IsaPrint.hs revision d6025ee06343191f356a59704d467866afa29900
{- |
Module : $Header$
Copyright : (c) University of Cambridge, Cambridge, England
adaption (c) Till Mossakowski, Uni Bremen 2002-2004
Licence : similar to LGPL, see HetCATS/LICENCE.txt or LIZENZ.txt
Maintainer : hets@tzi.de
Stability : provisional
Portability : portable
Printing functions for Isabelle logic.
-}
{-
todo: brackets in (? x . p x) ==> q
properly construct docs
-}
module Isabelle.IsaPrint where
import Isabelle.IsaSign
import Isabelle.IsaConsts
import Common.PrettyPrint
import Common.Lib.Pretty
import Data.Char
import qualified Common.Lib.Map as Map
------------------- Printing functions -------------------
instance PrettyPrint IsaClass where
printText0 _ (IsaClass c) = parens $ text c
instance PrintLaTeX Sentence where
printLatex0 = printText0
instance PrettyPrint Sentence where
printText0 _ = text . showTerm . senTerm
instance PrettyPrint Typ where
printText0 _ = text . showTyp 1000
showTyp :: Integer -> Typ -> String
showTyp pri (Type str _ [s,t])
| str == funS =
bracketize (pri<=10) (showTyp 10 s ++ " => " ++ showTyp 10 t)
| str == prodS =
lb ++ showTyp pri s ++ " * " ++ showTyp pri t ++ rb
showTyp _ (Type name _ args) =
case args of
[] -> name
arg:[] -> showTyp 10 arg ++ sp ++ name
_ -> let (tyVars,types) = foldl split ([],[]) args
in
lb ++ concat (map ((sp++) . show) tyVars) ++
concat (map ((sp++) . show) types) ++ rb ++ name
where split (tv,ty) t = case t of
TFree _ _ -> (tv++[t],ty)
_ -> (tv,ty++[t])
showTyp _ (TFree v _) = "\'" ++ v
showTyp _ (TVar (v,_) _) = "?\'" ++ v
instance PrettyPrint TypeSig where
printText0 _ tysig =
if Map.isEmpty (arities tysig) then empty
else text $ Map.foldWithKey showTycon "" (arities tysig)
where showTycon t arity' rest =
let arity = if null arity' then
error "IsaPrint.printText0 (TypeSig)"
else length (snd $ head arity') in
"typedecl "++
(if arity>0 then lb++concat (map ((" 'a"++).show) [1..arity])++rb
else "") ++ show t ++"\n"++rest
instance PrettyPrint Term where
printText0 _ = text . showTerm -- outerShowTerm
-- back to showTerm, because meta !! causes problems with show ?thesis
stringMap :: (a -> String) -> [a] -> String
stringMap f ls = concat [" " ++ (f x) | x <- ls]
typedVars2st :: (a -> String) -> (b -> String) -> [(a,b)] -> String
typedVars2st f g ls = concat [" (" ++ (f x) ++ "::" ++ (g y) ++ ")" | (x,y) <- ls]
showTypedVars :: [(Term,Typ)] -> String
showTypedVars ls = typedVars2st showTerm (showTyp 1000) ls
showQuantStr :: String -> String
showQuantStr s | s == allS = "!"
| s == exS = "?"
| s == ex1S = "?!"
