test/API/functionalities/memory/read/TestMemoryRead.py - llvm-project/lldb - Git at Google

 """
 Test the 'memory read' command.
 """


 import lldb
 from lldbsuite.test.lldbtest import *
 import lldbsuite.test.lldbutil as lldbutil


 class MemoryReadTestCase(TestBase):

     mydir = TestBase.compute_mydir(__file__)

     def setUp(self):
         # Call super's setUp().
         TestBase.setUp(self)
         # Find the line number to break inside main().
         self.line = line_number('main.cpp', '// Set break point at this line.')

     def test_memory_read(self):
         """Test the 'memory read' command with plain and vector formats."""
         self.build()
         exe = self.getBuildArtifact("a.out")
         self.runCmd("file " + exe, CURRENT_EXECUTABLE_SET)

         # Break in main() after the variables are assigned values.
         lldbutil.run_break_set_by_file_and_line(
             self, "main.cpp", self.line, num_expected_locations=1, loc_exact=True)

         self.runCmd("run", RUN_SUCCEEDED)

         # The stop reason of the thread should be breakpoint.
         self.expect("thread list", STOPPED_DUE_TO_BREAKPOINT,
                     substrs=['stopped', 'stop reason = breakpoint'])

         # The breakpoint should have a hit count of 1.
         self.expect("breakpoint list -f", BREAKPOINT_HIT_ONCE,
                     substrs=[' resolved, hit count = 1'])

         # Test the memory read commands.

         # (lldb) memory read -f d -c 1 `&argc`
         # 0x7fff5fbff9a0: 1
         self.runCmd("memory read -f d -c 1 `&argc`")

         # Find the starting address for variable 'argc' to verify later that the
         # '--format uint32_t[] --size 4 --count 4' option increments the address
         # correctly.
         line = self.res.GetOutput().splitlines()[0]
         items = line.split(':')
         address = int(items[0], 0)
         argc = int(items[1], 0)
         self.assertGreater(address, 0)
         self.assertEquals(argc, 1)

         # (lldb) memory read --format uint32_t[] --size 4 --count 4 `&argc`
         # 0x7fff5fbff9a0: {0x00000001}
         # 0x7fff5fbff9a4: {0x00000000}
         # 0x7fff5fbff9a8: {0x0ec0bf27}
         # 0x7fff5fbff9ac: {0x215db505}
         self.runCmd(
             "memory read --format uint32_t[] --size 4 --count 4 `&argc`")
         lines = self.res.GetOutput().splitlines()
         for i in range(4):
             if i == 0:
                 # Verify that the printout for argc is correct.
                 self.assertEqual(
                     argc, int(lines[i].split(':')[1].strip(' {}'), 0))
             addr = int(lines[i].split(':')[0], 0)
             # Verify that the printout for addr is incremented correctly.
             self.assertEqual(addr, (address + i * 4))

         # (lldb) memory read --format char[] --size 7 --count 1 `&my_string`
         # 0x7fff5fbff990: {abcdefg}
         self.expect(
             "memory read --format char[] --size 7 --count 1 `&my_string`",
             substrs=['abcdefg'])

         # (lldb) memory read --format 'hex float' --size 16 `&argc`
         # 0x7fff5fbff5b0: error: unsupported byte size (16) for hex float
         # format
         self.expect(
             "memory read --format 'hex float' --size 16 `&argc`",
             substrs=['unsupported byte size (16) for hex float format'])

         self.expect(
             "memory read --format 'float' --count 1 --size 8 `&my_double`",
             substrs=['1234.'])

         # (lldb) memory read --format 'float' --count 1 --size 20 `&my_double`
         # 0x7fff5fbff598: error: unsupported byte size (20) for float format
         self.expect(
             "memory read --format 'float' --count 1 --size 20 `&my_double`",
             substrs=['unsupported byte size (20) for float format'])

         self.expect('memory read --type int --count 5 `&my_ints[0]`',
                     substrs=['(int) 0x', '2', '4', '6', '8', '10'])

         self.expect(
             'memory read --type int --count 5 --format hex `&my_ints[0]`',
             substrs=[
                 '(int) 0x',
                 '0x',
                 '0a'])

         self.expect(
             'memory read --type int --count 5 --offset 5 `&my_ints[0]`',
             substrs=[
                 '(int) 0x',
                 '12',
                 '14',
                 '16',
                 '18',
                 '20'])

         # the gdb format specifier and the size in characters for
         # the returned values including the 0x prefix.
         variations = [['b', 4], ['h', 6], ['w', 10], ['g', 18]]
         for v in variations:
           formatter = v[0]
           expected_object_length = v[1]
           self.runCmd(
               "memory read --gdb-format 4%s &my_uint64s" % formatter)
           lines = self.res.GetOutput().splitlines()
           objects_read = []
           for l in lines:
               objects_read.extend(l.split(':')[1].split())
           # Check that we got back 4 0x0000 etc bytes
           for o in objects_read:
               self.assertEqual(len(o), expected_object_length)
           self.assertEquals(len(objects_read), 4)
	"""
	Test the 'memory read' command.
	"""



	import lldb
	from lldbsuite.test.lldbtest import *
	import lldbsuite.test.lldbutil as lldbutil


	class MemoryReadTestCase(TestBase):

	mydir = TestBase.compute_mydir(__file__)

	def setUp(self):
	# Call super's setUp().
	TestBase.setUp(self)
	# Find the line number to break inside main().
	self.line = line_number('main.cpp', '// Set break point at this line.')

