path: root/src/target/trx_toolkit/data_msg.py

# -*- coding: utf-8 -*-

# TRX Toolkit
# DATA interface message definitions and helpers
#
# (C) 2018-2019 by Vadim Yanitskiy <axilirator@gmail.com>
#
# All Rights Reserved
#
# This program is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 2 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
# GNU General Public License for more details.

import random
import struct
import abc

from typing import List
from enum import Enum
from gsm_shared import *

class Modulation(Enum):
	""" Modulation types defined in 3GPP TS 45.002 """
	ModGMSK		= (0b0000, 1 * GMSK_BURST_LEN)
	Mod8PSK		= (0b0100, 3 * GMSK_BURST_LEN)
	ModGMSK_AB	= (0b0110, 1 * GMSK_BURST_LEN)
	# ModRFU	= (0b0111, 0) # Reserved for Future Use
	Mod16QAM	= (0b1000, 4 * GMSK_BURST_LEN)
	Mod32QAM	= (0b1010, 5 * GMSK_BURST_LEN)
	ModAQPSK	= (0b1100, 2 * GMSK_BURST_LEN)

	def __init__(self, coding, bl):
		# Coding in TRXD header
		self.coding = coding
		# Burst length
		self.bl = bl

	@classmethod
	def pick(self, coding):
		for mod in list(self):
			if mod.coding == coding:
				return mod
		return None

	@classmethod
	def pick_by_bl(self, bl):
		for mod in list(self):
			if mod.bl == bl:
				return mod
		return None

class Msg(abc.ABC):
	''' TRXD (DATA) message coding API (common part). '''

	# NOTE: up to 16 versions can be encoded
	CHDR_VERSION_MAX = 0b1111
	KNOWN_VERSIONS = (0, 1)

	def __init__(self, fn = None, tn = None, burst = None, ver = 0):
		self.burst = burst
		self.ver = ver
		self.fn = fn
		self.tn = tn

	@property
	def CHDR_LEN(self):
		''' The common header length. '''
		return 1 + 4 # (VER + TN) + FN

	@abc.abstractmethod
	def gen_hdr(self):
		''' Generate message specific header. '''

	@abc.abstractmethod
	def parse_hdr(self, hdr):
		''' Parse message specific header. '''

	@abc.abstractmethod
	def gen_burst(self):
		''' Generate message specific burst. '''

	@abc.abstractmethod
	def parse_burst(self, burst):
		''' Parse message specific burst. '''

	@abc.abstractmethod
	def rand_burst(self):
		''' Generate a random message specific burst. '''

	def rand_fn(self):
		''' Generate a random frame number. '''
		return random.randint(0, GSM_HYPERFRAME)

	def rand_tn(self):
		''' Generate a random timeslot number. '''
		return random.randint(0, 7)

	def rand_hdr(self):
		''' Randomize the message header. '''
		self.fn = self.rand_fn()
		self.tn = self.rand_tn()

	def desc_hdr(self):
		''' Generate human-readable header description. '''

		result = ""

		if self.ver > 0:
			result += ("ver=%u " % self.ver)

		if self.fn is not None:
			result += ("fn=%u " % self.fn)

		if self.tn is not None:
			result += ("tn=%u " % self.tn)

		if self.burst is not None and len(self.burst) > 0:
			result += ("bl=%u " % len(self.burst))

		return result

	@staticmethod
	def usbit2sbit(bits: List[int]) -> List[int]:
		''' Convert unsigned soft-bits {254..0} to soft-bits {-127..127}. '''
		return [-127 if (b == 0xff) else 127 - b for b in bits]

	@staticmethod
	def sbit2usbit(bits: List[int]) -> List[int]:
		''' Convert soft-bits {-127..127} to unsigned soft-bits {254..0}. '''
		return [127 - b for b in bits]

	@staticmethod
	def sbit2ubit(bits: List[int]) -> List[int]:
		''' Convert soft-bits {-127..127} to bits {1..0}. '''
		return [int(b < 0) for b in bits]