| otherwise = error "IsaPrint.showQuantStr"
showTerm :: Term -> String
showTerm (Const c) = c
showTerm (Free v) = v
showTerm (Abs vs t NotCont) = lb++"%"++(showTypedVars vs)++" . "++showTerm t++rb
showTerm (Abs vs t IsCont) = lb++"LAM"++(showTypedVars vs)++" . "++showTerm t++rb
-- showTerm (Abs vs t NotCont) = lb++"% "++(stringMap (show . fst) vs)++" . "++showTerm t++rb
-- showTeshowTerm (Abs vs t IsCont) = lb++"LAM "++(stringMap (show . fst) vs)++" . "++showTerm t++rb
showTerm (App (Const q) (Abs vs t _) _) | q `elem` [allS, exS, ex1S] =
showQuant (showQuantStr q) vs t
showTerm (Case term alts) =
let sAlts = map showCaseAlt alts
in
lb ++ "case" ++ sp ++ showTerm term ++ sp ++ "of"
++ sp ++ head sAlts
++ concat (map ((++) ("\n" ++ sp ++ sp ++ sp ++ "|" ++ sp))
(tail sAlts)) ++ rb
-- Just t1 `App` t2 left
showTerm (If t1 t2 t3) =
lb ++ "if" ++ sp ++ showTerm t1 ++ sp ++ "then" ++ sp
++ showTerm t2 ++ sp ++ "else" ++ sp ++ showTerm t3 ++ rb
showTerm (Let pts t) = lb ++ "let" ++ sp ++ showPat False (head pts)
++ concat (map (showPat True) (tail pts))
++ sp ++ "in" ++ sp ++ showTerm t ++ rb
showTerm t = showPTree (toPrecTree t)
showPat :: Bool -> (Term, Term) -> String
showPat b (pat, term) =
let s = sp ++ showTerm pat ++ sp ++ "=" ++ sp ++ showTerm term
in
if b then ";" ++ s
else s
showCaseAlt :: (Term, Term) -> String
showCaseAlt (pat, term) =
showPattern pat ++ sp ++ "=>" ++ sp ++ showTerm term
showPattern :: Term -> String
showPattern (App t t' _) = showPattern t ++ sp ++ showPattern t'
showPattern t = showTerm t
showQuant :: String -> [(Term, Typ)] -> Term -> String
showQuant s vs term =
(s++sp++(showTypedVars vs)++" . "++showTerm term)
-- showQuant :: String -> [String] -> Term -> String
-- showQuant s vs term =
-- (s++sp++(stringMap showTerm vs)++" . "++showTerm term)
outerShowTerm :: Term -> String
outerShowTerm (App (Const q) (Abs vs t _) _) | q == allS =
outerShowQuant "!!" vs t
outerShowTerm (App (App (Const o) t1 _) t2 _) | o == impl =
showTerm t1 ++ " ==> " ++ outerShowTerm1 t2
outerShowTerm t = showTerm t
outerShowTerm1 :: Term -> String
outerShowTerm1 t@(App (App (Const o) _ _) _ _) | o == impl =
outerShowTerm t
outerShowTerm1 t = showTerm t
outerShowQuant :: String -> [(Term,Typ)] -> Term -> String
outerShowQuant s vs term =
(s++sp++(showTypedVars vs)++" . "++outerShowTerm term)
{-
For nearly perfect parenthesis - they only appear when needed -
a formula/term is broken open in following pieces:
(logical) connector
/ \
/ \
formula's lhs formula's rhs
Every connector is annotated with its precedence, every 'unbreakable'
formula gets the lowest precedence.
-}
-- term annotated with precedence
data PrecTerm = PrecTerm Term Precedence deriving (Show)
type Precedence = Int
{- Precedences (descending): __ __ (Isabelle's term application),
application of HasCASL ops, <=>, =, /\, \/, =>
Associativity: = -- left
=> -- right
/\ -- right
\/ -- right
-}
data PrecTermTree = Node PrecTerm [PrecTermTree]
isaAppPrec :: Term -> PrecTerm
isaAppPrec t = PrecTerm t 0
appPrec :: Term -> PrecTerm
appPrec t = PrecTerm t 5
eqvPrec :: Term -> PrecTerm
eqvPrec t = PrecTerm t 7
eqPrec :: Term -> PrecTerm
eqPrec t = PrecTerm t 10
andPrec :: Term -> PrecTerm
andPrec t = PrecTerm t 20
orPrec :: Term -> PrecTerm
orPrec t = PrecTerm t 30
implPrec :: Term -> PrecTerm
implPrec t = PrecTerm t 40
noPrec :: Term -> PrecTerm
noPrec t = PrecTerm t (-10)
quantS :: String
quantS = "QUANT"
dummyS :: String
dummyS = "Dummy"
binFunct :: String -> Term -> PrecTerm
binFunct s | s == eqv = eqvPrec
| s == eq = eqPrec
| s == conj = andPrec
| s == disj = orPrec
| s == impl = implPrec
| otherwise = appPrec
toPrecTree :: Term -> PrecTermTree
toPrecTree trm =
case trm of
App c1@(Const q) a2@(Abs _ _ _) _ | q `elem` [allS, exS, ex1S] ->
Node (isaAppPrec $ con quantS) [toPrecTree c1, toPrecTree a2]
App (App t@(Const o) t3 _) t2 _ ->
Node (binFunct o t) [toPrecTree t3, toPrecTree t2]
App t1 t2 _ -> Node (isaAppPrec $ con dummyS)
[toPrecTree t1, toPrecTree t2]
_ -> Node (noPrec trm) []
data Assoc = LeftAs | NoAs | RightAs
showPTree :: PrecTermTree -> String
showPTree (Node (PrecTerm term _) []) = showTerm term
showPTree (Node (PrecTerm term pre) annos) =
let leftChild = head annos
rightChild = last annos
in
case term of
Const c | c == eq -> infixP pre "=" LeftAs leftChild rightChild
| c `elem` [conj, disj, impl] ->
infixP pre (drop 3 c) RightAs leftChild rightChild
| c == dummyS -> simpleInfix pre leftChild rightChild
| c == isaPair -> pair leftChild rightChild
| c == quantS -> quant leftChild rightChild
| otherwise -> prefixP pre c leftChild rightChild
_ -> showTerm term
{- Logical connectors: For readability and by habit they are written
at an infix position.
