package octez-libs

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include module type of struct include Tezos_stdlib end
module Bits = Tezos_stdlib.Bits
module Bloomer = Tezos_stdlib.Bloomer
module Bounded_heap = Tezos_stdlib.Bounded_heap
module Circular_buffer = Tezos_stdlib.Circular_buffer
module Compare = Tezos_stdlib.Compare
module FallbackArray = Tezos_stdlib.FallbackArray
module FunctionalArray = Tezos_stdlib.FunctionalArray
module Hash_queue = Tezos_stdlib.Hash_queue
module Hex = Tezos_stdlib.Hex
module Lwt_dropbox = Tezos_stdlib.Lwt_dropbox
module Lwt_idle_waiter = Tezos_stdlib.Lwt_idle_waiter
module Lwt_pipe = Tezos_stdlib.Lwt_pipe
module Lwt_utils = Tezos_stdlib.Lwt_utils
module Memory = Tezos_stdlib.Memory
module Tag = Tezos_stdlib.Tag
module TzBytes = Tezos_stdlib.TzBytes
module TzEndian = Tezos_stdlib.TzEndian
module TzFilename = Tezos_stdlib.TzFilename
module TzList = Tezos_stdlib.TzList
module TzString = Tezos_stdlib.TzString
module Utils = Tezos_stdlib.Utils
module Error_monad = Tezos_error_monad.Error_monad
module Data_encoding = Data_encoding

The following modules are part of TzLwtreslib. We just remove

module List : sig ... end
module String : sig ... end
module Bytes : sig ... end
module Time = Time
module Fitness = Fitness
module User_activated = User_activated
module Block_header = Block_header
module Genesis = Genesis
module Operation = Operation
module Protocol = Protocol
module Test_chain_status = Test_chain_status
module Block_locator = Block_locator
module Mempool = Mempool
module P2p_addr = P2p_addr
module P2p_identity = P2p_identity
module P2p_peer = P2p_peer
module P2p_point = P2p_point
module P2p_connection = P2p_connection
module P2p_stat = P2p_stat
module P2p_version = P2p_version
module P2p_rejection = P2p_rejection
module Distributed_db_version = Distributed_db_version
module Network_version = Network_version
module Block_hash = Tezos_crypto.Hashed.Block_hash
module Block_metadata_hash = Tezos_crypto.Hashed.Block_metadata_hash
module Context_hash = Tezos_crypto.Hashed.Context_hash
module Operation_hash = Tezos_crypto.Hashed.Operation_hash
module Operation_list_hash = Tezos_crypto.Hashed.Operation_list_hash
module Operation_list_list_hash = Tezos_crypto.Hashed.Operation_list_list_hash
module Operation_metadata_hash = Tezos_crypto.Hashed.Operation_metadata_hash
module Operation_metadata_list_hash = Tezos_crypto.Hashed.Operation_metadata_list_hash
module Operation_metadata_list_list_hash = Tezos_crypto.Hashed.Operation_metadata_list_list_hash
module Protocol_hash = Tezos_crypto.Hashed.Protocol_hash
module Signature = Tezos_crypto.Signature
module Skip_list = Skip_list
include module type of Utils.Infix
val (--) : int -> int -> int list

Sequence: i--j is the sequence i;i+1;...;j-1;j

include module type of Tezos_error_monad.Error_monad
type error_category = [
  1. | `Branch
    (*

    Errors that may not happen in another context

    *)
  2. | `Temporary
    (*

    Errors that may not happen in a later context

    *)
  3. | `Permanent
    (*

    Errors that will happen no matter the context

    *)
]

Categories of error

Note: this is only meaningful within the protocol. It may be removed from the error monad and pushed to the protocol environment in the future. See https://gitlab.com/tezos/tezos/-/issues/1576

Assembling the different components of the error monad.

The main error type.

Whenever you add a variant to this type (with type Error_monad.error += …) you must also register the error with register_error_kind.

These errors are not meant to be inspected in general. Meaning that they should not be matched upon. Consequently it is acceptable to register an error in an implementation file and not mention it in the corresponding interface file.

CORE: encoding and pretty-printing for errors

include Tezos_error_monad.Sig.CORE with type error := error and type error_category := error_category
val string_of_category : error_category -> string
val error_encoding : error Data_encoding.t

The encoding for errors.

Note that this encoding has a few peculiarities, some of which may impact your code. These peculiarities are due to the type error being an extensible variant.

