_nonce.t option;
temporary_lazy_storage_ids : Lazy_storage_kind.Temp_ids.t;
internal_nonce : int;
internal_nonces_used : Int_set.t;
remaining_block_gas : Gas_limit_repr.Arith.fp;
unlimited_operation_gas : bool;
consensus : Raw_consensus.t;
non_consensus_operations_rev : Operation_hash.t list;
dictator_proposal_seen : bool;
sampler_state : (Seed_repr.seed * consensus_pk Sampler.t) Cycle_repr.Map.t;
stake_distribution_for_current_cycle :
Tez_repr.t Signature.Public_key_hash.Map.t option;
tx_rollup_current_messages :
Tx_rollup_inbox_repr.Merkle.tree Tx_rollup_repr.Map.t;
sc_rollup_current_messages : Sc_rollup_inbox_merkelized_payload_hashes_repr.t;
dal_slot_fee_market : Dal_slot_repr.Slot_market.t;
dal_attestation_slot_accountability : Dal_attestation_repr.Accountability.t;
dal_committee : dal_committee;
}
type t = {remaining_operation_gas : Gas_limit_repr.Arith.fp; back : back}
type root = t
let[@inline] context ctxt = ctxt.back.context
let[@inline] current_level ctxt = ctxt.back.level
let[@inline] predecessor_timestamp ctxt = ctxt.back.predecessor_timestamp
let[@inline] current_timestamp ctxt = ctxt.back.timestamp
let[@inline] round_durations ctxt = ctxt.back.round_durations
let[@inline] cycle_eras ctxt = ctxt.back.cycle_eras
let[@inline] constants ctxt = ctxt.back.constants
let[@inline] tx_rollup ctxt = ctxt.back.constants.tx_rollup
let[@inline] sc_rollup ctxt = ctxt.back.constants.sc_rollup
let[@inline] zk_rollup ctxt = ctxt.back.constants.zk_rollup
let[@inline] recover ctxt = ctxt.back.context
let[@inline] fees ctxt = ctxt.back.fees
let[@inline] origination_nonce ctxt = ctxt.back.origination_nonce
let[@inline] internal_nonce ctxt = ctxt.back.internal_nonce
let[@inline] internal_nonces_used ctxt = ctxt.back.internal_nonces_used
let[@inline] remaining_block_gas ctxt = ctxt.back.remaining_block_gas
let[@inline] unlimited_operation_gas ctxt = ctxt.back.unlimited_operation_gas
let[@inline] temporary_lazy_storage_ids ctxt =
ctxt.back.temporary_lazy_storage_ids
let[@inline] remaining_operation_gas ctxt = ctxt.remaining_operation_gas
let[@inline] non_consensus_operations_rev ctxt =
ctxt.back.non_consensus_operations_rev
let[@inline] dictator_proposal_seen ctxt = ctxt.back.dictator_proposal_seen
let[@inline] sampler_state ctxt = ctxt.back.sampler_state
let[@inline] update_back ctxt back = {ctxt with back}
let[@inline] update_remaining_block_gas ctxt remaining_block_gas =
update_back ctxt {ctxt.back with remaining_block_gas}
let[@inline] update_remaining_operation_gas ctxt remaining_operation_gas =
{ctxt with remaining_operation_gas}
let[@inline] update_unlimited_operation_gas ctxt unlimited_operation_gas =
update_back ctxt {ctxt.back with unlimited_operation_gas}
let[@inline] update_context ctxt context =
update_back ctxt {ctxt.back with context}
let[@inline] update_constants ctxt constants =
update_back ctxt {ctxt.back with constants}
let[@inline] update_origination_nonce ctxt origination_nonce =
update_back ctxt {ctxt.back with origination_nonce}
let[@inline] update_internal_nonce ctxt internal_nonce =
update_back ctxt {ctxt.back with internal_nonce}
let[@inline] update_internal_nonces_used ctxt internal_nonces_used =
update_back ctxt {ctxt.back with internal_nonces_used}
let[@inline] update_fees ctxt fees = update_back ctxt {ctxt.back with fees}
let[@inline] update_temporary_lazy_storage_ids ctxt temporary_lazy_storage_ids =
update_back ctxt {ctxt.back with temporary_lazy_storage_ids}
let[@inline] update_non_consensus_operations_rev ctxt
non_consensus_operations_rev =
update_back ctxt {ctxt.back with non_consensus_operations_rev}
let[@inline] update_dictator_proposal_seen ctxt dictator_proposal_seen =
update_back ctxt {ctxt.back with dictator_proposal_seen}
let[@inline] update_sampler_state ctxt sampler_state =
update_back ctxt {ctxt.back with sampler_state}
type error += Too_many_internal_operations
type error += Block_quota_exceeded
type error += Operation_quota_exceeded
type error += Stake_distribution_not_set
type error += Sampler_already_set of Cycle_repr.t
let () =
let open Data_encoding in
register_error_kind
`Permanent
~id:"too_many_internal_operations"
~title:"Too many internal operations"
~description:
"A transaction exceeded the hard limit of internal operations it can emit"
empty
(function Too_many_internal_operations -> Some () | _ -> None)
(fun () -> Too_many_internal_operations) ;
register_error_kind
`Temporary
~id:"gas_exhausted.operation"
~title:"Gas quota exceeded for the operation"
~description:
"A script or one of its callee took more time than the operation said it \
would"
empty
(function Operation_quota_exceeded -> Some () | _ -> None)
(fun () -> Operation_quota_exceeded) ;
register_error_kind
`Temporary
~id:"gas_exhausted.block"
~title:"Gas quota exceeded for the block"
~description:
"The sum of gas consumed by all the operations in the block exceeds the \
hard gas limit per block"
empty
(function Block_quota_exceeded -> Some () | _ -> None)
(fun () -> Block_quota_exceeded) ;
register_error_kind
`Permanent
~id:"delegate.stake_distribution_not_set"
~title:"Stake distribution not set"
~description:"The stake distribution for the current cycle is not set."
~pp:(fun ppf () ->
Format.fprintf
ppf
"The stake distribution for the current cycle is not set.")
empty
(function Stake_distribution_not_set -> Some () | _ -> None)
(fun () -> Stake_distribution_not_set) ;
register_error_kind
`Permanent
~id:"sampler_already_set"
~title:"Sampler already set"
~description:
"Internal error: Raw_context.set_sampler_for_cycle was called twice for \
a given cycle"
~pp:(fun ppf c ->
Format.fprintf
ppf
"Internal error: sampler already set for cycle %a."
