Exemplo n.º 1
0
def enum_blocks_edges(instructions):
    """
    Return a list of basicblock after
    statically parsing given instructions
    """

    basicblocks = list()
    edges = list()
    xrefs = enumerate_xref(instructions)
    # create the first block
    new_block = True

    for inst in instructions:
        if new_block:
            block = BasicBlock(start_offset=inst.offset,
                               start_instr=inst,
                               name='block_%x' % inst.offset)
            new_block = False

        # add current instruction to the basicblock
        block.instructions.append(inst)

        # next instruction in xrefs list
        if (inst.offset_end + 1) in xrefs:
            # absolute JUMP
            if inst.is_branch_unconditional:
                edges.append(
                    Edge(block.name, 'block_%x' % xref_of_instr(inst),
                         EDGE_UNCONDITIONAL))
            # conditionnal JUMPI / JUMPIF / ...
            elif inst.is_branch_conditional:
                edges.append(
                    Edge(block.name, 'block_%x' % xref_of_instr(inst),
                         EDGE_CONDITIONAL_TRUE))
                edges.append(
                    Edge(block.name, 'block_%x' % (inst.offset_end + 1),
                         EDGE_CONDITIONAL_FALSE))
            # Halt instruction : RETURN, STOP, RET, ...
            elif inst.is_halt:
                pass
            # just falls to the next instruction
            else:
                edges.append(
                    Edge(block.name, 'block_%x' % (inst.offset_end + 1),
                         EDGE_FALLTHROUGH))

            block.end_offset = inst.offset_end
            block.end_instr = inst
            basicblocks.append(block)
            new_block = True

    # add the last block
    basicblocks.append(block)
    edges = list(set(edges))

    return (basicblocks, edges)
Exemplo n.º 2
0
    def get_functions_call_edges(self, format_fname=False):

        nodes = list()
        edges = list()

        if not self.analyzer:
            self.analyzer = WasmModuleAnalyzer(self.module_bytecode)
        if not self.functions:
            self.functions = enum_func(self.module_bytecode)

        # create nodes
        for name, param_str, return_str, _ in self.analyzer.func_prototypes:
            if format_fname:
                nodes.append(format_func_name(name, param_str, return_str))
            else:
                nodes.append(name)

        logging.info('nodes: %s', nodes)

        # create edges
        tmp_edges = enum_func_call_edges(self.functions,
                                         len(self.analyzer.imports_func))

        # tmp_edges = [(node_from, node_to), (...), ...]
        for node_from, node_to in tmp_edges:
            # node_from
            name, param, ret, _ = self.analyzer.func_prototypes[node_from]
            if format_fname:
                from_final = format_func_name(name, param, ret)
            else:
                from_final = name
            # node_to
            name, param, ret, _ = self.analyzer.func_prototypes[node_to]
            to_final = format_func_name(name, param, ret)
            if format_fname:
                to_final = format_func_name(name, param, ret)
            else:
                to_final = name
            edges.append(Edge(from_final, to_final, EDGE_CALL))
        logging.info('edges: %s', edges)

        return (nodes, edges)
Exemplo n.º 3
0
def enum_blocks_edges(function_id, instructions):

    """
    Return a list of basicblock after
    statically parsing given instructions
    """

    basicblocks = list()
    edges = list()

    branches = []
    xrefs = []

    intent = 0
    blocks_tmp = []
    blocks_list = []

    # we need to do that because jump label are relative to the current block index
    for index, inst in enumerate(instructions[:-1]):

        if inst.is_block_terminator:
            start, name = blocks_tmp.pop()
            if inst.name == 'else':
                end = inst.offset - 1
            else:
                end = inst.offset_end
            blocks_list.append((intent, start, end, name))
            intent -= 1
        if inst.is_block_starter:  # in ['block', 'loop', 'if', 'else']:
            blocks_tmp.append((inst.offset, inst.name))
            intent += 1
        if inst.is_branch:
            branches.append((intent, inst))

    # add function body end
    blocks_list.append((0, 0, instructions[-1].offset_end, 'func'))
    blocks_list = sorted(blocks_list, key=lambda tup: (tup[1], tup[0]))

    for depth, inst in branches:
        labl = list()
        if inst.name == 'br_table':
            labl = [i for i in inst.insn_byte[2:]]
        else:
            labl.append(int(inst.operand_interpretation.split(' ')[-1]))

        for d2 in labl:
            rep = next(((i, s, e, n) for i, s, e, n in blocks_list if (i == (depth - d2) and s < inst.offset and e > inst.offset_end)), None)

            if rep:
                i, start, end, name = rep
                # if we branch to a 'loop' label
                # we go at the entry of the 'loop' block
                if name == 'loop':
                    value = start
                # if we branch to a 'block' label
                # we go at the end of the "block" block
                elif name == 'block' or name == 'func':
                    value = end
                # we don't know
                else:
                    value = None
                inst.xref.append(value)
                xrefs.append(value)