Because the error type is an extensible variant, you must register an encoding for each error constructor you add to error. This is done via register_error_kind.

Because the error type is an extensible variant, with dynamically registered errors (see peculiarity above), there are no tags associated with each error. This does not affect the JSON encoding, but it does impose restrictions on the binary encoding. The chosen workaround is to encode errors as JSON and to encode the JSON to binary form. As a result, errors can be somewhat large in binary: they include field names and such.

Because the error type is an extensible variant, with dynamically registered errors (see peculiarity above), the encoding must be recomputed when a new error is registered. This is achieved by the means of a Data_encoding.delayed combinator: the encoding is recomputed on-demand. There is a caching mechanism so that, in the case where no new errors have been registered since the last use, the last result is used.

This last peculiarity imposes a limit on the use of error_encoding itself. Specifically, it is invalid to use error_encoding inside the ~json argument of a Data_encoding.splitted. This is because splitted evaluates the delayed combinator once-and-for-all to produce a json encoding. (Note that the following data-encoding combinators use splitted internally: Data_encoding.Compact.make, Data_encoding.assoc, and Data_encoding.lazy_encoding. As a result, it is invalid to use error_encoding within the arguments of these combinators as well.)

val pp : Stdlib.Format.formatter -> error -> unit
val register_error_kind : error_category -> id:string -> title:string -> description:string -> ?pp:(Stdlib.Format.formatter -> 'err -> unit) -> 'err Data_encoding.t -> (error -> 'err option) -> ('err -> error) -> unit

The error data type is extensible. Each module can register specialized error serializers id unique name of this error. Ex.: overflow_time_counter title more readable name. Ex.: Overflow of time counter description human readable description. Ex.: The time counter overflowed while computing delta increase pp formatter used to pretty print additional arguments. Ex.: The time counter overflowed while computing delta increase. Previous value %d. Delta: %d encoder decoder data encoding for this error. If the error has no value, specify Data_encoding.empty

Classify an error using the registered kinds

type error += private
  1. | Unclassified of string

Catch all error when 'serializing' an error.

type error += private
  1. | Unregistered_error of Data_encoding.json

Catch all error when 'deserializing' an error.

val json_of_error : error -> Data_encoding.json

An error serializer

val error_of_json : Data_encoding.json -> error

Error documentation

type error_info = {
  1. category : error_category;
  2. id : string;
  3. title : string;
  4. description : string;
  5. schema : Data_encoding.json_schema;
}

Error information

val pp_info : Stdlib.Format.formatter -> error_info -> unit
val find_info_of_error : error -> error_info

find_info_of_error e retrieves the `error_info` associated with the given error `e`.

  • raises Invalid_argument

    if the error is a wrapped error from another monad

  • raises Not_found

    if the error's constructor has not been registered

val get_registered_errors : unit -> error_info list

Retrieves information of registered errors

WITH_WRAPPED: wrapping of errors from other instantiations within this one. Specifically, this is used to wrap errors of the economic protocol (e.g., operation is invalid) within the errors of the shell (e.g., failed to validate protocol data).

Functions from this module should only be used within the environment.

include Tezos_error_monad.Sig.WITH_WRAPPED with type error := error
module type Wrapped_error_monad = sig ... end

The purpose of this module is to wrap a specific error monad E into a more general error monad Eg.

val register_wrapped_error_kind : (module Wrapped_error_monad) -> id:string -> title:string -> description:string -> unit

Same as register_error_kind but for a wrapped error monad. The codec is defined in the module parameter. It makes the category of the error Wrapped instead of Main.

module TzTrace : Tezos_error_monad.Sig.TRACE with type 'error trace = 'error list

TzTrace: trace module specific to the Tezos Error monad. The trace type of this module is meant to become abstract in the medium-term (see https://gitlab.com/tezos/tezos/-/issues/1577).

type 'error trace = 'error TzTrace.trace

TzMonad: the Tezos-specific monad part of the Error_monad. It includes

  • syntax modules
  • consistent defaults,
  • some tracing helpers,
  • some other misc helpers.
include Tezos_error_monad.Monad_maker.S with type error := Tezos_error_monad.TzCore.error and type 'error trace := 'error TzTrace.trace
type 'a tzresult = ('a, tztrace) Stdlib.result
module Result_syntax : sig ... end
module Lwt_result_syntax : sig ... end
module Legacy_monad_globals : sig ... end
val pp_print_trace : Stdlib.Format.formatter -> tztrace -> unit
val pp_print_top_error_of_trace : Stdlib.Format.formatter -> tztrace -> unit

Pretty-prints the top error of a trace

val trace_encoding : tztrace Data_encoding.t
val result_encoding : 'a Data_encoding.t -> 'a tzresult Data_encoding.t

A serializer for result of a given type

val record_trace : 'err -> ('a, 'err TzTrace.trace) Stdlib.result -> ('a, 'err TzTrace.trace) Stdlib.result

record_trace err res is either res if res is Ok _, or it is Error (Trace.cons err tr) if res is Error tr.

