| 123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197 |
- # greaseweazle/image/scp.py
- #
- # Written & released by Keir Fraser <keir.xen@gmail.com>
- #
- # This is free and unencumbered software released into the public domain.
- # See the file COPYING for more details, or visit <http://unlicense.org>.
- import struct
- from greaseweazle import error
- from greaseweazle.flux import Flux
- class SCP:
- # 40MHz
- sample_freq = 40000000
- def __init__(self, start_cyl, nr_sides):
- self.start_cyl = start_cyl
- self.nr_sides = nr_sides
- self.nr_revs = None
- self.track_list = []
- @classmethod
- def to_file(cls, start_cyl, nr_sides):
- hfe = cls(start_cyl, nr_sides)
- return hfe
- @classmethod
- def from_file(cls, dat):
- header = struct.unpack("<3s9BI", dat[0:16])
- (sig, _, _, nr_revs, s_trk, e_trk, flags, _, ss, _, _) = header
- error.check(sig == b"SCP", "SCP: Bad signature")
- nr_sides = 1 if ss else 2
-
- trk_offs = struct.unpack("<168I", dat[16:0x2b0])
- scp = cls(s_trk // nr_sides, nr_sides)
- scp.nr_revs = nr_revs
- for trknr in range(s_trk, e_trk+1):
- trk_off = trk_offs[trknr]
- if trk_off == 0:
- scp.track_list.append((None, None))
- # Parse the SCP track header and extract the flux data.
- thdr = dat[trk_off:trk_off+4+12*nr_revs]
- sig, tnr, _, _, s_off = struct.unpack("<3sB3I", thdr[:16])
- error.check(sig == b"TRK", "SCP: Missing track signature")
- error.check(tnr == trknr, "SCP: Wrong track number in header")
- _, e_nr, e_off = struct.unpack("<3I", thdr[-12:])
- tdat = dat[trk_off+s_off:trk_off+e_off+e_nr*2]
- scp.track_list.append((thdr, tdat))
- return scp
- def get_track(self, cyl, side, writeout=False):
- if side >= self.nr_sides or cyl < self.start_cyl:
- return None
- off = (cyl - self.start_cyl) * self.nr_sides + side
- if off >= len(self.track_list):
- return None
- tdh, dat = self.track_list[off]
- if not dat:
- return None
- tdh = tdh[4:]
- # Writeout requires only a single revolution
- if writeout:
- tdh = tdh[:12]
- _, nr, _ = struct.unpack("<3I", tdh)
- dat = dat[:nr*2]
-
- index_list = []
- while tdh:
- ticks, _, _ = struct.unpack("<3I", tdh[:12])
- index_list.append(ticks)
- tdh = tdh[12:]
-
- # Decode the SCP flux data into a simple list of flux times.
- flux_list = []
- val = 0
- for i in range(0, len(dat), 2):
- x = dat[i]*256 + dat[i+1]
- if x == 0:
- val += 65536
- continue
- flux_list.append(val + x)
- val = 0
- return Flux(index_list, flux_list, SCP.sample_freq)
-
-
- # append_track:
- # Converts a Flux object into a Supercard Pro Track and appends it to
- # the current image-in-progress.
- def append_track(self, flux):
- nr_revs = len(flux.index_list)
- if not self.nr_revs:
- self.nr_revs = nr_revs
- else:
- assert self.nr_revs == nr_revs
-
- factor = SCP.sample_freq / flux.sample_freq
- trknr = self.start_cyl * self.nr_sides + len(self.track_list)
- tdh = struct.pack("<3sB", b"TRK", trknr)
- dat = bytearray()
- len_at_index = rev = 0
- to_index = flux.index_list[0]
- rem = 0.0
- for x in flux.list:
- # Does the next flux interval cross the index mark?
- while to_index < x:
- # Append to the TDH for the previous full revolution
- tdh += struct.pack("<III",
- int(round(flux.index_list[rev]*factor)),
- (len(dat) - len_at_index) // 2,
- 4 + nr_revs*12 + len_at_index)
- # Set up for the next revolution
- len_at_index = len(dat)
- rev += 1
- if rev >= nr_revs:
- # We're done: We simply discard any surplus flux samples
- self.track_list.append((tdh, dat))
- return
- to_index += flux.index_list[rev]
- # Process the current flux sample into SCP "bitcell" format
- to_index -= x
- y = x * factor + rem
- val = int(round(y))
- if (val & 65535) == 0:
- val += 1
- rem = y - val
- while val >= 65536:
- dat.append(0)
- dat.append(0)
- val -= 65536
- dat.append(val>>8)
- dat.append(val&255)
- # Header for last track(s) in case we ran out of flux timings.
- while rev < nr_revs:
- tdh += struct.pack("<III",
- int(round(flux.index_list[rev]*factor)),
- (len(dat) - len_at_index) // 2,
- 4 + nr_revs*12 + len_at_index)
- len_at_index = len(dat)
- rev += 1
- self.track_list.append((tdh, dat))
- def get_image(self):
- s_trk = self.start_cyl * self.nr_sides
- e_trk = s_trk + len(self.track_list) - 1
- # Generate the TLUT and concatenate all the tracks together.
- trk_offs = bytearray(s_trk * 4)
- trk_dat = bytearray()
- for tdh, dat in self.track_list:
- trk_offs += struct.pack("<I", 0x2b0 + len(trk_dat))
- trk_dat += tdh + dat
- trk_offs += bytes(0x2a0 - len(trk_offs))
- # Calculate checksum over all data (except 16-byte image header).
- csum = 0
- for x in trk_offs:
- csum += x
- for x in trk_dat:
- csum += x
- # Generate the image header.
- header = struct.pack("<3s9BI",
- b"SCP", # Signature
- 0, # Version
- 0x80, # DiskType = Other
- self.nr_revs, s_trk, e_trk,
- 0x01, # Flags = Index
- 0, # 16-bit cell width
- 1 if self.nr_sides == 1 else 0,
- 0, # 25ns capture
- csum & 0xffffffff)
- # Concatenate it all together and send it back.
- return header + trk_offs + trk_dat
- # Local variables:
- # python-indent: 4
- # End:
|
