adf435x: use .format() for Python string formatting

[libsigrokdecode.git] / decoders / adf435x / pd.py

##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2017 Joel Holdsworth <joel@airwebreathe.org.uk>
##
## 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 sigrokdecode as srd
from common.srdhelper import bitpack_lsb

def disabled_enabled(v):
    return ['Disabled', 'Enabled'][v]

def output_power(v):
    return '{:+d}dBm'.format([-4, -1, 2, 5][v])

regs = {
# reg:   name                        offset width parser
    0: [
        ('FRAC',                          3, 12, None),
        ('INT',                          15, 16, lambda v: 'Not Allowed' if v < 32 else v)
    ],
    1: [
        ('MOD',                           3, 12, None),
        ('Phase',                        15, 12, None),
        ('Prescalar',                    27,  1, lambda v: ['4/5', '8/9'][v]),
        ('Phase Adjust',                 28,  1, lambda v: ['Off', 'On'][v]),
    ],
    2: [
        ('Counter Reset',                 3,  1, disabled_enabled),
        ('Charge Pump Three-State',       4,  1, disabled_enabled),
        ('Power-Down',                    5,  1, disabled_enabled),
        ('PD Polarity',                   6,  1, lambda v: ['Negative', 'Positive'][v]),
        ('LDP',                           7,  1, lambda v: ['10ns', '6ns'][v]),
        ('LDF',                           8,  1, lambda v: ['FRAC-N', 'INT-N'][v]),
        ('Charge Pump Current Setting',   9,  4, lambda v: '{:0.2f}mA @ 5.1kΩ'.format(
            [0.31, 0.63, 0.94, 1.25, 1.56, 1.88, 2.19, 2.50,
            2.81, 3.13, 3.44, 3.75, 4.06, 4.38, 4.69, 5.00][v])),
        ('Double Buffer',                13,  1, disabled_enabled),
        ('R Counter',                    14, 10, None),
        ('RDIV2',                        24,  1, disabled_enabled),
        ('Reference Doubler',            25,  1, disabled_enabled),
        ('MUXOUT',                       26,  3, lambda v:
            ['Three-State Output', 'DVdd', 'DGND', 'R Counter Output', 'N Divider Output',
            'Analog Lock Detect', 'Digital Lock Detect', 'Reserved'][v]),
        ('Low Noise and Low Spur Modes', 29,  2, lambda v:
            ['Low Noise Mode', 'Reserved', 'Reserved', 'Low Spur Mode'][v])
    ],
    3: [
        ('Clock Divider',                 3, 12, None),
        ('Clock Divider Mode',           15,  2, lambda v:
            ['Clock Divider Off', 'Fast Lock Enable', 'Resync Enable', 'Reserved'][v]),
        ('CSR Enable',                   18,  1, disabled_enabled),
        ('Charge Cancellation',          21,  1, disabled_enabled),
        ('ABP',                          22,  1, lambda v: ['6ns (FRAC-N)', '3ns (INT-N)'][v]),
        ('Band Select Clock Mode',       23,  1, lambda v: ['Low', 'High'][v])
    ],
    4: [
        ('Output Power',                  3,  2, output_power),
        ('Output Enable',                 5,  1, disabled_enabled),
        ('AUX Output Power',              6,  2, output_power),
        ('AUX Output Select',             8,  1, lambda v: ['Divided Output', 'Fundamental'][v]),
        ('AUX Output Enable',             9,  1, disabled_enabled),
        ('MTLD',                         10,  1, disabled_enabled),
        ('VCO Power-Down',               11,  1, lambda v:
            'VCO Powered {updown}'.format(updown = 'Down' if v else 'Up')),
        ('Band Select Clock Divider',    12,  8, None),
        ('RF Divider Select',            20,  3, lambda v: '÷{:d}'.format(2 ** v)),
        ('Feedback Select',              23,  1, lambda v: ['Divided', 'Fundamental'][v]),
    ],
    5: [
        ('LD Pin Mode',                  22,  2, lambda v:
            ['Low', 'Digital Lock Detect', 'Low', 'High'][v])
    ]
}

ANN_REG = 0
ANN_WARN = 1

class Decoder(srd.Decoder):
    api_version = 3
    id = 'adf435x'
    name = 'ADF435x'
    longname = 'Analog Devices ADF4350/1'
    desc = 'Wideband synthesizer with integrated VCO.'
    license = 'gplv3+'
    inputs = ['spi']
    outputs = []
    tags = ['Clock/timing', 'IC', 'Wireless/RF']
    annotations = (
        # Sent from the host to the chip.
        ('write', 'Register write'),
        ('warning', "Warnings"),
    )
    annotation_rows = (
        ('writes', 'Register writes', (ANN_REG,)),
        ('warnings', 'Warnings', (ANN_WARN,)),
    )

    def __init__(self):
        self.reset()

    def reset(self):
        self.bits = []

    def start(self):
        self.out_ann = self.register(srd.OUTPUT_ANN)

    def putg(self, ss, es, cls, data):
        self.put(ss, es, self.out_ann, [ cls, data, ])

    def decode_bits(self, offset, width):
        '''Extract a bit field. Expects LSB input data.'''
        bits = self.bits[offset:][:width]
        ss, es = bits[-1][1], bits[0][2]
        value = bitpack_lsb(bits, 0)
        return ( value, ( ss, es, ))

    def decode_field(self, name, offset, width, parser):
        '''Interpret a bit field. Emits an annotation.'''
        val, ( ss, es, ) = self.decode_bits(offset, width)
        val = parser(val) if parser else '{}'.format(val)
        text = ['{name}: {val}'.format(name = name, val = val)]
        self.putg(ss, es, ANN_REG, text)

    def decode_word(self, ss, es, bits):
        '''Interpret a 32bit word after accumulation completes.'''
        # SPI transfer content must be exactly one 32bit word.
        count = len(self.bits)
        if count != 32:
            text = [
                'Frame error: Bit count: want 32, got {}'.format(count),
                'Frame error: Bit count',
                'Frame error',
            ]
            self.putg(ss, es, ANN_WARN, text)
            return
        # Holding bits in LSB order during interpretation simplifies
        # bit field extraction. And annotation emitting routines expect
        # this reverse order of bits' timestamps.
        self.bits.reverse()
        # Determine which register was accessed.
        reg_addr, ( reg_ss, reg_es, ) = self.decode_bits(0, 3)
        text = [
            'Register: {addr}'.format(addr = reg_addr),
            'Reg: {addr}'.format(addr = reg_addr),
            '[{addr}]'.format(addr = reg_addr),
        ]
        self.putg(reg_ss, reg_es, ANN_REG, text)
        # Interpret the register's content (when parsers are available).
        field_descs = regs.get(reg_addr, None)
        if not field_descs:
            return
        for field_desc in field_descs:
            self.decode_field(*field_desc)

    def decode(self, ss, es, data):
        ptype, _, _ = data

        if ptype == 'TRANSFER':
            # Process accumulated bits after completion of a transfer.
            self.decode_word(ss, es, self.bits)
            self.bits.clear()

        if ptype == 'BITS':
            _, mosi_bits, miso_bits = data
            # Accumulate bits in MSB order as they are seen in SPI frames.
            msb_bits = mosi_bits.copy()
            msb_bits.reverse()
            self.bits.extend(msb_bits)