package ppx_deriving

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Public API of ppx_deriving executable.

Registration

type deriver = {
  1. name : string;
  2. core_type : (Parsetree.core_type -> Parsetree.expression) option;
  3. type_decl_str : options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_declaration list -> Parsetree.structure;
  4. type_ext_str : options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_extension -> Parsetree.structure;
  5. type_decl_sig : options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_declaration list -> Parsetree.signature;
  6. type_ext_sig : options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_extension -> Parsetree.signature;
}

A type of deriving plugins.

A structure or signature deriving function accepts a list of ~options, a ~path of modules for the type declaration currently being processed (with [] for toplevel phrases), and a type declaration item (type t = .. and t' = ..), and returns a list of items to be appended after the type declaration item in structure and signature. It is invoked by [\@\@deriving] annotations.

A type deriving function accepts a type and returns a corresponding derived expression. It is invoked by [%derive.foo:] and [%foo:] annotations. If this function is missing, the corresponding [%foo:] annotation is ignored.

The structure and signature deriving functions are invoked in the order in which they appear in the source code.

val register : deriver -> unit

register deriver registers deriver according to its name field.

val create : string -> ?core_type:(Parsetree.core_type -> Parsetree.expression) -> ?type_ext_str: (options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_extension -> Parsetree.structure) -> ?type_ext_sig: (options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_extension -> Parsetree.signature) -> ?type_decl_str: (options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_declaration list -> Parsetree.structure) -> ?type_decl_sig: (options:(string * Parsetree.expression) list -> path:string list -> Parsetree.type_declaration list -> Parsetree.signature) -> unit -> deriver

Creating deriver structure.

val lookup : string -> deriver option

lookup name looks up a deriver called name.

Error handling

val raise_errorf : ?sub:Location.error list -> ?if_highlight:string -> ?loc:Location.t -> ('a, unit, string, 'b) Pervasives.format4 -> 'a

raise_error is a shorthand for raising Location.Error with the result of Location.errorf.

val string_of_core_type : Parsetree.core_type -> string

string_of_core_type typ unparses typ, omitting any attributes.

Option parsing

module Arg : sig ... end

Arg contains convenience functions that extract constants from AST fragments, to be used when parsing options or [\@attributes] attached to types, fields or constructors.

Hygiene

type quoter

A quoter remembers a set of expressions.

val create_quoter : unit -> quoter

quoter () creates an empty quoter.

quote quoter expr records a pure expression expr within quoter and returns an expression which has the same value as expr in the context that sanitize provides.

val sanitize : ?quoter:quoter -> Parsetree.expression -> Parsetree.expression

sanitize quoter expr wraps expr in a way that ensures that the contents of Ppx_deriving_runtime and Pervasives, as well as the identifiers in expressions returned by quote are in scope, and returns the wrapped expression.

val with_quoter : (quoter -> 'a -> Parsetree.expression) -> 'a -> Parsetree.expression

with_quoter fnfun fn a -> let quoter = create_quoter () in sanitize ~quoter (fn quoter a)

AST manipulation

val expand_path : path:string list -> string -> string

expand_path name returns name with the path module path prepended, e.g. expand_path ["Foo";"M"] "t" = "Foo.M.t" and expand_path [] "t" = "t"

val path_of_type_decl : path:string list -> Parsetree.type_declaration -> string list

path_of_type_decl ~path type_ returns path if type_ does not have a manifest or the manifest is not a constructor, and the module path of manifest otherwise.

path_of_type_decl is useful when determining the canonical path location of fields and constructors; e.g. for type bar = M.foo = A | B, it will return ["M"].

val mangle_type_decl : ?fixpoint:string -> [ `Prefix of string | `Suffix of string | `PrefixSuffix of string * string ] -> Parsetree.type_declaration -> string

mangle_type_decl ~fixpoint affix type_ derives a function name from type_ name by doing nothing if type_ is named fixpoint ("t" by default), or appending and/or prepending affix via an underscore.

val mangle_lid : ?fixpoint:string -> [ `Prefix of string | `Suffix of string | `PrefixSuffix of string * string ] -> Longident.t -> Longident.t

mangle_lid ~fixpoint affix lid does the same as mangle_type_decl, but for the last component of lid.