Cycle_repr.pp
c)
(obj1 (req "cycle" Cycle_repr.encoding))
(function Sampler_already_set c -> Some c | _ -> None)
(fun c -> Sampler_already_set c)
let fresh_internal_nonce ctxt =
if Compare.Int.(internal_nonce ctxt >= 65_535) then
error Too_many_internal_operations
else
ok
(update_internal_nonce ctxt (internal_nonce ctxt + 1), internal_nonce ctxt)
let reset_internal_nonce ctxt =
let ctxt = update_internal_nonce ctxt 0 in
update_internal_nonces_used ctxt Int_set.empty
let record_internal_nonce ctxt k =
update_internal_nonces_used ctxt (Int_set.add k (internal_nonces_used ctxt))
let internal_nonce_already_recorded ctxt k =
Int_set.mem k (internal_nonces_used ctxt)
let get_collected_fees ctxt = fees ctxt
let credit_collected_fees_only_call_from_token ctxt fees' =
let previous = get_collected_fees ctxt in
Tez_repr.(previous +? fees') >|? fun fees -> update_fees ctxt fees
let spend_collected_fees_only_call_from_token ctxt fees' =
let previous = get_collected_fees ctxt in
Tez_repr.(previous -? fees') >|? fun fees -> update_fees ctxt fees
type error += Undefined_operation_nonce
let () =
let open Data_encoding in
register_error_kind
`Permanent
~id:"undefined_operation_nonce"
~title:"Ill timed access to the origination nonce"
~description:
"An origination was attempted out of the scope of a manager operation"
empty
(function Undefined_operation_nonce -> Some () | _ -> None)
(fun () -> Undefined_operation_nonce)
let init_origination_nonce ctxt operation_hash =
let origination_nonce = Some (Origination_nonce.initial operation_hash) in
update_origination_nonce ctxt origination_nonce
let increment_origination_nonce ctxt =
match origination_nonce ctxt with
| None -> error Undefined_operation_nonce
| Some cur_origination_nonce ->
let origination_nonce =
Some (Origination_nonce.incr cur_origination_nonce)
in
let ctxt = update_origination_nonce ctxt origination_nonce in
ok (ctxt, cur_origination_nonce)
let get_origination_nonce ctxt =
match origination_nonce ctxt with
| None -> error Undefined_operation_nonce
| Some origination_nonce -> ok origination_nonce
let unset_origination_nonce ctxt = update_origination_nonce ctxt None
let gas_level ctxt =
let open Gas_limit_repr in
if unlimited_operation_gas ctxt then Unaccounted
else Limited {remaining = remaining_operation_gas ctxt}
let block_gas_level = remaining_block_gas
let consume_gas_limit_in_block ctxt gas_limit =
let open Gas_limit_repr in
check_gas_limit
~hard_gas_limit_per_operation:(constants ctxt).hard_gas_limit_per_operation
~gas_limit
>>? fun () ->
let block_gas = block_gas_level ctxt in
let limit = Arith.fp gas_limit in
if Arith.(limit > block_gas) then error Block_quota_exceeded
else
let level = Arith.sub (block_gas_level ctxt) limit in
let ctxt = update_remaining_block_gas ctxt level in
Ok ctxt
let set_gas_limit ctxt (remaining : 'a Gas_limit_repr.Arith.t) =
let open Gas_limit_repr in
let remaining_operation_gas = Arith.fp remaining in
let ctxt = update_unlimited_operation_gas ctxt false in
{ctxt with remaining_operation_gas}
let set_gas_unlimited ctxt = update_unlimited_operation_gas ctxt true
let consume_gas ctxt cost =
match Gas_limit_repr.raw_consume (remaining_operation_gas ctxt) cost with
| Some gas_counter -> Ok (update_remaining_operation_gas ctxt gas_counter)
| None ->
if unlimited_operation_gas ctxt then ok ctxt
else error Operation_quota_exceeded
let check_enough_gas ctxt cost =
consume_gas ctxt cost >>? fun (_ : t) -> Result.return_unit
let gas_consumed ~since ~until =
match (gas_level since, gas_level until) with
| Limited {remaining = before}, Limited {remaining = after} ->
Gas_limit_repr.Arith.sub before after
| _, _ -> Gas_limit_repr.Arith.zero
type missing_key_kind = Get | Set | Del | Copy
type storage_error =
| Incompatible_protocol_version of string
| Missing_key of string list * missing_key_kind
| Existing_key of string list
| Corrupted_data of string list
let storage_error_encoding =
let open Data_encoding in
union
[
case
(Tag 0)
~title:"Incompatible_protocol_version"
(obj1 (req "incompatible_protocol_version" @@ string Plain))
(function Incompatible_protocol_version arg -> Some arg | _ -> None)
(fun arg -> Incompatible_protocol_version arg);
case
(Tag 1)
~title:"Missing_key"
(obj2
(req "missing_key" (list @@ string Plain))
(req
"function"
(string_enum
[("get", Get); ("set", Set); ("del", Del); ("copy", Copy)])))
(function Missing_key (key, f) -> Some (key, f) | _ -> None)
(fun (key, f) -> Missing_key (key, f));
case
(Tag 2)
~title:"Existing_key"
(obj1 (req "existing_key" (list @@ string Plain)))
(function Existing_key key -> Some key | _ -> None)
(fun key -> Existing_key key);
case
(Tag 3)
~title:"Corrupted_data"
(obj1 (req "corrupted_data" (list @@ string Plain)))
(function Corrupted_data key -> Some key | _ -> None)
(fun key -> Corrupted_data key);
]
let pp_storage_error ppf = function
| Incompatible_protocol_version version ->
Format.fprintf
ppf
"Found a context with an unexpected version '%s'."
version
| Missing_key (key, Get) ->
Format.fprintf ppf "Missing key '%s'." (String.concat "/" key)
| Missing_key (key, Set) ->
Format.fprintf
ppf
"Cannot set undefined key '%s'."
(String.concat "/" key)
| Missing_key (key, Del) ->
Format.fprintf
ppf
"Cannot delete undefined key '%s'."
(String.concat "/" key)
| Missing_key (key, Copy) ->
Format.fprintf
ppf
"Cannot copy undefined key '%s'."
(String.concat "/" key)
| Existing_key key ->
Format.fprintf
ppf
"Cannot initialize defined key '%s'."
(String.concat "/" key)
| Corrupted_data key ->
Format.fprintf
ppf
"Failed to parse the data at '%s'."
