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cpuinfo.py
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cpuinfo.py
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#!/usr/bin/env python
# -*- coding: UTF-8 -*-
# Copyright (c) 2014-2019, Matthew Brennan Jones <[email protected]>
# Py-cpuinfo gets CPU info with pure Python 2 & 3
# It uses the MIT License
# It is hosted at: https://github.com/workhorsy/py-cpuinfo
#
# Permission is hereby granted, free of charge, to any person obtaining
# a copy of this software and associated documentation files (the
# "Software"), to deal in the Software without restriction, including
# without limitation the rights to use, copy, modify, merge, publish,
# distribute, sublicense, and/or sell copies of the Software, and to
# permit persons to whom the Software is furnished to do so, subject to
# the following conditions:
#
# The above copyright notice and this permission notice shall be included
# in all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
# EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
# MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
# IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
# CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
# TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
# SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
CPUINFO_VERSION = (5, 0, 0)
CPUINFO_VERSION_STRING = '.'.join([str(n) for n in CPUINFO_VERSION])
import os, sys
import platform
import multiprocessing
import ctypes
try:
import _winreg as winreg
except ImportError as err:
try:
import winreg
except ImportError as err:
pass
IS_PY2 = sys.version_info[0] == 2
CAN_CALL_CPUID_IN_SUBPROCESS = True
class DataSource(object):
bits = platform.architecture()[0]
cpu_count = multiprocessing.cpu_count()
is_windows = platform.system().lower() == 'windows'
arch_string_raw = platform.machine()
uname_string_raw = platform.uname()[5]
can_cpuid = True
@staticmethod
def has_proc_cpuinfo():
return os.path.exists('/proc/cpuinfo')
@staticmethod
def has_dmesg():
return len(_program_paths('dmesg')) > 0
@staticmethod
def has_var_run_dmesg_boot():
uname = platform.system().strip().strip('"').strip("'").strip().lower()
return 'linux' in uname and os.path.exists('/var/run/dmesg.boot')
@staticmethod
def has_cpufreq_info():
return len(_program_paths('cpufreq-info')) > 0
@staticmethod
def has_sestatus():
return len(_program_paths('sestatus')) > 0
@staticmethod
def has_sysctl():
return len(_program_paths('sysctl')) > 0
@staticmethod
def has_isainfo():
return len(_program_paths('isainfo')) > 0
@staticmethod
def has_kstat():
return len(_program_paths('kstat')) > 0
@staticmethod
def has_sysinfo():
return len(_program_paths('sysinfo')) > 0
@staticmethod
def has_lscpu():
return len(_program_paths('lscpu')) > 0
@staticmethod
def has_ibm_pa_features():
return len(_program_paths('lsprop')) > 0
@staticmethod
def has_wmic():
returncode, output = _run_and_get_stdout(['wmic', 'os', 'get', 'Version'])
return returncode == 0 and len(output) > 0
@staticmethod
def cat_proc_cpuinfo():
return _run_and_get_stdout(['cat', '/proc/cpuinfo'])
@staticmethod
def cpufreq_info():
return _run_and_get_stdout(['cpufreq-info'])
@staticmethod
def sestatus_b():
return _run_and_get_stdout(['sestatus', '-b'])
@staticmethod
def dmesg_a():
return _run_and_get_stdout(['dmesg', '-a'])
@staticmethod
