// for [databind#1301]
 public void testJavaTypeToString() throws Exception {
   TypeFactory tf = objectMapper().getTypeFactory();
   String desc = tf.constructType(DataDefinition.class).toString();
   assertNotNull(desc);
   // could try comparing exact message, but since it's informational try looser:
   if (!desc.contains("map type")) {
     fail("Description should contain 'map type', did not: " + desc);
   }
   if (!desc.contains("recursive type")) {
     fail("Description should contain 'recursive type', did not: " + desc);
   }
 }
Esempio n. 2
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 /** @see jaskell.compiler.JaskellVisitor#visit(ConstructorPattern) */
 public Object visit(ConstructorPattern a) {
   String cname = a.getConstructor().getName();
   /* retrieve parameter types of constructor */
   ConstructorDefinition ctor = (ConstructorDefinition) a.getConstructor().lookup(cname);
   if (ctor == null) throw new TypeError("Undefined constructor pattern  " + a);
   /* type of data constructed by constructor */
   TypeInstantiator ti = new TypeInstantiator(ctor.getDataType());
   Type rtype = ti.instance();
   Map map = ti.getMap();
   TypeSubstitution ts = new TypeSubstitution(map);
   Iterator ittypes = ctor.getParameters().iterator();
   /* retrieve type of patterns */
   Iterator it = a.getSubPatterns();
   while (it.hasNext()) {
     try {
       Pattern p = (Pattern) it.next();
       Type actual = TypeFactory.freshBinding();
       Type formal = ts.substitute((Type) ittypes.next());
       /* unify both types */
       p.setType(tu.unify(formal, actual, typeVariablesMap));
     } catch (NoSuchElementException nex) {
       throw new TypeError("Wrong number of arguments to pattern " + a);
     }
   }
   a.setType(rtype);
   return a.getType();
 }
 protected JavaType parseType(MyTokenizer tokens) throws IllegalArgumentException {
   if (!tokens.hasMoreTokens()) {
     throw _problem(tokens, "Unexpected end-of-string");
   }
   Class<?> base = findClass(tokens.nextToken(), tokens);
   // either end (ok, non generic type), or generics
   if (tokens.hasMoreTokens()) {
     String token = tokens.nextToken();
     if ("<".equals(token)) {
       return _factory._fromParameterizedClass(base, parseTypes(tokens));
     }
     // can be comma that separates types, or closing '>'
     tokens.pushBack(token);
   }
   return _factory._fromClass(base, null);
 }
Esempio n. 4
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 /** @see jaskell.compiler.JaskellVisitor#visit(Application) */
 public Object visit(Application a) {
   try {
     /* get type of function */
     Expression fun = a.getFunction();
     /* get type deduced from arguments */
     LinkedList l = new LinkedList();
     Iterator it = a.getArgs().iterator();
     while (it.hasNext()) {
       Expression e = (Expression) it.next();
       l.add((Type) e.visit(this));
     }
     Type vt = TypeFactory.freshBinding();
     Type ft = Types.fun(l, vt);
     log.finer("TypeChecker => In application " + a + ", type is " + ft);
     /* apply substitution on both types */
     ft = subst.substitute(ft);
     /* try to unify function type and constructed types */
     Type t = (Type) fun.visit(this);
     log.finer("In application, function " + fun + " :: " + t);
     t = subst.substitute(t);
     log.finer("In application, trying to unify function type " + t + " with body " + ft);
     /*
      * TODO : problem with unification of constrained types
      */
     TypeApplication uni = (TypeApplication) tu.unify(t, ft, typeVariablesMap);
     /* sets type of functional expression - this allows
      * polymorphic functions to receive several types
      * in the same code */
     // fun.setType(uni);
     /* apply arguments type to compute return type */
     log.finer("Done unify application :" + uni);
     it = PrimitiveType.functionIterator(uni);
     Iterator it2 = l.iterator();
     TypeApplication ut = uni;
     while (it2.hasNext()) {
       /* type of argument */
       Type at = (Type) it2.next();
       ut = (TypeApplication) it.next();
       /* try unification */
       tu.unify(((TypeApplication) ut.getDomain()).getRange(), at, new HashMap(typeVariablesMap));
     }
     ft = subst.substitute(ft);
     fun.setType(ft);
     log.finer("Setting type of functional element [" + fun + "] to :" + ft);
     a.setType(ut.getRange());
     return ut.getRange();
   } catch (TypeError te) {
     if (te.getLineCol() == null) te.setLineCol(a.getTag("source"));
     throw te;
   }
 }
Esempio n. 5
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 /** @see jaskell.compiler.JaskellVisitor#visit(Abstraction) */
 public Object visit(Abstraction a) {
   try {
     Type t = a.getType();
     if (t != null) return subst.substitute(t);
     log.finest("Visiting abstraction : " + a);
     Expression body = a.getBody();
     /* duplicate bindings map to assign types to variables */
     pushContext(a.getBindings());
     /* create fresh type variables as type for each bound
      * variable */
     Iterator it = namesMap.values().iterator();
     LinkedList tl = new LinkedList();
     while (it.hasNext()) {
       LocalBinding name = (LocalBinding) it.next();
       Type vt = TypeFactory.freshBinding();
       name.setType(vt);
       tl.add(vt);
     }
     Type tv = TypeFactory.freshBinding();
     /* create type with all variables for function */
     Type ft = Types.fun(tl, tv);
     log.finer("In abstraction, setting type to " + ft);
     a.setType(ft);
     /* analyze body */
     Type bt = (Type) body.visit(this);
     /* unify return type of function with type of body */
     Type ret = tu.unify(PrimitiveType.getReturnType(ft), bt, typeVariablesMap);
     TyvarSubstitution tys = new TyvarSubstitution(typeVariablesMap);
     tys.visit(a);
     log.finer("Done abstraction, setting type from " + ft + " to " + a.getType());
     popContext();
     return a.getType();
   } catch (TypeError te) {
     if (te.getLineCol() == null) te.setLineCol(a.getTag("source"));
     throw te;
   }
 }
Esempio n. 6
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 public JavaType resolveType(Type type) {
   return _typeFactory._constructType(type, this);
 }
Esempio n. 7
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 public JavaType resolveType(Class<?> cls) {
   return _typeFactory._constructType(cls, this);
 }
Esempio n. 8
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  protected void _resolveBindings(Type t) {
    if (t == null) return;

