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- import macros
- macro case_token(n: varargs[untyped]): untyped =
- # creates a lexical analyzer from regular expressions
- # ... (implementation is an exercise for the reader :-)
- nil
- case_token: # this colon tells the parser it is a macro statement
- of r"[A-Za-z_]+[A-Za-z_0-9]*":
- return tkIdentifier
- of r"0-9+":
- return tkInteger
- of r"[\+\-\*\?]+":
- return tkOperator
- else:
- return tkUnknown
- case_token: inc i
- #bug #488
- macro foo() =
- var exp = newCall("whatwhat", newIntLitNode(1))
- if compiles(getAst(exp)):
- return exp
- else: echo "Does not compute! (test OK)"
- foo()
- #------------------------------------
- # bug #8287
- type MyString = distinct string
- proc `$` (c: MyString): string {.borrow.}
- proc `!!` (c: cstring): int =
- c.len
- proc f(name: MyString): int =
- !! $ name
- macro repr_and_parse(fn: typed) =
- let fn_impl = fn.getImpl
- fn_impl.name = genSym(nskProc, $fn_impl.name)
- echo fn_impl.repr
- result = parseStmt(fn_impl.repr)
- macro repr_to_string(fn: typed): string =
- let fn_impl = fn.getImpl
- result = newStrLitNode(fn_impl.repr)
- repr_and_parse(f)
- #------------------------------------
- # bugs #8343 and #8344
- proc one_if_proc(x, y : int): int =
- if x < y: result = x
- else: result = y
- proc test_block(x, y : int): int =
- block label:
- result = x
- result = y
- #------------------------------------
- # bugs #8348
- template `>`(x, y: untyped): untyped =
- ## "is greater" operator. This is the same as ``y < x``.
- y < x
- proc test_cond_stmtlist(x, y: int): int =
- result = x
- if x > y:
- result = x
- #------------------------------------
- # bug #8762
- proc t2(a, b: int): int =
- `+`(a, b)
- #------------------------------------
- # bug #8761
- proc fn1(x, y: int):int =
- 2 * (x + y)
- proc fn2(x, y: float): float =
- (y + 2 * x) / (x - y)
- proc fn3(x, y: int): bool =
- (((x and 3) div 4) or (x mod (y xor -1))) == 0 or y notin [1,2]
- proc fn4(x: int): int =
- if x mod 2 == 0: return x + 2
- else: return 0
- proc fn5(a, b: float): float =
- result = - a * a / (b * b)
- proc `{}`(x: seq[float], i: int, j: int): float =
- x[i + 0 * j]
- proc `{}=`(x: var seq[float], i: int, val: float) =
- x[i] = val
- proc fn6() =
- var a = @[1.0, 2.0]
- let z = a{0, 1}
- a{2} = 5.0
- #------------------------------------
- # bug #10807
- proc fn_unsafeaddr(x: int): int =
- cast[int](unsafeAddr(x))
- static:
- let fn1s = "proc fn1(x, y: int): int =\n result = 2 * (x + y)\n"
- let fn2s = "proc fn2(x, y: float): float =\n result = (y + 2 * x) / (x - y)\n"
- let fn3s = "proc fn3(x, y: int): bool =\n result = ((x and 3) div 4 or x mod (y xor -1)) == 0 or not contains([1, 2], y)\n"
- let fn4s = "proc fn4(x: int): int =\n if x mod 2 == 0:\n return x + 2\n else:\n return 0\n"
- let fn5s = "proc fn5(a, b: float): float =\n result = -a * a / (b * b)\n"
- let fn6s = "proc fn6() =\n var a = @[1.0, 2.0]\n let z = a{0, 1}\n a{2} = 5.0\n"
- let fnAddr = "proc fn_unsafeaddr(x: int): int =\n result = cast[int](unsafeAddr(x))\n"
- doAssert fn1.repr_to_string == fn1s
- doAssert fn2.repr_to_string == fn2s
- doAssert fn3.repr_to_string == fn3s
- doAssert fn4.repr_to_string == fn4s
- doAssert fn5.repr_to_string == fn5s
- doAssert fn6.repr_to_string == fn6s
- doAssert fn_unsafeaddr.repr_to_string == fnAddr
- #------------------------------------
- # bug #8763
- type
- A {.pure.} = enum
- X, Y
- B {.pure.} = enum
- X, Y
- proc test_pure_enums(a: B) =
- case a
- of B.X: echo B.X
- of B.Y: echo B.Y
- repr_and_parse(one_if_proc)
- repr_and_parse(test_block)
- repr_and_parse(test_cond_stmtlist)
- repr_and_parse(t2)
- repr_and_parse(test_pure_enums)
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