##
import sigrokdecode as srd
+from common.srdhelper import bitpack_lsb
def disabled_enabled(v):
return ['Disabled', 'Enabled'][v]
def output_power(v):
- return '%+ddBm' % [-4, -1, 2, 5][v]
+ return '{:+d}dBm'.format([-4, -1, 2, 5][v])
regs = {
# reg: name offset width parser
('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: '%0.2fmA @ 5.1kΩ' %
+ ('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]),
+ 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),
('AUX Output Enable', 9, 1, disabled_enabled),
('MTLD', 10, 1, disabled_enabled),
('VCO Power-Down', 11, 1, lambda v:
- 'VCO Powered ' + ('Down' if v == 1 else 'Up')),
+ 'VCO Powered {updown}'.format(updown = 'Down' if v else 'Up')),
('Band Select Clock Divider', 12, 8, None),
- ('RF Divider Select', 20, 3, lambda v: '÷' + str(2**v)),
+ ('RF Divider Select', 20, 3, lambda v: '÷{:d}'.format(2 ** v)),
('Feedback Select', 23, 1, lambda v: ['Divided', 'Fundamental'][v]),
],
5: [
}
ANN_REG = 0
+ANN_WARN = 1
class Decoder(srd.Decoder):
api_version = 3
desc = 'Wideband synthesizer with integrated VCO.'
license = 'gplv3+'
inputs = ['spi']
- outputs = ['adf435x']
+ outputs = []
+ tags = ['Clock/timing', 'IC', 'Wireless/RF']
annotations = (
# Sent from the host to the chip.
- ('register', 'Register written to the device'),
+ ('write', 'Register write'),
+ ('warning', "Warnings"),
)
annotation_rows = (
- ('registers', 'Register writes', (ANN_REG,)),
+ ('writes', 'Register writes', (ANN_REG,)),
+ ('warnings', 'Warnings', (ANN_WARN,)),
)
def __init__(self):
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):
- return (sum([(1 << i) if self.bits[offset + i][0] else 0 for i in range(width)]),
- (self.bits[offset + width - 1][1], self.bits[offset][2]))
+ '''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):
- val, pos = self.decode_bits(offset, width)
- self.put(pos[0], pos[1], self.out_ann, [ANN_REG,
- ['%s: %s' % (name, parser(val) if parser else str(val))]])
- return val
+ '''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()
- ptype, data1, data2 = data
-
- if ptype == 'CS-CHANGE':
- if data1 == 1:
- if len(self.bits) == 32:
- reg_value, reg_pos = self.decode_bits(0, 3)
- self.put(reg_pos[0], reg_pos[1], self.out_ann, [ANN_REG,
- ['Register: %d' % reg_value, 'Reg: %d' % reg_value,
- '[%d]' % reg_value]])
- if reg_value < len(regs):
- field_descs = regs[reg_value]
- for field_desc in field_descs:
- field = self.decode_field(*field_desc)
- self.bits = []
if ptype == 'BITS':
- self.bits = data1 + self.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)