lldb/examples/synthetic/bitfield/example.py - llvm-project - Git at Google

 # Synthetic children provider example for class MaskedData
 # to use me:
 # command script import ./example.py --allow-reload
 # type synthetic add MaskedData --python-class
 # example.MaskedData_SyntheticChildrenProvider


 class MaskedData_SyntheticChildrenProvider:

     def __init__(self, valobj, dict):
         # remember the SBValue since you will not have another chance to get it
         # :-)
         self.valobj = valobj

     def num_children(self):
         # you could perform calculations involving the SBValue and/or its children to determine this value
         # here, we have an hardcoded value - but since you have stored the SBValue you could use it to
         # help figure out the correct thing to return here. if you return a number N, you should be prepared to
         # answer questions about N children
         return 4

     def has_children(self):
         # we simply say True here because we know we have 4 children
         # in general, you want to make this calculation as simple as possible
         # and return True if in doubt (you can always return num_children == 0
         # later)
         return True

     def get_child_index(self, name):
         # given a name, return its index
         # you can return None if you don't know the answer for a given name
         if name == "value":
             return 0
         # here, we are using a reserved C++ keyword as a child name - we could not do that in the source code
         # but we are free to use the names we like best in the synthetic children provider class
         # we are also not respecting the order of declaration in the C++ class itself - as long as
         # we are consistent, we can do that freely
         if name == "operator":
             return 1
         if name == "mask":
             return 2
         # this member does not exist in the original class - we will compute its value and show it to the user
         # when returning synthetic children, there is no need to only stick to
         # what already exists in memory
         if name == "apply()":
             return 3
         return None  # no clue, just say none

     def get_child_at_index(self, index):
         # precautionary measures
         if index < 0:
             return None
         if index > self.num_children():
             return None
         if self.valobj.IsValid() == False:
             return None
         if index == 0:
             return self.valobj.GetChildMemberWithName("value")
         if index == 1:
             # fetch the value of the operator
             op_chosen = self.valobj.GetChildMemberWithName(
                 "oper").GetValueAsUnsigned()
             # if it is a known value, return a descriptive string for it
             # we are not doing this in the most efficient possible way, but the code is very readable
             # and easy to maintain - if you change the values on the C++ side,
             # the same changes must be made here
             if op_chosen == 0:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"none"')
             elif op_chosen == 1:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"AND"')
             elif op_chosen == 2:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"OR"')
             elif op_chosen == 3:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"XOR"')
             elif op_chosen == 4:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"NAND"')
             elif op_chosen == 5:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"NOR"')
             else:
                 return self.valobj.CreateValueFromExpression(
                     "operator", '(const char*)"unknown"')  # something else
         if index == 2:
             return self.valobj.GetChildMemberWithName("mask")
         if index == 3:
             # for this, we must fetch all the other elements
             # in an efficient implementation, we would be caching this data for
             # efficiency
             value = self.valobj.GetChildMemberWithName(
                 "value").GetValueAsUnsigned()
             operator = self.valobj.GetChildMemberWithName(
                 "oper").GetValueAsUnsigned()
             mask = self.valobj.GetChildMemberWithName(
                 "mask").GetValueAsUnsigned()
             # compute the masked value according to the operator
             if operator == 1:
                 value = value & mask
             elif operator == 2:
                 value = value | mask
             elif operator == 3:
                 value = value ^ mask
             elif operator == 4:
                 value = ~(value & mask)
             elif operator == 5:
                 value = ~(value | mask)
             else:
                 pass
             value &= 0xFFFFFFFF  # make sure Python does not extend our values to 64-bits
             # return it - again, not the most efficient possible way. we should actually be pushing the computed value
             # into an SBData, and using the SBData to create an SBValue - this
             # has the advantage of readability
             return self.valobj.CreateValueFromExpression(
                 "apply()", '(uint32_t)(' + str(value) + ')')