def cat_var_run_dmesg_boot():
return _run_and_get_stdout(['cat', '/var/run/dmesg.boot'])
@staticmethod
def sysctl_machdep_cpu_hw_cpufrequency():
return _run_and_get_stdout(['sysctl', 'machdep.cpu', 'hw.cpufrequency'])
@staticmethod
def isainfo_vb():
return _run_and_get_stdout(['isainfo', '-vb'])
@staticmethod
def kstat_m_cpu_info():
return _run_and_get_stdout(['kstat', '-m', 'cpu_info'])
@staticmethod
def sysinfo_cpu():
return _run_and_get_stdout(['sysinfo', '-cpu'])
@staticmethod
def lscpu():
return _run_and_get_stdout(['lscpu'])
@staticmethod
def ibm_pa_features():
import glob
ibm_features = glob.glob('/proc/device-tree/cpus/*/ibm,pa-features')
if ibm_features:
return _run_and_get_stdout(['lsprop', ibm_features[0]])
@staticmethod
def wmic_cpu():
return _run_and_get_stdout(['wmic', 'cpu', 'get', 'Name,CurrentClockSpeed,L2CacheSize,L3CacheSize,Description,Caption,Manufacturer', '/format:list'])
@staticmethod
def winreg_processor_brand():
key = winreg.OpenKey(winreg.HKEY_LOCAL_MACHINE, r"Hardware\Description\System\CentralProcessor\0")
processor_brand = winreg.QueryValueEx(key, "ProcessorNameString")[0]
winreg.CloseKey(key)
return processor_brand.strip()
@staticmethod
def winreg_vendor_id_raw():
key = winreg.OpenKey(winreg.HKEY_LOCAL_MACHINE, r"Hardware\Description\System\CentralProcessor\0")
vendor_id_raw = winreg.QueryValueEx(key, "VendorIdentifier")[0]
winreg.CloseKey(key)
return vendor_id_raw
@staticmethod
def winreg_arch_string_raw():
key = winreg.OpenKey(winreg.HKEY_LOCAL_MACHINE, r"SYSTEM\CurrentControlSet\Control\Session Manager\Environment")
arch_string_raw = winreg.QueryValueEx(key, "PROCESSOR_ARCHITECTURE")[0]
winreg.CloseKey(key)
return arch_string_raw
@staticmethod
def winreg_hz_actual():
key = winreg.OpenKey(winreg.HKEY_LOCAL_MACHINE, r"Hardware\Description\System\CentralProcessor\0")
hz_actual = winreg.QueryValueEx(key, "~Mhz")[0]
winreg.CloseKey(key)
hz_actual = _to_decimal_string(hz_actual)
return hz_actual
@staticmethod
def winreg_feature_bits():
key = winreg.OpenKey(winreg.HKEY_LOCAL_MACHINE, r"Hardware\Description\System\CentralProcessor\0")
feature_bits = winreg.QueryValueEx(key, "FeatureSet")[0]
winreg.CloseKey(key)
return feature_bits
def _program_paths(program_name):
paths = []
exts = filter(None, os.environ.get('PATHEXT', '').split(os.pathsep))
path = os.environ['PATH']
for p in os.environ['PATH'].split(os.pathsep):
p = os.path.join(p, program_name)
if os.access(p, os.X_OK):
paths.append(p)
for e in exts:
pext = p + e
if os.access(pext, os.X_OK):
paths.append(pext)
return paths
def _run_and_get_stdout(command, pipe_command=None):
from subprocess import Popen, PIPE
if not pipe_command:
p1 = Popen(command, stdout=PIPE, stderr=PIPE, stdin=PIPE)
output = p1.communicate()[0]
if not IS_PY2:
output = output.decode(encoding='UTF-8')
return p1.returncode, output
else:
p1 = Popen(command, stdout=PIPE, stderr=PIPE, stdin=PIPE)
p2 = Popen(pipe_command, stdin=p1.stdout, stdout=PIPE, stderr=PIPE)
p1.stdout.close()
output = p2.communicate()[0]
if not IS_PY2:
output = output.decode(encoding='UTF-8')
return p2.returncode, output
# Make sure we are running on a supported system
def _check_arch():
arch, bits = _parse_arch(DataSource.arch_string_raw)
if not arch in ['X86_32', 'X86_64', 'ARM_7', 'ARM_8', 'PPC_64', 'S390X']:
raise Exception("py-cpuinfo currently only works on X86 and some ARM/PPC/S390X CPUs.")