    # assign xref for "if" branch
    # needed because 'if' don't used label
    for index, inst in enumerate(instructions[:-1]):
        if inst.name == 'if':
            g_block = next(iter([b for b in blocks_list if b[1] == inst.offset]), None)
            jump_target = g_block[2] + 1
            inst.xref.append(jump_target)
            xrefs.append(jump_target)
        elif inst.name == 'else':
            g_block = next(iter([b for b in blocks_list if b[1] == inst.offset]), None)
            jump_target = g_block[2] + 1
            inst.xref.append(jump_target)
            xrefs.append(jump_target)

    # enumerate blocks
    new_block = True

    for index, inst in enumerate(instructions):

        # creation of a block
        if new_block:
            block = BasicBlock(inst.offset,
                               inst,
                               name=format_bb_name(function_id, inst.offset))
            new_block = False
        # add current instruction to the basicblock
        block.instructions.append(inst)

        # next instruction is a jump target
        if index < (len(instructions) - 1) and \
                instructions[index + 1].offset in xrefs:
            new_block = True
        # absolute jump - br
        elif inst.is_branch_unconditional:
            new_block = True
        # conditionnal jump - br_if
        elif inst.is_branch_conditional:
            new_block = True
        # is_block_terminator
        # GRAPHICAL OPTIMIZATION: merge end together
        elif index < (len(instructions) - 1) and \
                instructions[index + 1].name in ['else', 'loop']:  # is_block_terminator
            new_block = True
        # last instruction of the bytecode
        elif inst.offset == instructions[-1].offset:
            new_block = True

        if new_block:
            block.end_offset = inst.offset_end
            block.end_instr = inst
            basicblocks.append(block)

    # enumerate edges
    for index, block in enumerate(basicblocks):
        # get the last instruction
        inst = block.end_instr
        # unconditional jump - br
        if inst.is_branch_unconditional:
            for ref in inst.xref:
                edges.append(Edge(block.name, format_bb_name(function_id, ref), EDGE_UNCONDITIONAL))
        # conditionnal jump - br_if, if
        elif inst.is_branch_conditional:
            if inst.name == 'if':
                edges.append(Edge(block.name,
                             format_bb_name(function_id, inst.offset_end + 1),
                             EDGE_CONDITIONAL_TRUE))
                if_b = next(iter([b for b in blocks_list if b[1] == inst.offset]), None)
                #else_block = blocks_list[blocks_list.index(if_block) + 1]
                jump_target = if_b[2] + 1
                edges.append(Edge(block.name,
                             format_bb_name(function_id, jump_target),
                             EDGE_CONDITIONAL_FALSE))
            else:
                for ref in inst.xref:
                    if ref and ref != inst.offset_end + 1:
                        # create conditionnal true edges
                        edges.append(Edge(block.name,
                                          format_bb_name(function_id, ref),
                                          EDGE_CONDITIONAL_TRUE))
                # create conditionnal false edge
                edges.append(Edge(block.name,
                             format_bb_name(function_id, inst.offset_end + 1),
                             EDGE_CONDITIONAL_FALSE))
        # instruction that end the flow
        elif [i.name for i in block.instructions if i.is_halt]:
            pass
        elif inst.is_halt:
            pass

        # handle the case when you have if and else following
        elif inst.offset != instructions[-1].offset and \
                block.start_instr.name != 'else' and \
                instructions[instructions.index(inst) + 1].name == 'else':

            else_ins = instructions[instructions.index(inst) + 1]
            else_b = next(iter([b for b in blocks_list if b[1] == else_ins.offset]), None)

            edges.append(Edge(block.name, format_bb_name(function_id, else_b[2] + 1), EDGE_FALLTHROUGH))
        # add the last intruction "end" in the last block
        elif inst.offset != instructions[-1].offset:
            # EDGE_FALLTHROUGH
            edges.append(Edge(block.name, format_bb_name(function_id, inst.offset_end + 1), EDGE_FALLTHROUGH))

