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##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2014 Jens Steinhauser <jens.steinhauser@gmail.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 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.
##
## You should have received a copy of the GNU General Public License
## along with this program; if not, write to the Free Software
## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
##
import sigrokdecode as srd
class ChannelError(Exception):
pass
regs = {
# addr: ('name', size)
0x00: ('CONFIG', 1),
0x01: ('EN_AA', 1),
0x02: ('EN_RXADDR', 1),
0x03: ('SETUP_AW', 1),
0x04: ('SETUP_RETR', 1),
0x05: ('RF_CH', 1),
0x06: ('RF_SETUP', 1),
0x07: ('STATUS', 1),
0x08: ('OBSERVE_TX', 1),
0x09: ('RPD', 1),
0x0a: ('RX_ADDR_P0', 5),
0x0b: ('RX_ADDR_P1', 5),
0x0c: ('RX_ADDR_P2', 1),
0x0d: ('RX_ADDR_P3', 1),
0x0e: ('RX_ADDR_P4', 1),
0x0f: ('RX_ADDR_P5', 1),
0x10: ('TX_ADDR', 5),
0x11: ('RX_PW_P0', 1),
0x12: ('RX_PW_P1', 1),
0x13: ('RX_PW_P2', 1),
0x14: ('RX_PW_P3', 1),
0x15: ('RX_PW_P4', 1),
0x16: ('RX_PW_P5', 1),
0x17: ('FIFO_STATUS', 1),
0x1c: ('DYNPD', 1),
0x1d: ('FEATURE', 1),
}
xn297_regs = {
0x19: ('DEMOD_CAL', 5),
0x1e: ('RF_CAL', 7),
0x1f: ('BB_CAL', 5),
}
class Decoder(srd.Decoder):
api_version = 2
id = 'nrf24l01'
name = 'nRF24L01(+)'
longname = 'Nordic Semiconductor nRF24L01/nRF24L01+'
desc = '2.4GHz transceiver chip.'
license = 'gplv2+'
inputs = ['spi']
outputs = ['nrf24l01']
options = (
{'id': 'chip', 'desc': 'Chip type',
'default': 'nrf24l01', 'values': ('nrf24l01', 'xn297')},
)
annotations = (
# Sent from the host to the chip.
('cmd', 'Commands sent to the device'),
('tx-data', 'Payload sent to the device'),
# Returned by the chip.
('register', 'Registers read from the device'),
('rx-data', 'Payload read from the device'),
('warning', 'Warnings'),
)
ann_cmd = 0
ann_tx = 1
ann_reg = 2
ann_rx = 3
ann_warn = 4
annotation_rows = (
('commands', 'Commands', (ann_cmd, ann_tx)),
('responses', 'Responses', (ann_reg, ann_rx)),
('warnings', 'Warnings', (ann_warn,)),
)
def __init__(self):
self.next()
self.requirements_met = True
self.cs_was_released = False
def start(self):
self.out_ann = self.register(srd.OUTPUT_ANN)
if self.options['chip'] == 'xn297':
regs.update(xn297_regs)
def warn(self, pos, msg):
'''Put a warning message 'msg' at 'pos'.'''
self.put(pos[0], pos[1], self.out_ann, [self.ann_warn, [msg]])
def putp(self, pos, ann, msg):
'''Put an annotation message 'msg' at 'pos'.'''
self.put(pos[0], pos[1], self.out_ann, [ann, [msg]])
def next(self):
'''Resets the decoder after a complete command was decoded.'''
# 'True' for the first byte after CS went low.
self.first = True
# The current command, and the minimum and maximum number
# of data bytes to follow.
self.cmd = None
self.min = 0
self.max = 0
# Used to collect the bytes after the command byte
# (and the start/end sample number).
self.mb = []
self.mb_s = -1
self.mb_e = -1
def mosi_bytes(self):
'''Returns the collected MOSI bytes of a multi byte command.'''
return [b[0] for b in self.mb]
def miso_bytes(self):
'''Returns the collected MISO bytes of a multi byte command.'''
return [b[1] for b in self.mb]
def decode_command(self, pos, b):
'''Decodes the command byte 'b' at position 'pos' and prepares
the decoding of the following data bytes.'''
c = self.parse_command(b)
if c is None:
self.warn(pos, 'unknown command')
return
self.cmd, self.dat, self.min, self.max = c
if self.cmd in ('W_REGISTER', 'ACTIVATE'):
# Don't output anything now, the command is merged with
# the data bytes following it.
self.mb_s = pos[0]
else:
self.putp(pos, self.ann_cmd, self.format_command())
def format_command(self):
'''Returns the label for the current command.'''
if self.cmd == 'R_REGISTER':
reg = regs[self.dat][0] if self.dat in regs else 'unknown register'
return 'Cmd R_REGISTER "{}"'.format(reg)
else:
return 'Cmd {}'.format(self.cmd)
def parse_command(self, b):
'''Parses the command byte.