def _obj_to_b64(thing):
import pickle
import base64
a = thing
b = pickle.dumps(a)
c = base64.b64encode(b)
d = c.decode('utf8')
return d
def _b64_to_obj(thing):
import pickle
import base64
try:
a = base64.b64decode(thing)
b = pickle.loads(a)
return b
except:
return {}
def _utf_to_str(input):
if IS_PY2 and isinstance(input, unicode):
return input.encode('utf-8')
elif isinstance(input, list):
return [_utf_to_str(element) for element in input]
elif isinstance(input, dict):
return {_utf_to_str(key): _utf_to_str(value)
for key, value in input.items()}
else:
return input
def _copy_new_fields(info, new_info):
keys = [
'vendor_id_raw', 'hardware_raw', 'brand_raw', 'hz_advertised_friendly', 'hz_actual_friendly',
'hz_advertised', 'hz_actual', 'arch', 'bits', 'count',
'arch_string_raw', 'uname_string_raw',
'l2_cache_size', 'l2_cache_line_size', 'l2_cache_associativity',
'stepping', 'model', 'family',
'processor_type', 'extended_model', 'extended_family', 'flags',
'l3_cache_size', 'l1_data_cache_size', 'l1_instruction_cache_size'
]
for key in keys:
if new_info.get(key, None) and not info.get(key, None):
info[key] = new_info[key]
elif key == 'flags' and new_info.get('flags'):
for f in new_info['flags']:
if f not in info['flags']: info['flags'].append(f)
info['flags'].sort()
def _get_field_actual(cant_be_number, raw_string, field_names):
for line in raw_string.splitlines():
for field_name in field_names:
field_name = field_name.lower()
if ':' in line:
left, right = line.split(':', 1)
left = left.strip().lower()
right = right.strip()
if left == field_name and len(right) > 0:
if cant_be_number:
if not right.isdigit():
return right
else:
return right
return None
def _get_field(cant_be_number, raw_string, convert_to, default_value, *field_names):
retval = _get_field_actual(cant_be_number, raw_string, field_names)
# Convert the return value
if retval and convert_to:
try:
retval = convert_to(retval)
except:
retval = default_value
# Return the default if there is no return value
if retval is None:
retval = default_value
return retval
def _to_decimal_string(ticks):
try:
# Convert to string
ticks = '{0}'.format(ticks)
# Strip off non numbers and decimal places
ticks = "".join(n for n in ticks if n.isdigit() or n=='.').strip()
if ticks == '':
ticks = '0'
# Add decimal if missing
if '.' not in ticks:
ticks = '{0}.0'.format(ticks)
# Remove trailing zeros
ticks = ticks.rstrip('0')
# Add one trailing zero for empty right side
if ticks.endswith('.'):
ticks = '{0}0'.format(ticks)
# Make sure the number can be converted to a float
ticks = float(ticks)
ticks = '{0}'.format(ticks)
return ticks
except:
return '0.0'
def _hz_short_to_full(ticks, scale):
try:
# Make sure the number can be converted to a float
ticks = float(ticks)
ticks = '{0}'.format(ticks)
# Scale the numbers
hz = ticks.lstrip('0')
old_index = hz.index('.')
hz = hz.replace('.', '')
hz = hz.ljust(scale + old_index+1, '0')
new_index = old_index + scale
hz = '{0}.{1}'.format(hz[:new_index], hz[new_index:])
left, right = hz.split('.')
left, right = int(left), int(right)
return (left, right)
except:
return (0, 0)
def _hz_friendly_to_full(hz_string):
try:
hz_string = hz_string.strip().lower()
hz, scale = (None, None)
if hz_string.endswith('ghz'):
scale = 9
elif hz_string.endswith('mhz'):
scale = 6
elif hz_string.endswith('hz'):
scale = 0
hz = "".join(n for n in hz_string if n.isdigit() or n=='.').strip()
if not '.' in hz:
hz += '.0'
hz, scale = _hz_short_to_full(hz, scale)
return (hz, scale)
except:
return (0, 0)
def _hz_short_to_friendly(ticks, scale):
try:
# Get the raw Hz as a string
left, right = _hz_short_to_full(ticks, scale)
result = '{0}.{1}'.format(left, right)
# Get the location of the dot, and remove said dot
dot_index = result.index('.')
result = result.replace('.', '')
# Get the Hz symbol and scale
symbol = "Hz"
scale = 0
if dot_index > 9:
symbol = "GHz"
scale = 9
elif dot_index > 6:
symbol = "MHz"
scale = 6
elif dot_index > 3:
symbol = "KHz"
scale = 3
# Get the Hz with the dot at the new scaled point
result = '{0}.{1}'.format(result[:-scale-1], result[-scale-1:])