    # prevent duplicate edges
    edges = list(set(edges))
    return basicblocks, edges
Exemplo n.º 4
0
    def emulate(self, state=EvmVMstate(), depth=0):

        #  create fake stack for tests
        state.symbolic_stack = list(range(1000))

        # get current instruction
        instr = self.reverse_instructions[state.pc]

        # create the first basicblock of this branch
        # print('%d : %s' % (instr.offset, instr.name))
        self.current_basicblock = self.basicblock_per_instr[instr.offset]

        # beginning of a function
        if instr in self.functions_start_instr:

            # cleaning duplicate block in previous function
            self.current_function.basicblocks = list(
                set(self.current_function.basicblocks))
            # retrive matching function
            self.current_function = next(
                filter(lambda f: f.start_instr == instr, self.functions))
            # self.ssa_counter = 0
            logging.info("[+] Entering function - %x: ",
                         self.current_function.start_offset,
                         self.current_function.prefered_name)

        # associate function to basicblock
        # TODO: create list of function_name
        self.current_basicblock.function_name = self.current_function.prefered_name
        # associate basicblock to function
        self.current_function.basicblocks.append(self.current_basicblock)

        # halt variable use to catch ending branch
        halt = False
        while not halt:

            # get current instruction
            instr = self.reverse_instructions[state.pc]

            # handle fall-thrown due to JUMPDEST
            if instr.name == 'JUMPDEST':
                # doesn't match new block that start with JUMPDEST
                if self.current_basicblock.start_offset != instr.offset:
                    self.edges.append(
                        Edge(self.current_basicblock.name,
                             'block_%x' % instr.offset, EDGE_FALLTHROUGH))

            # get current basicblock
            self.current_basicblock = self.basicblock_per_instr[instr.offset]
            self.current_function.basicblocks.append(self.current_basicblock)

            # add this instruction to his functions
            # TODO: verify if it's not useless for ethereum
            self.current_function.instructions.append(instr)

            # Save instruction and state
            state.instr = instr
            self.states[self.states_total] = state
            state = copy.deepcopy(state)
            self.states_total += 1
            state.pc += 1

            # execute single instruction
            halt = self.emulate_one_instruction(instr, state, depth)
            state.instructions_visited.append(instr.offset)
            #state.instructions_visited[instr.offset] = instr.offset

        logging.info("[X] Returning from basicblock %s",
                     self.current_basicblock.name)

        # automatic remove duplicated edges
        self.edges = list(set(self.edges))
Exemplo n.º 5
0
    def ssa_stack_memory_storage_flow_instruction(self, instr, state, depth):

        halt = False
        op = instr.name

        if op == 'POP':
            # SSA STACK
            s0 = state.ssa_stack.pop()
            instr.ssa = SSA(method_name=instr.name)

        elif op in ['MLOAD', 'SLOAD']:
            # SSA STACK
            s0 = state.ssa_stack.pop()
            instr.ssa = SSA(new_assignement=self.ssa_counter,
                            method_name=instr.name,
                            args=[s0])
            state.ssa_stack.append(instr)
            self.ssa_counter += 1

        elif op in ['MSTORE', 'MSTORE8', 'SSTORE']:
            # SSA STACK
            s0, s1 = state.ssa_stack.pop(), state.ssa_stack.pop()
            instr.ssa = SSA(method_name=instr.name, args=[s0, s1])

        elif op == 'JUMP':
            # SSA STACK
            push_instr = state.ssa_stack.pop()
            instr.ssa = SSA(method_name=instr.name, args=[push_instr])

            # get instruction with this value as offset
            if push_instr.ssa.is_constant:
                #jump_addr = int.from_bytes(push_instr.operand, byteorder='big')
                jump_addr = push_instr.operand_interpretation
                # get instruction with this value as offset
                target = next(
                    filter(lambda element: element.offset == jump_addr,
                           self.instructions))
            else:
                # try to resolve the SSA repr
                jump_addr = self.simplify_ssa.resolve_instr_ssa(push_instr)
                target = next(
                    filter(lambda element: element.offset == jump_addr,
                           self.instructions))
                if not jump_addr:
                    logging.warning('JUMP DYNAMIC')
                    logging.warning('[X] push_instr %x: %s ' %
                                    (push_instr.offset, push_instr.name))
                    logging.warning('[X] push_instr.ssa %s' %
                                    push_instr.ssa.format())
                    list_args = [
                        arg.ssa.format() for arg in push_instr.ssa.args
                    ]
                    logging.warning('[X] push_instr.ssa %s' % list_args)
                    return True