In other words, record_trace err res enriches the trace that is carried by res (if it is carrying a trace) with the error err. It leaves res untouched if res is not carrying a trace.

You can use this to add high-level information to potential low-level errors. E.g.,

record_trace
   Failure_to_load_config
   (load_data_from_file config_encoding config_file_name)

Note that record_trace takes a fully evaluated error err as argument. It means that, whatever the value of the result res, the error err is evaluated. This is not an issue if the error is a simple expression (a literal or a constructor with simple parameters). However, for any expression that is more complex (e.g., one that calls a function) you should prefer record_trace_eval.

val trace : 'err -> ('b, 'err TzTrace.trace) Stdlib.result Lwt.t -> ('b, 'err TzTrace.trace) Stdlib.result Lwt.t

trace is identical to record_trace but applies to a promise. More formally, trace err p is a promise that resolves to Ok v if p resolves to Ok v, or it resolves to Error (Trace.cons err tr) if res resolves to Error tr.

In other words, trace err p enriches the trace that p resolves to (if it does resolve to a trace) with the error err. It leaves the value that p resolves to untouched if it is not a trace.

You can use this to add high-level information to potential low-level errors.

Note that, like record_trace, trace takes a fully evaluated error as argument. For a similar reason as explained there, you should only use trace with simple expressions (literal or constructor with simple parameters) and prefer trace_eval for any other expression (such as ones that include functions calls).

val record_trace_eval : (unit -> 'err) -> ('a, 'err TzTrace.trace) Stdlib.result -> ('a, 'err TzTrace.trace) Stdlib.result

record_trace_eval is identical to record_trace except that the error that enriches the trace is wrapped in a function that is evaluated only if it is needed. More formally record_trace_eval mkerr res is res if res is Ok _, or it is Error (Trace.cons (mkerr ()) tr) if res is Error tr.

You can achieve the same effect by hand with

match res with
| Ok _ -> res
| Error tr -> Error (Trace.cons (mkerr ()) tr)

Prefer record_trace_eval over record_trace when the enriching error is expensive to compute or heavy to allocate.

val trace_eval : (unit -> 'err) -> ('b, 'err TzTrace.trace) Stdlib.result Lwt.t -> ('b, 'err TzTrace.trace) Stdlib.result Lwt.t

trace_eval is identical to trace except that the error that enriches the trace is wrapped in a function that is evaluated only if and when it is needed. More formally trace_eval mkerr p is a promise that resolves to Ok v if p resolves to Ok v, or it resolves to Error (Trace.cons err tr) if p resolves to Error tr and then mkerr () resolves to err.

You can achieve the same effect by hand with

p >>= function
| Ok _ -> p
| Error tr ->
   mkerr () >>= fun err ->
   Lwt.return (Error (Trace.cons err tr))

Note that the evaluation of the error can be arbitrarily delayed. Avoid using references and other mutable values in the function mkerr.

Prefer trace_eval over trace when the enriching error is expensive to compute or heavy to allocate or when evaluating it requires the use of Lwt.

val error_unless : bool -> 'err -> (unit, 'err TzTrace.trace) Stdlib.result

error_unless flag err is Ok () if b is true, it is Error (Trace.make err) otherwise.

val error_when : bool -> 'err -> (unit, 'err TzTrace.trace) Stdlib.result

error_when flag err is Error (Trace.make err) if b is true, it is Ok () otherwise.

val fail_unless : bool -> 'err -> (unit, 'err TzTrace.trace) Stdlib.result Lwt.t

fail_unless flag err is Lwt.return @@ Ok () if b is true, it is Lwt.return @@ Error (Trace.make err) otherwise.

val fail_when : bool -> 'err -> (unit, 'err TzTrace.trace) Stdlib.result Lwt.t

fail_when flag err is Lwt.return @@ Error (Trace.make err) if b is true, it is Lwt.return @@ Ok () otherwise.

val unless : bool -> (unit -> (unit, 'trace) Stdlib.result Lwt.t) -> (unit, 'trace) Stdlib.result Lwt.t

unless b f is f () if b is false and it is a promise already resolved to Ok () otherwise.

