CHIRP

# Copyright 2013 Dan Smith <dsmith@danplanet.com>

#

# 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 3 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.

#

# You should have received a copy of the GNU General Public License

# along with this program. If not, see <http://www.gnu.org/licenses/>.

import os

import struct

import time

from chirp import bitwise

from chirp import chirp_common

from chirp import directory

from chirp import errors

from chirp import memmap

from chirp import util

_mem_format = """

#seekto 0x0100;

struct {

u8 even_unknown:2,

even_pskip:1,

even_skip:1,

odd_unknown:2,

odd_pskip:1,

odd_skip:1;

} flags[379];

"""

mem_format = _mem_format + """

struct memory {

bbcd freq[4];

bbcd offset[4];

u8 unknownA:4,

tune_step:4;

u8 rxdcsextra:1,

txdcsextra:1,

rxinv:1,

txinv:1,

channel_width:2,

unknownB:2;

u8 unknown8:3,

is_am:1,

power:2,

duplex:2;

u8 unknown4:4,

rxtmode:2,

txtmode:2;

u8 unknown5:2,

txtone:6;

u8 unknown6:2,

rxtone:6;

u8 txcode;

u8 rxcode;

u8 unknown7[2];

u8 unknown2[5];

char name[7];

u8 unknownZ[2];

};

#seekto 0x2000;

struct memory memory[758];

"""

class FlagObj(object):

def __init__(self, flagobj, which):

self._flagobj = flagobj

self._which = which

def _get(self, flag):

return getattr(self._flagobj, "%s_%s" % (self._which, flag))

def _set(self, flag, value):

return setattr(self._flagobj, "%s_%s" % (self._which, flag), value)

def get_skip(self):

return self._get("skip")

def set_skip(self, value):

self._set("skip", value)

skip = property(get_skip, set_skip)

def get_pskip(self):

return self._get("pskip")

def set_pskip(self, value):

self._set("pskip", value)

pskip = property(get_pskip, set_pskip)

def set(self):

self._set("unknown", 3)

self._set("skip", 1)

self._set("pskip", 1)

def clear(self):

self._set("unknown", 0)

self._set("skip", 0)

self._set("pskip", 0)

def get(self):

return (self._get("unknown") << 2 |

self._get("skip") << 1 |

self._get("pskip"))

def __repr__(self):

return repr(self._flagobj)

def _is_loc_used(memobj, loc):

return memobj.flags[loc / 2].get_raw() != "\xFF"

def _addr_to_loc(addr):

return (addr - 0x2000) / 32

def _should_send_addr(memobj, addr):

if addr < 0x2000 or addr >= 0x7EC0:

return True

else:

return _is_loc_used(memobj, _addr_to_loc(addr))

def _debug(string):

if "CHIRP_DEBUG" in os.environ or True:

print string

def _echo_write(radio, data):

try:

radio.pipe.write(data)

radio.pipe.read(len(data))

except Exception, e:

print "Error writing to radio: %s" % e

raise errors.RadioError("Unable to write to radio")

def _read(radio, length):

try:

data = radio.pipe.read(length)

except Exception, e:

print "Error reading from radio: %s" % e

raise errors.RadioError("Unable to read from radio")

if len(data) != length:

print "Short read from radio (%i, expected %i)" % (len(data),

length)

print util.hexprint(data)

raise errors.RadioError("Short read from radio")

return data

def _ident(radio):

radio.pipe.setTimeout(1)

_echo_write(radio, "PROGRAM")

response = radio.pipe.read(3)

if response != "QX\x06":

print "Response was:\n%s" % util.hexprint(response)

raise errors.RadioError("Unsupported model")

_echo_write(radio, "\x02")

response = radio.pipe.read(16)

_debug(util.hexprint(response))

if response[1:8] != "HR-2040":

print "Response was:\n%s" % util.hexprint(response)

raise errors.RadioError("Unsupported model")

def _finish(radio):

endframe = "\x45\x4E\x44"