(String.concat "/" key)
type error += Storage_error of storage_error
let () =
register_error_kind
`Permanent
~id:"context.storage_error"
~title:"Storage error (fatal internal error)"
~description:
"An error that should never happen unless something has been deleted or \
corrupted in the database."
~pp:(fun ppf err ->
Format.fprintf ppf "@[<v 2>Storage error:@ %a@]" pp_storage_error err)
storage_error_encoding
(function Storage_error err -> Some err | _ -> None)
(fun err -> Storage_error err)
let storage_error err = error (Storage_error err)
let version_key = ["version"]
let version_value = "mumbai_016"
let version = "v1"
let cycle_eras_key = [version; "cycle_eras"]
let constants_key = [version; "constants"]
let protocol_param_key = ["protocol_parameters"]
let get_cycle_eras ctxt =
Context.find ctxt cycle_eras_key >|= function
| None -> storage_error (Missing_key (cycle_eras_key, Get))
| Some bytes -> (
match
Data_encoding.Binary.of_bytes_opt Level_repr.cycle_eras_encoding bytes
with
| None -> storage_error (Corrupted_data cycle_eras_key)
| Some cycle_eras -> ok cycle_eras)
let set_cycle_eras ctxt cycle_eras =
let bytes =
Data_encoding.Binary.to_bytes_exn Level_repr.cycle_eras_encoding cycle_eras
in
Context.add ctxt cycle_eras_key bytes >|= ok
type error += Failed_to_parse_parameter of bytes
type error += Failed_to_decode_parameter of Data_encoding.json * string
let () =
register_error_kind
`Temporary
~id:"context.failed_to_parse_parameter"
~title:"Failed to parse parameter"
~description:"The protocol parameters are not valid JSON."
~pp:(fun ppf bytes ->
Format.fprintf
ppf
"@[<v 2>Cannot parse the protocol parameter:@ %s@]"
(Bytes.to_string bytes))
Data_encoding.(obj1 (req "contents" @@ bytes Hex))
(function Failed_to_parse_parameter data -> Some data | _ -> None)
(fun data -> Failed_to_parse_parameter data) ;
register_error_kind
`Temporary
~id:"context.failed_to_decode_parameter"
~title:"Failed to decode parameter"
~description:"Unexpected JSON object."
~pp:(fun ppf (json, msg) ->
Format.fprintf
ppf
"@[<v 2>Cannot decode the protocol parameter:@ %s@ %a@]"
msg
Data_encoding.Json.pp
json)
Data_encoding.(obj2 (req "contents" json) (req "error" @@ string Plain))
(function
| Failed_to_decode_parameter (json, msg) -> Some (json, msg) | _ -> None)
(fun (json, msg) -> Failed_to_decode_parameter (json, msg))
let get_proto_param ctxt =
Context.find ctxt protocol_param_key >>= function
| None -> failwith "Missing protocol parameters."
| Some bytes -> (
match Data_encoding.Binary.of_bytes_opt Data_encoding.json bytes with
| None -> tzfail (Failed_to_parse_parameter bytes)
| Some json -> (
Context.remove ctxt protocol_param_key >|= fun ctxt ->
match Data_encoding.Json.destruct Parameters_repr.encoding json with
| exception (Data_encoding.Json.Cannot_destruct _ as exn) ->
Format.kasprintf
failwith
"Invalid protocol_parameters: %a %a"
(fun ppf -> Data_encoding.Json.print_error ppf)
exn
Data_encoding.Json.pp
json
| param ->
Parameters_repr.check_params param >>? fun () -> ok (param, ctxt))
)
let add_constants ctxt constants =
let bytes =
Data_encoding.Binary.to_bytes_exn
Constants_parametric_repr.encoding
constants
in
Context.add ctxt constants_key bytes
let get_constants ctxt =
Context.find ctxt constants_key >|= function
| None -> failwith "Internal error: cannot read constants in context."
| Some bytes -> (
match
Data_encoding.Binary.of_bytes_opt
Constants_parametric_repr.encoding
bytes
with
| None -> failwith "Internal error: cannot parse constants in context."
| Some constants -> ok constants)
let patch_constants ctxt f =
let constants = f (constants ctxt) in
add_constants (context ctxt) constants >|= fun context ->
let ctxt = update_context ctxt context in
update_constants ctxt constants
let check_inited ctxt =
Context.find ctxt version_key >|= function
| None -> failwith "Internal error: un-initialized context."
| Some bytes ->
let s = Bytes.to_string bytes in
if Compare.String.(s = version_value) then Result.return_unit
else storage_error (Incompatible_protocol_version s)
let check_cycle_eras (cycle_eras : Level_repr.cycle_eras)
(constants : Constants_parametric_repr.t) =
let current_era = Level_repr.current_era cycle_eras in
assert (
Compare.Int32.(current_era.blocks_per_cycle = constants.blocks_per_cycle)) ;
assert (
Compare.Int32.(
current_era.blocks_per_commitment = constants.blocks_per_commitment))
let prepare ~level ~predecessor_timestamp ~timestamp ctxt =
Raw_level_repr.of_int32 level >>?= fun level ->
check_inited ctxt >>=? fun () ->
get_constants ctxt >>=? fun constants ->
Round_repr.Durations.create
~first_round_duration:constants.minimal_block_delay
~delay_increment_per_round:constants.delay_increment_per_round
>>?= fun round_durations ->
get_cycle_eras ctxt >|=? fun cycle_eras ->
check_cycle_eras cycle_eras constants ;
let level = Level_repr.level_from_raw ~cycle_eras level in
let sc_rollup_current_messages =
Sc_rollup_inbox_repr.init_witness_no_history
in
{
remaining_operation_gas = Gas_limit_repr.Arith.zero;
back =
{
context = ctxt;
constants;
level;
predecessor_timestamp;
timestamp;
round_durations;
cycle_eras;
fees = Tez_repr.zero;
origination_nonce = None;
temporary_lazy_storage_ids = Lazy_storage_kind.Temp_ids.init;
internal_nonce = 0;
internal_nonces_used = Int_set.empty;
remaining_block_gas =
Gas_limit_repr.Arith.fp
constants.Constants_parametric_repr.hard_gas_limit_per_block;
unlimited_operation_gas = true;
consensus = Raw_consensus.empty;
non_consensus_operations_rev = [];
dictator_proposal_seen = false;
sampler_state = Cycle_repr.Map.empty;
stake_distribution_for_current_cycle = None;
tx_rollup_current_messages = Tx_rollup_repr.Map.empty;
sc_rollup_current_messages;
dal_slot_fee_market =
Dal_slot_repr.Slot_market.init
~length:constants.Constants_parametric_repr.dal.number_of_slots;
dal_attestation_slot_accountability =
Dal_attestation_repr.Accountability.init
~length:constants.Constants_parametric_repr.dal.number_of_slots;
dal_committee = empty_dal_committee;
};
}
type previous_protocol = Genesis of Parameters_repr.t | Lima_015
let check_and_update_protocol_version ctxt =
(Context.find ctxt version_key >>= function
| None ->
failwith "Internal error: un-initialized context in check_first_block."