            # depth of 1 - prevent looping
            #if (depth < self.max_depth):
            if target.name != "JUMPDEST":
                logging.info('[X] Bad JUMP to 0x%x' % jump_addr)
                return True

            if target.offset not in state.instructions_visited:
                logging.info('[X] follow JUMP branch offset 0x%x' %
                             target.offset)
                new_state = copy.deepcopy(state)
                new_state.pc = self.instructions.index(target)
                #state.pc = self.instructions.index(target)

                # follow the JUMP
                self.edges.append(
                    Edge(self.current_basicblock.name,
                         'block_%x' % target.offset, EDGE_UNCONDITIONAL))
                self.emulate(new_state, depth=depth + 1)

                halt = True

            else:
                #logging.info('[X] Max depth reached, skipping JUMP 0x%x' % jump_addr)
                self.edges.append(
                    Edge(self.current_basicblock.name,
                         'block_%x' % target.offset, EDGE_UNCONDITIONAL))
                logging.info('[X] Loop detected, skipping JUMP 0x%x' %
                             jump_addr)
                halt = True

            self.current_basicblock = self.basicblock_per_instr[instr.offset]

        elif op == 'JUMPI':
            # SSA STACK
            push_instr, condition = state.ssa_stack.pop(), state.ssa_stack.pop(
            )
            instr.ssa = SSA(method_name=instr.name,
                            args=[push_instr, condition])

            logging.info('[X] follow JUMPI default branch offset 0x%x' %
                         (instr.offset_end + 1))
            new_state = copy.deepcopy(state)
            self.edges.append(
                Edge(self.current_basicblock.name,
                     'block_%x' % (instr.offset_end + 1),
                     EDGE_CONDITIONAL_FALSE))
            self.emulate(new_state, depth=depth + 1)
            self.current_basicblock = self.basicblock_per_instr[instr.offset]

            # get instruction with this value as offset
            if push_instr.ssa.is_constant:
                #jump_addr = int.from_bytes(push_instr.operand, byteorder='big')
                jump_addr = push_instr.operand_interpretation
                # get instruction with this value as offset
                target = next(
                    filter(lambda element: element.offset == jump_addr,
                           self.instructions))
            else:
                # try to resolve the SSA repr
                jump_addr = self.simplify_ssa.resolve_instr_ssa(push_instr)
                target = next(
                    filter(lambda element: element.offset == jump_addr,
                           self.instructions))
                if not jump_addr:
                    logging.warning('JUMP DYNAMIC')
                    logging.warning('[X] push_instr %x: %s ' %
                                    (push_instr.offset, push_instr.name))
                    logging.warning('[X] push_instr.ssa %s' %
                                    push_instr.ssa.format())
                    list_args = [
                        arg.ssa.format() for arg in push_instr.ssa.args
                    ]
                    logging.warning('[X] push_instr.ssa %s' % list_args)
                    return True

            if target.name != "JUMPDEST":
                logging.info('[X] Bad JUMP to 0x%x' % jump_addr)
                return True

            if target.offset not in state.instructions_visited:
                # condition are True
                logging.info('[X] follow JUMPI branch offset 0x%x' %
                             (target.offset))
                new_state = copy.deepcopy(state)
                new_state.pc = self.instructions.index(target)

                # follow the JUMPI
                self.edges.append(
                    Edge(self.current_basicblock.name,
                         'block_%x' % target.offset, EDGE_CONDITIONAL_TRUE))
                self.emulate(new_state, depth=depth + 1)

            else:
                self.edges.append(
                    Edge(self.current_basicblock.name,
                         'block_%x' % target.offset, EDGE_CONDITIONAL_TRUE))
                logging.warning('[X] Loop detected, skipping JUMPI 0x%x' %
                                jump_addr)
                logging.warning('[X] push_instr.ssa %s' %
                                push_instr.ssa.format())
                halt = True
            halt = True

        elif op in ['PC', 'MSIZE', 'GAS']:
            # SSA STACK
            instr.ssa = SSA(new_assignement=self.ssa_counter,
                            method_name=instr.name)
            state.ssa_stack.append(instr)
            self.ssa_counter += 1

        elif op == 'JUMPDEST':
            # SSA STACK
            instr.ssa = SSA(method_name=instr.name)

        return halt
Exemplo n.º 6
0
def enum_blocks_edges(function_id, instructions):
    """
    Return a list of basicblock after
    statically parsing given instructions
    """

