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freebsd_api.py
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freebsd_api.py
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"""
Author: Armon Dadgar
Start Date: April 7th, 2009
Description:
This file provides a python interface to low-level system call on the Linux platform.
It is designed to abstract away the C-level detail and provide a high-level method of doing
common management tasks.
"""
import ctypes # Allows us to make C calls
import ctypes.util # Helps to find the C library
import os # Provides some convenience functions
import time # Provides time.time
import freebsd_kinfo # Imports the kinfo structure, along with others
import nix_common_api as nix_api # Import the Common API
import textops # Import the seattlelib textops library
import portable_popen # Import for Popen
# Manually import the common functions we want
exists_outgoing_network_socket = nix_api.exists_outgoing_network_socket
exists_listening_network_socket = nix_api.exists_listening_network_socket
get_available_interfaces = nix_api.get_available_interfaces
get_ctypes_errno = nix_api.get_ctypes_errno
get_ctypes_error_str = nix_api.get_ctypes_error_str
# Get the standard library
libc = nix_api.libc
# Globals
# Cache the last process info struct so as to avoid redundant memory allocation
# and to fetch additional info without constantly updating
last_proc_info_struct = None
last_proc_info_size = 0 # Stores the size of the struct
# Functions
_sysctl = libc.sysctl # Makes system calls
_clock_gettime = libc.clock_gettime # Get the CPU time
# Constants
CTL_KERN = 1
KERN_PROC = 14
KERN_PROC_PID = 1
FourIntegers = ctypes.c_int * 4 # A C array with 4 ints, used for syscalls
PAGE_SIZE = libc.getpagesize() # Call into libc to get our page size
KERN_BOOTTIME = 21
TwoIntegers = ctypes.c_int * 2 # C array with 2 ints
CLOCK_THREAD_CPUTIME_ID = 14 # Get the CPU time for the current thread
# Structures
kinfo_proc = freebsd_kinfo.kinfo_proc # Import from the external file
class timeval(ctypes.Structure):
_fields_ = [("tv_sec", ctypes.c_long),
("tv_usec", ctypes.c_long)]
def _get_proc_info_by_pid(pid):
"""
<Purpose>
Immediately updates the internal kinfo_proc structure.
<Arguments>
pid: The Process Identifier for which data should be retrieved
<Exceptions>
Raises an Exception if there is an error.
<Returns>
Nothing
"""
global last_proc_info_struct
global last_proc_info_size
# Create the argument array
mib = FourIntegers(CTL_KERN, KERN_PROC, KERN_PROC_PID, pid)
# Check if we need to allocate a structure
if last_proc_info_struct == None:
# Allocate a kinfo structure
last_proc_info_struct = kinfo_proc(0)
last_proc_info_size = ctypes.c_int(0)
# Make a system call without a pointer to the kinfo structure, this sets
# ths proper size of the structure for future system calls
status = _sysctl(mib, 4, None, ctypes.byref(last_proc_info_size), None, 0)
# Check the status
if status != 0:
raise Exception,"Fatal error with sysctl. Errno:"+str(get_ctypes_errno())+", Error: "+get_ctypes_error_str()
# Make the call to update
status = _sysctl(mib, 4, ctypes.byref(last_proc_info_struct), ctypes.byref(last_proc_info_size), None, 0)
# Check the status
if status != 0:
raise Exception,"Fatal error with sysctl. Errno:"+str(get_ctypes_errno())+", Error: "+get_ctypes_error_str()
def get_process_cpu_time(pid):
"""
<Purpose>
Returns the total CPU time used by a process.
<Arguments>
pid: The process identifier for the process to query.
<Exceptions>
See _get_proc_info_by_pid.
<Returns>
The total cpu time.
"""
global last_proc_info_struct
# Update the info
_get_proc_info_by_pid(pid)
# Get the rusage field in the structure
ru = last_proc_info_struct.ki_rusage
# Calculate user time and system, for the process and its children,
# divide by 1 million since the usec field is in microseconds
utime = ru.ru_utime.tv_sec + ru.ru_utime.tv_usec/1000000.0
stime = ru.ru_stime.tv_sec + ru.ru_stime.tv_usec/1000000.0
# Switch ru to the child structure
ru = last_proc_info_struct.ki_rusage_ch
utime_ch = ru.ru_utime.tv_sec + ru.ru_utime.tv_usec/1000000.0
stime_ch = ru.ru_stime.tv_sec + ru.ru_stime.tv_usec/1000000.0
# Calculate the total time
total_time = utime + stime + utime_ch + stime_ch
return total_time
def get_process_rss(force_update=False, pid=None):
"""
<Purpose>
Returns the Resident Set Size of a process. By default, this will
return the information cached by the last call to _get_proc_info_by_pid.