	@staticmethod
	def ubit2sbit(bits: List[int]) -> List[int]:
		''' Convert bits {1..0} to soft-bits {-127..127}. '''
		return [-127 if b else 127 for b in bits]

	def validate(self):
		''' Validate the message fields (throws ValueError). '''

		if not self.ver in self.KNOWN_VERSIONS:
			raise ValueError("Unknown TRXD header version %d" % self.ver)

		if self.fn is None:
			raise ValueError("TDMA frame-number is not set")

		if self.fn < 0 or self.fn > GSM_HYPERFRAME:
			raise ValueError("TDMA frame-number %d is out of range" % self.fn)

		if self.tn is None:
			raise ValueError("TDMA time-slot is not set")

		if self.tn < 0 or self.tn > 7:
			raise ValueError("TDMA time-slot %d is out of range" % self.tn)

	def gen_msg(self, legacy = False):
		''' Generate a TRX DATA message. '''

		# Validate all the fields
		self.validate()

		# Allocate an empty byte-array
		buf = bytearray()

		# Put version (4 bits) and TDMA TN (3 bits)
		buf.append((self.ver << 4) | (self.tn & 0x07))

		# Put TDMA FN (4 octets, BE)
		buf += struct.pack(">L", self.fn)

		# Generate message specific header part
		hdr = self.gen_hdr()
		buf += hdr

		# Generate burst
		if self.burst is not None:
			buf += self.gen_burst()

		# This is a rudiment from (legacy) OpenBTS transceiver,
		# some L1 implementations still expect two dummy bytes.
		if legacy and self.ver == 0x00:
			buf += bytearray(2)

		return buf

	def parse_msg(self, msg):
		''' Parse a TRX DATA message. '''

		# Make sure we have at least common header
		if len(msg) < self.CHDR_LEN:
			raise ValueError("Message is to short: missing common header")

		# Parse the header version first
		self.ver = (msg[0] >> 4)
		if not self.ver in self.KNOWN_VERSIONS:
			raise ValueError("Unknown TRXD header version %d" % self.ver)

		# Parse TDMA TN and FN
		self.tn = (msg[0] & 0x07)
		self.fn = struct.unpack(">L", msg[1:5])[0]

		# Make sure we have the whole header,
		# including the version specific fields
		if len(msg) < self.HDR_LEN:
			raise ValueError("Message is to short: missing version specific header")

		# Specific message part
		self.parse_hdr(msg)

		# Copy burst, skipping header
		msg_burst = msg[self.HDR_LEN:]
		if len(msg_burst) > 0:
			self.parse_burst(msg_burst)
		else:
			self.burst = None

class TxMsg(Msg):
	''' Tx (L1 -> TRX) message coding API. '''

	# Constants
	PWR_MIN = 0x00
	PWR_MAX = 0xff

	# Specific message fields
	pwr = None

	@property
	def HDR_LEN(self):
		''' Calculate header length depending on its version. '''

		# Common header length
		length = self.CHDR_LEN

		# Message specific header length
		if self.ver in (0x00, 0x01):
			length += 1 # PWR
		else:
			raise IndexError("Unhandled version %u" % self.ver)

		return length

	def validate(self):
		''' Validate the message fields (throws ValueError). '''

		# Validate common fields
		Msg.validate(self)

		if self.pwr is None:
			raise ValueError("Tx Attenuation level is not set")

		if self.pwr < self.PWR_MIN or self.pwr > self.PWR_MAX:
			raise ValueError("Tx Attenuation %d is out of range" % self.pwr)

		# FIXME: properly handle IDLE / NOPE indications
		if self.burst is None:
			raise ValueError("Tx burst bits are not set")

