test_common.py

#!/usr/bin/env python3

import os
import re
import sys
import time
import fcntl
import struct
import serial
import socket
import subprocess


def eprint(*args, **kargs):
    print(*args, file=sys.stderr, **kargs)


class DeviceUnderTest:
    def __init__(self):
        pass

    def flash(self):
        """
        This method should be overridden to flash the DUT.
        """
        pass

    def dump_ram(self):
        """
        This should be overridden to return the RAM dump as a bytes string.
        """
        return None


class DeviceUnderTestAeadUARTP(DeviceUnderTest):
    def __init__(self, ser=None):
        self.ser = ser

    def prepare(self):
        exp_hello = b"Hello, World!"
        hello = self.ser.read(13)

        if hello[-13:] != exp_hello:
            time.sleep(2)
            hello += self.ser.read(self.ser.in_waiting)

        if hello[-13:] != exp_hello:
            raise Exception(
                "Improper board initialization message: %s" % hello)
        self.uartp = UARTP(self.ser)

    def send_var(self, key, value):
        self.uartp.send(struct.pack("B", key) + value)
        ack = self.uartp.recv()
        if len(ack) != 1 or ack[0] != key:
            raise Exception("Unacknowledged variable transfer")

    def obtain_var(self, key):
        c = struct.pack("B", key)
        self.uartp.send(c)
        v = self.uartp.recv()
        if len(v) < 1 or v[0] != key:
            raise Exception("Could not obtain variable from board")
        return v[1:]

    def do_cmd(self, action):
        c = struct.pack("B", action)
        self.uartp.send(c)
        ack = self.uartp.recv()
        if len(ack) != 1 or ack[0] != action:
            raise Exception("Unacknowledged command")


class UARTP:
    def __init__(self, ser):
        UARTP.SYN = 0xf9
        UARTP.FIN = 0xf3
        self.ser = ser

    def uart_read(self):
        r = self.ser.read(1)
        if len(r) != 1:
            raise Exception("Serial read error")
        return r[0]

    def uart_write(self, c):
        b = struct.pack("B", c)
        r = self.ser.write(b)
        if r != len(b):
            raise Exception("Serial write error")
        return r

    def send(self, buf):
        self.uart_write(UARTP.SYN)
        len_ind_0 = 0xff & len(buf)
        len_ind_1 = 0xff & (len(buf) >> 7)
        if len(buf) < 128:
            self.uart_write(len_ind_0)
        else:
            self.uart_write(len_ind_0 | 0x80)
            self.uart_write(len_ind_1)
        fcs = 0
        for i in range(len(buf)):
            info = buf[i]
            fcs = (fcs + info) & 0xff
            self.uart_write(buf[i])
        fcs = (0xff - fcs) & 0xff
        self.uart_write(fcs)
        self.uart_write(UARTP.FIN)
        # eprint("sent frame '%s'" % buf.hex())

    def recv(self):
        tag_old = UARTP.FIN
        while 1:
            tag = tag_old
            while 1:
                if tag_old == UARTP.FIN:
                    if tag == UARTP.SYN:
                        break
                tag_old = tag
                tag = self.uart_read()
            tag_old = tag

            pkt = self.uart_read()
            if pkt & 0x80:
                pkt &= 0x7f
                pkt |= self.uart_read() << 7

            fcs = 0
            buf = []
            for i in range(pkt):
                info = self.uart_read()
                buf.append(info)
                fcs = (fcs + info) & 0xff
            fcs = (fcs + self.uart_read()) & 0xff

            tag = self.uart_read()
            if fcs == 0xff:
                if tag == UARTP.FIN:
                    buf = bytes(buf)
                    # eprint("rcvd frame '%s'" % buf.hex())
                    if len(buf) >= 1 and buf[0] == 0xde:
                        sys.stderr.buffer.write(buf[1:])
                        sys.stderr.flush()
                    else:
                        return buf


def run_nist_aead_test_line(dut, i, m, ad, k, npub, c):
    eprint()
    eprint("Count = %d" % i)
    eprint("   m = %s" % m.hex())
    eprint("  ad = %s" % ad.hex())
    eprint("npub = %s" % npub.hex())
    eprint("   k = %s" % k.hex())
    eprint("   c = %s" % c.hex())

    dut.send_var(ord('c'), b"\0" * (len(m) + 32))
    dut.send_var(ord('s'), b"")

    dut.send_var(ord('m'), m)
    dut.send_var(ord('a'), ad)
    dut.send_var(ord('k'), k)
    dut.send_var(ord('p'), npub)

    dut.do_cmd(ord('e'))
    output = dut.obtain_var(ord('C'))
    print("   c = %s" % output.hex())
    if c != output:
        raise Exception("output of encryption is different from " +
                        "expected ciphertext")