This call is used in get_process_cpu_time.
<Arguments>
force_update:
Allows the caller to force a data update, instead of using the cached data.
pid:
If force_update is True, this parameter must be specified to force the update.
<Exceptions>
See _get_proc_info_by_pid.
<Returns>
The RSS of the process in bytes.
"""
global last_proc_info_struct
# Check if an update is being forced
if force_update and pid != None:
# Update the info
_get_proc_info_by_pid(pid)
# Get RSS
rss_pages = last_proc_info_struct.ki_rssize
rss_bytes = rss_pages * PAGE_SIZE
return rss_bytes
# Get the CPU time of the current thread
def get_current_thread_cpu_time():
"""
<Purpose>
Gets the total CPU time for the currently executing thread.
<Exceptions>
An AssertionError will be raised if the underlying system call fails.
<Returns>
A floating amount of time in seconds.
"""
# Allocate a structure
time_struct = timeval()
# Make the system call
result = _clock_gettime(CLOCK_THREAD_CPUTIME_ID, ctypes.byref(time_struct))
# Sum up the CPU usage
cpu_time = time_struct.tv_sec + time_struct.tv_usec / 1000000000.0
# Safety check, result should be 0
# Do the safety check after we free the memory to avoid leaks
assert(result == 0)
# Return the structure
return cpu_time
# Return the timeval struct with our boottime
def _get_boottime_struct():
# Get an array with 2 elements, set the syscall parameters
mib = TwoIntegers(CTL_KERN, KERN_BOOTTIME)
# Get timeval structure, set the size
boottime = timeval()
size = ctypes.c_size_t(ctypes.sizeof(boottime))
# Make the syscall
libc.sysctl(mib, 2, ctypes.pointer(boottime), ctypes.pointer(size), None, 0)
return boottime
def get_system_uptime():
"""
<Purpose>
Returns the system uptime.
<Returns>
The system uptime.
"""
# Get the boot time struct
boottime = _get_boottime_struct()
# Calculate uptime from current time
uptime = time.time() - boottime.tv_sec+boottime.tv_usec*1.0e-6
return uptime
def get_uptime_granularity():
"""
<Purpose>
Determines the granularity of the get_system_uptime call.
<Returns>
A numerical representation of the minimum granularity.
E.g. 2 digits of granularity would return 0.01
"""
# Get the boot time struct
boottime = _get_boottime_struct()
# Check if the number of nano seconds is 0
if boottime.tv_usec == 0:
granularity = 0
else:
# Convert nanoseconds to string
nanosecondstr = str(boottime.tv_usec)
# Justify with 0's to 9 digits
nanosecondstr = nanosecondstr.rjust(9,"0")
# Strip the 0's on the other side
nanosecondstr = nanosecondstr.rstrip("0")
# Get granularity from the length of the string
granularity = len(nanosecondstr)
# Convert granularity to a number
return pow(10, 0-granularity)
def get_system_thread_count():
"""
<Purpose>
Returns the number of active threads running on the system.
<Returns>
The thread count.
"""
# Use PS since it is can get the info for us
process = portable_popen.Popen(["ps", "axH"])
ps_output, _ = process.communicate()
# Subtract 1 from the number of lines because the first line is a a table
# header: " PID TTY STAT TIME COMMAND"
threads = len(textops.textops_rawtexttolines(ps_output)) - 1
return threads
def get_interface_ip_addresses(interfaceName):
"""
<Purpose>
Returns the IP address associated with the interface.
<Arguments>
interfaceName: The string name of the interface, e.g. eth0
<Returns>
A list of IP addresses associated with the interface.
"""
# Launch up a shell, get the feed back
# We use ifconfig with the interface name.
ifconfig_process = portable_popen.Popen(["/sbin/ifconfig", interfaceName.strip()])
ifconfig_output, _ = ifconfig_process.communicate()
ifconfig_lines = textops.textops_rawtexttolines(ifconfig_output)
# Look for ipv4 addresses
target_lines = textops.textops_grep("inet", ifconfig_lines)
# and not ipv6
target_lines = textops.textops_grep("inet6", target_lines, exclude=True)
# Only take the ip(s)
target_lines = textops.textops_cut(target_lines, delimiter=" ", fields=[1])
# Create an array for the ip's
ipaddressList = []
for line in target_lines:
# Strip the newline and any spacing
line = line.strip("\n\t ")
ipaddressList.append(line)
# Done, return the interfaces
return ipaddressList