Merge branch 'georges-tutorial' into 'dev'
Tutorial on the trace monad See merge request ligolang/ligo!12
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vendors/ligo-utils/simple-utils/dune
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(library
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(name simple_utils)
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(public_name simple-utils)
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(preprocess
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(pps simple-utils.ppx_let_generalized))
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(libraries
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yojson
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unix
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vendors/ligo-utils/simple-utils/trace.ml
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(** Trace tutorial
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The module below guides the reader through the writing of a
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simplified version of the trace monad (`result`), and the
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definition of a few operations that make it easier to work with
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`result`.
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*)
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module Trace_tutorial = struct
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(** The trace monad is fairly similar to the option type: *)
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type 'a option =
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Some of 'a (* Ok also stores a list of annotations *)
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| None;; (* Errors also stores a list of messages *)
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type annotation = string;;
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type error = string;;
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type 'a result =
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Ok of 'a * annotation list
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| Errors of error list;;
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(** When applying a partial function on a result, it can return a valid result
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(Some v), or indicate failure (None). *)
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let divide a b =
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if b = 0
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then None
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else Some (a/b);;
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(** With the trace monad, the Errors case also indicates some information about
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the failure, to ease debugging. *)
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let divide_trace a b =
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if b = 0
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then (Errors [Printf.sprintf "division by zero: %d / %d" a b])
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else Ok ((a/b) , []);;
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(** when composing two functions, the error case is propagated. *)
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let divide_three a b c =
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let maybe_a_div_b = divide_trace a b in
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match maybe_a_div_b with
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Ok (a_div_b , _) -> divide_trace a_div_b c
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| (Errors _) as e -> e;;
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(** If both calls are successful, the lists of annotations are concatenated. *)
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let divide_three_annots a b c =
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let maybe_a_div_b = divide_trace a b in
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match maybe_a_div_b with
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Ok (a_div_b , annots1) ->
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let maybe_a_div_b_div_c = divide_trace a_div_b c in
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begin
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match maybe_a_div_b_div_c with
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Ok (a_div_b_div_c , annots2)
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-> Ok (a_div_b_div_c , annots2 @ annots1)
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| (Errors _) as e2 -> e2
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end
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| (Errors _) as e1 -> e1;;
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(** This incurs quite a lot of noise, so we define a `bind` operator which
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takes a function ('x -> ('y result)) and applies it to an existing
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('x result).
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* If the existing result is Errors, `bind` returns that error without
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calling the function
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* Otherwise `bind` unwraps the Ok and calls the function
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* That function may itself return an error
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* Otherwise `bind` combines the annotations and returns the second
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result. *)
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let bind f = function
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| Ok (x, annotations) ->
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(match f x with
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Ok (x', annotations') -> Ok (x', annotations' @ annotations)
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| Errors _ as e' -> ignore annotations; e')
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| Errors _ as e -> e;;
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(** The following function divide_three_bind is equivalent to the verbose
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divide_three. *)
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let divide_three_bind a b c =
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let maybe_a_div_b = divide_trace a b in
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let continuation a_div_b = divide_trace a_div_b c in
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bind continuation maybe_a_div_b;;
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(** This made the code shorter, but the reading order is a bit awkward.
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We define an operator symbol for `bind`: *)
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let (>>?) x f = bind f x;;
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let divide_three_bind_symbol a b c =
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let maybe_a_div_b = divide_trace a b in
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let continuation a_div_b = divide_trace a_div_b c in
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maybe_a_div_b >>? continuation;;
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(** and we inline the two temporary let definitions: *)
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let divide_three_bind_symbol' a b c =
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divide_trace a b >>? (fun a_div_b -> divide_trace a_div_b c);;
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(** This is now fairly legible, but chaining many such functions is
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not the usual way of writing code. We use ppx_let to add some
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syntactic sugar.
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The ppx is enabled by adding the following lines inside the
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section (library …) or (executable …) of the dune file for
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the project that uses ppx_let.
