bio  website  decom.ufop.br/romildo 

location  Brazil  
age  47  
visits  member for  4 years, 5 months 
seen  yesterday  
stats  profile views  51 
I am teacher at the Computer Science Department of Federal University of Ouro Preto, in Brazil. My main interest is in Programming Languages, particularly the functional ones.
Jul 28 
comment 
How to customize emacs themes without editing the theme?
I suppose one advantage is that the customization (without editing the theme) is not lost when the theme is updated. 
Jul 2 
awarded  Curious 
Jun 8 
revised 
Parsing file inside a file being parsed with java cup
Fix spelling of Cup 
Jun 8 
suggested  suggested edit on Parsing file inside a file being parsed with java cup 
May 28 
comment 
Haskell: < in do notation for monad
runWriter writer runs the writer computation and results in the pair composed by the its return value and the final context. In your example, the computation returns 15 and the final context is ["Got number: 3","Got number: 5"] , therefore the result is the pair (15,["Got number: 3","Got number: 5"]) .

May 28 
comment 
Haskell: < in do notation for monad
No. Writer is a type constructor with arity 2 (that is, the Writer type constructor expects 2 type arguments in order to have a type). As a monad always is a type constructor of arity 1, we need first apply Writter to a type argument in order to get a monad. Therefore Writer is not a monad, but Writer [String] is.

Feb 18 
awarded  Caucus 
Dec 28 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, but main = print (2*a) where a = 3 is right, and the where belongs to the full equation, and not to any particular expression. The variable a is defined locally to the equation, and could be used on its right hand side, or even in any guards on the left hand side.

Dec 28 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, consider for instance the following equation in a Haskell program: main = print (2*a where a = 3) . It is wrong because 2*a where a = 3 is not a valid expression and the Haskell compiler just reports it as a syntax error.

Dec 28 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, as you think GHCi is no good example, then write a small Haskell program with an equation trying to use `where' in any place an expression is expected, except at the end of the equation, and you will get an error. 
Dec 28 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, being a purely functional language is not related to the need to construct declarations. GHCi accepts expressions, which are compiled and then evaluated. It also accepts IO a actions as if they were part of a do expression. In this case the action is run. A Haskell program is built from a set of modules. One of them should be named Main , and should export the variable main :: IO a . A module can contain only declarations (types, variables, ...).

Dec 28 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, GHCi accepts expressions for evaluation. It evaluates the expression and proceeds differently based on its type. If the type of the expression is IO a , that is, the expression is a computation in the IO monad, that computation is run and its return value is shown. Otherwise the value of the expression is shown.

Dec 28 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, the expression let a = 3 in 2 * a evaluates to 6 with no problems in GHCi. It should not give any error. If it fails for you, something is wrong with your system.

Dec 27 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, but <expr> where <decls> is not valid Haskell syntax. For instance, if typed in GHCi , the phrase 2*a where a=3 is rejected with the error message parse error on input `where' . This happens because where can be used only with an equation, not with an expression. The source of misunderstanding may be the fact that the right hand side of an equation is an expression, making one to think the where is attached to it. But that is not the case. It is attached to the whole equation.

Dec 27 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, in <left> = let <decls> in <right> it just happens that the right hand side of the equation is a let expression. It could be any expression. The scope of any variable binding introduced by decls is limited to the let expression. With where the scope is the full equation, including any guards that may appear in the equation.

Dec 26 
comment 
Why should I use case expressions if I can use “equations”?
Summary: let is an expression which may introduce local variable bindings, and where may introduce local variable bindings to the right hand side of an equation.

Dec 26 
comment 
Why should I use case expressions if I can use “equations”?
@JMCF125, where is not just let backwards. let <decls> in <expr> is a an expression, and as such it can be evaluated. Any variable bindings introducing ind <decls> are local to the let expression. <left> = <right> where <decls> is an equation that may define some variables appearing in <left> . For that it may use some local definitions introduced by <decls> . Any variable binding introduced in <decl> is local to <right> .

Dec 25 
comment 
Why should I use case expressions if I can use “equations”?
@dfeuer This answer as it stands is still wrong: where can be used to introduce local declarations to an equation, not to an expression. You should use let in this case: let {f pat1 = e1; f pat2 = e2; etc} in f exp .

Dec 24 
suggested  suggested edit on Why should I use case expressions if I can use “equations”? 
Sep 13 
comment 
Annotated recursive data types with different type of annotation in AST
I do not know how I have not seen that! I was trying to share the unannotated tree between the input and output annotated trees, which does not have compatible types. The unannotated tree has to be reconstructed. Rewriting the first alternative of the case expression as follows fixes the issue: Num n > return (In (Ann NUMERIC (Num n)))
