mirror of
https://github.com/Sneed-Group/Poodletooth-iLand
synced 2024-12-27 05:32:41 -06:00
472 lines
19 KiB
Python
472 lines
19 KiB
Python
from direct.showbase.PythonUtil import *
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from types import *
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import string
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import FFIConstants
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import FFISpecs
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import FFITypes
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"""
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Things that are not supported:
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- Overloading a function based on an enum being differentiated from an int
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- Type names from C++ cannot have __enum__ in their name
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- Overloading static and non-static methods with the same name
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"""
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AT_not_atomic = 0
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AT_int = 1
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AT_float = 2
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AT_double = 3
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AT_bool = 4
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AT_char = 5
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AT_void = 6
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AT_string = 7
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AT_longlong = 8
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def cullOverloadedMethods(fullMethodDict):
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"""
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Find all the entries that have multiple indexes for the same method name
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Get rid of all others.
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"""
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tmpDict = {}
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# For each class
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for methodName in fullMethodDict.keys():
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methodList = fullMethodDict[methodName]
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# See if this method has more than one function index (overloaded)
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if (len(methodList) > 1):
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tmpDict[methodName] = methodList
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# Mark all the method specifications as overloaded
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for methodSpec in methodList:
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methodSpec.overloaded = 1
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return tmpDict
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def getTypeName(classTypeDesc, typeDesc):
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"""
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Map the interrogate primitive type names to python type names.
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We assume that the module using this has imported the types module.
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It is valid to pass in None for classTypeDesc if we are not in a class
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"""
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typeName = typeDesc.getFullNestedName()
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# Atomic C++ types are type checked against the builtin
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# Python types. This code sorts out the mapping
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if typeDesc.isAtomic():
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# Ints, bools, and chars are treated as ints.
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# Enums are special and are not atomic, see below
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if ((typeDesc.atomicType == AT_int) or
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(typeDesc.atomicType == AT_bool) or
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(typeDesc.atomicType == AT_char)):
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return 'IntType'
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# Floats and doubles are both floats in Python
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elif ((typeDesc.atomicType == AT_float) or
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(typeDesc.atomicType == AT_double)):
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return 'FloatType'
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elif ((typeDesc.atomicType == AT_longlong)):
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return 'LongType'
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# Strings are treated as Python strings
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elif ((typeDesc.atomicType == AT_string)):
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return 'StringType'
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elif (typeDesc.atomicType == AT_void):
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# Convert the void type to None type... I guess...
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# So far we do not have any code that uses this
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return 'NoneType'
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else:
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FFIConstants.notify.error("Unknown atomicType: %s" % (typeDesc.atomicType))
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# If the type is an enum, we really want to treat it like an int
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# To handle this, the type will have __enum__ in the name
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# Usually it will start the typeName, but some typeNames have the
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# surrounding class as part of their name
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# like BoundedObject.__enum__BoundingVolumeType
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elif (typeName.find('__enum__') >= 0):
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return 'IntType'
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# If it was not atomic or enum, it must be a class which is a
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# bit trickier because we output different things depending on the
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# scoping of the type.
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else:
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# classTypeDesc typeDesc fullNestedName Resulting TypeName
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# 1 Outer Other Other Other.Other
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# 2 Outer Outer Outer Outer
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# 3 Outer Inner Outer.Inner Outer.Inner
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# 4 Inner Other Other Other.Other
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# 5 Inner Outer Outer Outer
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# 6 Inner Inner Outer.Inner Outer.Inner
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# 7 None Other Other Other.Other
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# CASES 1, 4, and 7 are the only ones that are different from the full
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# nested name, returning Other.Other
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returnNestedTypeNames = string.split(typeName, '.')
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returnModuleName = returnNestedTypeNames[0]
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if classTypeDesc:
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classTypeName = classTypeDesc.getFullNestedName()
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classNestedTypeNames = string.split(classTypeName, '.')