You can use unless to avoid having to write an if statement that you then need to populate entirely to satisfy the type-checker. E.g, you can write unless b f instead of if not b then f () else return_unit.

val when_ : bool -> (unit -> (unit, 'trace) Stdlib.result Lwt.t) -> (unit, 'trace) Stdlib.result Lwt.t

when_ b f is f () if b is true and it is a promise already resolved to Ok () otherwise.

You can use when_ to avoid having to write an if statement that you then need to populate entirely to satisfy the type-checker. E.g, you can write when_ b f instead of if b then f () else return_unit.

val dont_wait : (unit -> (unit, 'trace) Stdlib.result Lwt.t) -> ('trace -> unit) -> (exn -> unit) -> unit

Wrapper around Lwt_utils.dont_wait

Exception-Error bridge

This part of the interface groups functions that are used to interact with code that raises exceptions. Typically, you should be using these functions when calling into a library that raises exceptions.

Remember that the keyword error is for failure within the Result monad (or, more specifically, the TracedResult monad) whilst fail is for failure within the LwtResult monad (or, more specifically, the LwtTracedResult monad).

Failing: to error out and to fail

This sub-part of the interface groups functions that fail (either in the TracedResult monad or the LwtTracedResult monad) whilst carrying information provided as argument. When reading this sub-part you should read error and fail as verbs. E.g., error_with_exn errors out and carries a provided exception. The next sub-part will group noun-like, declarative functions.

val error_with : ('a, Stdlib.Format.formatter, unit, 'b tzresult) Stdlib.format4 -> 'a

error_with fmt … errors out: it fails within the TracedResult monad. The payload of the Error constructor is unspecified beyond the fact that it includes the string formatted by fmt …. E.g.,

if n < 0 then
   error_with "Index (%d) is negative" n
else if n >= Array.length a then
   error_with "Index (%d) is beyond maximum index (%d)" n (Array.length a - 1)
else
   Ok a.(n)

Note: this is somewhat equivalent to Stdlib.failwith in that it is a generic failure mechanism with a simple error message. Like Stdlib.failwith it should be replaced by a more specific error mechanism in most cases.

val failwith : ('a, Stdlib.Format.formatter, unit, 'b tzresult Lwt.t) Stdlib.format4 -> 'a

failwith fmt … fails: it fails within the LwtTracedResult monad. The payload of the Error constructor is unspecified beyond the fact that it includes the string formatted by fmt …. E.g.,

match find key store with
| None ->
   failwith "Key %a not found in store" pp_key key
| Some value ->
   LwtResult.return value

Note: this is somewhat equivalent to Stdlib.failwith in that it is a generic failure mechanism with a simple error message. Like Stdlib.failwith it should be replaced by a more specific error mechanism in most cases.

val error_with_exn : exn -> 'a tzresult

error_with_exn exc errors out: it fails within the TracedResult monad. The payload of the Error constructor is unspecified but it includes the exception.

It is meant as a way to switch from exception-based error management to tzresult-based error management, e.g., when calling external libraries that use exceptions.

try Ok (parse_input s) with Lex_error | Parse_error as exc -> error_with_exn exc

Whilst it is useful in specific places, it is generally better to use a dedicated error.

val fail_with_exn : exn -> 'a tzresult Lwt.t

fail_with_exn exc fails: it fails within the LwtTracedResult monad. The payload of the Error constructor is unspecified but it includes the info from the exception.

It is meant as a way to switch, inside of Lwt code, from exception-based error management to tzresult-based error management, e.g., when calling external libraries that use exceptions.

Lwt.catch
   (fun () -> parse_input s)
   (function
      | Lex_error | Parse_error as exc -> fail_with_exn exc
      | exn -> raise exn (* re-raise by default *))

Whilst it is useful in specific places, it is generally better to use a dedicated error.