# Format the ticks to have 4 numbers after the decimal
# and remove any superfluous zeroes.
result = '{0:.4f} {1}'.format(float(result), symbol)
result = result.rstrip('0')
return result
except:
return '0.0000 Hz'
def _to_friendly_bytes(input):
import re
if not input:
return input
input = "{0}".format(input)
formats = {
r"^[0-9]+B$" : 'B',
r"^[0-9]+K$" : 'KB',
r"^[0-9]+M$" : 'MB',
r"^[0-9]+G$" : 'GB'
}
for pattern, friendly_size in formats.items():
if re.match(pattern, input):
return "{0} {1}".format(input[ : -1].strip(), friendly_size)
return input
def _parse_cpu_brand_string(cpu_string):
# Just return 0 if the processor brand does not have the Hz
if not 'hz' in cpu_string.lower():
return ('0.0', 0)
hz = cpu_string.lower()
scale = 0
if hz.endswith('mhz'):
scale = 6
elif hz.endswith('ghz'):
scale = 9
if '@' in hz:
hz = hz.split('@')[1]
else:
hz = hz.rsplit(None, 1)[1]
hz = hz.rstrip('mhz').rstrip('ghz').strip()
hz = _to_decimal_string(hz)
return (hz, scale)
def _parse_cpu_brand_string_dx(cpu_string):
import re
# Find all the strings inside brackets ()
starts = [m.start() for m in re.finditer('\(', cpu_string)]
ends = [m.start() for m in re.finditer('\)', cpu_string)]
insides = {k: v for k, v in zip(starts, ends)}
insides = [cpu_string[start+1 : end] for start, end in insides.items()]
# Find all the fields
vendor_id, stepping, model, family = (None, None, None, None)
for inside in insides:
for pair in inside.split(','):
pair = [n.strip() for n in pair.split(':')]
if len(pair) > 1:
name, value = pair[0], pair[1]
if name == 'origin':
vendor_id = value.strip('"')
elif name == 'stepping':
stepping = int(value.lstrip('0x'), 16)
elif name == 'model':
model = int(value.lstrip('0x'), 16)
elif name in ['fam', 'family']:
family = int(value.lstrip('0x'), 16)
# Find the Processor Brand
# Strip off extra strings in brackets at end
brand = cpu_string.strip()
is_working = True
while is_working:
is_working = False
for inside in insides:
full = "({0})".format(inside)
if brand.endswith(full):
brand = brand[ :-len(full)].strip()
is_working = True
# Find the Hz in the brand string
hz_brand, scale = _parse_cpu_brand_string(brand)
# Find Hz inside brackets () after the brand string
if hz_brand == '0.0':
for inside in insides:
hz = inside
for entry in ['GHz', 'MHz', 'Hz']:
if entry in hz:
hz = "CPU @ " + hz[ : hz.find(entry) + len(entry)]
hz_brand, scale = _parse_cpu_brand_string(hz)
break
return (hz_brand, scale, brand, vendor_id, stepping, model, family)
def _parse_dmesg_output(output):
try:
# Get all the dmesg lines that might contain a CPU string
lines = output.split(' CPU0:')[1:] + \
output.split(' CPU1:')[1:] + \
output.split(' CPU:')[1:] + \
output.split('\nCPU0:')[1:] + \
output.split('\nCPU1:')[1:] + \
output.split('\nCPU:')[1:]
lines = [l.split('\n')[0].strip() for l in lines]
# Convert the lines to CPU strings
cpu_strings = [_parse_cpu_brand_string_dx(l) for l in lines]
# Find the CPU string that has the most fields
best_string = None
highest_count = 0
for cpu_string in cpu_strings:
count = sum([n is not None for n in cpu_string])
if count > highest_count:
highest_count = count
best_string = cpu_string
# If no CPU string was found, return {}
if not best_string:
return {}
hz_actual, scale, processor_brand, vendor_id, stepping, model, family = best_string
# Origin
if ' Origin=' in output:
fields = output[output.find(' Origin=') : ].split('\n')[0]
fields = fields.strip().split()
fields = [n.strip().split('=') for n in fields]
fields = [{n[0].strip().lower() : n[1].strip()} for n in fields]
for field in fields:
name = list(field.keys())[0]
value = list(field.values())[0]
if name == 'origin':
vendor_id = value.strip('"')
elif name == 'stepping':
stepping = int(value.lstrip('0x'), 16)
elif name == 'model':
model = int(value.lstrip('0x'), 16)
elif name in ['fam', 'family']:
family = int(value.lstrip('0x'), 16)
# Features
flag_lines = []
for category in [' Features=', ' Features2=', ' AMD Features=', ' AMD Features2=']:
if category in output:
flag_lines.append(output.split(category)[1].split('\n')[0])
flags = []
for line in flag_lines:
line = line.split('<')[1].split('>')[0].lower()
for flag in line.split(','):
flags.append(flag)
flags.sort()
# Convert from GHz/MHz string to Hz
hz_advertised, scale = _parse_cpu_brand_string(processor_brand)
# If advertised hz not found, use the actual hz
if hz_advertised == '0.0':
scale = 6
hz_advertised = _to_decimal_string(hz_actual)
info = {
'vendor_id_raw' : vendor_id,
'brand_raw' : processor_brand,
'stepping' : stepping,
'model' : model,
'family' : family,
'flags' : flags
}
if hz_advertised and hz_advertised != '0.0':
info['hz_advertised_friendly'] = _hz_short_to_friendly(hz_advertised, scale)
info['hz_actual_friendly'] = _hz_short_to_friendly(hz_actual, scale)
if hz_advertised and hz_advertised != '0.0':
info['hz_advertised'] = _hz_short_to_full(hz_advertised, scale)
info['hz_actual'] = _hz_short_to_full(hz_actual, scale)
return {k: v for k, v in info.items() if v}
except:
#raise
pass
return {}
def _parse_arch(arch_string_raw):
import re
arch, bits = None, None
arch_string_raw = arch_string_raw.lower()
# X86
if re.match('^i\d86$|^x86$|^x86_32$|^i86pc$|^ia32$|^ia-32$|^bepc$', arch_string_raw):
arch = 'X86_32'
bits = 32
elif re.match('^x64$|^x86_64$|^x86_64t$|^i686-64$|^amd64$|^ia64$|^ia-64$', arch_string_raw):
arch = 'X86_64'
bits = 64
# ARM
elif re.match('^armv8-a|aarch64$', arch_string_raw):
arch = 'ARM_8'
bits = 64
elif re.match('^armv7$|^armv7[a-z]$|^armv7-[a-z]$|^armv6[a-z]$', arch_string_raw):
arch = 'ARM_7'
bits = 32
elif re.match('^armv8$|^armv8[a-z]$|^armv8-[a-z]$', arch_string_raw):
arch = 'ARM_8'
bits = 32
# PPC
elif re.match('^ppc32$|^prep$|^pmac$|^powermac$', arch_string_raw):
arch = 'PPC_32'
bits = 32
elif re.match('^powerpc$|^ppc64$|^ppc64le$', arch_string_raw):
arch = 'PPC_64'
bits = 64
# SPARC
elif re.match('^sparc32$|^sparc$', arch_string_raw):
arch = 'SPARC_32'
bits = 32
elif re.match('^sparc64$|^sun4u$|^sun4v$', arch_string_raw):
arch = 'SPARC_64'
bits = 64
# S390X
elif re.match('^s390x$', arch_string_raw):
arch = 'S390X'
bits = 64
return (arch, bits)
def _is_bit_set(reg, bit):
mask = 1 << bit
is_set = reg & mask > 0
return is_set
def _is_selinux_enforcing():
# Just return if the SE Linux Status Tool is not installed
if not DataSource.has_sestatus():
return False
# Run the sestatus, and just return if it failed to run
returncode, output = DataSource.sestatus_b()
