# Comprehensions # -------------- # * Array Comprehensions # * Range Comprehensions # * Object Comprehensions # * Comprehensions with Nonstandard Step # TODO: refactor comprehension tests # Basic array comprehensions. nums = (n * n for n in [1, 2, 3] when n & 1) results = (n * 2 for n in nums) ok results.join(',') is '2,18' # Basic object comprehensions. obj = {one: 1, two: 2, three: 3} names = (prop + '!' for prop of obj) odds = (prop + '!' for prop, value of obj when value & 1) ok names.join(' ') is "one! two! three!" ok odds.join(' ') is "one! three!" # Basic range comprehensions. nums = (i * 3 for i in [1..3]) negs = (x for x in [-20..-5*2]) negs = negs[0..2] result = nums.concat(negs).join(', ') ok result is '3, 6, 9, -20, -19, -18' # With range comprehensions, you can loop in steps. results = (x for x in [0...15] by 5) ok results.join(' ') is '0 5 10' results = (x for x in [0..100] by 10) ok results.join(' ') is '0 10 20 30 40 50 60 70 80 90 100' # And can loop downwards, with a negative step. results = (x for x in [5..1]) ok results.join(' ') is '5 4 3 2 1' ok results.join(' ') is [(10-5)..(-2+3)].join(' ') results = (x for x in [10..1]) ok results.join(' ') is [10..1].join(' ') results = (x for x in [10...0] by -2) ok results.join(' ') is [10, 8, 6, 4, 2].join(' ') # Range comprehension gymnastics. eq "#{i for i in [5..1]}", '5,4,3,2,1' eq "#{i for i in [5..-5] by -5}", '5,0,-5' a = 6 b = 0 c = -2 eq "#{i for i in [a..b]}", '6,5,4,3,2,1,0' eq "#{i for i in [a..b] by c}", '6,4,2,0' # Multiline array comprehension with filter. evens = for num in [1, 2, 3, 4, 5, 6] when not (num & 1) num *= -1 num -= 2 num * -1 eq evens + '', '4,6,8' # The in operator still works, standalone. ok 2 of evens # all isn't reserved. all = 1 # Ensure that the closure wrapper preserves local variables. obj = {} for method in ['one', 'two', 'three'] then do (method) -> obj[method] = -> "I'm " + method ok obj.one() is "I'm one" ok obj.two() is "I'm two" ok obj.three() is "I'm three" # Index values at the end of a loop. i = 0 for i in [1..3] -> 'func' break if false ok i is 4 # Ensure that local variables are closed over for range comprehensions. funcs = for i in [1..3] do (i) -> -> -i eq (func() for func in funcs).join(' '), '-1 -2 -3' ok i is 4 # Even when referenced in the filter. list = ['one', 'two', 'three'] methods = for num, i in list when num isnt 'two' and i isnt 1 do (num, i) -> -> num + ' ' + i ok methods.length is 2 ok methods[0]() is 'one 0' ok methods[1]() is 'three 2' # Even a convoluted one. funcs = [] for i in [1..3] do (i) -> x = i * 2 ((z)-> funcs.push -> z + ' ' + i )(x) ok (func() for func in funcs).join(', ') is '2 1, 4 2, 6 3' funcs = [] results = for i in [1..3] do (i) -> z = (x * 3 for x in [1..i]) ((a, b, c) -> [a, b, c].join(' ')).apply this, z ok results.join(', ') is '3 , 3 6 , 3 6 9' # Naked ranges are expanded into arrays. array = [0..10] ok(num % 2 is 0 for num in array by 2) # Nested shared scopes. foo = -> for i in [0..7] do (i) -> for j in [0..7] do (j) -> -> i + j eq foo()[3][4](), 7 # Scoped loop pattern matching. a = [[0], [1]] funcs = [] for [v] in a do (v) -> funcs.push -> v eq funcs[0](), 0 eq funcs[1](), 1 # Nested comprehensions. multiLiner = for x in [3..5] for y in [3..5] [x, y] singleLiner = (([x, y] for y in [3..5]) for x in [3..5]) ok multiLiner.length is singleLiner.length ok 5 is multiLiner[2][2][1] ok 5 is singleLiner[2][2][1] # Comprehensions within parentheses. result = null store = (obj) -> result = obj store (x * 2 for x in [3, 2, 1]) ok result.join(' ') is '6 4 2' # Closure-wrapped comprehensions that refer to the "arguments" object. expr = -> result = (item * item for item in arguments) ok expr(2, 4, 8).join(' ') is '4 16 64' # Fast object comprehensions over all properties, including prototypal ones. class Cat constructor: -> @name = 'Whiskers' breed: 'tabby' hair: 'cream' whiskers = new Cat own = (value for own key, value of whiskers) all = (value for key, value of whiskers) ok own.join(' ') is 'Whiskers' ok all.sort().join(' ') is 'Whiskers cream tabby' # Optimized range comprehensions. exxes = ('x' for [0...10]) ok exxes.join(' ') is 'x x x x x x x x x x' # Comprehensions safely redeclare parameters if they're not present in closest # scope. rule = (x) -> x learn = -> rule for rule in [1, 2, 3] ok learn().join(' ') is '1 2 3' ok rule(101) is 101 f = -> [-> ok no, 'should cache source'] ok yes for k of [f] = f() # Lenient on pure statements not trying to reach out of the closure val = for i in [1] for j in [] then break i ok val[0] is i # Comprehensions only wrap their last line in a closure, allowing other lines # to have pure expressions in them. func = -> for i in [1] break if i is 2 j for j in [1] ok func()[0][0] is 1 i = 6 odds = while i-- continue unless i & 1 i ok odds.join(', ') is '5, 3, 1' # Issue #897: Ensure that plucked function variables aren't leaked. facets = {} list = ['one', 'two'] (-> for entity in list facets[entity] = -> entity )() eq typeof entity, 'undefined' eq facets['two'](), 'two' # Issue #905. Soaks as the for loop subject. a = {b: {c: [1, 2, 3]}} for d in a.b?.c e = d eq e, 3 # Issue #948. Capturing loop variables. funcs = [] list = -> [1, 2, 3] for y in list() do (y) -> z = y funcs.push -> "y is #{y} and z is #{z}" eq funcs[1](), "y is 2 and z is 2" # Cancel the comprehension if there's a jump inside the loop. result = try for i in [0...10] continue if i < 5 i eq result, 10 # Comprehensions over break. arrayEq (break for [1..10]), [] # Comprehensions over continue. arrayEq (break for [1..10]), [] # Comprehensions over function literals. a = 0 for f in [-> a = 1] do (f) -> do f eq a, 1 # Comprehensions that mention arguments. list = [arguments: 10] args = for f in list do (f) -> f.arguments eq args[0], 10