{.used.} # nim-result is also available stand-alone from https://github.com/arnetheduck/nim-result/ import ../stew/results type R = Result[int, string] # Basic usage, producer block: func works(): R = R.ok(42) func works2(): R = result.ok(42) func works3(): R = ok(42) func fails(): R = R.err("dummy") func fails2(): R = result.err("dummy") func fails3(): R = err("dummy") let rOk = works() rOk2 = works2() rOk3 = works3() rErr = fails() rErr2 = fails2() rErr3 = fails3() doAssert rOk.isOk doAssert rOk2.isOk doAssert rOk3.isOk doAssert (not rOk.isErr) doAssert rErr.isErr doAssert rErr2.isErr doAssert rErr3.isErr # Mutate var x = rOk x.err("failed now") doAssert x.isErr doAssert x.error == "failed now" # Combine doAssert (rOk and rErr).isErr doAssert (rErr and rOk).isErr doAssert (rOk or rErr).isOk doAssert (rErr or rOk).isOk # Fail fast proc failFast(): int = raiseAssert "shouldn't evaluate" proc failFastR(): R = raiseAssert "shouldn't evaluate" doAssert (rErr and failFastR()).isErr doAssert (rOk or failFastR()).isOk # `and` heterogenous types doAssert (rOk and Result[string, string].ok($rOk.get())).get() == $(rOk[]) # `or` heterogenous types doAssert (rErr or Result[int, int].err(len(rErr.error))).error == len(rErr.error) # Exception on access doAssert (try: (discard rOk.tryError(); false) except ResultError[int]: true) doAssert (try: (discard rErr.tryGet(); false) except ResultError[string]: true) # Value access or default doAssert rOk.get(100) == rOk.get() doAssert rErr.get(100) == 100 doAssert rOk.get() == rOk.unsafeGet() doAssert rOk.valueOr(failFast()) == rOk.value() let rErrV = rErr.valueOr: error.len doAssert rErrV == rErr.error.len() let rOkV = rOk.errorOr: $value doAssert rOkV == $rOk.get() # Exceptions -> results func raises(): int = raise (ref CatchableError)(msg: "hello") let c = catch: raises() doAssert c.isErr # De-reference when (NimMajor, NimMinor) >= (1, 6): {.warning[BareExcept]:off.} try: echo rErr[] doAssert false except: discard when (NimMajor, NimMinor) >= (1, 6): {.warning[BareExcept]:on.} # Comparisons doAssert (rOk == rOk) doAssert (rErr == rErr) doAssert (rOk != rErr) # Mapping doAssert (rOk.map(func(x: int): string = $x)[] == $rOk.value) doAssert (rOk.map(func(x: int) = discard)).isOk() doAssert (rOk.flatMap( proc(x: int): Result[string, string] = Result[string, string].ok($x))[] == $rOk.value) doAssert (rErr.mapErr(func(x: string): string = x & "no!").error == (rErr.error & "no!")) # Casts and conversions doAssert rOk.mapConvert(int64)[] == int64(42) doAssert rOk.mapConvert(uint64)[] == uint64(42) doAssert rOk.mapCast(int8)[] == int8(42) doAssert (rErr.orErr(32)).error == 32 doAssert (rOk.orErr(failFast())).get() == rOk.get() # string conversion doAssert $rOk == "ok(42)" doAssert $rErr == "err(dummy)" # Exception interop let e = capture(int, (ref ValueError)(msg: "test")) doAssert e.isErr doAssert e.error.msg == "test" try: discard rOk.tryError() doAssert false, "should have raised" except ValueError: discard try: discard e.tryGet() doAssert false, "should have raised" except ValueError as e: doAssert e.msg == "test" # Nice way to checks if (let v = works(); v.isOk): doAssert v[] == v.value # Expectations doAssert rOk.expect("testOk never fails") == 42 # Question mark operator func testQn(): Result[int, string] = let x = ?works() - ?works() ok(x) func testQn2(): Result[int, string] = # looks like we can even use it creatively like this if ?fails() == 42: raise (ref ValueError)(msg: "shouldn't happen") func testQn3(): Result[bool, string] = # different T but same E let x = ?works() - ?works() ok(x == 0) doAssert testQn()[] == 0 doAssert testQn2().isErr doAssert testQn3()[] proc heterOr(): Result[int, int] = let value = ? (rErr or err(42)) # TODO ? binds more tightly than `or` - can that be fixed? doAssert value + 1 == value, "won't reach, ? will shortcut execution" ok(value) doAssert heterOr().error() == 42 # Flatten doAssert Result[R, string].ok(rOk).flatten() == rOk doAssert Result[R, string].ok(rErr).flatten() == rErr # Filter doAssert rOk.filter(proc(x: int): auto = Result[void, string].ok()) == rOk doAssert rOk.filter(proc(x: int): auto = Result[void, string].err("filter")).error == "filter" doAssert rErr.filter(proc(x: int): auto = Result[void, string].err("filter")) == rErr # Exception conversions - toException must not be inside a block type AnEnum = enum anEnumA anEnumB AnException = ref object of CatchableError v: AnEnum func toException(v: AnEnum): AnException = AnException(v: v) func testToException(): int = try: var r = Result[int, AnEnum].err(anEnumA) r.tryGet except AnException: 42 doAssert testToException() == 42 type AnEnum2 = enum anEnum2A anEnum2B func testToString(): int = try: var r = Result[int, AnEnum2].err(anEnum2A) r.tryGet except