		# FIXME: properly handle IDLE / NOPE indications
		if len(self.burst) not in (GMSK_BURST_LEN, EDGE_BURST_LEN):
			raise ValueError("Tx burst has odd length %u" % len(self.burst))

	def rand_pwr(self, min = None, max = None):
		''' Generate a random power level. '''

		if min is None:
			min = self.PWR_MIN

		if max is None:
			max = self.PWR_MAX

		return random.randint(min, max)

	def rand_hdr(self):
		''' Randomize message specific header. '''

		Msg.rand_hdr(self)
		self.pwr = self.rand_pwr()

	def desc_hdr(self):
		''' Generate human-readable header description. '''

		# Describe the common part
		result = Msg.desc_hdr(self)

		if self.pwr is not None:
			result += ("pwr=%u " % self.pwr)

		# Strip useless whitespace and return
		return result.strip()

	def gen_hdr(self):
		''' Generate message specific header part. '''

		# Allocate an empty byte-array
		buf = bytearray()

		# Put power
		buf.append(self.pwr)

		return buf

	def parse_hdr(self, hdr):
		''' Parse message specific header part. '''

		# Parse power level
		self.pwr = hdr[5]

	def gen_burst(self):
		''' Generate message specific burst. '''

		# Copy burst 'as is'
		return bytearray(self.burst)

	def parse_burst(self, burst):
		''' Parse message specific burst. '''

		length = len(burst)

		# Distinguish between GSM and EDGE
		if length >= EDGE_BURST_LEN:
			self.burst = list(burst[:EDGE_BURST_LEN])
		else:
			self.burst = list(burst[:GMSK_BURST_LEN])

	def rand_burst(self, length = GMSK_BURST_LEN):
		''' Generate a random message specific burst. '''
		self.burst = [random.randint(0, 1) for _ in range(length)]

	def trans(self, ver = None):
		''' Transform this message into RxMsg. '''

		# Allocate a new message
		msg = RxMsg(fn = self.fn, tn = self.tn,
			ver = self.ver if ver is None else ver)

		# Convert burst bits
		if self.burst is not None:
			msg.burst = self.ubit2sbit(self.burst)
		else:
			msg.nope_ind = True

		return msg

class RxMsg(Msg):
	''' Rx (TRX -> L1) message coding API. '''

	# rxlev2dbm(0..63) gives us [-110..-47], plus -10 dbm for noise
	RSSI_MIN = -120
	RSSI_MAX = -47

	# Min and max values of int16_t
	TOA256_MIN = -32768
	TOA256_MAX = 32767

	# TSC (Training Sequence Code) range
	TSC_RANGE = range(0, 8)

	# C/I range (in centiBels)
	CI_MIN = -1280
	CI_MAX = 1280

	# IDLE frame / nope detection indicator
	NOPE_IND = (1 << 7)

	# Specific message fields
	rssi = None
	toa256 = None

	# Version 0x01 specific (default values)
	mod_type = Modulation.ModGMSK
	nope_ind = False

	tsc_set = None
	tsc = None
	ci = None

	@property
	def HDR_LEN(self):
		''' Calculate header length depending on its version. '''

		# Common header length
		length = self.CHDR_LEN

		# Message specific header length
		if self.ver == 0x00:
			# RSSI + ToA
			length += 1 + 2
		elif self.ver == 0x01:
			# RSSI + ToA + TS + C/I
			length += 1 + 2 + 1 + 2
		else:
			raise IndexError("Unhandled version %u" % self.ver)

		return length

	def _validate_burst_v0(self):
		# Burst is mandatory
		if self.burst is None:
			raise ValueError("Rx burst bits are not set")

		# ... and can be either of GSM (GMSK) or EDGE (8-PSK)
		if len(self.burst) not in (GMSK_BURST_LEN, EDGE_BURST_LEN):
			raise ValueError("Rx burst has odd length %u" % len(self.burst))

	def _validate_burst_v1(self):
		# Burst is omitted in case of an IDLE / NOPE indication
		if self.nope_ind and self.burst is None:
			return

		if self.nope_ind and self.burst is not None:
			raise ValueError("NOPE.ind comes with burst?!?")
		if self.burst is None:
			raise ValueError("Rx burst bits are not set")

