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ambiguity
Not directly an ambiguity but something to be aware of:
Ambiguity should ideally be resolved by the compiler by asking questions.
a {x=1} Did you mean a:{x=1} or [a,{x=1}] ?
a>b:c Did you mean a>b : c or a > b:c ?
significant-whitespace / semantic resolution
in general in wasp lists plus element means extending the list:
(x,y)+z=(x,y,z)
in general in wasp lists of one element are identical to the element:
(x)=x
however this might lead to conflicts, eg in list extensions:
(x)+y=(x y) ≠ x+y
resolvable by the parser?
Different list separators have different bindings: While 1,2,3 binds as one expression, 1;2;3 yields the last element as return value.
Consider a b (a) (b) {a} (b) and {a}(b).
Are they the same? A group with one element is identical to the element itself:
Axiom (a) == a
Is a block with one element identical to the element itself?
{a} == a ?
Is {a} (b) a list with elements {a} and b or is it b applied to {a} {a}(b) ?
while the precedence of ',' and '; is clear:
1,2;3,4 == ((1,2);(3,4)) the precedence of ',' and ' ' less is clear: 1 2 3 , 4 5 6and1,2,3 4,5,6`
both seam like reasonably natural groupings.
Problematic is the ambiguity in mixing 'and', comma and other operators
x, y == a, b
x, (y == a) , b
The last reading is sometimes the desired one, e.g. in argument lists
x, y as point == x, (y as point) or x, y as point == (x, y) as point == point(x,y)
[[Todo]]! What to do?
For colons the situation is dire as well:
`a b c:d` versus
`to skin a cat: do something`
[[significant-white]] space to the rescue!
### burden of calls withoug parens
`square 3` yields a certain [[beauty]]
However when mixing function calls and operators, things can get ambiguous quickly:
`square 3 * 3 ` can be read as `square (3 * 3)` or `(square 3) * 3`
`square 3 + square 3` can be read as `square (3 + square 3)` or `(square 3) + square 3`
Operators [bind](precedence) more tightly than functions.
Only the last case where functions are inter-mixed needs special attention:
### resolution: braces via IDE
One way to resolve ambiguities is by making the IDE suggest and insert braces
square 3 + 4 times 3 square(3 + (4 times 3))
Even though there might not be an ambiguity to the compiler, it can be helpful to insert braces to make it easier for the user to parse the meaning:
`a or b and c => a or (b and c)`
The reasoning behind this is that the developer might not always we be aware of the [[function]] [[operator]] [[precedence]].
### ambiguity in c
```while (char c = dest[i] and i>0) ```
sets c to 0 or 1 because and binds stronger than assignment!!
## ambiguous referenceIndices
### ambiguous it keyword
In [lambda](closures) expression, the `it` keyword refers to the first (implicit argument), otherwise it refers
to [[self]] or the last [[result]], which can be very ambivalent:
double=it2 # ok, interpret immediately? double:it2 # may interpret to anything later double:=it*2 # ok, implicit argument for function 'double'
### functions or functors
```map [1 2 3] square``` could be read as
```map [1 2 3] :square``` symbolic function pointer
```map ([1 2 3] square) == map [1 4 9]```
## variables vs functions
ambiguous [[assignment]] concepts:
name, age, source = "Crystal, 123, GitHub".split(", ") # deconstruction assignment name age, source := "Crystal, 123, GitHub".split(", ") # function 'name' with arguments age, source
The last case is especially problematic with
# Multi word variable names and typed variables
name age := age+1 The function 'name' with parameter age could also be read as name_age or age(type=name)
### block evaluation
Ideally we could reconcile `f={a:1 b:2} f[a] == 1` with the current mechanism `f(a=3) == {a:3 b:2}` or `f(a=3) == b:2`
or `f(a=3)==2` because the last expression of the block is returned.
[[Map]] [[match]]ing versus [[block]] [[selection]] versus [[construction]].
### is not
`a is not b // ambiguity: a == !b vs a != b`
### Broadcasting
Broadcasting applies to functions but not to basic operators:
[1,2,3]+4 == [1,2,3,4] [1,2,3]>>1 == [2, 3] [1,2,3]++ == [2, 3]
Because √ and ^ lack graphical grouping or closure in text, their usage is ambivalent:
√1+2 ≠ √(1+2)
2^x+1 ≠ 2^(x+1)
The default is that they are strongly binding (high precedence), but a warning shall be emitted!
similar operators
3 ≈ 3.1
In an early talk Ken was explaining the advantages of tolerant comparison. A member of the audience asked incredulously, “Surely you don’t mean that when A=B and B=C, A may not equal C?” Without skipping a beat, Ken replied, “Any carpenter knows that!” and went on to the next question.
2x == 2*x OK only without space: [2 x] = [2,x] BUT 2 km??