_echo_write(radio, endframe)

result = radio.pipe.read(1)

if result != "\x06":

print "Got:\n%s" % util.hexprint(result)

raise errors.RadioError("Radio did not finish cleanly")

def _checksum(data):

cs = 0

for byte in data:

cs += ord(byte)

return cs % 256

def _send(radio, cmd, addr, length, data=None):

frame = struct.pack(">cHb", cmd, addr, length)

if data:

frame += data

frame += chr(_checksum(frame[1:]))

frame += "\x06"

_echo_write(radio, frame)

_debug("Sent:\n%s" % util.hexprint(frame))

if data:

result = radio.pipe.read(1)

if result != "\x06":

print "Ack was: %s" % repr(result)

raise errors.RadioError("Radio did not accept block at %04x" % addr)

return

result = _read(radio, length + 6)

_debug("Got:\n%s" % util.hexprint(result))

header = result[0:4]

data = result[4:-2]

ack = result[-1]

if ack != "\x06":

print "Ack was: %s" % repr(ack)

raise errors.RadioError("Radio NAK'd block at %04x" % addr)

_cmd, _addr, _length = struct.unpack(">cHb", header)

if _addr != addr or _length != _length:

print "Expected/Received:"

print " Length: %02x/%02x" % (length, _length)

print " Addr: %04x/%04x" % (addr, _addr)

raise errors.RadioError("Radio send unexpected block")

cs = _checksum(result[1:-2])

if cs != ord(result[-2]):

print "Calculated: %02x" % cs

print "Actual: %02x" % ord(result[-2])

raise errors.RadioError("Block at 0x%04x failed checksum" % addr)

return data

def _download(radio):

_ident(radio)

memobj = None

data = ""

for start, end in radio._ranges:

for addr in range(start, end, 0x10):

if memobj is not None and not _should_send_addr(memobj, addr):

block = "\xFF" * 0x10

else:

block = _send(radio, 'R', addr, 0x10)

data += block

status = chirp_common.Status()

status.cur = len(data)

status.max = end

status.msg = "Cloning from radio"

radio.status_fn(status)

if addr == 0x19F0:

memobj = bitwise.parse(_mem_format, data)

_finish(radio)

return memmap.MemoryMap(data)

def _upload(radio):

_ident(radio)

for start, end in radio._ranges:

for addr in range(start, end, 0x10):

if addr < 0x0100:

continue

if not _should_send_addr(radio._memobj, addr):

continue

block = radio._mmap[addr:addr + 0x10]

_send(radio, 'W', addr, len(block), block)

status = chirp_common.Status()

status.cur = addr

status.max = end

status.msg = "Cloning to radio"

radio.status_fn(status)

_finish(radio)

TONES = [62.5] + list(chirp_common.TONES)

TMODES = ['', 'Tone', 'DTCS']

DUPLEXES = ['', '-', '+']

MODES = ["FM", "FM", "NFM"]

@directory.register

class PolmarDB50Madio(chirp_common.CloneModeRadio,

chirp_common.ExperimentalRadio):

"""Polmar DB-50M"""

VENDOR = "Polmar"

MODEL = "DB-50M"

BAUD_RATE = 9600

# May try to mirror the OEM behavior later

_ranges = [

(0x0000, 0x8000),

]

@classmethod

def get_experimental_warning(cls):

return "FOO"

def get_features(self):

rf = chirp_common.RadioFeatures()

rf.has_bank = False

rf.has_cross = True

rf.has_tuning_step = False

rf.has_rx_dtcs = True

rf.valid_skips = ["", "S", "P"]

rf.valid_modes = ["FM", "NFM", "AM"]

rf.valid_tmodes = ['', 'Tone', 'TSQL', 'DTCS', 'Cross']

rf.valid_cross_modes = ['Tone->DTCS', 'DTCS->Tone',

'->Tone', '->DTCS', 'Tone->Tone']

rf.valid_dtcs_codes = chirp_common.ALL_DTCS_CODES

rf.valid_bands = [(136000000, 500000000)]

rf.valid_characters = chirp_common.CHARSET_UPPER_NUMERIC

rf.valid_name_length = 7

rf.memory_bounds = (1, 758)

return rf

def sync_in(self):

self._mmap = _download(self)

self.process_mmap()

def sync_out(self):