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# If there is no nesting, return typeName.typeName
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if ((not (classTypeDesc.foreignTypeName in returnNestedTypeNames)) and
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(not (typeDesc.foreignTypeName in classNestedTypeNames))):
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return (returnModuleName + '.' + typeName)
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# All other cases, we just need typeName
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else:
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return typeName
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else:
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# If you had no class, you need to specify module plus typename
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return (returnModuleName + '.' + typeName)
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def inheritsFrom(type1, type2):
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"""
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Return true if type1 inherits from type2
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This works by recursively checking parentTypes for type1
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"""
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if type1.parentTypes:
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if type2 in type1.parentTypes:
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return 1
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else:
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result = 0
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for type in type1.parentTypes:
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result = (result or inheritsFrom(type, type2))
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return result
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else:
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return 0
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def getInheritanceLevel(type, checkNested = 1):
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if type.__class__ == FFITypes.PyObjectTypeDescriptor:
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# A special case: PyObject * is always the most general
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# object. Everything is a PyObject.
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return -1
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# If this is a nested type, return the inheritance level of the outer type.
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if type.isNested:
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# Check the level of your outer class
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# pass the checkNested flag as 0 to prevent an infinite loop
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# between the parent and child
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level = getInheritanceLevel(type.outerType, 0)
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else:
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level = 0
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for parentType in type.parentTypes:
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# Add 1 because you are one level higher than your parent
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level = max(level, 1+getInheritanceLevel(parentType))
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if checkNested:
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for nestedType in type.nestedTypes:
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# Do not add 1 to your nested types
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level = max(level, getInheritanceLevel(nestedType))
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return level
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def inheritanceLevelSort(type1, type2):
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level1 = getInheritanceLevel(type1)
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level2 = getInheritanceLevel(type2)
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if (level1 == level2):
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# If they are equal in the inheritance,
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# sort them alphabetically by their type name
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return cmp(type1.foreignTypeName, type2.foreignTypeName)
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elif (level1 < level2):
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return -1
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elif (level1 > level2):
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return 1
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def subclass(type1, type2):
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"""
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Helper funcion used in sorting classes by inheritance
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"""
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# If the types are the same, return 0
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if type1 == type2:
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return 0
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# If you have no args, sort you first
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elif (type1 == 0):
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return 1
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elif (type2 == 0):
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return -1
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# If class1 inherits from class2 return -1
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elif inheritsFrom(type1, type2):
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return -1
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# If class2 inherits from class1 return 1
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elif inheritsFrom(type2, type1):
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return 1
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else:
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# This is the don't care case. We must specify a sorting
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# rule just so it is not arbitrary
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if (type1.foreignTypeName > type2.foreignTypeName):
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return -1
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else:
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return 1
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class FFIMethodArgumentTreeCollection:
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def __init__(self, classTypeDesc, methodSpecList):
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self.classTypeDesc = classTypeDesc
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self.methodSpecList = methodSpecList
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self.methodDict = {}
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self.treeDict = {}
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def outputOverloadedMethodHeader(self, file, nesting):
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# If one is static, we assume they all are.
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# The current system does not support overloading static and non-static
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# methods with the same name
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# Constructors are not treated as static. They are special because
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# they are not really constructors, they are instance methods that fill
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# in the this pointer.
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# Global functions do not need static versions
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if (self.methodSpecList[0].isStatic() and
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(not self.methodSpecList[0].isConstructor())):
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indent(file, nesting, 'def ' +
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self.methodSpecList[0].name + '(*_args):\n')
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else:
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indent(file, nesting, 'def ' +
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self.methodSpecList[0].name + '(self, *_args):\n')
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self.methodSpecList[0].outputCFunctionComment(file, nesting+2)
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indent(file, nesting+2, 'numArgs = len(_args)\n')
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def outputOverloadedMethodFooter(self, file, nesting):
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# If this is a static method, we need to output a static version
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# If one is static, we assume they all are.
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# The current system does not support overloading static and non-static
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# methods with the same name
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# Constructors are not treated as static. They are special because
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# they are not really constructors, they are instance methods that fill
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# in the this pointer.