if returncode != 0:
return False
# Figure out if explicitly in enforcing mode
for line in output.splitlines():
line = line.strip().lower()
if line.startswith("current mode:"):
if line.endswith("enforcing"):
return True
else:
return False
# Figure out if we can execute heap and execute memory
can_selinux_exec_heap = False
can_selinux_exec_memory = False
for line in output.splitlines():
line = line.strip().lower()
if line.startswith("allow_execheap") and line.endswith("on"):
can_selinux_exec_heap = True
elif line.startswith("allow_execmem") and line.endswith("on"):
can_selinux_exec_memory = True
return (not can_selinux_exec_heap or not can_selinux_exec_memory)
class CPUID(object):
def __init__(self):
self.prochandle = None
# Figure out if SE Linux is on and in enforcing mode
self.is_selinux_enforcing = _is_selinux_enforcing()
def _asm_func(self, restype=None, argtypes=(), byte_code=[]):
byte_code = bytes.join(b'', byte_code)
address = None
if DataSource.is_windows:
# Allocate a memory segment the size of the byte code, and make it executable
size = len(byte_code)
# Alloc at least 1 page to ensure we own all pages that we want to change protection on
if size < 0x1000: size = 0x1000
MEM_COMMIT = ctypes.c_ulong(0x1000)
PAGE_READWRITE = ctypes.c_ulong(0x4)
pfnVirtualAlloc = ctypes.windll.kernel32.VirtualAlloc
pfnVirtualAlloc.restype = ctypes.c_void_p
address = pfnVirtualAlloc(None, ctypes.c_size_t(size), MEM_COMMIT, PAGE_READWRITE)
if not address:
raise Exception("Failed to VirtualAlloc")
# Copy the byte code into the memory segment
memmove = ctypes.CFUNCTYPE(ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_size_t)(ctypes._memmove_addr)
if memmove(address, byte_code, size) < 0:
raise Exception("Failed to memmove")
# Enable execute permissions
PAGE_EXECUTE = ctypes.c_ulong(0x10)
old_protect = ctypes.c_ulong(0)
pfnVirtualProtect = ctypes.windll.kernel32.VirtualProtect
res = pfnVirtualProtect(ctypes.c_void_p(address), ctypes.c_size_t(size), PAGE_EXECUTE, ctypes.byref(old_protect))
if not res:
raise Exception("Failed VirtualProtect")
# Flush Instruction Cache
# First, get process Handle
if not self.prochandle:
pfnGetCurrentProcess = ctypes.windll.kernel32.GetCurrentProcess
pfnGetCurrentProcess.restype = ctypes.c_void_p
self.prochandle = ctypes.c_void_p(pfnGetCurrentProcess())
# Actually flush cache
res = ctypes.windll.kernel32.FlushInstructionCache(self.prochandle, ctypes.c_void_p(address), ctypes.c_size_t(size))
if not res:
raise Exception("Failed FlushInstructionCache")
else:
# Allocate a memory segment the size of the byte code
size = len(byte_code)
pfnvalloc = ctypes.pythonapi.valloc
pfnvalloc.restype = ctypes.c_void_p
address = pfnvalloc(ctypes.c_size_t(size))
if not address:
raise Exception("Failed to valloc")
# Mark the memory segment as writeable only
if not self.is_selinux_enforcing:
WRITE = 0x2
if ctypes.pythonapi.mprotect(ctypes.c_void_p(address), size, WRITE) < 0:
raise Exception("Failed to mprotect")
# Copy the byte code into the memory segment
if ctypes.pythonapi.memmove(ctypes.c_void_p(address), byte_code, ctypes.c_size_t(size)) < 0:
raise Exception("Failed to memmove")