     def update(self):
         # we do not do anything special in update - but this would be the right place to lookup
         # the data we use in get_child_at_index and cache it
         pass
	# Synthetic children provider example for class MaskedData
	# to use me:
	# command script import ./example.py --allow-reload
	# type synthetic add MaskedData --python-class
	# example.MaskedData_SyntheticChildrenProvider


	class MaskedData_SyntheticChildrenProvider:

	def __init__(self, valobj, dict):
	# remember the SBValue since you will not have another chance to get it
	# :-)
	self.valobj = valobj

	def num_children(self):
	# you could perform calculations involving the SBValue and/or its children to determine this value
	# here, we have an hardcoded value - but since you have stored the SBValue you could use it to
	# help figure out the correct thing to return here. if you return a number N, you should be prepared to
	# answer questions about N children
	return 4

	def has_children(self):
	# we simply say True here because we know we have 4 children
	# in general, you want to make this calculation as simple as possible
	# and return True if in doubt (you can always return num_children == 0
	# later)
	return True

	def get_child_index(self, name):
	# given a name, return its index
	# you can return None if you don't know the answer for a given name
	if name == "value":
	return 0
	# here, we are using a reserved C++ keyword as a child name - we could not do that in the source code
	# but we are free to use the names we like best in the synthetic children provider class
	# we are also not respecting the order of declaration in the C++ class itself - as long as
	# we are consistent, we can do that freely
	if name == "operator":
	return 1
	if name == "mask":
	return 2
	# this member does not exist in the original class - we will compute its value and show it to the user
	# when returning synthetic children, there is no need to only stick to
	# what already exists in memory
	if name == "apply()":
	return 3
	return None # no clue, just say none

	def get_child_at_index(self, index):
	# precautionary measures
	if index < 0:
	return None
	if index > self.num_children():
	return None
	if self.valobj.IsValid() == False:
	return None
	if index == 0:
	return self.valobj.GetChildMemberWithName("value")
	if index == 1:
	# fetch the value of the operator
	op_chosen = self.valobj.GetChildMemberWithName(
	"oper").GetValueAsUnsigned()
	# if it is a known value, return a descriptive string for it
	# we are not doing this in the most efficient possible way, but the code is very readable
	# and easy to maintain - if you change the values on the C++ side,
	# the same changes must be made here
	if op_chosen == 0:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"none"')
	elif op_chosen == 1:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"AND"')
	elif op_chosen == 2:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"OR"')
	elif op_chosen == 3:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"XOR"')
	elif op_chosen == 4:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"NAND"')
	elif op_chosen == 5:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"NOR"')
	else:
	return self.valobj.CreateValueFromExpression(
	"operator", '(const char*)"unknown"') # something else
	if index == 2:
	return self.valobj.GetChildMemberWithName("mask")
	if index == 3:
	# for this, we must fetch all the other elements
	# in an efficient implementation, we would be caching this data for
	# efficiency
	value = self.valobj.GetChildMemberWithName(
	"value").GetValueAsUnsigned()
	operator = self.valobj.GetChildMemberWithName(
	"oper").GetValueAsUnsigned()
	mask = self.valobj.GetChildMemberWithName(
	"mask").GetValueAsUnsigned()
	# compute the masked value according to the operator
	if operator == 1:
	value = value & mask
	elif operator == 2:
	value = value \| mask
	elif operator == 3:
	value = value ^ mask
	elif operator == 4:
	value = ~(value & mask)
	elif operator == 5:
	value = ~(value \| mask)
	else:
	pass
	value &= 0xFFFFFFFF # make sure Python does not extend our values to 64-bits
	# return it - again, not the most efficient possible way. we should actually be pushing the computed value
	# into an SBData, and using the SBData to create an SBValue - this
	# has the advantage of readability
	return self.valobj.CreateValueFromExpression(
	"apply()", '(uint32_t)(' + str(value) + ')')

	def update(self):
	# we do not do anything special in update - but this would be the right place to lookup
	# the data we use in get_child_at_index and cache it
	pass