		# Burst length depends on modulation type
		if len(self.burst) != self.mod_type.bl:
			raise ValueError("Rx burst has odd length %u" % len(self.burst))

	def validate_burst(self):
		''' Validate the burst (throws ValueError). '''

		if self.ver == 0x00:
			self._validate_burst_v0()
		elif self.ver >= 0x01:
			self._validate_burst_v1()

	def validate(self):
		''' Validate the message header fields (throws ValueError). '''

		# Validate common fields
		Msg.validate(self)

		if self.rssi is None:
			raise ValueError("RSSI is not set")

		if self.rssi < self.RSSI_MIN or self.rssi > self.RSSI_MAX:
			raise ValueError("RSSI %d is out of range" % self.rssi)

		if self.toa256 is None:
			raise ValueError("ToA256 is not set")

		if self.toa256 < self.TOA256_MIN or self.toa256 > self.TOA256_MAX:
			raise ValueError("ToA256 %d is out of range" % self.toa256)

		# Version specific parameters (omited for NOPE.ind)
		if self.ver >= 0x01 and not self.nope_ind:
			if type(self.mod_type) is not Modulation:
				raise ValueError("Unknown Rx modulation type")

			if self.tsc_set is None:
				raise ValueError("TSC set is not set")

			if self.mod_type is Modulation.ModGMSK:
				if self.tsc_set not in range(0, 4):
					raise ValueError("TSC set %d is out of range" % self.tsc_set)
			else:
				if self.tsc_set not in range(0, 2):
					raise ValueError("TSC set %d is out of range" % self.tsc_set)

			if self.tsc is None:
				raise ValueError("TSC is not set")

			if self.tsc not in self.TSC_RANGE:
				raise ValueError("TSC %d is out of range" % self.tsc)

		# Version specific parameters (also present in NOPE.ind)
		if self.ver >= 0x01:
			if self.ci is None:
				raise ValueError("C/I is not set")

			if self.ci < self.CI_MIN or self.ci > self.CI_MAX:
				raise ValueError("C/I %d is out of range" % self.ci)

		self.validate_burst()

	def rand_rssi(self, min = None, max = None):
		''' Generate a random RSSI value. '''

		if min is None:
			min = self.RSSI_MIN

		if max is None:
			max = self.RSSI_MAX

		return random.randint(min, max)

	def rand_toa256(self, min = None, max = None):
		''' Generate a random ToA (Time of Arrival) value. '''

		if min is None:
			min = self.TOA256_MIN

		if max is None:
			max = self.TOA256_MAX

		return random.randint(min, max)

	def rand_hdr(self):
		''' Randomize message specific header. '''

		Msg.rand_hdr(self)
		self.rssi = self.rand_rssi()
		self.toa256 = self.rand_toa256()

		if self.ver >= 0x01:
			self.mod_type = random.choice(list(Modulation))
			if self.mod_type is Modulation.ModGMSK:
				self.tsc_set = random.randint(0, 3)
			else:
				self.tsc_set = random.randint(0, 1)
			self.tsc = random.choice(self.TSC_RANGE)

			# C/I: Carrier-to-Interference ratio
			self.ci = random.randint(self.CI_MIN, self.CI_MAX)

	def desc_hdr(self):
		''' Generate human-readable header description. '''

		# Describe the common part
		result = Msg.desc_hdr(self)

		if self.rssi is not None:
			result += ("rssi=%d " % self.rssi)

		if self.toa256 is not None:
			result += ("toa256=%d " % self.toa256)

		if self.ver >= 0x01:
			if not self.nope_ind:
				if self.mod_type is not None:
					result += ("%s " % self.mod_type)
				if self.tsc_set is not None:
					result += ("set=%u " % self.tsc_set)
				if self.tsc is not None:
					result += ("tsc=%u " % self.tsc)
				if self.ci is not None:
					result += ("C/I=%d cB " % self.ci)
			else:
				result += "(IDLE / NOPE IND) "