If the precedence of one side is weaker (here: higher number) than the
connector's one it is bracketed. Otherwise not.
-}
infixP :: Precedence -> String -> Assoc -> PrecTermTree -> PrecTermTree -> String
infixP pAdult stAdult assoc leftChild rightChild
| (pAdult < prLeftCld) && (pAdult < prRightCld) = both
| pAdult < prLeftCld =
case assoc of
LeftAs -> if pAdult == prRightCld then both else left
RightAs -> left
NoAs -> left
| pAdult < prRightCld =
case assoc of
LeftAs -> right
RightAs -> if pAdult == prLeftCld then both else right
NoAs -> right
| (pAdult == prLeftCld) && (pAdult == prRightCld) =
case assoc of
LeftAs -> right
RightAs -> left
NoAs -> no
| pAdult == prLeftCld =
case assoc of
LeftAs -> no
RightAs -> left
NoAs -> no
| pAdult == prRightCld =
case assoc of
LeftAs -> right
RightAs -> no
NoAs -> no
| otherwise = no
where prLeftCld = pr leftChild
prRightCld = pr rightChild
stLeftCld = showPTree leftChild
stRightCld = showPTree rightChild
left = lb++ stLeftCld ++rb++sp++ stAdult ++sp++ stRightCld
both = lb++ stLeftCld ++rb++sp++ stAdult ++sp++lb++ stRightCld ++rb
right = stLeftCld ++sp++ stAdult ++sp++lb++ stRightCld ++rb
no = stLeftCld ++sp++ stAdult ++sp++ stRightCld
{- Application of (HasCASL-)operations with two arguments.
Both arguments are usually bracketed, except single ones.
-}
prefixP :: Precedence -> String -> PrecTermTree -> PrecTermTree -> String
prefixP pAdult stAdult leftChild rightChild
| (pAdult <= prLeftCld) && (pAdult <= prRightCld) =
stAdult ++
sp++lb++ stLeftCld ++rb++
sp++lb++ stRightCld ++rb
| pAdult <= prLeftCld =
stAdult ++
sp++lb++ stLeftCld ++rb++
sp++ stRightCld
| pAdult <= prRightCld =
stAdult ++
sp++ stLeftCld ++
sp++lb++ stRightCld ++rb
| otherwise = stAdult ++
sp++ stLeftCld ++
sp++ stRightCld
where prLeftCld = pr leftChild
prRightCld = pr rightChild
stLeftCld = showPTree leftChild
stRightCld = showPTree rightChild
{- Isabelle application: An operation/a datatype-constructor is applied
to one argument. The whole expression is always bracketed.
-}
simpleInfix :: Precedence -> PrecTermTree -> PrecTermTree -> String
simpleInfix pAdult leftChild rightChild
| (pAdult < prLeftCld) && (pAdult < prRightCld) =
lbb++ stLeftCld ++rb++
sp++lb++ stRightCld ++rbb
| pAdult < prLeftCld =
lbb++ stLeftCld ++rb++
sp++ stRightCld ++rb
| pAdult < prRightCld =
lb++ stLeftCld ++sp++
lb++ stRightCld ++rbb
| otherwise = lb++ stLeftCld ++sp++
stRightCld ++rb
where prLeftCld = pr leftChild
prRightCld = pr rightChild
stLeftCld = showPTree leftChild
stRightCld = showPTree rightChild
{- Quantification _in_ Formulas
-}
quant :: PrecTermTree -> PrecTermTree -> String
quant (Node (PrecTerm (Const q) _) [])
(Node (PrecTerm (Abs vs t _) _) []) =
lb++showQuant (showQuantStr q) vs t++rb
quant _ _ = error "[Isabelle.IsaPrint] Wrong quantification!?"
