Mercurial > ~darius > hgwebdir.cgi > musiccutter
view musiccutter.py @ 42:3925ac56d99e
Allow flushing notes.
Requires refactoring a bunch of crap though and makes some of the
functions know a bit bunch..
author | Daniel O'Connor <darius@dons.net.au> |
---|---|
date | Tue, 24 May 2016 19:42:02 +0930 |
parents | 21da8af1cdd2 |
children | c69e53b8917c |
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#!/usr/bin/env python from IPython.core.debugger import Tracer import ConfigParser import exceptions import itertools import math import mido import os.path import reportlab.lib.colors import reportlab.pdfgen.canvas from reportlab.lib.units import mm import sys CUT_COLOUR = reportlab.lib.colors.red ENGRAVE_COLOUR = reportlab.lib.colors.black class Stats(object): pass class EVWrap(object): def __init__(self, ev): self.ev = ev def test(filename = None, shift = 0): if filename == None: filename = 'test.midi' # Card layout from http://www.orgues-de-barbarie.com/wp-content/uploads/2014/09/format-cartons.pdf # Notes are read from right to left # Highest note is at the bottom (closest to the crank) # fold fold # in out # V ^ # +---+---+---+ lowest note # | | | | # +---+---+---+ highest note # m = Midi2PDF(**{ 'config' : 'orgues-de-barbarie-27.ini', 'leadin' : 50, 'timemarks' : False, 'trytranspose' : True, 'drawrect' : False, 'notenames' : False, 'notelines' : False, 'noteoffset' : shift, 'pagesperpdf' : 1, 'timescale' : 30, 'notescale' : 0.9, 'fontname' : 'Helvetica', 'fontsize' : 12, }) base, ext = os.path.splitext(filename) base = os.path.basename(base) m.processMidi(filename, base + '-%02d.pdf') class Midi2PDF(object): def __init__(self, config, leadin, timemarks, trytranspose, drawrect, notenames, notelines, noteoffset, pagesperpdf, timescale, notescale, fontname, fontsize): cp = ConfigParser.ConfigParser() cp.read(config) self.pagewidth = cp.getfloat('default', 'pagewidth') self.pageheight = cp.getfloat('default', 'pageheight') self.pitch = cp.getfloat('default', 'pitch') self.slotsize = cp.getfloat('default', 'slotsize') self.heel = cp.getfloat('default', 'heel') self.leadin = leadin # Extra at the start self.timemarks = timemarks # Draw vertical time lines self.trytranspose = trytranspose # Attempt to tranpose unplayable notes self.drawrect = drawrect # Draw rectangle around each page self.notenames = notenames # Draw note names on the right edge self.notelines = notelines # Draw line rulers self.noteoffset = noteoffset # Amount to adjust note pitches by (+12 = 1 octave) self.pagesperpdf = pagesperpdf # Number of pages to emit per PDF self.timescale = timescale # Width per second self.notescale = notescale # Multiply all note lengths by this (to get rearticulation) self.fontname = fontname self.fontsize = fontsize # Points self.pdfwidth = self.pagewidth * self.pagesperpdf self.midi2note, self.note2midi = Midi2PDF.genmidi2note() self.note2slot, self.slot2note = Midi2PDF.loadnote2slot(cp.get('default', 'notes').split(), self.note2midi) def processMidi(self, midifile, outpat): self.stats = Stats() self.stats.playablecount = 0 self.stats.unplayablecount = 0 self.stats.transposeupcount = 0 self.stats.transposedowncount = 0 midi = mido.MidiFile(midifile) self.ctime = 0 self.channels = [] for i in range(16): # 16 is the maximum number of MIDI channels self.channels.append({}) npages = int(math.ceil(((midi.length * self.timescale) + self.leadin) / self.pagewidth)) npdfs = int(math.ceil(float(npages) / self.pagesperpdf)) print 'npages %d, npdfs %d' % (npages, npdfs) self.pdfs = [] for i in range(npdfs): pdf = reportlab.pdfgen.canvas.Canvas(file(outpat % (i + 1), 'w'), pagesize = (self.pdfwidth * mm, self.pageheight * mm)) self.pdfs.append(pdf) title = os.path.basename(midifile) title, ext = os.path.splitext(title) for ev in midi: # Adjust pitch if hasattr(ev, 'note'): ev.note += self.noteoffset self.ctime += ev.time print '%.03f: %s' % (self.ctime, str(ev)) #Tracer()() if ev.type == 'text' and self.ctime == 0: title = ev.text if ev.type == 'note_on' and ev.velocity > 0: if ev.note in self.channels[ev.channel]: print 'Duplicate note_on message at %.1f sec channel %d note %d' % (self.ctime, ev.channel, ev.note) else: # Store start time self.channels[ev.channel][ev.note] = self.ctime # note_on with velocity of 0 is a note_off elif ev.type == 'note_off' or (ev.type == 'note_on' and ev.velocity == 0): if ev.note not in self.channels[ev.channel]: # These can be rests (iWriteMusic) print 'note_off with no corresponding note_on at %.1f sec for channel %d note %d' % (self.ctime, ev.channel, ev.note) continue else: orignote = self.emitnote(ev) del self.channels[ev.channel][orignote] elif ev.type == 'end_of_track': for chan in self.channels: for ev in chan: print 'Flushed', ev self.emitnote(ev) print ev print 'Playable count:', self.stats.playablecount print 'Unplayable count:', self.stats.unplayablecount if self.trytranspose: print 'Transpose down:', self.stats.transposedowncount print 'Transpose up:', self.stats.transposeupcount # Do per-page things for pindx in range(npages): pdf = self.pdfs[pindx / self.pagesperpdf] # PDF for this page # Offset into PDF where the page starts pageofs = self.pagewidth * (self.pagesperpdf - (pindx % self.pagesperpdf) - 1) # Add title and page number Midi2PDF.textHelper(pdf, pageofs * mm, 1 * mm, ENGRAVE_COLOUR, True, self.fontname, self.fontsize, '%s (%d / %d)' % (title, pindx + 1, npages)) pdf.saveState() pdf.setLineWidth(0) # Draw time marks every 5 seconds if self.timemarks: pdfidx = pindx / self.pagesperpdf # Work out start and end times (pdf 1 is special due to leadin) tstart = self.leadin / self.timescale tend = (self.pagewidth * self.pagesperpdf) / self.timescale if pindx > 0: tsize = self.pagewidth / self.timescale # Amount of time per pdf tstart = tend + tsize * pdfidx tend = tend + tsize * (pdfidx + 1) for s in range(tstart, tend, 5): x = self.pagewidth - (float(s * self.timescale + self.leadin) % self.pagewidth) pdf.line(x * mm, self.heel, x * mm, self.pageheight * mm) Midi2PDF.textHelper(pdf, x * mm, 1 * mm, ENGRAVE_COLOUR, False, self.fontname, self.fontsize, str(s) + 's') # Draw rectangle around page (upper and right hand ends don't seem to render though) if self.drawrect: pdf.rect((pindx % self.pagesperpdf) * self.pagewidth * mm, 0, self.pagewidth * mm, self.pageheight * mm, fill = False, stroke = True) # Draw lines per note for slot in sorted(self.slot2note.keys()): ofs = self.pageheight - (self.heel + slot * self.pitch) - self.slotsize / 2 if self.notelines: pdf.line(0, ofs * mm, self.pdfwidth * mm, ofs * mm) # Note name if self.notenames: Midi2PDF.textHelper(pdf, (self.pdfwidth - 10) * mm, (ofs + 0.5) * mm, ENGRAVE_COLOUR, False, self.fontname, self.fontsize, self.slot2note[slot]) pdf.restoreState() for pdf in self.pdfs: pdf.save() def noteisplayable(self, midi): #Tracer()() if midi in self.midi2note: notename = self.midi2note[midi] if notename in self.note2slot: return True return False # Check if the organ can play the note def transposenote(self, evw, amount): evw.ev.note += amount evw.notename = self.midi2note[evw.ev.note] evw.slot = self.note2slot[evw.notename] # Work out which slot to use for the note, transpose if desired def getslotfornote(self, evw): evw.slot = None evw.notename = None # First off, is the note in our midi table? if evw.ev.note in self.midi2note: evw.notename = self.midi2note[evw.ev.note] # Is it playable? if self.noteisplayable(evw.ev.note): evw.slot = self.note2slot[evw.notename] # Nope, maybe we can transpose? elif self.trytranspose: # Go for -3 to +3 octaves (going down first) for i in [-12, -24, -36, 12, 24, 36]: if self.noteisplayable(evw.ev.note + i): self.transposenote(evw, i) if i < 0: self.stats.transposedowncount += 1 tmp = 'down' else: self.stats.transposeupcount += 1 tmp = 'up' print 'Transposed note at %.1f sec %s (%d) %s %d octave(s) to %s (%d)' % ( self.ctime, self.midi2note[evw.ev.note - i], evw.ev.note - i, tmp, abs(i / 12), evw.notename, evw.ev.note) break if evw.slot != None: self.stats.playablecount += 1 else: print 'Note at %.1f sec %d (%s) not playable' % (self.ctime, evw.ev.note, self.midi2note[evw.ev.note]) self.stats.unplayablecount += 1 else: print 'Note at %.1f sec, %d not in MIDI table' % (self.ctime, evw.ev.note) self.stats.unplayablecount += 1 # http://newt.phys.unsw.edu.au/jw/notes.html # But this seems dumb since the lowest MIDI note is 0 which would be C-1.. @staticmethod def genmidi2note(): '''Create forward & reverse tables for midi number to note name (assuming 69 = A4 = A440)''' names = ['C%d', 'C%d#', 'D%d', 'D%d#', 'E%d', 'F%d', 'F%d#', 'G%d', 'G%d#', 'A%d', 'A%d#', 'B%d'] midi2note = {} note2midi = {} for midi in range(12, 128): octave = midi / len(names) - 1 index = midi % len(names) name = names[index] % (octave) midi2note[midi] = name note2midi[name] = midi return midi2note, note2midi @staticmethod def loadnote2slot(notelist, note2midi): note2slot = {} slot2note = {} index = 0 for note in notelist: note = note.strip() if note[0] == '#': continue if note not in note2midi: raise exceptions.ValueError('Note \'%s\' not valid' % note) note2slot[note] = index slot2note[index] = note index += 1 return note2slot, slot2note def emitnote(self, ev): orignote = ev.note start = self.channels[ev.channel][orignote] evw = EVWrap(ev) # Find a slot (plus adjust pitch, attempt transposition etc) if hasattr(ev, 'note'): self.getslotfornote(evw) # Check if it was unplayable if evw.slot == None: return orignote notelen = self.ctime - start print 'Note %s (%d) at %.2f length %.2f' % (evw.notename, evw.slot, start, notelen) x = start * self.timescale + self.leadin # Convert start time to distance pdfidx = int(x / self.pdfwidth) # Determine which pdf x = x % self.pdfwidth # and where on that pdf h = self.slotsize y = self.pageheight - (self.heel + evw.slot * self.pitch - self.slotsize / 2) - self.slotsize w = notelen * self.timescale # Convert note length in time to distance #print 'pdf = %d x = %.3f y = %.3f w = %.3f h = %.3f' % (pdfidx, x, y, w, h) w1 = w # Check if the note crosses a pdf if x + w > self.pdfwidth: w1 = self.pdfwidth - x # Crop first note w2 = w - w1 # Calculate length of second note assert w2 <= self.pdfwidth, 'note extends for more than a pdf' # Emit second half of note #print 'split note, pdf %d w2 = %.3f' % (pdfidx + 1, w2) Midi2PDF._emitnote(self.pdfs[pdfidx + 1], self.pdfwidth - w2, y, w2, h) Midi2PDF._emitnote(self.pdfs[pdfidx], self.pdfwidth - x - w1, y, w1, h) return orignote @staticmethod def _emitnote(pdf, x, y, w, h): pdf.saveState() pdf.setStrokeColor(CUT_COLOUR) pdf.setLineWidth(0) pdf.rect(x * mm, y * mm, w * mm, h * mm, fill = False, stroke = True) pdf.restoreState() @staticmethod def textHelper(pdf, x, y, colour, fill, fontname, fontsize, text): tobj = pdf.beginText() tobj.setTextOrigin(x, y) tobj.setFont(fontname, fontsize) tobj.setStrokeColor(colour) tobj.setFillColor(colour) if fill: tobj.setTextRenderMode(0) else: tobj.setTextRenderMode(1) tobj.textLine(text) pdf.drawText(tobj) if __name__ == '__main__': main()