# Mark the memory segment as writeable and executable only
if not self.is_selinux_enforcing:
WRITE_EXECUTE = 0x2 | 0x4
if ctypes.pythonapi.mprotect(ctypes.c_void_p(address), size, WRITE_EXECUTE) < 0:
raise Exception("Failed to mprotect")
# Cast the memory segment into a function
functype = ctypes.CFUNCTYPE(restype, *argtypes)
fun = functype(address)
return fun, address
def _run_asm(self, *byte_code):
# Convert the byte code into a function that returns an int
restype = ctypes.c_uint32
argtypes = ()
func, address = self._asm_func(restype, argtypes, byte_code)
# Call the byte code like a function
retval = func()
byte_code = bytes.join(b'', byte_code)
size = ctypes.c_size_t(len(byte_code))
# Free the function memory segment
if DataSource.is_windows:
MEM_RELEASE = ctypes.c_ulong(0x8000)
ctypes.windll.kernel32.VirtualFree(ctypes.c_void_p(address), ctypes.c_size_t(0), MEM_RELEASE)
else:
# Remove the executable tag on the memory
READ_WRITE = 0x1 | 0x2
if ctypes.pythonapi.mprotect(ctypes.c_void_p(address), size, READ_WRITE) < 0:
raise Exception("Failed to mprotect")
ctypes.pythonapi.free(ctypes.c_void_p(address))
return retval
# http://en.wikipedia.org/wiki/CPUID#EAX.3D0:_Get_vendor_ID
def get_vendor_id(self):
# EBX
ebx = self._run_asm(
b"\x31\xC0", # xor eax,eax
b"\x0F\xA2" # cpuid
b"\x89\xD8" # mov ax,bx
b"\xC3" # ret
)
# ECX
ecx = self._run_asm(
b"\x31\xC0", # xor eax,eax
b"\x0f\xa2" # cpuid
b"\x89\xC8" # mov ax,cx
b"\xC3" # ret
)
# EDX
edx = self._run_asm(
b"\x31\xC0", # xor eax,eax
b"\x0f\xa2" # cpuid
b"\x89\xD0" # mov ax,dx
b"\xC3" # ret
)
# Each 4bits is a ascii letter in the name
vendor_id = []
for reg in [ebx, edx, ecx]:
for n in [0, 8, 16, 24]:
vendor_id.append(chr((reg >> n) & 0xFF))
vendor_id = ''.join(vendor_id)
return vendor_id
# http://en.wikipedia.org/wiki/CPUID#EAX.3D1:_Processor_Info_and_Feature_Bits
def get_info(self):
# EAX
eax = self._run_asm(
b"\xB8\x01\x00\x00\x00", # mov eax,0x1"
b"\x0f\xa2" # cpuid
b"\xC3" # ret
)
# Get the CPU info
stepping = (eax >> 0) & 0xF # 4 bits
model = (eax >> 4) & 0xF # 4 bits
family = (eax >> 8) & 0xF # 4 bits
processor_type = (eax >> 12) & 0x3 # 2 bits
extended_model = (eax >> 16) & 0xF # 4 bits
extended_family = (eax >> 20) & 0xFF # 8 bits
return {
'stepping' : stepping,
'model' : model,
'family' : family,
'processor_type' : processor_type,
'extended_model' : extended_model,
'extended_family' : extended_family
}
# http://en.wikipedia.org/wiki/CPUID#EAX.3D80000000h:_Get_Highest_Extended_Function_Supported
def get_max_extension_support(self):
# Check for extension support
max_extension_support = self._run_asm(
b"\xB8\x00\x00\x00\x80" # mov ax,0x80000000
b"\x0f\xa2" # cpuid
b"\xC3" # ret
)
return max_extension_support
# http://en.wikipedia.org/wiki/CPUID#EAX.3D1:_Processor_Info_and_Feature_Bits
def get_flags(self, max_extension_support):
# EDX
edx = self._run_asm(
b"\xB8\x01\x00\x00\x00", # mov eax,0x1"
b"\x0f\xa2" # cpuid
b"\x89\xD0" # mov ax,dx
b"\xC3" # ret
)
# ECX
ecx = self._run_asm(
b"\xB8\x01\x00\x00\x00", # mov eax,0x1"
b"\x0f\xa2" # cpuid
b"\x89\xC8" # mov ax,cx
b"\xC3" # ret
)
# Get the CPU flags
flags = {
'fpu' : _is_bit_set(edx, 0),
'vme' : _is_bit_set(edx, 1),
'de' : _is_bit_set(edx, 2),
'pse' : _is_bit_set(edx, 3),