pr :: PrecTermTree -> Precedence
pr (Node (PrecTerm _ p) _) = p
-- Prints: (p1, p2)
pair :: PrecTermTree -> PrecTermTree -> String
pair leftChild rightChild = lb++showPTree leftChild++", "++
showPTree rightChild++rb
instance PrettyPrint Sign where
printText0 ga sig = text
(baseSig sig) <> colon $$
printText0 ga (tsig sig) $$
showDataTypeDefs (dataTypeTab sig) $$
showsConstTab (constTab sig) $$
showCaseLemmata (dataTypeTab sig)
where
showsConstTab tab =
if Map.isEmpty tab then empty
else text("consts") $$ Map.foldWithKey showConst empty tab
showConst c t rest = text (show c ++ " :: " ++ "\"" ++ showTyp 1000 t
++ "\"" ++ showDecl c) $$ rest
showDecl c = sp ++ sp ++ sp ++ "( \"" ++ quote_underscores c ++ "\" )"
showDataTypeDefs dtDefs = vcat $ map (text . showDataTypeDef) dtDefs
showDataTypeDef [] = ""
showDataTypeDef (dt:dts) =
"datatype " ++ showDataType dt
++ (concat $ map (("and "++) . showDataType) dts) ++ "\n"
showDataType (_,[]) = error "IsaPrint.showDataType"
showDataType (t,op:ops) =
showTyp 1000 t ++ " = " ++ showOp op
++ (concat $ map ((" | "++) . showOp) ops)
showOp (opname,args) =
opname ++ (concat $ map ((sp ++) . showArg) args)
showArg arg = case arg of
TFree _ _ -> showTyp 1000 arg
_ -> "\"" ++ showTyp 1000 arg ++ "\""
showCaseLemmata dtDefs = text (concat $ map showCaseLemmata1 dtDefs)
showCaseLemmata1 dts = concat $ map showCaseLemma dts
showCaseLemma (_, []) = ""
showCaseLemma (tyCons, (c:cons)) =
let cs = "case caseVar of" ++ sp
sc b = showCons b c ++ (concat $ map ((" | " ++) . (showCons b)) cons)
clSome = sc True
cl = sc False
showCons b (cName, args) =
let pat = cName ++ (concat $ map ((sp ++) . showArg) args)
++ sp ++ "=>" ++ sp
term = showCaseTerm cName args
in
if b then pat ++ "Some" ++ sp ++ lb ++ term ++ rb ++ "\n"
else pat ++ term ++ "\n"
showCaseTerm name args = if null name then sa
else [toLower (head name)] ++ sa
where sa = (concat $ map ((sp ++) . showArg) args)
showArg (TFree [] _) = "varName"
showArg (TFree (n:ns) _) = [toLower n] ++ ns
showArg (TVar ([], _) _) = "varName"
showArg (TVar ((n:ns), _) _) = [toLower n] ++ ns
showArg (Type [] _ _) = "varName"
showArg (Type m@(n:ns) _ s) =
if m == "typeAppl" || m == "fun" || m == "*" then concat $ map showArg s
else [toLower n] ++ ns
showName (TFree v _) = v
showName (TVar (v, _) _) = v
showName (Type n _ _) = n
proof = "apply (case_tac caseVar)\napply (auto)\ndone\n"
in
"lemma" ++ sp ++ "case_" ++ showName tyCons ++ "_SomeProm" ++ sp
++ "[simp]:\"" ++ sp ++ lb ++ cs ++ clSome ++ rb ++ sp
++ "=\n" ++ "Some" ++ sp ++ lb ++ cs ++ cl ++ rb ++ "\"\n"
++ proof
quote_underscores :: String -> String
quote_underscores [] = []
quote_underscores ('_':'_':rest) = '_':quote_underscores rest
quote_underscores ('_':rest) = '\'':'_':quote_underscores rest
quote_underscores (c:rest) = c:quote_underscores rest
-- instance PrettyPrint Sign where
-- printText0 _ = ptext . show
instance PrintLaTeX Sign where
printLatex0 = printText0
sp :: String
sp = " "
rb :: String
rb = ")"
rbb :: String
rbb = rb++rb
lb :: String
lb = "("
lbb :: String
lbb = lb++lb
bracketize :: Bool -> String -> String
bracketize b s = if b then lb++s++rb else s