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methodName = self.methodSpecList[0].name
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if (self.methodSpecList[0].isStatic() and
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(not self.methodSpecList[0].isConstructor()) and
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(not isinstance(self.methodSpecList[0], FFISpecs.GlobalFunctionSpecification))):
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self.outputOverloadedStaticFooter(file, nesting)
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else:
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if self.classTypeDesc:
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indent(file, nesting, "FFIExternalObject.funcToMethod("+methodName+','+ self.classTypeDesc.foreignTypeName+ ",'"+methodName+"')\n")
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indent(file, nesting, 'del '+methodName+'\n')
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indent(file, nesting, ' \n')
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indent(file, nesting+1, '\n')
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def outputOverloadedStaticFooter(self, file, nesting):
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# foo = staticmethod(foo)
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methodName = self.methodSpecList[0].name
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indent(file, nesting, self.classTypeDesc.foreignTypeName + '.' + methodName + ' = staticmethod(' + methodName + ')\n')
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indent(file, nesting,'del ' +methodName+' \n\n')
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def setup(self):
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for method in self.methodSpecList:
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numArgs = len(method.typeDescriptor.thislessArgTypes())
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numArgsList = self.methodDict.setdefault(numArgs, [])
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numArgsList.append(method)
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for numArgs in self.methodDict.keys():
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methodList = self.methodDict[numArgs]
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tree = FFIMethodArgumentTree(self.classTypeDesc, methodList)
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treeList = self.treeDict.setdefault(numArgs, [])
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treeList.append(tree)
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def generateCode(self, file, nesting):
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self.setup()
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self.outputOverloadedMethodHeader(file, nesting)
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numArgsKeys = self.treeDict.keys()
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numArgsKeys.sort()
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for i in range(len(numArgsKeys)):
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numArgs = numArgsKeys[i]
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trees = self.treeDict[numArgs]
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for tree in trees:
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# If this is the first case, output an if clause
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if (i == 0):
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indent(file, nesting+2, 'if (numArgs == ' + repr(numArgs) + '):\n')
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# If this is a subsequent first case, output an elif clause
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else:
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indent(file, nesting+2, 'elif (numArgs == ' + repr(numArgs) + '):\n')
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tree.setup()
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tree.traverse(file, nesting+1, 0)
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# If the overloaded function got all the way through the if statements
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# it must have had the wrong number or type of arguments
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indent(file, nesting+2, "else:\n")
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indent(file, nesting+3, "raise TypeError, 'Invalid number of arguments: ' + repr(numArgs) + ', expected one of: ")
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for numArgs in numArgsKeys:
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indent(file, 0, (repr(numArgs) + ' '))
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indent(file, 0, "'\n")
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self.outputOverloadedMethodFooter(file, nesting)
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class FFIMethodArgumentTree:
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"""
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Tree is made from nested dictionaries.
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The keys are methodNamed.
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The values are [tree, methodSpec]
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methodSpec may be None at any level
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If tree is None, it is a leaf node and methodSpec will be defined
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"""
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def __init__(self, classTypeDesc, methodSpecList):
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self.argSpec = None
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self.classTypeDesc = classTypeDesc
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self.methodSpecList = methodSpecList
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# The actual tree is implemented as nested dictionaries
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self.tree = {}
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def setup(self):
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for methodSpec in self.methodSpecList:
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argTypes = methodSpec.typeDescriptor.thislessArgTypes()
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self.fillInArgTypes(argTypes, methodSpec)
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def fillInArgTypes(self, argTypes, methodSpec):
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# If the method takes no arguments, we will assign a type index of 0
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if (len(argTypes) == 0):
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self.tree[0] = [
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FFIMethodArgumentTree(self.classTypeDesc,
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self.methodSpecList),
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methodSpec]
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else:
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self.argSpec = argTypes[0]
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typeDesc = self.argSpec.typeDescriptor.recursiveTypeDescriptor()
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if (len(argTypes) == 1):
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# If this is the last parameter, we are a leaf node, so store the
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# methodSpec in this dictionary
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self.tree[typeDesc] = [None, methodSpec]
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else:
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if typeDesc in self.tree:
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# If there already is a tree here, jump into and pass the
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# cdr of the arg list
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subTree = self.tree[typeDesc][0]
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subTree.fillInArgTypes(argTypes[1:], methodSpec)
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else:
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# Add a subtree for the rest of the arg list
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subTree = FFIMethodArgumentTree(self.classTypeDesc,
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self.methodSpecList)
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subTree.fillInArgTypes(argTypes[1:], methodSpec)
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# This subtree has no method spec
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self.tree[typeDesc] = [subTree, None]
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def traverse(self, file, nesting, level):
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oneTreeHasArgs = 0
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typeNameList = []
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# First see if this tree branches at all. If it does not there are
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# drastic optimizations we can take because we can simply call the
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# bottom-most function. We are not checking the types of all the
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# arguments for the sake of type checking, we are simply trying to
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# figure out which overloaded function to call. If there is only
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# one overloaded function with this number of arguements at this
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# level, it must be the one. No need to continue checking all the
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# arguments.