_upload(self)

def process_mmap(self):

self._memobj = bitwise.parse(mem_format, self._mmap)

def _get_memobjs(self, number):

number -= 1

_mem = self._memobj.memory[number]

_flg = FlagObj(self._memobj.flags[number / 2],

number % 2 and "even" or "odd")

return _mem, _flg

def _get_dcs_index(self, _mem, which):

base = getattr(_mem, '%scode' % which)

extra = getattr(_mem, '%sdcsextra' % which)

return (int(extra) << 8) | int(base)

def _set_dcs_index(self, _mem, which, index):

base = getattr(_mem, '%scode' % which)

extra = getattr(_mem, '%sdcsextra' % which)

base.set_value(index & 0xFF)

extra.set_value(index >> 8)

def get_raw_memory(self, number):

_mem, _flg = self._get_memobjs(number)

return repr(_mem) + repr(_flg)

def get_memory(self, number):

_mem, _flg = self._get_memobjs(number)

mem = chirp_common.Memory()

mem.number = number

if _flg.get() == 0x0F:

mem.empty = True

return mem

mem.freq = int(_mem.freq) * 100

mem.offset = int(_mem.offset) * 100

mem.name = str(_mem.name).rstrip()

mem.duplex = DUPLEXES[_mem.duplex]

mem.mode = _mem.is_am and "AM" or MODES[_mem.channel_width]

rxtone = txtone = None

rxmode = TMODES[_mem.rxtmode]

txmode = TMODES[_mem.txtmode]

if txmode == "Tone":

txtone = TONES[_mem.txtone]

elif txmode == "DTCS":

txtone = chirp_common.ALL_DTCS_CODES[self._get_dcs_index(_mem,

'tx')]

if rxmode == "Tone":

rxtone = TONES[_mem.rxtone]

elif rxmode == "DTCS":

rxtone = chirp_common.ALL_DTCS_CODES[self._get_dcs_index(_mem,

'rx')]

rxpol = _mem.rxinv and "R" or "N"

txpol = _mem.txinv and "R" or "N"

chirp_common.split_tone_decode(mem,

(txmode, txtone, txpol),

(rxmode, rxtone, rxpol))

mem.skip = _flg.get_skip() and "S" or _flg.get_pskip() and "P" or ""

return mem

def set_memory(self, mem):

_mem, _flg = self._get_memobjs(mem.number)

if mem.empty:

_flg.set()

return

_flg.clear()

_mem.set_raw("\x00" * 32)

_mem.freq = mem.freq / 100

_mem.offset = mem.offset / 100

_mem.name = mem.name.ljust(7)

_mem.is_am = mem.mode == "AM"

_mem.duplex = DUPLEXES.index(mem.duplex)

try:

_mem.channel_width = MODES.index(mem.mode)

except ValueError:

_mem.channel_width = 0

((txmode, txtone, txpol),

(rxmode, rxtone, rxpol)) = chirp_common.split_tone_encode(mem)

_mem.txtmode = TMODES.index(txmode)

_mem.rxtmode = TMODES.index(rxmode)

if txmode == "Tone":

_mem.txtone = TONES.index(txtone)

elif txmode == "DTCS":

self._set_dcs_index(_mem, 'tx',

chirp_common.ALL_DTCS_CODES.index(txtone))

if rxmode == "Tone":

_mem.rxtone = TONES.index(rxtone)

elif rxmode == "DTCS":

self._set_dcs_index(_mem, 'rx',

chirp_common.ALL_DTCS_CODES.index(rxtone))

_mem.txinv = txpol == "R"

_mem.rxinv = rxpol == "R"

_flg.set_skip(mem.skip == "S")

_flg.set_pskip(mem.skip == "P")

@classmethod

def match_model(cls, filedata, filename):

return filedata[0x21:0x28] == "QX588UV"