| Some bytes ->
let s = Bytes.to_string bytes in
if Compare.String.(s = version_value) then
failwith "Internal error: previously initialized context."
else if Compare.String.(s = "genesis") then
get_proto_param ctxt >|=? fun (param, ctxt) -> (Genesis param, ctxt)
else if Compare.String.(s = "lima_015") then return (Lima_015, ctxt)
else Lwt.return @@ storage_error (Incompatible_protocol_version s))
>>=? fun (previous_proto, ctxt) ->
Context.add ctxt version_key (Bytes.of_string version_value) >|= fun ctxt ->
ok (previous_proto, ctxt)
let[@warning "-32"] get_previous_protocol_constants ctxt =
Context.find ctxt constants_key >>= function
| None ->
failwith
"Internal error: cannot read previous protocol constants in context."
| Some bytes -> (
match
Data_encoding.Binary.of_bytes_opt
Constants_parametric_previous_repr.encoding
bytes
with
| None ->
failwith
"Internal error: cannot parse previous protocol constants in \
context."
| Some constants -> Lwt.return constants)
let update_block_time_related_constants (c : Constants_parametric_repr.t) =
let divide_period p =
Period_repr.of_seconds_exn
Int64.(div (add (Period_repr.to_seconds p) 1L) 2L)
in
let minimal_block_delay = divide_period c.minimal_block_delay in
let delay_increment_per_round = divide_period c.delay_increment_per_round in
let hard_gas_limit_per_block =
let two = Z.(succ one) in
Gas_limit_repr.Arith.(
integral_exn (Z.div (integral_to_z c.hard_gas_limit_per_block) two))
in
let Constants_repr.Generated.
{
consensus_threshold = _;
baking_reward_fixed_portion;
baking_reward_bonus_per_slot;
endorsing_reward_per_slot;
liquidity_baking_subsidy;
} =
Constants_repr.Generated.generate
~consensus_committee_size:
c.Constants_parametric_repr.consensus_committee_size
~blocks_per_minute:
{
numerator = 60;
denominator =
minimal_block_delay |> Period_repr.to_seconds |> Int64.to_int;
}
in
let double = Int32.mul 2l in
let blocks_per_cycle = double c.blocks_per_cycle in
let blocks_per_commitment = double c.blocks_per_commitment in
let nonce_revelation_threshold = double c.nonce_revelation_threshold in
let blocks_per_stake_snapshot = double c.blocks_per_stake_snapshot in
let max_operations_time_to_live = 2 * c.max_operations_time_to_live in
{
c with
blocks_per_cycle;
blocks_per_commitment;
nonce_revelation_threshold;
blocks_per_stake_snapshot;
max_operations_time_to_live;
minimal_block_delay;
delay_increment_per_round;
hard_gas_limit_per_block;
baking_reward_fixed_portion;
baking_reward_bonus_per_slot;
endorsing_reward_per_slot;
liquidity_baking_subsidy;
}
let update_cycle_eras ctxt level ~prev_blocks_per_cycle ~blocks_per_cycle
~blocks_per_commitment =
get_cycle_eras ctxt >>=? fun cycle_eras ->
let current_era = Level_repr.current_era cycle_eras in
let current_cycle =
let level_position =
Int32.sub level (Raw_level_repr.to_int32 current_era.first_level)
in
Cycle_repr.add
current_era.first_cycle
(Int32.to_int (Int32.div level_position prev_blocks_per_cycle))
in
let new_cycle_era =
Level_repr.
{
first_level = Raw_level_repr.of_int32_exn (Int32.succ level);
first_cycle = Cycle_repr.succ current_cycle;
blocks_per_cycle;
blocks_per_commitment;
}
in
Level_repr.add_cycle_era new_cycle_era cycle_eras >>?= fun new_cycle_eras ->
set_cycle_eras ctxt new_cycle_eras
let prepare_first_block ~level ~timestamp ctxt =
check_and_update_protocol_version ctxt >>=? fun (previous_proto, ctxt) ->
(match previous_proto with
| Genesis param ->
Raw_level_repr.of_int32 level >>?= fun first_level ->
let cycle_era =
{
Level_repr.first_level;
first_cycle = Cycle_repr.root;
blocks_per_cycle = param.constants.blocks_per_cycle;
blocks_per_commitment = param.constants.blocks_per_commitment;
}
in
Level_repr.create_cycle_eras [cycle_era] >>?= fun cycle_eras ->
set_cycle_eras ctxt cycle_eras >>=? fun ctxt ->
add_constants ctxt param.constants >|= ok
| Lima_015 ->
get_previous_protocol_constants ctxt >>= fun c ->
let tx_rollup =
Constants_parametric_repr.
{
enable = false;
origination_size = c.tx_rollup.origination_size;
hard_size_limit_per_inbox = c.tx_rollup.hard_size_limit_per_inbox;
hard_size_limit_per_message =
c.tx_rollup.hard_size_limit_per_message;
max_withdrawals_per_batch = c.tx_rollup.max_withdrawals_per_batch;
max_ticket_payload_size = c.tx_rollup.max_ticket_payload_size;
commitment_bond = c.tx_rollup.commitment_bond;
finality_period = c.tx_rollup.finality_period;
withdraw_period = c.tx_rollup.withdraw_period;
max_inboxes_count = c.tx_rollup.max_inboxes_count;
max_messages_per_inbox = c.tx_rollup.max_messages_per_inbox;
max_commitments_count = c.tx_rollup.max_commitments_count;
cost_per_byte_ema_factor = c.tx_rollup.cost_per_byte_ema_factor;
rejection_max_proof_size = c.tx_rollup.rejection_max_proof_size;
sunset_level = c.tx_rollup.sunset_level;
}
in
let cryptobox_parameters =
{
Dal.page_size = 4096;
number_of_shards = 2048;
slot_size = 1 lsl 20;
redundancy_factor = 16;
}
in
let dal =
Constants_parametric_repr.