'tsc' : _is_bit_set(edx, 4),
'msr' : _is_bit_set(edx, 5),
'pae' : _is_bit_set(edx, 6),
'mce' : _is_bit_set(edx, 7),
'cx8' : _is_bit_set(edx, 8),
'apic' : _is_bit_set(edx, 9),
#'reserved1' : _is_bit_set(edx, 10),
'sep' : _is_bit_set(edx, 11),
'mtrr' : _is_bit_set(edx, 12),
'pge' : _is_bit_set(edx, 13),
'mca' : _is_bit_set(edx, 14),
'cmov' : _is_bit_set(edx, 15),
'pat' : _is_bit_set(edx, 16),
'pse36' : _is_bit_set(edx, 17),
'pn' : _is_bit_set(edx, 18),
'clflush' : _is_bit_set(edx, 19),
#'reserved2' : _is_bit_set(edx, 20),
'dts' : _is_bit_set(edx, 21),
'acpi' : _is_bit_set(edx, 22),
'mmx' : _is_bit_set(edx, 23),
'fxsr' : _is_bit_set(edx, 24),
'sse' : _is_bit_set(edx, 25),
'sse2' : _is_bit_set(edx, 26),
'ss' : _is_bit_set(edx, 27),
'ht' : _is_bit_set(edx, 28),
'tm' : _is_bit_set(edx, 29),
'ia64' : _is_bit_set(edx, 30),
'pbe' : _is_bit_set(edx, 31),
'pni' : _is_bit_set(ecx, 0),
'pclmulqdq' : _is_bit_set(ecx, 1),
'dtes64' : _is_bit_set(ecx, 2),
'monitor' : _is_bit_set(ecx, 3),
'ds_cpl' : _is_bit_set(ecx, 4),
'vmx' : _is_bit_set(ecx, 5),
'smx' : _is_bit_set(ecx, 6),
'est' : _is_bit_set(ecx, 7),
'tm2' : _is_bit_set(ecx, 8),
'ssse3' : _is_bit_set(ecx, 9),
'cid' : _is_bit_set(ecx, 10),
#'reserved3' : _is_bit_set(ecx, 11),
'fma' : _is_bit_set(ecx, 12),
'cx16' : _is_bit_set(ecx, 13),
'xtpr' : _is_bit_set(ecx, 14),
'pdcm' : _is_bit_set(ecx, 15),
#'reserved4' : _is_bit_set(ecx, 16),
'pcid' : _is_bit_set(ecx, 17),
'dca' : _is_bit_set(ecx, 18),
'sse4_1' : _is_bit_set(ecx, 19),
'sse4_2' : _is_bit_set(ecx, 20),
'x2apic' : _is_bit_set(ecx, 21),
'movbe' : _is_bit_set(ecx, 22),
'popcnt' : _is_bit_set(ecx, 23),
'tscdeadline' : _is_bit_set(ecx, 24),
'aes' : _is_bit_set(ecx, 25),
'xsave' : _is_bit_set(ecx, 26),
'osxsave' : _is_bit_set(ecx, 27),
'avx' : _is_bit_set(ecx, 28),
'f16c' : _is_bit_set(ecx, 29),
'rdrnd' : _is_bit_set(ecx, 30),
'hypervisor' : _is_bit_set(ecx, 31)
}
# Get a list of only the flags that are true
flags = [k for k, v in flags.items() if v]
# http://en.wikipedia.org/wiki/CPUID#EAX.3D7.2C_ECX.3D0:_Extended_Features
if max_extension_support >= 7:
# EBX
ebx = self._run_asm(
b"\x31\xC9", # xor ecx,ecx
b"\xB8\x07\x00\x00\x00" # mov eax,7
b"\x0f\xa2" # cpuid
b"\x89\xD8" # mov ax,bx
b"\xC3" # ret
)
# ECX
ecx = self._run_asm(
b"\x31\xC9", # xor ecx,ecx
b"\xB8\x07\x00\x00\x00" # mov eax,7
b"\x0f\xa2" # cpuid
b"\x89\xC8" # mov ax,cx
b"\xC3" # ret
)
# Get the extended CPU flags
extended_flags = {
#'fsgsbase' : _is_bit_set(ebx, 0),
#'IA32_TSC_ADJUST' : _is_bit_set(ebx, 1),
'sgx' : _is_bit_set(ebx, 2),
'bmi1' : _is_bit_set(ebx, 3),
'hle' : _is_bit_set(ebx, 4),
'avx2' : _is_bit_set(ebx, 5),
#'reserved' : _is_bit_set(ebx, 6),
'smep' : _is_bit_set(ebx, 7),
'bmi2' : _is_bit_set(ebx, 8),
'erms' : _is_bit_set(ebx, 9),
'invpcid' : _is_bit_set(ebx, 10),
'rtm' : _is_bit_set(ebx, 11),
'pqm' : _is_bit_set(ebx, 12),
#'FPU CS and FPU DS deprecated' : _is_bit_set(ebx, 13),
'mpx' : _is_bit_set(ebx, 14),
'pqe' : _is_bit_set(ebx, 15),
'avx512f' : _is_bit_set(ebx, 16),
'avx512dq' : _is_bit_set(ebx, 17),
'rdseed' : _is_bit_set(ebx, 18),
'adx' : _is_bit_set(ebx, 19),
'smap' : _is_bit_set(ebx, 20),
'avx512ifma' : _is_bit_set(ebx, 21),
'pcommit' : _is_bit_set(ebx, 22),