Conversions: an exception, an error, a trace, a result

This sub-part of the interface groups declarative functions that convert between different styles of error (exceptions, errors, traces, results). By themselves these functions have no effect within the Result or LwtResult monad, and they are generally used along with constructors or combinators.

val error_of_exn : exn -> error

error_of_exn e is an error that carries the exception e. This function is intended to be used when interacting with a part of the code (most likely an external library) which uses exceptions.

val error_of_fmt : ('a, Stdlib.Format.formatter, unit, error) Stdlib.format4 -> 'a

error_of_fmt … is like error_with … but the error isn't wrapped in a trace in a result. Instead, an error is returned and the caller is expected to pass it to whichever error-combinator is appropriate to the situation. E.g.,

fail_unless (check_valid input) (error_of_fmt "Invalid_input: %a" pp input)

Standard errors

type error +=
  1. | Exn of exn

Wrapped OCaml/Lwt exception

type error +=
  1. | Canceled

Cancelation

Catching exceptions

val protect : ?on_error:(error trace -> 'a tzresult Lwt.t) -> ?canceler:Lwt_canceler.t -> (unit -> 'a tzresult Lwt.t) -> 'a tzresult Lwt.t

protect is a wrapper around Lwt.catch where the error handler operates over trace instead of exn. Besides, protect ~on_error ~canceler ~f may *cancel* f via a Lwt_canceler.t.

More precisely, protect ~on_error ~canceler f runs f (). An Lwt failure triggered by f () is wrapped into an Exn. If a canceler is given and Lwt_canceler.cancellation canceler is determined before f (), a Canceled error is returned.

Errors are caught by ~on_error (if given), otherwise the previous value is returned. An Lwt failure triggered by ~on_error is wrapped into an Exn

val catch : ?catch_only:(exn -> bool) -> (unit -> 'a) -> 'a tzresult

catch f executes f within a try-with block and wraps exceptions within a tzresult. catch f is equivalent to try Ok (f ()) with e -> Error (error_of_exn e).

If catch_only is set, then only exceptions e such that catch_only e is true are caught.

Whether catch_only is set or not, this function never catches non-deterministic runtime exceptions of OCaml such as Stack_overflow and Out_of_memory.

val catch_e : ?catch_only:(exn -> bool) -> (unit -> 'a tzresult) -> 'a tzresult

catch_e is like catch but when f returns a tzresult. I.e., catch_e f is equivalent to try f () with e -> Error (error_of_exn e).

catch_only has the same use as with catch. The same restriction on catching non-deterministic runtime exceptions applies.

val catch_f : ?catch_only:(exn -> bool) -> (unit -> 'a) -> (exn -> error) -> 'a tzresult

catch_f f handler is equivalent to map_error (catch f) handler. In other words, it catches exceptions in f () and either returns the value in an Ok or passes the exception to handler for the Error.

No attempt is made to catch the exceptions raised by handler.

catch_only has the same use as with catch. The same restriction on catching non-deterministic runtime exceptions applies.

val catch_s : ?catch_only:(exn -> bool) -> (unit -> 'a Lwt.t) -> 'a tzresult Lwt.t

catch_s is like catch but when f returns a promise. It is equivalent to

Lwt.try_bind f
  (fun v -> Lwt.return (Ok v))
  (fun e -> Lwt.return (Error (error_of_exn e)))

catch_only has the same use as with catch. The same restriction on catching non-deterministic runtime exceptions applies.

val catch_es : ?catch_only:(exn -> bool) -> (unit -> 'a tzresult Lwt.t) -> 'a tzresult Lwt.t

catch_es is like catch_s but when f returns a promise of a tzresult. I.e., catch_es f is equivalent to Lwt.catch f (fun e -> Lwt.return_error (error_of_exn e)).

catch_only has the same use as with catch. The same restriction on catching non-deterministic runtime exceptions applies.

val protect_result : ?canceler:Lwt_canceler.t -> (unit -> 'a Lwt.t) -> ('a, exn) Stdlib.result Lwt.t

protect_result is similar to protect except that any non runtime exception raised by Lwt.catch is wrapped under an Error value.

Misc

type error +=
  1. | Timeout
val with_timeout : ?canceler:Lwt_canceler.t -> unit Lwt.t -> (Lwt_canceler.t -> 'a tzresult Lwt.t) -> 'a tzresult Lwt.t
module Internal_event = Tezos_event_logging.Internal_event
module Filename : sig ... end
module Bounded = Bounded
module Empty : sig ... end

The main purpose of this module is to be used with parametric types such as ('a, Empty.t) result. Such type is actually isomorphic to 'a (see get_ok function). This is useful if a module signature expects a generic ('a,'b) result type, but for some instantiation, 'b is actually empty. Here is a small example how such module can be used:

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