Mercurial > hg-public > lasercut-scripts / file revision
printrun-src/printrun/gcoder.py@f4730ef55ca8
printrun-src/printrun/gcoder.py
Tue, 26 Sep 2017 19:08:02 +0200
- author
- mdd
- date
- Tue, 26 Sep 2017 19:08:02 +0200
- changeset 36
- f4730ef55ca8
- parent 15
- 0bbb006204fc
- child 46
- cce0af6351f0
- permissions
- -rw-r--r--
SVG options: offset, original scale
SVG Bugfix: "scale" does now really fit to dimensions
#!/usr/bin/env python # This file is copied from GCoder. # # GCoder 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. # # GCoder 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 Printrun. If not, see <http://www.gnu.org/licenses/>. import sys import re import math import datetime import logging from array import array gcode_parsed_args = ["x", "y", "e", "f", "z", "i", "j"] gcode_parsed_nonargs = ["g", "t", "m", "n"] to_parse = "".join(gcode_parsed_args + gcode_parsed_nonargs) gcode_exp = re.compile("\([^\(\)]*\)|;.*|[/\*].*\n|([%s])([-+]?[0-9]*\.?[0-9]*)" % to_parse) gcode_strip_comment_exp = re.compile("\([^\(\)]*\)|;.*|[/\*].*\n") m114_exp = re.compile("\([^\(\)]*\)|[/\*].*\n|([XYZ]):?([-+]?[0-9]*\.?[0-9]*)") specific_exp = "(?:\([^\(\)]*\))|(?:;.*)|(?:[/\*].*\n)|(%s[-+]?[0-9]*\.?[0-9]*)" move_gcodes = ["G0", "G1", "G2", "G3"] class PyLine(object): __slots__ = ('x', 'y', 'z', 'e', 'f', 'i', 'j', 'raw', 'command', 'is_move', 'relative', 'relative_e', 'current_x', 'current_y', 'current_z', 'extruding', 'current_tool', 'gcview_end_vertex') def __init__(self, l): self.raw = l def __getattr__(self, name): return None class PyLightLine(object): __slots__ = ('raw', 'command') def __init__(self, l): self.raw = l def __getattr__(self, name): return None try: import gcoder_line Line = gcoder_line.GLine LightLine = gcoder_line.GLightLine except Exception, e: logging.warning("Memory-efficient GCoder implementation unavailable: %s" % e) Line = PyLine LightLine = PyLightLine def find_specific_code(line, code): exp = specific_exp % code bits = [bit for bit in re.findall(exp, line.raw) if bit] if not bits: return None else: return float(bits[0][1:]) def S(line): return find_specific_code(line, "S") def P(line): return find_specific_code(line, "P") def split(line): split_raw = gcode_exp.findall(line.raw.lower()) if split_raw and split_raw[0][0] == "n": del split_raw[0] if not split_raw: line.command = line.raw line.is_move = False logging.warning("raw G-Code line \"%s\" could not be parsed" % line.raw) return [line.raw] command = split_raw[0] line.command = command[0].upper() + command[1] line.is_move = line.command in move_gcodes return split_raw def parse_coordinates(line, split_raw, imperial = False, force = False): # Not a G-line, we don't want to parse its arguments if not force and line.command[0] != "G": return unit_factor = 25.4 if imperial else 1 for bit in split_raw: code = bit[0] if code not in gcode_parsed_nonargs and bit[1]: setattr(line, code, unit_factor * float(bit[1])) class Layer(list): __slots__ = ("duration", "z") def __init__(self, lines, z = None): super(Layer, self).__init__(lines) self.z = z class GCode(object): line_class = Line lines = None layers = None all_layers = None layer_idxs = None line_idxs = None append_layer = None append_layer_id = None imperial = False relative = False relative_e = False current_tool = 0 # Home position: current absolute position counted from machine origin home_x = 0 home_y = 0 home_z = 0 # Current position: current absolute position counted from machine origin current_x = 0 current_y = 0 current_z = 0 # For E this is the absolute position from machine start current_e = 0 current_e_multi=[0] total_e = 0 total_e_multi=[0] max_e = 0 max_e_multi=[0] # Current feedrate current_f = 0 # Offset: current offset between the machine origin and the machine current # absolute coordinate system (as shifted by G92s) offset_x = 0 offset_y = 0 offset_z = 0 offset_e = 0 offset_e_multi = [0] # Expected behavior: # - G28 X => X axis is homed, offset_x <- 0, current_x <- home_x # - G92 Xk => X axis does not move, so current_x does not change # and offset_x <- current_x - k, # - absolute G1 Xk => X axis moves, current_x <- offset_x + k # How to get... # current abs X from machine origin: current_x # current abs X in