{
feature_enable = c.dal.feature_enable;
number_of_slots = c.dal.number_of_slots;
attestation_lag = c.dal.endorsement_lag;
availability_threshold = c.dal.availability_threshold;
cryptobox_parameters;
}
in
let sc_rollup =
Constants_parametric_repr.
{
enable = true;
arith_pvm_enable = false;
origination_size = c.sc_rollup.origination_size;
challenge_window_in_blocks = 80_640;
stake_amount = c.sc_rollup.stake_amount;
commitment_period_in_blocks = 60;
max_lookahead_in_blocks = 172_800l;
max_active_outbox_levels = 80_640l;
max_outbox_messages_per_level =
c.sc_rollup.max_outbox_messages_per_level;
number_of_sections_in_dissection =
c.sc_rollup.number_of_sections_in_dissection;
timeout_period_in_blocks = 40_320;
max_number_of_stored_cemented_commitments =
c.sc_rollup.max_number_of_stored_cemented_commitments;
max_number_of_parallel_games = 32;
}
in
let zk_rollup =
Constants_parametric_repr.
{
enable = c.zk_rollup.enable;
origination_size = c.zk_rollup.origination_size;
min_pending_to_process = c.zk_rollup.min_pending_to_process;
}
in
let constants =
Constants_parametric_repr.
{
preserved_cycles = c.preserved_cycles;
blocks_per_cycle = c.blocks_per_cycle;
blocks_per_commitment = c.blocks_per_commitment;
nonce_revelation_threshold = c.nonce_revelation_threshold;
blocks_per_stake_snapshot = c.blocks_per_stake_snapshot;
cycles_per_voting_period = c.cycles_per_voting_period;
hard_gas_limit_per_operation = c.hard_gas_limit_per_operation;
hard_gas_limit_per_block = c.hard_gas_limit_per_block;
proof_of_work_threshold = c.proof_of_work_threshold;
minimal_stake = c.minimal_stake;
vdf_difficulty = c.vdf_difficulty;
seed_nonce_revelation_tip = c.seed_nonce_revelation_tip;
origination_size = c.origination_size;
max_operations_time_to_live = c.max_operations_time_to_live;
baking_reward_fixed_portion = c.baking_reward_fixed_portion;
baking_reward_bonus_per_slot = c.baking_reward_bonus_per_slot;
endorsing_reward_per_slot = c.endorsing_reward_per_slot;
cost_per_byte = c.cost_per_byte;
hard_storage_limit_per_operation =
c.hard_storage_limit_per_operation;
quorum_min = c.quorum_min;
quorum_max = c.quorum_max;
min_proposal_quorum = c.min_proposal_quorum;
liquidity_baking_subsidy = c.liquidity_baking_subsidy;
liquidity_baking_toggle_ema_threshold =
c.liquidity_baking_toggle_ema_threshold;
minimal_block_delay = c.minimal_block_delay;
delay_increment_per_round = c.delay_increment_per_round;
consensus_committee_size = c.consensus_committee_size;
consensus_threshold = c.consensus_threshold;
minimal_participation_ratio = c.minimal_participation_ratio;
max_slashing_period = c.max_slashing_period;
frozen_deposits_percentage = c.frozen_deposits_percentage;
double_baking_punishment = c.double_baking_punishment;
ratio_of_frozen_deposits_slashed_per_double_endorsement =
c.ratio_of_frozen_deposits_slashed_per_double_endorsement;
testnet_dictator = c.testnet_dictator;
initial_seed = c.initial_seed;
cache_script_size = c.cache_script_size;
cache_stake_distribution_cycles = c.cache_stake_distribution_cycles;
cache_sampler_state_cycles = c.cache_sampler_state_cycles;
tx_rollup;
dal;
sc_rollup;
zk_rollup;
}
in
let block_time_is_at_least_15s =
Compare.Int64.(Period_repr.to_seconds c.minimal_block_delay >= 15L)
in
(if block_time_is_at_least_15s then
let new_constants = update_block_time_related_constants constants in
update_cycle_eras
ctxt
level
~prev_blocks_per_cycle:constants.blocks_per_cycle
~blocks_per_cycle:new_constants.blocks_per_cycle
~blocks_per_commitment:new_constants.blocks_per_commitment
>>=? fun ctxt -> return (ctxt, new_constants)
else return (ctxt, constants))
>>=? fun (ctxt, constants) ->
add_constants ctxt constants >>= fun ctxt -> return ctxt)
>>=? fun ctxt ->
prepare ctxt ~level ~predecessor_timestamp:timestamp ~timestamp
>|=? fun ctxt -> (previous_proto, ctxt)
let activate ctxt h = Updater.activate (context ctxt) h >|= update_context ctxt
type key = string list
type value = bytes
type tree = Context.tree
module type T =
Raw_context_intf.T
with type root := root
and type key := key
and type value := value
and type tree := tree
let mem ctxt k = Context.mem (context ctxt) k
let mem_tree ctxt k = Context.mem_tree (context ctxt) k
let get ctxt k =
Context.find (context ctxt) k >|= function
| None -> storage_error (Missing_key (k, Get))
| Some v -> ok v
let get_tree ctxt k =
Context.find_tree (context ctxt) k >|= function
| None -> storage_error (Missing_key (k, Get))
| Some v -> ok v
let find ctxt k = Context.find (context ctxt) k
let find_tree ctxt k = Context.find_tree (context ctxt) k
let add ctxt k v = Context.add (context ctxt) k v >|= update_context ctxt
let add_tree ctxt k v =
Context.add_tree (context ctxt) k v >|= update_context ctxt
let init ctxt k v =
Context.mem (context ctxt) k >>= function
| true -> Lwt.return @@ storage_error (Existing_key k)
| _ ->
Context.add (context ctxt) k v >|= fun context ->
ok (update_context ctxt context)
let init_tree ctxt k v : _ tzresult Lwt.t =
Context.mem_tree (context ctxt) k >>= function
| true -> Lwt.return @@ storage_error (Existing_key k)
| _ ->
Context.add_tree (context ctxt) k v >|= fun context ->
ok (update_context ctxt context)
let update ctxt k v =
Context.mem (context ctxt) k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Set))
| _ ->
Context.add (context ctxt) k v >|= fun context ->
ok (update_context ctxt context)
let update_tree ctxt k v =