    dut.send_var(ord('m'), b"\0" * len(c))
    dut.send_var(ord('s'), b"")

    dut.send_var(ord('c'), c)
    dut.send_var(ord('a'), ad)
    dut.send_var(ord('k'), k)
    dut.send_var(ord('p'), npub)

    dut.do_cmd(ord('d'))
    output = dut.obtain_var(ord('M'))
    print("   m = %s" % output.hex())
    if m != output:
        raise Exception("output of encryption is different from " +
                        "expected ciphertext")


def compare_dumps(dump_a, dump_b):
    """
    Gets the length of the longes streaks of equal bytes in two RAM dumps
    """
    streaks = []
    streak_beg = 0
    streak_end = 0
    for i in range(len(dump_a)):
        if dump_a[i] == dump_b[i]:
            streak_end = i
        else:
            if streak_end != streak_beg:
                streaks.append((streak_beg, streak_end))
            streak_beg = i
            streak_end = i

    for b, e in streaks:
        eprint("equal bytes from 0x%x to 0x%x (length: %d)" %
               (b, e, e-b))

    b, e = max(streaks, key=lambda a: a[1]-a[0])
    eprint(
        "longest equal bytes streak from 0x%x to 0x%x (length: %d)" %
        (b, e, e-b))
    return e-b


def parse_nist_aead_test_vectors(test_file_path):
    with open(test_file_path, 'r') as test_file:
        lineprog = re.compile(
            r"^\s*([A-Z]+)\s*=\s*(([0-9a-f])*)\s*$",
            re.IGNORECASE)
        m = b""
        ad = b""
        k = b""
        npub = b""
        c = b""
        i = -1
        for line in test_file.readlines():
            line = line.strip()
            res = lineprog.match(line)
            if line == "":
                yield i, m, ad, k, npub, c
                m = b""
                ad = b""
                k = b""
                npub = b""
                c = b""
            elif res is not None:
                if res[1].lower() == 'count':
                    i = int(res[2], 10)
                elif res[1].lower() == 'key':
                    k = bytes.fromhex(res[2])
                elif res[1].lower() == 'nonce':
                    npub = bytes.fromhex(res[2])
                elif res[1].lower() == 'pt':
                    m = bytes.fromhex(res[2])
                elif res[1].lower() == 'ad':
                    ad = bytes.fromhex(res[2])
                elif res[1].lower() == 'ct':
                    c = bytes.fromhex(res[2])
                else:
                    raise Exception(
                        "ERROR: unparsed line in test vectors file: '%s'"
                        % res)
            else:
                raise Exception(
                    "ERROR: unparsed line in test vectors file: '%s'" % line)


class TimeMeasurementTool:
    def begin_measurement(self):
        pass

    def arm(self):
        pass

    def unarm(self):
        pass

    def end_measurement(self):
        pass


class LogicMultiplexerTimeMeasurements(TimeMeasurementTool):

    def __init__(self, mask=0xffffffffffffffff):
        self.mask = mask
        self.sock = None
        self.capture = []

    def recv_samples(self):
        import socket

        capture = []
        while 1:
            try:
                rcvd = self.sock.recv(16)
            except socket.timeout:
                break
            except BlockingIOError:
                break
            if len(rcvd) != 16:
                raise Exception("Could not receive 16 bytes of logic sample!")

            time, value = struct.unpack("<dQ", rcvd)
            eprint("%16.10f: %016x" % (time, value))
            capture.append((time, value))
        return capture

    def begin_measurement(self):
        import socket

        server_addr = os.path.expandvars('$XDG_RUNTIME_DIR/lwc-logic-socket')
        self.sock = socket.socket(socket.AF_UNIX, socket.SOCK_STREAM)
        self.sock.settimeout(0)
        self.server_addr = server_addr
        self.sock.connect(self.server_addr)
        self.sock.send(struct.pack("<Q", self.mask))

    def arm(self):
        self.capture.extend(self.recv_samples())

    def unarm(self):
        self.capture.extend(self.recv_samples())

    def end_measurement(self):
        time.sleep(1)
        self.capture.extend(self.recv_samples())
        self.sock.close()


class SaleaeTimeMeasurements(TimeMeasurementTool):
    __slots__ = ['sal']

    def __init__(self, channels=[0, 1]):
        import saleae
        sal = saleae.Saleae()
        sal.set_active_channels(self.channels, [])
        sal.set_sample_rate(sal.get_all_sample_rates()[0])
        sal.set_capture_seconds(6000)
        self.sal = sal

    def begin_measurement(self):
        # Channel 0 is reset
        # Channel 1 is crypto_busy
        import time
        sal = self.sal