machine current coordinate system: current_x - offset_x filament_length = None filament_length_multi=[0] duration = None xmin = None xmax = None ymin = None ymax = None zmin = None zmax = None width = None depth = None height = None est_layer_height = None # abs_x is the current absolute X in machine current coordinate system # (after the various G92 transformations) and can be used to store the # absolute position of the head at a given time def _get_abs_x(self): return self.current_x - self.offset_x abs_x = property(_get_abs_x) def _get_abs_y(self): return self.current_y - self.offset_y abs_y = property(_get_abs_y) def _get_abs_z(self): return self.current_z - self.offset_z abs_z = property(_get_abs_z) def _get_abs_e(self): return self.current_e - self.offset_e abs_e = property(_get_abs_e) def _get_abs_e_multi(self,i): return self.current_e_multi[i] - self.offset_e_multi[i] abs_e = property(_get_abs_e) def _get_abs_pos(self): return (self.abs_x, self.abs_y, self.abs_z) abs_pos = property(_get_abs_pos) def _get_current_pos(self): return (self.current_x, self.current_y, self.current_z) current_pos = property(_get_current_pos) def _get_home_pos(self): return (self.home_x, self.home_y, self.home_z) def _set_home_pos(self, home_pos): if home_pos: self.home_x, self.home_y, self.home_z = home_pos home_pos = property(_get_home_pos, _set_home_pos) def _get_layers_count(self): return len(self.all_zs) layers_count = property(_get_layers_count) def __init__(self, data = None, home_pos = None, layer_callback = None, deferred = False): if not deferred: self.prepare(data, home_pos, layer_callback) def prepare(self, data = None, home_pos = None, layer_callback = None): self.home_pos = home_pos if data: line_class = self.line_class self.lines = [line_class(l2) for l2 in (l.strip() for l in data) if l2] self._preprocess(build_layers = True, layer_callback = layer_callback) else: self.lines = [] self.append_layer_id = 0 self.append_layer = Layer([]) self.all_layers = [self.append_layer] self.all_zs = set() self.layers = {} self.layer_idxs = array('I', []) self.line_idxs = array('I', []) def __len__(self): return len(self.line_idxs) def __iter__(self): return self.lines.__iter__() def prepend_to_layer(self, commands, layer_idx): # Prepend commands in reverse order commands = [c.strip() for c in commands[::-1] if c.strip()] layer = self.all_layers[layer_idx] # Find start index to append lines # and end index to append new indices start_index = self.layer_idxs.index(layer_idx) for i in range(start_index, len(self.layer_idxs)): if self.layer_idxs[i] != layer_idx: end_index = i break else: end_index = i + 1 end_line = self.line_idxs[end_index - 1] for i, command in enumerate(commands): gline = Line(command) # Split to get command split(gline) # Force is_move to False gline.is_move = False # Insert gline at beginning of layer layer.insert(0, gline) # Insert gline at beginning of list self.lines.insert(start_index, gline) # Update indices arrays & global gcodes list self.layer_idxs.insert(end_index + i, layer_idx) self.line_idxs.insert(end_index + i, end_line + i + 1) return commands[::-1] def rewrite_layer(self, commands, layer_idx): # Prepend commands in reverse order commands = [c.strip() for c in commands[::-1] if c.strip()] layer = self.all_layers[layer_idx] # Find start index to append lines # and end index to append new indices start_index = self.layer_idxs.index(layer_idx) for i in range(start_index, len(self.layer_idxs)): if self.layer_idxs[i] != layer_idx: end_index = i break else: end_index = i + 1 self.layer_idxs = self.layer_idxs[:start_index] + array('I', len(commands) * [layer_idx]) + self.layer_idxs[end_index:] self.line_idxs = self.line_idxs[:start_index] + array('I', range(len(commands))) + self.line_idxs[end_index:] del self.lines[start_index:end_index] del layer[:] for i, command in enumerate(commands): gline = Line(command) # Split to get command split(gline) # Force is_move to False gline.is_move = False # Insert gline at beginning of layer layer.insert(0, gline) # Insert gline at beginning of list self.lines.insert(start_index, gline) return commands[::-1] def append(self, command, store = True): command = command.strip() if not command: return gline = Line(command) self._preprocess([gline]) if store: self.lines.append(gline) self.append_layer.append(gline) self.layer_idxs.append(self.append_layer_id) self.line_idxs.append(len(self.append_layer)) return gline def _preprocess(self, lines = None, build_layers = False, layer_callback = None): """Checks for imperial/relativeness settings and tool changes""" if not lines: lines = self.lines imperial = self.imperial relative = self.relative relative_e = self.relative_e current_tool = self.current_tool current_x = self.current_x current_y = self.current_y current_z = self.current_z offset_x = self.offset_x offset_y = self.offset_y offset_z = self.offset_z # Extrusion computation current_e = self.current_e offset_e = self.offset_e total_e = self.total_e max_e = self.max_e current_e_multi = self.current_e_multi[current_tool] offset_e_multi = self.offset_e_multi[current_tool] total_e_multi = self.total_e_multi[current_tool] max_e_multi = self.max_e_multi[current_tool] # Store this one out of the build_layers scope for efficiency cur_layer_has_extrusion = False # Initialize layers and other global computations if build_layers: # Bounding box computation xmin = float("inf") ymin = float("inf") zmin = 0 xmax = float("-inf") ymax = float("-inf") zmax = float("-inf") # Also compute extrusion-only values xmin_e = float("inf") ymin_e = float("inf") xmax_e = float("-inf") ymax_e = float("-inf") # Duration estimation # TODO: # get device caps from firmware: max speed, acceleration/axis # (including extruder) # calculate the maximum move duration accounting for above ;) lastx = lasty = lastz = laste = lastf = 0.0 lastdx = 0 lastdy = 0 x = y = e = f = 0.0 currenttravel = 0.0 moveduration = 0.0 totalduration = 0.0 acceleration = 2000.0 # mm/s^2 layerbeginduration = 0.0 # Initialize layers all_layers = self.all_layers = [] all_zs = self.all_zs = set() layer_idxs = self.layer_idxs = [] line_idxs = self.line_idxs = [] layer_id = 0 layer_line = 0 last_layer_z = None prev_z = None prev_base_z = (None, None) cur_z = None cur_lines = [] if self.line_class != Line: get_line = lambda l: Line(l.raw) else: get_line = lambda l: l for true_line in lines: # # Parse line # Use a heavy copy of the light line to preprocess line = get_line(true_line) split_raw = split(line) if line.command: # Update properties if line.is_move: line.relative = relative line.relative_e = relative_e line.current_tool = current_tool elif line.command == "G20": imperial = True elif line.command == "G21": imperial = False elif line.command == "G90": relative = False relative_e = False elif line.command == "G91": relative = True relative_e = True elif line.command == "M82": relative_e = False elif line.command == "M83": relative_e = True elif line.command[0] == "T": current_tool = int(line.command[1:]) while(current_tool+1>len(self.current_e_multi)): self.current_e_multi+=[0] self.offset_e_multi+=[0] self.total_e_multi+=[0] self.max_e_multi+=[0] current_e_multi = self.current_e_multi[current_tool] offset_e_multi = self.offset_e_multi[current_tool] total_e_multi = self.total_e_multi[current_tool] max_e_multi = self.max_e_multi[current_tool] if line.command[0] == "G": parse_coordinates(line, split_raw, imperial) # Compute current position if line.is_move: x = line.x y = line.y z = line.z if line.f is not None: self.current_f = line.f if line.relative: x = current_x + (x or 0) y = current_y + (y or 0) z = current_z + (z or 0) else: if x is not None: x = x + offset_x if y is not None: y = y + offset_y if z is not None: z = z + offset_z if x is not None: current_x = x if y is not None: current_y = y if z is not None: current_z = z elif line.command == "G28": home_all = not any([line.x, line.y, line.z]) if home_all or line.x is not None: offset_x = 0 current_x = self.home_x if home_all or line.y is not None: offset_y = 0 current_y = self.home_y if home_all or line.z is not None: offset_z = 0 current_z = self.home_z elif line.command == "G92": if line.x is not None: offset_x = current_x - line.x if line.y is not None: offset_y = current_y - line.y if line.z is not None: offset_z = current_z - line.z line.current_x = current_x line.current_y = current_y line.current_z = current_z # # Process extrusion if line.e is not None: if line.is_move: if line.relative_e: line.extruding = line.e > 0 total_e += line.e current_e += line.e total_e_multi += line.e current_e_multi += line.e else: new_e = line.e + offset_e line.extruding = new_e > current_e total_e += new_e - current_e current_e = new_e new_e_multi = line.e + offset_e_multi total_e_multi += new_e_multi - current_e_multi current_e_multi = new_e_multi max_e = max(max_e, total_e) max_e_multi=max(max_e_multi, total_e_multi) cur_layer_has_extrusion |= line.extruding elif line.command == "G92": offset_e = current_e - line.e offset_e_multi = current_e_multi - line.e self.current_e_multi[current_tool]=current_e_multi self.offset_e_multi[current_tool]=offset_e_multi self.max_e_multi[current_tool]=max_e_multi self.total_e_multi[current_tool]=total_e_multi # # Create layers and perform global computations if build_layers: # Update bounding box if line.is_move: if line.extruding: if line.current_x is not None: xmin_e = min(xmin_e, line.current_x) xmax_e = max(xmax_e, line.current_x) if line.current_y is not None: ymin_e = min(ymin_e, line.current_y) ymax_e = max(ymax_e, line.current_y) if max_e <= 0: if line.current_x is not None: xmin = min(xmin, line.current_x) xmax = max(xmax, line.current_x) if line.current_y is not None: ymin = min(ymin, line.current_y) ymax = max(ymax, line.current_y) # Compute duration if line.command == "G0" or line.command == "G1": x = line.x if line.x is not None else lastx y = line.y if line.y is not None else lasty z = line.z if line.z is not None else lastz e = line.e if line.e is not None else laste # mm/s vs mm/m => divide by 60 f = line.f / 60.0 if line.f is not None else lastf # given last feedrate and current feedrate calculate the # distance needed to achieve current feedrate. # if travel is longer than req'd distance, then subtract # distance to achieve full speed, and add the time it took # to get there. # then calculate the time taken to complete the remaining # distance # FIXME: this code has been proven to be super wrong when 2 # subsquent moves are in opposite directions, as requested # speed is constant but printer has to fully decellerate # and reaccelerate # The following code tries to fix it by forcing a full # reacceleration if this move is in the opposite direction # of the previous one dx = x - lastx dy = y - lasty if dx * lastdx + dy * lastdy <= 0: lastf = 0 currenttravel = math.hypot(dx, dy) if currenttravel == 0: if line.z is not None: currenttravel = abs(line.z) if line.relative else abs(line.z - lastz) elif line.e is not None: currenttravel = abs(line.e) if line.relative_e else abs(line.e - laste) # Feedrate hasn't changed, no acceleration/decceleration planned if f == lastf: moveduration = currenttravel / f if f != 0 else 0. else: # FIXME: review this better # this looks wrong : there's little chance that the feedrate we'll decelerate to is the previous feedrate # shouldn't we instead look at three consecutive moves ? distance = 2 * abs(((lastf + f) * (f - lastf) * 0.5) / acceleration) # multiply by 2 because we have to accelerate and decelerate if distance <= currenttravel and lastf + f != 0 and f != 0: moveduration = 2 * distance / (lastf + f) # This is distance / mean(lastf, f) moveduration += (currenttravel - distance) / f else: moveduration = 2 * currenttravel / (lastf + f) # This is currenttravel / mean(lastf, f) # FIXME: probably a little bit optimistic, but probably a much better estimate than the previous one: # moveduration = math.sqrt(2 * distance / acceleration) # probably buggy : not taking actual travel into account lastdx = dx lastdy = dy totalduration += moveduration lastx = x lasty = y lastz = z laste = e lastf = f elif line.command == "G4": moveduration = P(line) if moveduration: moveduration /= 1000.0 totalduration += moveduration # FIXME : looks like this needs to be tested with "lift Z on move" if line.z is not None: if line.command == "G92": cur_z = line.z elif line.is_move: if line.relative and cur_z is not None: cur_z += line.z else: cur_z = line.z # FIXME: the logic behind this code seems to work, but it might be # broken if cur_z != prev_z: if prev_z is not None and last_layer_z is not None: offset = self.est_layer_height if self.est_layer_height else 0.01 if abs(prev_z - last_layer_z) < offset: if self.est_layer_height is None: zs = sorted([l.z for l in all_layers if l.z is not None]) heights = [round(zs[i + 1] - zs[i], 3) for i in range(len(zs) - 1)] heights = [height for height in heights if height] if len(heights) >= 2: self.est_layer_height = heights[1] elif heights: self.est_layer_height = heights[0] else: self.est_layer_height = 0.1 base_z = round(prev_z - (prev_z % self.est_layer_height), 2) else: base_z = round(prev_z, 2) else: base_z = prev_z if base_z != prev_base_z: new_layer = Layer(cur_lines, base_z) new_layer.duration = totalduration - layerbeginduration layerbeginduration = totalduration all_layers.append(new_layer) if cur_layer_has_extrusion and prev_z not in all_zs: all_zs.add(prev_z) cur_lines = [] cur_layer_has_extrusion = False layer_id += 1 layer_line = 0 last_layer_z = base_z if layer_callback is not None: layer_callback(self, len(all_layers) - 1) prev_base_z = base_z if build_layers: cur_lines.append(true_line) layer_idxs.append(layer_id) line_idxs.append(layer_line) layer_line += 1 prev_z = cur_z # ## Loop done # Store current status self.imperial = imperial self.relative = relative self.relative_e = relative_e self.current_tool = current_tool self.current_x = current_x self.current_y = current_y self.current_z = current_z self.offset_x = offset_x self.offset_y = offset_y self.offset_z = offset_z self.current_e = current_e self.offset_e = offset_e self.max_e = max_e self.total_e = total_e self.current_e_multi[current_tool]=current_e_multi self.offset_e_multi[current_tool]=offset_e_multi self.max_e_multi[current_tool]=max_e_multi self.total_e_multi[current_tool]=total_e_multi # Finalize layers if build_layers: if cur_lines: new_layer = Layer(cur_lines, prev_z) new_layer.duration = totalduration - layerbeginduration layerbeginduration = totalduration all_layers.append(new_layer) if cur_layer_has_extrusion and prev_z not in all_zs: all_zs.add(prev_z) self.append_layer_id = len(all_layers) self.append_layer = Layer([]) self.append_layer.duration = 0 all_layers.append(self.append_layer) self.layer_idxs = array('I', layer_idxs) self.line_idxs = array('I', line_idxs) # Compute bounding box all_zs = self.all_zs.union(set([zmin])).difference(set([None])) zmin = min(all_zs) zmax = max(all_zs) self.filament_length = self.max_e while len(self.filament_length_multi)<len(self.max_e_multi): self.filament_length_multi+=[0] for i in enumerate(self.max_e_multi): self.filament_length_multi[i[0]]=i[1] if self.filament_length > 0: self.xmin = xmin_e if not math.isinf(xmin_e) else 0 self.xmax = xmax_e if not math.isinf(xmax_e) else 0 self.ymin = ymin_e if not math.isinf(ymin_e) else 0 self.ymax = ymax_e if not math.isinf(ymax_e) else 0 else: self.xmin = xmin if not math.isinf(xmin) else 0 self.xmax = xmax if not math.isinf(xmax) else 0 self.ymin = ymin if not math.isinf(ymin) else 0 self.ymax = ymax if not math.isinf(ymax) else 0 self.zmin = zmin if not math.isinf(zmin) else 0 self.zmax = zmax if not math.isinf(zmax) else 0 self.width = self.xmax - self.xmin self.depth = self.ymax - self.ymin self.height = self.zmax - self.zmin # Finalize duration totaltime = datetime.timedelta(seconds = int(totalduration)) self.duration = totaltime def idxs(self, i): return self.layer_idxs[i], self.line_idxs[i] def estimate_duration(self): return self.layers_count, self.duration class LightGCode(GCode): line_class = LightLine def main(): if len(sys.argv) < 2: print "usage: %s filename.gcode" % sys.argv[0] return print "Line object size:", sys.getsizeof(Line("G0 X0")) print "Light line object size:", sys.getsizeof(LightLine("G0 X0")) gcode = GCode(open(sys.argv[1], "rU")) print "Dimensions:" xdims = (gcode.xmin, gcode.xmax, gcode.width) print "\tX: %0.02f - %0.02f (%0.02f)" % xdims ydims = (gcode.ymin, gcode.ymax, gcode.depth) print "\tY: %0.02f - %0.02f (%0.02f)" % ydims zdims = (gcode.zmin, gcode.zmax, gcode.height) print "\tZ: %0.02f - %0.02f (%0.02f)" % zdims print "Filament used: %0.02fmm" % gcode.filament_length for i in enumerate(gcode.filament_length_multi): print "E%d %0.02fmm" % (i[0],i[1]) print "Number of layers: %d" % gcode.layers_count print "Estimated duration: %s" % gcode.estimate_duration()[1] if __name__ == '__main__': main()