Context.mem_tree (context ctxt) k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Set))
| _ ->
Context.add_tree (context ctxt) k v >|= fun context ->
ok (update_context ctxt context)
let remove_existing ctxt k =
Context.mem (context ctxt) k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Del))
| _ ->
Context.remove (context ctxt) k >|= fun context ->
ok (update_context ctxt context)
let remove_existing_tree ctxt k =
Context.mem_tree (context ctxt) k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Del))
| _ ->
Context.remove (context ctxt) k >|= fun context ->
ok (update_context ctxt context)
let remove ctxt k = Context.remove (context ctxt) k >|= update_context ctxt
let add_or_remove ctxt k = function
| None -> remove ctxt k
| Some v -> add ctxt k v
let add_or_remove_tree ctxt k = function
| None -> remove ctxt k
| Some v -> add_tree ctxt k v
let list ctxt ?offset ?length k = Context.list (context ctxt) ?offset ?length k
let fold ?depth ctxt k ~order ~init ~f =
Context.fold ?depth (context ctxt) k ~order ~init ~f
let config ctxt = Context.config (context ctxt)
module Proof = Context.Proof
let length ctxt key = Context.length (context ctxt) key
module Tree :
Raw_context_intf.TREE
with type t := t
and type key := key
and type value := value
and type tree := tree = struct
include Context.Tree
let empty ctxt = Context.Tree.empty (context ctxt)
let get t k =
find t k >|= function
| None -> storage_error (Missing_key (k, Get))
| Some v -> ok v
let get_tree t k =
find_tree t k >|= function
| None -> storage_error (Missing_key (k, Get))
| Some v -> ok v
let init t k v =
mem t k >>= function
| true -> Lwt.return @@ storage_error (Existing_key k)
| _ -> add t k v >|= ok
let init_tree t k v =
mem_tree t k >>= function
| true -> Lwt.return @@ storage_error (Existing_key k)
| _ -> add_tree t k v >|= ok
let update t k v =
mem t k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Set))
| _ -> add t k v >|= ok
let update_tree t k v =
mem_tree t k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Set))
| _ -> add_tree t k v >|= ok
let remove_existing t k =
mem t k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Del))
| _ -> remove t k >|= ok
let remove_existing_tree t k =
mem_tree t k >>= function
| false -> Lwt.return @@ storage_error (Missing_key (k, Del))
| _ -> remove t k >|= ok
let add_or_remove t k = function None -> remove t k | Some v -> add t k v
let add_or_remove_tree t k = function
| None -> remove t k
| Some v -> add_tree t k v
end
let verify_tree_proof proof f = Context.verify_tree_proof proof f
let verify_stream_proof proof f = Context.verify_stream_proof proof f
let equal_config = Context.equal_config
let project x = x
let absolute_key _ k = k
let description = Storage_description.create ()
let fold_map_temporary_lazy_storage_ids ctxt f =
f (temporary_lazy_storage_ids ctxt) |> fun (temporary_lazy_storage_ids, x) ->
(update_temporary_lazy_storage_ids ctxt temporary_lazy_storage_ids, x)
let map_temporary_lazy_storage_ids_s ctxt f =
f (temporary_lazy_storage_ids ctxt)
>|= fun (ctxt, temporary_lazy_storage_ids) ->
update_temporary_lazy_storage_ids ctxt temporary_lazy_storage_ids
module Cache = struct
type key = Context.Cache.key
type value = Context.Cache.value = ..
let key_of_identifier = Context.Cache.key_of_identifier
let identifier_of_key = Context.Cache.identifier_of_key
let pp fmt ctxt = Context.Cache.pp fmt (context ctxt)
let find c k = Context.Cache.find (context c) k
let set_cache_layout c layout =
Context.Cache.set_cache_layout (context c) layout >>= fun ctxt ->
Lwt.return (update_context c ctxt)
let update c k v = Context.Cache.update (context c) k v |> update_context c
let sync c cache_nonce =
Context.Cache.sync (context c) ~cache_nonce >>= fun ctxt ->
Lwt.return (update_context c ctxt)
let clear c = Context.Cache.clear (context c) |> update_context c
let list_keys c ~cache_index =
Context.Cache.list_keys (context c) ~cache_index
let key_rank c key = Context.Cache.key_rank (context c) key
let cache_size_limit c ~cache_index =
Context.Cache.cache_size_limit (context c) ~cache_index
let cache_size c ~cache_index =
Context.Cache.cache_size (context c) ~cache_index
let future_cache_expectation c ~time_in_blocks =
Context.Cache.future_cache_expectation (context c) ~time_in_blocks
|> update_context c
end
let record_non_consensus_operation_hash ctxt operation_hash =
update_non_consensus_operations_rev
ctxt
(operation_hash :: non_consensus_operations_rev ctxt)
let non_consensus_operations ctxt = List.rev (non_consensus_operations_rev ctxt)
let record_dictator_proposal_seen ctxt = update_dictator_proposal_seen ctxt true
let dictator_proposal_seen ctxt = dictator_proposal_seen ctxt
let init_sampler_for_cycle ctxt cycle seed state =
let map = sampler_state ctxt in
if Cycle_repr.Map.mem cycle map then error (Sampler_already_set cycle)
else
let map = Cycle_repr.Map.add cycle (seed, state) map in
let ctxt = update_sampler_state ctxt map in
ok ctxt
let sampler_for_cycle ~read ctxt cycle =
let map = sampler_state ctxt in
match Cycle_repr.Map.find cycle map with
| Some (seed, state) -> return (ctxt, seed, state)
| None ->
read ctxt >>=? fun (seed, state) ->
let map = Cycle_repr.Map.add cycle (seed, state) map in
let ctxt = update_sampler_state ctxt map in
return (ctxt, seed, state)
let stake_distribution_for_current_cycle ctxt =
match ctxt.back.stake_distribution_for_current_cycle with
| None -> error Stake_distribution_not_set