    basicblocks = list()
    edges = list()

    branches = []
    xrefs = []

    intent = 0
    blocks_tmp = []
    blocks_list = []
    # remove last instruction that is 'end' for the funtion
    #tt = instructions[:-1]
    for index, inst in enumerate(instructions[:-1]):

        if inst.is_block_terminator:
            start, name = blocks_tmp.pop()
            blocks_list.append((intent, start, inst.offset_end, name))
            intent -= 1
        if inst.is_block_starter:  # in ['block', 'loop']:
            blocks_tmp.append((inst.offset, inst.name))
            intent += 1
        if inst.is_branch:
            branches.append((intent, inst))

    # add function body end
    blocks_list.append((0, 0, instructions[-1].offset_end, 'func'))
    blocks_list = sorted(blocks_list, key=lambda tup: tup[1])

    for depth, inst in branches:
        d2 = int(inst.operand_interpretation.split(' ')[-1])
        rep = next(((i, s, e, n) for i, s, e, n in blocks_list if (
            i == (depth - d2) and s < inst.offset and e > inst.offset_end)),
                   None)
        if rep:
            i, start, end, name = rep
            if name == 'loop':
                value = start  # else name == 'block'
            elif name == 'block' or name == 'func':
                value = end
            else:
                value = None
            inst.xref = value
            xrefs.append(value)

    # remove "block" instruction - not usefull graphicaly
    # instructions = [x for x in instructions if x.name not in ['block', 'loop']]

    # enumerate blocks

    new_block = True

    for index, inst in enumerate(instructions):

        # creation of a block
        if new_block:
            block = BasicBlock(inst.offset,
                               inst,
                               name=format_bb_name(function_id, inst.offset))
            new_block = False

        # add current instruction to the basicblock
        block.instructions.append(inst)

        # next instruction is a jump target
        if index < (len(instructions) - 1) and \
           instructions[index + 1].offset in xrefs:
            new_block = True
        # absolute jump - br
        elif inst.is_branch_unconditional:
            new_block = True
        # conditionnal jump - br_if
        elif inst.is_branch_conditional:
            new_block = True
        # end of a block
        elif index < (len(instructions) - 1) and \
                inst.name in ['end']:  # is_block_terminator
            new_block = True
        elif index < (len(instructions) - 1) and \
                instructions[index + 1].name == 'else':  # is_block_terminator
            new_block = True
        # start of a block
        elif index < (len(instructions) - 1) and \
                instructions[index + 1].is_block_starter:
            new_block = True
        # last instruction of the bytecode
        elif inst.offset == instructions[-1].offset:
            new_block = True

        if new_block:
            block.end_offset = inst.offset_end
            block.end_instr = inst
            basicblocks.append(block)
            new_block = True

    # TODO: detect and remove end instruction that end loop

    # enumerate edges
    for index, block in enumerate(basicblocks):
        # get the last instruction
        inst = block.end_instr
        # unconditional jump - br
        if inst.is_branch_unconditional:
            if inst.xref is not None:
                edges.append(
                    Edge(block.name, format_bb_name(function_id, inst.xref),
                         EDGE_UNCONDITIONAL))
            else:
                log.error('Bad branch target')
        # conditionnal jump - br_if, if
        elif inst.is_branch_conditional:
            if inst.name == 'if':
                edges.append(
                    Edge(block.name,
                         format_bb_name(function_id, inst.offset_end + 1),
                         EDGE_CONDITIONAL_TRUE))
                edges.append(
                    Edge(
                        block.name,
                        format_bb_name(
                            function_id,
                            basicblocks[index + 2].start_instr.offset),
                        EDGE_CONDITIONAL_FALSE))
            else:
                if inst.xref is not None:
                    edges.append(
                        Edge(block.name,
                             format_bb_name(function_id,
                                            inst.xref), EDGE_CONDITIONAL_TRUE))
                else:
                    log.error('Bad branch target')
                edges.append(
                    Edge(block.name,
                         format_bb_name(function_id, inst.offset_end + 1),
                         EDGE_CONDITIONAL_FALSE))
        elif inst.offset != instructions[-1].offset:
            # EDGE_FALLTHROUGH
            edges.append(
                Edge(block.name,
                     format_bb_name(function_id, inst.offset_end + 1),
                     EDGE_FALLTHROUGH))

    # prevent duplicate edges
    edges = list(set(edges))
    return basicblocks, edges