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branches = 0
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subTree = self
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prevTree = subTree
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levelCopy = level
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while subTree:
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if (len(subTree.tree.keys()) == 0):
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# Dead end branch
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break
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if (len(subTree.tree.keys()) > 1):
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# Ok, we branch, it was worth a try though
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branches = 1
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break
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prevTree = subTree
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# Must only have one subtree, traverse it
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subTree = subTree.tree.values()[0][0]
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levelCopy += 1
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# If there were no branches, this is easy
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# Just output the function and return
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# Note this operates on prevTree because subTree went one too far
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if not branches:
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methodSpec = prevTree.tree.values()[0][1]
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indent(file, nesting+2, 'return ')
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methodSpec.outputOverloadedCall(file, prevTree.classTypeDesc, levelCopy)
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return
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# Ok, We must have a branch down here somewhere
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# Make a copy of the keys so we can sort them in place
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sortedKeys = self.tree.keys()
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# Sort the keys based on inheritance hierarchy, most specific classes first
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sortedKeys.sort(subclass)
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for i in range(len(sortedKeys)):
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typeDesc = sortedKeys[i]
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# See if this takes no arguments
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if (typeDesc == 0):
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# Output the function
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methodSpec = self.tree[0][1]
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indent(file, nesting+2, 'return ')
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methodSpec.outputOverloadedCall(file, self.classTypeDesc, 0)
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else:
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# This is handled at the top of the file now (?)
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# Import a file if we need to for this typeDesc
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# if ((typeDesc != 0) and
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# (not typeDesc.isNested) and
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# # Do not put our own module in the import list
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# (self.classTypeDesc != typeDesc) and
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# # If this is a class (not a primitive), put it on the list
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# (typeDesc.__class__ == FFITypes.ClassTypeDescriptor)):
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# indent(file, nesting+2, 'import ' + typeDesc.foreignTypeName + '\n')
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# Specify that at least one of these trees had arguments
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# so we know to output an else clause
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oneTreeHasArgs = 1
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typeName = getTypeName(self.classTypeDesc, typeDesc)
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typeNameList.append(typeName)
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if typeDesc.__class__ == FFITypes.PyObjectTypeDescriptor:
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# A special case: if one of the parameters is
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# PyObject *, that means anything is accepted.
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condition = '1'
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else:
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# Otherwise, we'll check the particular type of
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# the object.
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condition = '(isinstance(_args[' + repr(level) + '], ' + typeName + '))'
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# Legal types for a float parameter include int and long.
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if (typeName == 'FloatType'):
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condition += (' or (isinstance(_args[' + repr(level) + '], IntType))')
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condition += (' or (isinstance(_args[' + repr(level) + '], LongType))')
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# Legal types for a long parameter include int.
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elif (typeName == 'LongType'):
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condition += (' or (isinstance(_args[' + repr(level) + '], IntType))')
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# Legal types for an int parameter include long.
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elif (typeName == 'IntType'):
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condition += (' or (isinstance(_args[' + repr(level) + '], LongType))')
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indent(file, nesting+2, 'if ' + condition + ':\n')
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if (self.tree[typeDesc][0] is not None):
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self.tree[typeDesc][0].traverse(file, nesting+1, level+1)
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else:
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methodSpec = self.tree[typeDesc][1]
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indent(file, nesting+3, 'return ')
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numArgs = level+1
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methodSpec.outputOverloadedCall(file, self.classTypeDesc, numArgs)
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# Output an else clause if one of the trees had arguments
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if oneTreeHasArgs:
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indent(file, nesting+2, "raise TypeError, 'Invalid argument " + repr(level) + ", expected one of: ")
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for name in typeNameList:
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indent(file, 0, ('<' + name + '> '))
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indent(file, 0, "'\n")
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def isSinglePath(self):
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if (len(self.tree.keys()) > 1):
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# More than one child, return false
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return 0
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else:
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# Only have one child, see if he only has one child
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key = self.tree.keys()[0]
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tree = self.tree[key][0]
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if tree:
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return tree.isSinglePath()
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else:
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return self.tree[key][1]
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