| Some s -> ok s
let init_stake_distribution_for_current_cycle ctxt
stake_distribution_for_current_cycle =
update_back
ctxt
{
ctxt.back with
stake_distribution_for_current_cycle =
Some stake_distribution_for_current_cycle;
}
module Internal_for_tests = struct
let add_level ctxt l =
let new_level = Level_repr.Internal_for_tests.add_level ctxt.back.level l in
let new_back = {ctxt.back with level = new_level} in
{ctxt with back = new_back}
let add_cycles ctxt l =
let blocks_per_cycle = Int32.to_int (constants ctxt).blocks_per_cycle in
let new_level =
Level_repr.Internal_for_tests.add_cycles
~blocks_per_cycle
ctxt.back.level
l
in
let new_back = {ctxt.back with level = new_level} in
{ctxt with back = new_back}
end
module type CONSENSUS = sig
type t
type 'value slot_map
type slot_set
type slot
type round
type consensus_pk
val allowed_endorsements : t -> (consensus_pk * int) slot_map
val allowed_preendorsements : t -> (consensus_pk * int) slot_map
val current_endorsement_power : t -> int
val initialize_consensus_operation :
t ->
allowed_endorsements:(consensus_pk * int) slot_map ->
allowed_preendorsements:(consensus_pk * int) slot_map ->
t
val record_grand_parent_endorsement :
t -> Signature.Public_key_hash.t -> t tzresult
val record_endorsement : t -> initial_slot:slot -> power:int -> t tzresult
val record_preendorsement :
t -> initial_slot:slot -> power:int -> round -> t tzresult
val endorsements_seen : t -> slot_set
val get_preendorsements_quorum_round : t -> round option
val set_preendorsements_quorum_round : t -> round -> t
val locked_round_evidence : t -> (round * int) option
val set_endorsement_branch : t -> Block_hash.t * Block_payload_hash.t -> t
val endorsement_branch : t -> (Block_hash.t * Block_payload_hash.t) option
val set_grand_parent_branch : t -> Block_hash.t * Block_payload_hash.t -> t
val grand_parent_branch : t -> (Block_hash.t * Block_payload_hash.t) option
end
module Consensus :
CONSENSUS
with type t := t
and type slot := Slot_repr.t
and type 'a slot_map := 'a Slot_repr.Map.t
and type slot_set := Slot_repr.Set.t
and type round := Round_repr.t
and type consensus_pk := consensus_pk = struct
let[@inline] allowed_endorsements ctxt =
ctxt.back.consensus.allowed_endorsements
let[@inline] allowed_preendorsements ctxt =
ctxt.back.consensus.allowed_preendorsements
let[@inline] current_endorsement_power ctxt =
ctxt.back.consensus.current_endorsement_power
let[@inline] get_preendorsements_quorum_round ctxt =
ctxt.back.consensus.preendorsements_quorum_round
let[@inline] locked_round_evidence ctxt =
Raw_consensus.locked_round_evidence ctxt.back.consensus
let[@inline] update_consensus_with ctxt f =
{ctxt with back = {ctxt.back with consensus = f ctxt.back.consensus}}
let[@inline] update_consensus_with_tzresult ctxt f =
f ctxt.back.consensus >|? fun consensus ->
{ctxt with back = {ctxt.back with consensus}}
let[@inline] initialize_consensus_operation ctxt ~allowed_endorsements
~allowed_preendorsements =
update_consensus_with
ctxt
(Raw_consensus.initialize_with_endorsements_and_preendorsements
~allowed_endorsements
~allowed_preendorsements)
let[@inline] record_grand_parent_endorsement ctxt pkh =
update_consensus_with_tzresult ctxt (fun ctxt ->
Raw_consensus.record_grand_parent_endorsement ctxt pkh)
let[@inline] record_preendorsement ctxt ~initial_slot ~power round =
update_consensus_with_tzresult
ctxt
(Raw_consensus.record_preendorsement ~initial_slot ~power round)
let[@inline] record_endorsement ctxt ~initial_slot ~power =
update_consensus_with_tzresult
ctxt
(Raw_consensus.record_endorsement ~initial_slot ~power)
let[@inline] endorsements_seen ctxt = ctxt.back.consensus.endorsements_seen
let[@inline] set_preendorsements_quorum_round ctxt round =
update_consensus_with
ctxt
(Raw_consensus.set_preendorsements_quorum_round round)
let[@inline] endorsement_branch ctxt =
Raw_consensus.endorsement_branch ctxt.back.consensus
let[@inline] set_endorsement_branch ctxt branch =
update_consensus_with ctxt (fun ctxt ->
Raw_consensus.set_endorsement_branch ctxt branch)
let[@inline] grand_parent_branch ctxt =
Raw_consensus.grand_parent_branch ctxt.back.consensus
let[@inline] set_grand_parent_branch ctxt branch =
update_consensus_with ctxt (fun ctxt ->
Raw_consensus.set_grand_parent_branch ctxt branch)
end
module Tx_rollup = struct
let add_message ctxt rollup message =
let root = ref Tx_rollup_inbox_repr.Merkle.(root empty) in
let updater element =
let tree =
Option.value element ~default:Tx_rollup_inbox_repr.Merkle.(empty)
in
let tree = Tx_rollup_inbox_repr.Merkle.add_message tree message in
root := Tx_rollup_inbox_repr.Merkle.root tree ;
Some tree
in
let map =
Tx_rollup_repr.Map.update
rollup
updater
ctxt.back.tx_rollup_current_messages
in
let back = {ctxt.back with tx_rollup_current_messages = map} in
({ctxt with back}, !root)
end
module Sc_rollup_in_memory_inbox = struct
let current_messages ctxt = ctxt.back.sc_rollup_current_messages
let set_current_messages ctxt witness =
{ctxt with back = {ctxt.back with sc_rollup_current_messages = witness}}
end
module Dal = struct
type error +=
let () =
register_error_kind
`Permanent
~id:"dal_register_invalid_slot"
~title:"Dal register invalid slot"
~description:
"Attempt to register a slot which is invalid (the index is out of \
bounds)."
~pp:(fun ppf (length, slot) ->
Format.fprintf
ppf
"The slot provided is invalid. Slot index should be between 0 and \
%d. Found: %a."