ResultError[AnEnum2]: 42 doAssert testToString() == 42 block: # Result[void, E] type VoidRes = Result[void, int] func worksVoid(): VoidRes = VoidRes.ok() func worksVoid2(): VoidRes = result.ok() func worksVoid3(): VoidRes = ok() func failsVoid(): VoidRes = VoidRes.err(42) func failsVoid2(): VoidRes = result.err(42) func failsVoid3(): VoidRes = err(42) let vOk = worksVoid() vOk2 = worksVoid2() vOk3 = worksVoid3() vErr = failsVoid() vErr2 = failsVoid2() vErr3 = failsVoid3() doAssert vOk.isOk doAssert vOk2.isOk doAssert vOk3.isOk doAssert (not vOk.isErr) doAssert vErr.isErr doAssert vErr2.isErr doAssert vErr3.isErr vOk.get() vOk.unsafeGet() vOk.expect("should never fail") vOk[] # Comparisons doAssert (vOk == vOk) doAssert (vErr == vErr) doAssert (vOk != vErr) # Mapping doAssert vOk.map(proc (): int = 42).get() == 42 vOk.map(proc () = discard).get() vOk.mapErr(proc(x: int): int = 10).get() vOk.mapErr(proc(x: int) = discard).get() doAssert vErr.mapErr(proc(x: int): int = 10).error() == 10 # string conversion doAssert $vOk == "ok()" doAssert $vErr == "err(42)" # Question mark operator func voidF(): VoidRes = ok() func voidF2(): Result[int, int] = ? voidF() ok(42) doAssert voidF2().isOk # flatten doAssert Result[VoidRes, int].ok(vOk).flatten() == vOk doAssert Result[VoidRes, int].ok(vErr).flatten() == vErr # Filter doAssert vOk.filter(proc(): auto = Result[void, int].ok()) == vOk doAssert vOk.filter(proc(): auto = Result[void, int].err(100)).error == 100 doAssert vErr.filter(proc(): auto = Result[void, int].err(100)) == vErr block: # Result[T, void] aka `Opt` type OptInt = Result[int, void] func worksOpt(): OptInt = OptInt.ok(42) func worksOpt2(): OptInt = result.ok(42) func worksOpt3(): OptInt = ok(42) func failsOpt(): OptInt = OptInt.err() func failsOpt2(): OptInt = result.err() func failsOpt3(): OptInt = err() let oOk = worksOpt() oOk2 = worksOpt2() oOk3 = worksOpt3() oErr = failsOpt() oErr2 = failsOpt2() oErr3 = failsOpt3() doAssert oOk.isOk doAssert oOk2.isOk doAssert oOk3.isOk doAssert (not oOk.isErr) doAssert oErr.isErr doAssert oErr2.isErr doAssert oErr3.isErr # Comparisons doAssert (oOk == oOk) doAssert (oErr == oErr) doAssert (oOk != oErr) doAssert oOk.get() == oOk.unsafeGet() oErr.error() oErr.unsafeError() # Mapping doAssert oOk.map(proc(x: int): string = $x).get() == $oOk.get() oOk.map(proc(x: int) = discard).get() doAssert oOk.mapErr(proc(): int = 10).get() == oOk.get() doAssert oOk.mapErr(proc() = discard).get() == oOk.get() doAssert oErr.mapErr(proc(): int = 10).error() == 10 # string conversion doAssert $oOk == "ok(42)" doAssert $oErr == "none()" proc optQuestion(): OptInt = let v = ? oOk ok(v) doAssert optQuestion().isOk() # Flatten doAssert Result[OptInt, void].ok(oOk).flatten() == oOk doAssert Result[OptInt, void].ok(oErr).flatten() == oErr # Filter doAssert oOk.filter(proc(x: int): auto = Result[void, void].ok()) == oOk doAssert oOk.filter(proc(x: int): auto = Result[void, void].err()).isErr() doAssert oErr.filter(proc(x: int): auto = Result[void, void].err()) == oErr doAssert oOk.filter(proc(x: int): bool = true) == oOk doAssert oOk.filter(proc(x: int): bool = false).isErr() doAssert oErr.filter(proc(x: int): bool = true) == oErr doAssert Opt.some(42).get() == 42 doAssert Opt.none(int).isNone() block: # `cstring` dangling reference protection type CSRes = Result[void, cstring] func cstringF(s: string): CSRes = when compiles(err(s)): doAssert false discard cstringF("test") block: # Experiments # Can formalise it into a template (https://github.com/arnetheduck/nim-result/issues/8) template `?=`(v: untyped{nkIdent}, vv: Result): bool = (let vr = vv; template v: auto {.used.} = unsafeGet(vr); vr.isOk) if f ?= Result[int, string].ok(42): doAssert f == 42 # TODO there's a bunch of operators that one could lift through magic - this # is mainly an example template `+`(self, other: Result): untyped = ## Perform `+` on the values of self and other, if both are ok type R = type(other) if self.isOk: if other.isOk: R.ok(self.value + other.value) else: R.err(other.error) else: R.err(self.error) let rOk = Result[int, string].ok(42) # Simple lifting.. doAssert (rOk + rOk)[] == rOk.value + rOk.value iterator items[T, E](self: Result[T, E]): T = ## Iterate over result as if it were a collection of either 0 or 1 items ## TODO should a Result[seq[X]] iterate over items in seq? there are ## arguments for and against if self.isOk: yield self.value # Iteration var counter2 = 0 for v in rOk: counter2 += 1 doAssert counter2 == 1, "one-item collection when set" block: # Constants # TODO https://github.com/nim-lang/Nim/issues/20699 type WithOpt = object opt: Opt[int] const noneWithOpt = WithOpt(opt: Opt.none(int)) proc checkIt(v: WithOpt) = doAssert v.opt.isNone() checkIt(noneWithOpt)