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(preprocess
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(pps simple-utils.ppx_let_generalized))
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*)
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module Let_syntax = struct
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let bind m ~f = m >>? f
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module Open_on_rhs_bind = struct end
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end;;
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(** divide_three_bind_ppx_let is equivalent to divide_three_bind_symbol'.
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Strictly speaking, the only difference is that the module
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Open_on_rhs_bind is opened around the expression on the righ-hand side
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of the `=` sign, namely `divide_trace a b` *)
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let divide_three_bind_ppx_let a b c =
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let%bind a_div_b = divide_trace a b in
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divide_trace a_div_b c;;
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(** This notation scales fairly well: *)
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let divide_many_bind_ppx_let a b c d e f =
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let x = a in
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let%bind x = divide_trace x b in
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let%bind x = divide_trace x c in
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let%bind x = divide_trace x d in
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let%bind x = divide_trace x e in
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let%bind x = divide_trace x f in
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Ok (x , []);;
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(** We define a couple of shorthands for common use cases.
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`ok` lifts a ('foo) value to a ('foo result): *)
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let ok x = Ok (x, []);;
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(** `map` lifts a regular ('foo -> 'bar) function on values
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to a function on results, with type ('foo result -> 'bar result): *)
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let map f = function
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| Ok (x, annotations) -> Ok (f x, annotations)
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| Errors _ as e -> e;;
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(** `bind_list` turns a (('foo result) list) into a (('foo list) result).
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If the list only contains Ok values, it strips the Ok returns that list
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wrapped with Ok.
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Otherwise, when one or more of the elements of the original list is
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Errors, `bind_list` returns the first error in the list. *)
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let rec bind_list = function
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| [] -> ok []
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| hd :: tl -> (
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hd >>? fun hd ->
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bind_list tl >>? fun tl ->
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ok @@ hd :: tl
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);;
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(**
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A major feature of Trace is that it enables having a stack of errors (that
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should act as a simplified stack frame), rather than a unique error.
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It is done by using the function `trace`.
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For instance, let's say that you have a function that can trigger two errors,
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and you want to pass their data along with an other error, what you would
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usually do is:
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```
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let foobarer ... =
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... in
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let value =
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try ( get key map )
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with
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| Bad_key _ -> raise (Foobar_error ("bad key" , key , map))
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| Missing_value _ -> raise (Foobar_error ("missing index" , key , map))
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in ...
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```
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With Trace, you would instead:
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```
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let foobarer ... =
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... in
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let%bind value =
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trace (simple_error "error getting key") @@
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get key map
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in ...
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```
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And this will pass along the error triggered by "get key map".
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*)
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let trace err = function
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| Ok _ as o -> o
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| Errors errs -> Errors (err :: errs);;
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(** The real trace monad is very similar to the one that we have
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defined above. The main difference is that the errors and
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annotations are structured data (instead of plain strings) and are
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lazily-generated. *)
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let the_end = "End of the tutorial.";;
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end (* end Trace_tutorial. *)
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module J = Yojson.Basic
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module JSON_string_utils = struct
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@ -208,34 +418,6 @@ let internal_assertion_failure str = simple_error ("assertion failed: " ^ str)
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*)
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let dummy_fail = simple_fail "dummy"
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(**
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A major feature of Trace is that it enables having a stack of errors (that
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should act as a simplified stack frame), rather than a unique error.
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It is done by using the function `trace`.
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For instance, let's say that you have a function that can trigger two errors,
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and you want to pass their data along with an other error, what you would
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usually do is:
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```
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let foobarer ... =
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... in
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let value =
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try ( get key map )
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with
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| Bad_key _ -> raise (Foobar_error ("bad key" , key , map))
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| Missing_value _ -> raise (Foobar_error ("missing index" , key , map))
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in ...
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```
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With Trace, you would instead:
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```
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let foobarer ... =
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... in
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let%bind value =
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trace (simple_error "error getting key") @@
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get key map
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in ...
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```
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And this will pass along the error triggered by "get key map".
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*)
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let trace info = function
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| Ok _ as o -> o
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| Error err -> Error (fun () -> prepend_info (info ()) (err ()))
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