		# Strip useless whitespace and return
		return result.strip()

	def gen_mts(self):
		''' Encode Modulation and Training Sequence info. '''

		# IDLE / nope indication has no MTS info
		if self.nope_ind:
			return self.NOPE_IND

		# TSC: . . . . . X X X
		mts = self.tsc & 0b111

		# MTS: . X X X X . . .
		mts |= self.mod_type.coding << 3
		mts |= self.tsc_set << 3

		return mts

	def parse_mts(self, mts):
		''' Parse Modulation and Training Sequence info. '''

		# IDLE / nope indication has no MTS info
		self.nope_ind = (mts & self.NOPE_IND) > 0
		if self.nope_ind:
			self.mod_type = None
			self.tsc_set = None
			self.tsc = None
			return

		# TSC: . . . . . X X X
		self.tsc = mts & 0b111

		# MTS: . X X X X . . .
		mts = (mts >> 3) & 0b1111
		if (mts & 0b1100) > 0:
			# Mask: . . . . M M M S
			self.mod_type = Modulation.pick(mts & 0b1110)
			self.tsc_set = mts & 0b1
		else:
			# GMSK: . . . . 0 0 S S
			self.mod_type = Modulation.ModGMSK
			self.tsc_set = mts & 0b11

	def gen_hdr(self):
		''' Generate message specific header part. '''

		# Allocate an empty byte-array
		buf = bytearray()

		# Put RSSI
		buf.append(-self.rssi)

		# Encode ToA (Time of Arrival)
		# Big endian, 2 bytes (int32_t)
		buf += struct.pack(">h", self.toa256)

		if self.ver >= 0x01:
			# Modulation and Training Sequence info
			mts = self.gen_mts()
			buf.append(mts)

			# C/I: Carrier-to-Interference ratio (in centiBels)
			buf += struct.pack(">h", self.ci)

		return buf

	def parse_hdr(self, hdr):
		''' Parse message specific header part. '''

		# Parse RSSI
		self.rssi = -(hdr[5])

		# Parse ToA (Time of Arrival)
		self.toa256 = struct.unpack(">h", hdr[6:8])[0]

		if self.ver >= 0x01:
			# Modulation and Training Sequence info
			self.parse_mts(hdr[8])

			# C/I: Carrier-to-Interference ratio (in centiBels)
			self.ci = struct.unpack(">h", hdr[9:11])[0]

	def gen_burst(self):
		''' Generate message specific burst. '''

		# Convert soft-bits to unsigned soft-bits
		burst_usbits = self.sbit2usbit(self.burst)

		# Encode to bytes
		return bytearray(burst_usbits)

	def _parse_burst_v0(self, burst):
		''' Parse message specific burst for header version 0. '''

		bl = len(burst)

		# We need to guess modulation by the length of burst
		self.mod_type = Modulation.pick_by_bl(bl)
		if self.mod_type is None:
			# Some old transceivers append two dummy bytes
			self.mod_type = Modulation.pick_by_bl(bl - 2)

		if self.mod_type is None:
			raise ValueError("Odd burst length %u" % bl)

		return burst[:self.mod_type.bl]

	def parse_burst(self, burst):
		''' Parse message specific burst. '''

		burst = list(burst)

		if self.ver == 0x00:
			burst = self._parse_burst_v0(burst)

		# Convert unsigned soft-bits to soft-bits
		self.burst = self.usbit2sbit(burst)

	def rand_burst(self, length = None):
		''' Generate a random message specific burst. '''

		if length is None:
			length = self.mod_type.bl

		self.burst = [random.randint(-127, 127) for _ in range(length)]

	def trans(self, ver = None):
		''' Transform this message to TxMsg. '''

		# Allocate a new message
		msg = TxMsg(fn = self.fn, tn = self.tn,
			ver = self.ver if ver is None else ver)

		# Convert burst bits
		if self.burst is not None:
			msg.burst = self.sbit2ubit(self.burst)

		return msg