val attr : deriver:string -> string -> Parsetree.attributes -> Parsetree.attribute option

attr ~deriver name attrs searches for an attribute [\@deriving.deriver.attr] in attrs if any attribute with name starting with \@deriving.deriver exists, or [\@deriver.attr] if any attribute with name starting with \@deriver exists, or [\@attr] otherwise.

attr_warning expr builds the attribute \@ocaml.warning expr

val free_vars_in_core_type : Parsetree.core_type -> string list

free_vars_in_core_type typ returns unique free variables in typ in lexical order.

val fresh_var : string list -> string

fresh_var bound returns a fresh variable name not present in bound. The name is selected in alphabetical succession.

val fold_left_type_decl : ('a -> string -> 'a) -> 'a -> Parsetree.type_declaration -> 'a

fold_left_type_decl fn accum type_ performs a left fold over all type variable (i.e. not wildcard) parameters in type_.

val fold_right_type_decl : (string -> 'a -> 'a) -> Parsetree.type_declaration -> 'a -> 'a

fold_right_type_decl fn accum type_ performs a right fold over all type variable (i.e. not wildcard) parameters in type_.

val fold_left_type_ext : ('a -> string -> 'a) -> 'a -> Parsetree.type_extension -> 'a

fold_left_type_ext fn accum type_ performs a left fold over all type variable (i.e. not wildcard) parameters in type_.

val fold_right_type_ext : (string -> 'a -> 'a) -> Parsetree.type_extension -> 'a -> 'a

fold_right_type_ext fn accum type_ performs a right fold over all type variable (i.e. not wildcard) parameters in type_.

poly_fun_of_type_decl type_ expr wraps expr into fun poly_N -> ... for every type parameter 'N present in type_. For example, if type_ refers to type ('a, 'b) map, expr will be wrapped into fun poly_a poly_b -> [%e expr].

_ parameters are ignored.

Same as poly_fun_of_type_decl but for type extension.

poly_apply_of_type_decl type_ expr wraps expr into expr poly_N for every type parameter 'N present in type_. For example, if type_ refers to type ('a, 'b) map, expr will be wrapped into [%e expr] poly_a poly_b.

_ parameters are ignored.

Same as poly_apply_of_type_decl but for type extension.

poly_arrow_of_type_decl fn type_ typ wraps typ in an arrow with fn [%type: 'N] as argument for every type parameter 'N present in type_. For example, if type_ refers to type ('a, 'b) map and fn is fun var -> [%type: [%t var] -> string], typ will be wrapped into ('a -> string) -> ('b -> string) -> [%t typ].

_ parameters are ignored.

val core_type_of_type_decl : Parsetree.type_declaration -> Parsetree.core_type

core_type_of_type_decl type_ constructs type ('a, 'b, ...) t for type declaration type ('a, 'b, ...) t = ....

val core_type_of_type_ext : Parsetree.type_extension -> Parsetree.core_type

Same as core_type_of_type_decl but for type extension.

val instantiate : string list -> Parsetree.type_declaration -> Parsetree.core_type * string list * string list

instantiate bound type_ returns typ, vars, bound' where typ is a type instantiated from type declaration type_, varsfree_vars_in_core_type typ and bound'bound @ vars.

fold_exprs ~unit fn exprs folds exprs using head of exprs as initial accumulator value, or unit if exprs = [].

See also seq_reduce and binop_reduce.

When sep is present: seq_reducefun x a b -> [%expr [%e a]; [%e x]; [%e b]]. When sep is missing: seq_reducefun a b -> [%expr [%e a]; [%e b]].

binop_reducefun x a b -> [%expr [%e x] [%e a] [%e b]].

val strong_type_of_type : Parsetree.core_type -> Parsetree.core_type

strong_type_of_type ty transform a type ty to freevars . ty, giving a strong polymorphic type

val mapper : Ast_mapper.mapper

The mapper for the currently loaded deriving plugins. It is useful for recursively processing expression-valued attributes.

Miscellanea

val hash_variant : string -> int

hash_variant xBtype.hash_variant x.

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