    Class<?> raw;
    if (t instanceof ParameterizedType) {
      ParameterizedType pt = (ParameterizedType) t;
      Type[] args = pt.getActualTypeArguments();
      if (args != null && args.length > 0) {
        Class<?> rawType = (Class<?>) pt.getRawType();
        TypeVariable<?>[] vars = rawType.getTypeParameters();
        if (vars.length != args.length) {
          throw new IllegalArgumentException(
              "Strange parametrized type (in class "
                  + rawType.getName()
                  + "): number of type arguments != number of type parameters ("
                  + args.length
                  + " vs "
                  + vars.length
                  + ")");
        }
        for (int i = 0, len = args.length; i < len; ++i) {
          TypeVariable<?> var = vars[i];
          String name = var.getName();
          if (_bindings == null) {
            _bindings = new LinkedHashMap<String, JavaType>();
          } else {
            /* 24-Mar-2010, tatu: Better ensure that we do not overwrite something
             *  collected earlier (since we descend towards super-classes):
             */
            if (_bindings.containsKey(name)) continue;
          }
          // first: add a placeholder to prevent infinite loops
          _addPlaceholder(name);
          // then resolve type
          _bindings.put(name, _typeFactory._constructType(args[i], this));
        }
      }
      raw = (Class<?>) pt.getRawType();
    } else if (t instanceof Class<?>) {
      raw = (Class<?>) t;
      /* [JACKSON-677]: If this is an inner class then the generics are defined on the
       * enclosing class so we have to check there as well.  We don't
       * need to call getEnclosingClass since anonymous classes declare
       * generics
       */
      _resolveBindings(raw.getDeclaringClass());
      /* 24-Mar-2010, tatu: Can not have true generics definitions, but can
       *   have lower bounds ("<T extends BeanBase>") in declaration itself
       */
      TypeVariable<?>[] vars = raw.getTypeParameters();
      if (vars != null && vars.length > 0) {
        JavaType[] typeParams = null;

        if (_contextType != null && raw.isAssignableFrom(_contextType.getRawClass())) {
          typeParams = _typeFactory.findTypeParameters(_contextType, raw);
        }

        for (int i = 0; i < vars.length; i++) {
          TypeVariable<?> var = vars[i];

          String name = var.getName();
          Type varType = var.getBounds()[0];
          if (varType != null) {
            if (_bindings == null) {
              _bindings = new LinkedHashMap<String, JavaType>();
            } else { // and no overwriting...
              if (_bindings.containsKey(name)) continue;
            }
            _addPlaceholder(name); // to prevent infinite loops

            if (typeParams != null) {
              _bindings.put(name, typeParams[i]);
            } else {
              _bindings.put(name, _typeFactory._constructType(varType, this));
            }
          }
        }
      }
    } else { // probably can't be any of these... so let's skip for now
      // if (type instanceof GenericArrayType) {
      // if (type instanceof TypeVariable<?>) {
      // if (type instanceof WildcardType) {
      return;
    }
    // but even if it's not a parameterized type, its super types may be:
    _resolveBindings(raw.getGenericSuperclass());
    for (Type intType : raw.getGenericInterfaces()) {
      _resolveBindings(intType);
    }
  }
 // for [databind#1301]
 public void testRecursiveType() {
   TypeFactory tf = TypeFactory.defaultInstance();
   JavaType type = tf.constructType(HashTree.class);
   assertNotNull(type);
 }