length
Dal_slot_repr.Index.pp
slot.Dal_slot_repr.Header.id.index)
Data_encoding.(
obj2
(req "length" int31)
(req "slot_header" Dal_slot_repr.Header.encoding))
(function
| Dal_register_invalid_slot_header {length; } ->
Some (length, slot_header)
| _ -> None)
(fun (length, ) ->
Dal_register_invalid_slot_header {length; slot_header})
let record_available_shards ctxt slots shards =
let dal_attestation_slot_accountability =
Dal_attestation_repr.Accountability.record_shards_availability
ctxt.back.dal_attestation_slot_accountability
slots
shards
in
{ctxt with back = {ctxt.back with dal_attestation_slot_accountability}}
let ctxt =
match
Dal_slot_repr.Slot_market.register
ctxt.back.dal_slot_fee_market
slot_header
with
| None ->
let length =
Dal_slot_repr.Slot_market.length ctxt.back.dal_slot_fee_market
in
error (Dal_register_invalid_slot_header {length; slot_header})
| Some (dal_slot_fee_market, updated) ->
ok ({ctxt with back = {ctxt.back with dal_slot_fee_market}}, updated)
let candidates ctxt =
Dal_slot_repr.Slot_market.candidates ctxt.back.dal_slot_fee_market
let is_slot_index_available ctxt =
let threshold =
ctxt.back.constants.Constants_parametric_repr.dal.availability_threshold
in
let number_of_shards =
ctxt.back.constants.Constants_parametric_repr.dal.cryptobox_parameters
.number_of_shards
in
Dal_attestation_repr.Accountability.is_slot_available
ctxt.back.dal_attestation_slot_accountability
~threshold
~number_of_shards
type committee = dal_committee = {
pkh_to_shards :
(Dal_attestation_repr.shard_index * int) Signature.Public_key_hash.Map.t;
shard_to_pkh : Signature.Public_key_hash.t Dal_attestation_repr.Shard_map.t;
}
let compute_committee ctxt pkh_from_tenderbake_slot =
let Constants_parametric_repr.
{
dal = {cryptobox_parameters = {number_of_shards; _}; _};
consensus_committee_size;
_;
} =
ctxt.back.constants
in
let update_committee committee pkh ~slot_index ~power =
{
pkh_to_shards =
Signature.Public_key_hash.Map.update
pkh
(function
| None -> Some (slot_index, power)
| Some (initial_shard_index, old_power) ->
Some (initial_shard_index, old_power + power))
committee.pkh_to_shards;
shard_to_pkh =
List.fold_left
(fun shard_to_pkh slot ->
Dal_attestation_repr.Shard_map.add slot pkh shard_to_pkh)
committee.shard_to_pkh
Misc.(slot_index --> (slot_index + (power - 1)));
}
in
let rec compute_power index committee =
if Compare.Int.(index < 0) then return committee
else
let shard_index = index mod consensus_committee_size in
Slot_repr.of_int shard_index >>?= fun slot ->
pkh_from_tenderbake_slot slot >>=? fun (_ctxt, pkh) ->
let slot_index = Slot_repr.to_int slot in
let committee = update_committee committee pkh ~slot_index ~power:1 in
compute_power (index - 1) committee
in
compute_power (number_of_shards - 1) empty_dal_committee
>>=? fun unordered_committee ->
let dal_committee =
Signature.Public_key_hash.Map.fold
(fun pkh (_, power) (total_power, committee) ->
let committee =
update_committee committee pkh ~slot_index:total_power ~power
in
let new_total_power = total_power + power in
(new_total_power, committee))
unordered_committee.pkh_to_shards
(0, empty_dal_committee)
|> snd
in
return dal_committee
let init_committee ctxt committee =
{ctxt with back = {ctxt.back with dal_committee = committee}}
let shards_of_attestor ctxt ~attestor:pkh =
let rec make acc (initial_shard_index, power) =
if Compare.Int.(power <= 0) then List.rev acc
else make (initial_shard_index :: acc) (initial_shard_index + 1, power - 1)
in
Signature.Public_key_hash.Map.find_opt
pkh
ctxt.back.dal_committee.pkh_to_shards
|> Option.map (fun pre_shards -> make [] pre_shards)
end
type local_context = {
tree : tree;
path : key;
remaining_operation_gas : Gas_limit_repr.Arith.fp;
unlimited_operation_gas : bool;
}
let with_local_context ctxt key f =
(find_tree ctxt key >|= function None -> Tree.empty ctxt | Some tree -> tree)
>>= fun tree ->
let local_ctxt =
{
tree;
path = key;
remaining_operation_gas = remaining_operation_gas ctxt;
unlimited_operation_gas = unlimited_operation_gas ctxt;
}
in
f local_ctxt >>=? fun (local_ctxt, res) ->
add_tree ctxt key local_ctxt.tree >|= fun ctxt ->
update_remaining_operation_gas ctxt local_ctxt.remaining_operation_gas
|> fun ctxt ->
update_unlimited_operation_gas ctxt local_ctxt.unlimited_operation_gas
|> fun ctxt -> ok (ctxt, res)
module Local_context : sig
include
Raw_context_intf.VIEW
with type t = local_context
and type key := key
and type value := value
and type tree := tree
val consume_gas :
local_context -> Gas_limit_repr.cost -> local_context tzresult
val absolute_key : local_context -> key -> key
end = struct
type t = local_context
let consume_gas local cost =
match Gas_limit_repr.raw_consume local.remaining_operation_gas cost with
| Some gas_counter -> Ok {local with remaining_operation_gas = gas_counter}
| None ->
if local.unlimited_operation_gas then ok local
else error Operation_quota_exceeded
let tree local = local.tree
let update_root_tree local tree = {local with tree}
let absolute_key local key = local.path @ key
let find local = Tree.find (tree local)
let find_tree local = Tree.find_tree (tree local)
let mem local = Tree.mem (tree local)
let mem_tree local = Tree.mem_tree (tree local)
let get local = Tree.get (tree local)
let get_tree local = Tree.get_tree (tree local)
let update local key b =
Tree.update (tree local) key b >|=? update_root_tree local
let update_tree local key b =
Tree.update_tree (tree local) key b >|=? update_root_tree local
let init local key b =
Tree.init (tree local) key b >|=? update_root_tree local
let init_tree local key t =
Tree.init_tree (tree local) key t >|=? update_root_tree local
let add local i b = Tree.add (tree local) i b >|= update_root_tree local
let add_tree local i t =
Tree.add_tree (tree local) i t >|= update_root_tree local
let remove local i = Tree.remove (tree local) i >|= update_root_tree local
let remove_existing local key =
Tree.remove_existing (tree local) key >|=? update_root_tree local
let remove_existing_tree local key =
Tree.remove_existing_tree (tree local) key >|=? update_root_tree local
let add_or_remove local key vopt =
Tree.add_or_remove (tree local) key vopt >|= update_root_tree local
let add_or_remove_tree local key topt =
Tree.add_or_remove_tree (tree local) key topt >|= update_root_tree local
let fold ?depth local key ~order ~init ~f =
Tree.fold ?depth (tree local) key ~order ~init ~f
let list local ?offset ?length key =
Tree.list (tree local) ?offset ?length key
let config local = Tree.config (tree local)
let length local i = Tree.length (tree local) i
end