{ ... }: rec { # Compute the fixed point of the given function `f`, which is usually an # attribute set that expects its final, non-recursive representation as an # argument: # # f = self: { foo = "foo"; bar = "bar"; foobar = self.foo + self.bar; } # # Nix evaluates this recursion until all references to `self` have been # resolved. At that point, the final result is returned and `f x = x` holds: # # nix-repl> fix f # { bar = "bar"; foo = "foo"; foobar = "foobar"; } # # Type: fix :: (a -> a) -> a # # See https://en.wikipedia.org/wiki/Fixed-point_combinator for further # details. fix = f: let x = f x; in x; # A variant of `fix` that records the original recursive attribute set in the # result. This is useful in combination with the `extends` function to # implement deep overriding. See pkgs/development/haskell-modules/default.nix # for a concrete example. fix' = f: let x = f x // { __unfix__ = f; }; in x; # Modify the contents of an explicitly recursive attribute set in a way that # honors `self`-references. This is accomplished with a function # # g = self: super: { foo = super.foo + " + "; } # # that has access to the unmodified input (`super`) as well as the final # non-recursive representation of the attribute set (`self`). `extends` # differs from the native `//` operator insofar as that it's applied *before* # references to `self` are resolved: # # nix-repl> fix (extends g f) # { bar = "bar"; foo = "foo + "; foobar = "foo + bar"; } # # The name of the function is inspired by object-oriented inheritance, i.e. # think of it as an infix operator `g extends f` that mimics the syntax from # Java. It may seem counter-intuitive to have the "base class" as the second # argument, but it's nice this way if several uses of `extends` are cascaded. extends = f: rattrs: self: let super = rattrs self; in super // f self super; # Compose two extending functions of the type expected by 'extends' # into one where changes made in the first are available in the # 'super' of the second composeExtensions = f: g: self: super: let fApplied = f self super; super' = super // fApplied; in fApplied // g self super'; # Create an overridable, recursive attribute set. For example: # # nix-repl> obj = makeExtensible (self: { }) # # nix-repl> obj # { __unfix__ = «lambda»; extend = «lambda»; } # # nix-repl> obj = obj.extend (self: super: { foo = "foo"; }) # # nix-repl> obj # { __unfix__ = «lambda»; extend = «lambda»; foo = "foo"; } # # nix-repl> obj = obj.extend (self: super: { foo = super.foo + " + "; bar = "bar"; foobar = self.foo + self.bar; }) # # nix-repl> obj # { __unfix__ = «lambda»; bar = "bar"; extend = «lambda»; foo = "foo + "; foobar = "foo + bar"; } makeExtensible = makeExtensibleWithCustomName "extend"; # Same as `makeExtensible` but the name of the extending attribute is # customized. makeExtensibleWithCustomName = extenderName: f: makeExtensibleWithInterface (fixedPoint: extend: fixedPoint // { ${extenderName} = ext: extend (_: ext); }) (_: f); # A version of `makeExtensible` that allows the function being fixed # to return a different interface than the interface returned to the # user. Along with `self` and `super` views of the internal # interface, a `self` view of the output interface is also # provided. `extend` is not added to the output by default. This is # the job of the interface. # # nix-repl> foo = {a, b}: {c = a + b;} # # nix-repl> interface = {args, val, ...}: extend: val // {inherit extend;} # # nix-repl> obj = makeExtensibleWithInterface interface (output: self: { args = {a = 1; b = 2;}; val = foo self.args; }) # # nix-repl> obj.c # 3 # # nix-repl> obj = obj.extend (output: self: super: { args = super.args // { b = output.d; }; }) # # nix-repl> obj = obj.extend (output: self: super: { val = super.val // { d = 10; }; }) # # nix-repl> { inherit (obj) c d; } # { c = 11; d = 10; } makeExtensibleWithInterface = interface: f: let i = interface (fix' (f i)) (fext: makeExtensibleWithInterface interface (i': (extends (fext i') (f i')))); in i; }