	def test_memory_read(self):
	"""Test the 'memory read' command with plain and vector formats."""
	self.build()
	exe = self.getBuildArtifact("a.out")
	self.runCmd("file " + exe, CURRENT_EXECUTABLE_SET)

	# Break in main() after the variables are assigned values.
	lldbutil.run_break_set_by_file_and_line(
	self, "main.cpp", self.line, num_expected_locations=1, loc_exact=True)

	self.runCmd("run", RUN_SUCCEEDED)

	# The stop reason of the thread should be breakpoint.
	self.expect("thread list", STOPPED_DUE_TO_BREAKPOINT,
	substrs=['stopped', 'stop reason = breakpoint'])

	# The breakpoint should have a hit count of 1.
	self.expect("breakpoint list -f", BREAKPOINT_HIT_ONCE,
	substrs=[' resolved, hit count = 1'])

	# Test the memory read commands.

	# (lldb) memory read -f d -c 1 `&argc`
	# 0x7fff5fbff9a0: 1
	self.runCmd("memory read -f d -c 1 `&argc`")

	# Find the starting address for variable 'argc' to verify later that the
	# '--format uint32_t[] --size 4 --count 4' option increments the address
	# correctly.
	line = self.res.GetOutput().splitlines()[0]
	items = line.split(':')
	address = int(items[0], 0)
	argc = int(items[1], 0)
	self.assertGreater(address, 0)
	self.assertEquals(argc, 1)

	# (lldb) memory read --format uint32_t[] --size 4 --count 4 `&argc`
	# 0x7fff5fbff9a0: {0x00000001}
	# 0x7fff5fbff9a4: {0x00000000}
	# 0x7fff5fbff9a8: {0x0ec0bf27}
	# 0x7fff5fbff9ac: {0x215db505}
	self.runCmd(
	"memory read --format uint32_t[] --size 4 --count 4 `&argc`")
	lines = self.res.GetOutput().splitlines()
	for i in range(4):
	if i == 0:
	# Verify that the printout for argc is correct.
	self.assertEqual(
	argc, int(lines[i].split(':')[1].strip(' {}'), 0))
	addr = int(lines[i].split(':')[0], 0)
	# Verify that the printout for addr is incremented correctly.
	self.assertEqual(addr, (address + i * 4))

	# (lldb) memory read --format char[] --size 7 --count 1 `&my_string`
	# 0x7fff5fbff990: {abcdefg}
	self.expect(
	"memory read --format char[] --size 7 --count 1 `&my_string`",
	substrs=['abcdefg'])

	# (lldb) memory read --format 'hex float' --size 16 `&argc`
	# 0x7fff5fbff5b0: error: unsupported byte size (16) for hex float
	# format
	self.expect(
	"memory read --format 'hex float' --size 16 `&argc`",
	substrs=['unsupported byte size (16) for hex float format'])

	self.expect(
	"memory read --format 'float' --count 1 --size 8 `&my_double`",
	substrs=['1234.'])

	# (lldb) memory read --format 'float' --count 1 --size 20 `&my_double`
	# 0x7fff5fbff598: error: unsupported byte size (20) for float format
	self.expect(
	"memory read --format 'float' --count 1 --size 20 `&my_double`",
	substrs=['unsupported byte size (20) for float format'])

	self.expect('memory read --type int --count 5 `&my_ints[0]`',
	substrs=['(int) 0x', '2', '4', '6', '8', '10'])

	self.expect(
	'memory read --type int --count 5 --format hex `&my_ints[0]`',
	substrs=[
	'(int) 0x',
	'0x',
	'0a'])

	self.expect(
	'memory read --type int --count 5 --offset 5 `&my_ints[0]`',
	substrs=[
	'(int) 0x',
	'12',
	'14',
	'16',
	'18',
	'20'])

	# the gdb format specifier and the size in characters for
	# the returned values including the 0x prefix.
	variations = [['b', 4], ['h', 6], ['w', 10], ['g', 18]]
	for v in variations:
	formatter = v[0]
	expected_object_length = v[1]
	self.runCmd(
	"memory read --gdb-format 4%s &my_uint64s" % formatter)
	lines = self.res.GetOutput().splitlines()
	objects_read = []
	for l in lines:
	objects_read.extend(l.split(':')[1].split())
	# Check that we got back 4 0x0000 etc bytes
	for o in objects_read:
	self.assertEqual(len(o), expected_object_length)
	self.assertEquals(len(objects_read), 4)