Returns a tuple consisting of:
- the name of the command
- additional data needed to dissect the following bytes
- minimum number of following bytes
- maximum number of following bytes
'''
if (b & 0xe0) in (0b00000000, 0b00100000):
c = 'R_REGISTER' if not (b & 0xe0) else 'W_REGISTER'
d = b & 0x1f
m = regs[d][1] if d in regs else 1
return (c, d, 1, m)
if b == 0b01010000:
# nRF24L01 only
return ('ACTIVATE', None, 1, 1)
if b == 0b01100001:
return ('R_RX_PAYLOAD', None, 1, 32)
if b == 0b01100000:
return ('R_RX_PL_WID', None, 1, 1)
if b == 0b10100000:
return ('W_TX_PAYLOAD', None, 1, 32)
if b == 0b10110000:
return ('W_TX_PAYLOAD_NOACK', None, 1, 32)
if (b & 0xf8) == 0b10101000:
return ('W_ACK_PAYLOAD', b & 0x07, 1, 32)
if b == 0b11100001:
return ('FLUSH_TX', None, 0, 0)
if b == 0b11100010:
return ('FLUSH_RX', None, 0, 0)
if b == 0b11100011:
return ('REUSE_TX_PL', None, 0, 0)
if b == 0b11111111:
return ('NOP', None, 0, 0)
def decode_register(self, pos, ann, regid, data):
'''Decodes a register.
pos -- start and end sample numbers of the register
ann -- is the annotation number that is used to output the register.
regid -- may be either an integer used as a key for the 'regs'
dictionary, or a string directly containing a register name.'
data -- is the register content.
'''
if type(regid) == int:
# Get the name of the register.
if regid not in regs:
self.warn(pos, 'unknown register')
return
name = regs[regid][0]
else:
name = regid
# Multi byte register come LSByte first.
data = reversed(data)
if self.cmd == 'W_REGISTER' and ann == self.ann_cmd:
# The 'W_REGISTER' command is merged with the following byte(s).
label = '{}: {}'.format(self.format_command(), name)
else:
label = 'Reg {}'.format(name)
self.decode_mb_data(pos, ann, data, label, True)
def decode_mb_data(self, pos, ann, data, label, always_hex):
'''Decodes the data bytes 'data' of a multibyte command at position
'pos'. The decoded data is prefixed with 'label'. If 'always_hex' is
True, all bytes are decoded as hex codes, otherwise only non
printable characters are escaped.'''
if always_hex:
def escape(b):
return '{:02X}'.format(b)
else:
def escape(b):
c = chr(b)
if not str.isprintable(c):
return '\\x{:02X}'.format(b)
return c
data = ''.join([escape(b) for b in data])
text = '{} = "{}"'.format(label, data)
self.putp(pos, ann, text)
def finish_command(self, pos):
'''Decodes the remaining data bytes at position 'pos'.'''
if self.cmd == 'R_REGISTER':
self.decode_register(pos, self.ann_reg,
self.dat, self.miso_bytes())
elif self.cmd == 'W_REGISTER':
self.decode_register(pos, self.ann_cmd,
self.dat, self.mosi_bytes())
elif self.cmd == 'R_RX_PAYLOAD':
self.decode_mb_data(pos, self.ann_rx,
self.miso_bytes(), 'RX payload', False)
elif (self.cmd == 'W_TX_PAYLOAD' or
self.cmd == 'W_TX_PAYLOAD_NOACK'):
self.decode_mb_data(pos, self.ann_tx,
self.mosi_bytes(), 'TX payload', False)
elif self.cmd == 'W_ACK_PAYLOAD':
lbl = 'ACK payload for pipe {}'.format(self.dat)
self.decode_mb_data(pos, self.ann_tx,
self.mosi_bytes(), lbl, False)
elif self.cmd == 'R_RX_PL_WID':
msg = 'Payload width = {}'.format(self.mb[0][1])
self.putp(pos, self.ann_reg, msg)
elif self.cmd == 'ACTIVATE':
self.putp(pos, self.ann_cmd, self.format_command())
if self.mosi_bytes()[0] != 0x73:
self.warn(pos, 'wrong data for "ACTIVATE" command')
def decode(self, ss, es, data):
if not self.requirements_met:
return
ptype, data1, data2 = data
if ptype == 'CS-CHANGE':
if data1 is None:
if data2 is None:
self.requirements_met = False
raise ChannelError('CS# pin required.')
elif data2 == 1:
self.cs_was_released = True
if data1 == 0 and data2 == 1:
# Rising edge, the complete command is transmitted, process
# the bytes that were send after the command byte.
if self.cmd:
# Check if we got the minimum number of data bytes
# after the command byte.
if len(self.mb) < self.min:
self.warn((ss, ss), 'missing data bytes')
elif self.mb:
self.finish_command((self.mb_s, self.mb_e))
self.next()
self.cs_was_released = True
elif ptype == 'DATA' and self.cs_was_released:
mosi, miso = data1, data2
pos = (ss, es)
if miso is None or mosi is None:
self.requirements_met = False
raise ChannelError('Both MISO and MOSI pins required.')
if self.first:
self.first = False
# First MOSI byte is always the command.
self.decode_command(pos, mosi)
# First MISO byte is always the status register.
self.decode_register(pos, self.ann_reg, 'STATUS', [miso])
else:
if not self.cmd or len(self.mb) >= self.max:
self.warn(pos, 'excess byte')
else:
# Collect the bytes after the command byte.
if self.mb_s == -1:
self.mb_s = ss
self.mb_e = es
self.mb.append((mosi, miso))
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