        sal.capture_start()
        time.sleep(1)
        if sal.is_processing_complete():
            raise Exception("Capture didn't start successfully")

    def end_measurement(self):
        import time
        sal = self.sal

        if sal.is_processing_complete():
            raise Exception("Capture finished before expected")
        time.sleep(1)
        sal.capture_stop()
        time.sleep(.1)
        for attempt in range(3):
            if not sal.is_processing_complete():
                print("Waiting for capture to complete...")
                time.sleep(1)
                continue
            outfile = "measurement_%s.csv" % time.strftime("%Y%m%d-%H%M%S")
            outfile = os.path.join("measurements", outfile)
            if os.path.isfile(outfile):
                os.unlink(outfile)
            sal.export_data2(os.path.abspath(outfile))
            print("Measurements written to '%s'" % outfile)
            mdbfile = os.path.join("measurements", "measurements.txt")
            mdbfile = open(mdbfile, "a")
            mdbfile.write("%s > %s\n" % (' '.join(sys.argv), outfile))
            mdbfile.close()
            return 0
        raise Exception("Capture didn't complete successfully")


def main(argv):
    if len(argv) < 3:
        print("Usage: test_common.py port LWC_AEAD_KAT.txt")

    eprint(argv[0])
    script_dir = os.path.split(argv[0])[0]
    if len(script_dir) > 0:
        os.chdir(script_dir)

    kat = list(parse_nist_aead_test_vectors(argv[2]))

    dev = argv[1]
    ser = serial.Serial(dev, baudrate=115200, timeout=5)
    dut = DeviceUnderTestAeadUARTP(ser)

    try:
        tool = SaleaeTimeMeasurements()
        tool.begin_measurement()
        dut.flash()
        eprint("Flashed")
        dut.prepare()
        eprint("Prepared")
        sys.stdout.write("Hello, World!\n")
        sys.stdout.flush()

        dump_a = dut.dump_ram()

        for i, m, ad, k, npub, c in kat:
            tool.arm()
            run_nist_aead_test_line(dut, i, m, ad, k, npub, c)
            tool.unarm()

            if dump_a is not None and i == 1:
                dump_b = dut.dump_ram()
                longest = compare_dumps(dump_a, dump_b)
                print("  longest chunk of untouched memory = %d" % longest)

    except Exception as ex:
        print("TEST FAILED")
        raise ex

    finally:
        tool.end_measurement()
        sys.stdout.flush()
        sys.stderr.flush()


class FileMutex:
    def __init__(self, lock_path):
        self.lock_path = lock_path
        self.locked = False
        self.lock_fd = None
        eprint("Locking %s mutex" % lock_path)
        self.lock_fd = open(lock_path, 'w')
        fcntl.lockf(self.lock_fd, fcntl.LOCK_EX)
        self.locked = True
        print('%d' % os.getpid(), file=self.lock_fd)
        self.lock_fd.flush()
        eprint("%s mutex locked." % lock_path)

    def __del__(self):
        if not self.locked:
            return
        eprint("Releasing %s mutex" % self.lock_path)
        self.lock_fd.close()
        self.locked = False
        eprint("%s mutex released." % self.lock_path)


class OpenOcd:

    def __init__(self, config_file, tcl_port=6666, verbose=False):
        self.verbose = verbose
        self.tclRpcIp = "127.0.0.1"
        self.tclRpcPort = tcl_port
        self.bufferSize = 4096

        self.process = subprocess.Popen([
            'openocd',
            '-f', config_file,
            '-c', 'tcl_port %d' % tcl_port,
            '-c', 'gdb_port disabled',
            '-c', 'telnet_port disabled',
            ], stderr=sys.stderr, stdout=sys.stderr)
        self.sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
        while 1:
            try:
                self.sock.connect((self.tclRpcIp, self.tclRpcPort))
                break
            except Exception:
                time.sleep(.1)

    def __del__(self):
        self.send('exit')
        self.sock.close()
        self.process.kill()
        time.sleep(.1)
        self.process.send_signal(9)

    def send(self, cmd):
        """
        Send a command string to TCL RPC. Return the result that was read.
        """
        data = cmd.encode('ascii')
        if self.verbose:
            print("<- ", data)

        self.sock.send(data + b"\x1a")
        res = self._recv()
        return res

    def _recv(self):
        """
        Read from the stream until the token (\x1a) was received.
        """
        data = b''
        while len(data) < 1 or data[-1] != 0x1a:
            chunk = self.sock.recv(self.bufferSize)
            data += chunk
        data = data[:-1]  # strip trailing \x1a

        if self.verbose:
            print("-> ", data)

        return data.decode('ascii')


if __name__ == "__main__":
    sys.exit(main(sys.argv))