Trac3r-python/main.py

from tkinter import Tk, Label, filedialog, Button
from PIL import Image, ImageTk
from svgpathtools import svg2paths, Line, QuadraticBezier, CubicBezier
import cairo, subprocess, bezier, os, math, time
import numpy as np


class GCoder(Tk):
    def __init__(self):
        super().__init__()

        # Setup the file structure
        if not os.path.exists("output"):
            os.makedirs("output")

        # Height at which the pen touches and draws on the surface
        self.touch_height = 20
        # How far to raise the pen tip to raise it off the page
        self.raise_height = 2
        # The inherent offset from true 0 we have from the pen bracket
        self.head_x_offset = 50
        # XY movement speed
        self.speed = 500
        # Weather we render lift markers
        self.lift_markers = True

        # X and Y offsets to place the image on A11 paper
        self.offset_x = 75 + self.head_x_offset
        self.offset_y = 20

        # Bed dimensions to fit A11 paper
        self.bed_max_x = 280
        self.bed_min_x = self.offset_x
        self.bed_max_y = 280
        self.bed_min_y = 20
        self.started = False

        self.gcode_preamble = '''
        G91         ; Set to relative mode for the initial pen lift
        G1 Z20      ; Lift head by 20
        G90         ; Set back to absolute position mode
        M107        ; Fan off
        M190 S0     ; Set bed temp
        M104 S0     ; Set nozzle temp
        G28         ; home all axes
        G0 F{1}     ; Set the feed rate
        G1 Z{0}     ; Move the pen to just above the paper
        '''.format(self.touch_height + self.raise_height, self.speed)

        self.gcode_end = '''
        G1 Z{0} F7000   ; Raise the pen high up so we can fit a cap onto it
        M104 S0         ; Set the nozzle to 0
        G28 X0 Y0       ; Home back to (0,0) for (x,y)
        M84             ; Turn off the motors
        '''.format(75)

        w, h = 300, 300

        self.geometry("{}x{}".format(w, h))

        self.surface = cairo.ImageSurface(cairo.FORMAT_ARGB32, 300, 300)

        self.context = cairo.Context(self.surface)
        self.context.scale(1, 1)
        self.context.set_line_width(0.4)


        self.button = Button(self, text="Select Image", command=self.file_select_callback)
        self.button.pack()

        self.mainloop()

    def file_select_callback(self):
        filepath = filedialog.askopenfilename(initialdir=".", title="Select file",
                                                   filetypes=(("jpeg files", "*.jpg"), ("all files", "*.*")))
        if len(filepath) is 0:
            return

        self.context.rectangle(0, 0, 300, 300)
        self.context.set_source_rgba(1, 1, 1, 1.0)
        self.context.fill()

        self.context.set_source_rgba(0, 0, 0, 1.0)

        filename = os.path.basename(filepath)
        self.convert_image(filename)
        self.convert_gcode()
        self.render_gcode()

        self._image_ref = ImageTk.PhotoImage(
            Image.frombuffer("RGBA", (300, 300), self.surface.get_data().tobytes(), "raw", "BGRA", 0, 1))
        self.label = Label(self, image=self._image_ref)
        self.label.pack(expand=True, fill="both")

    def convert_image(self, file_name):

        base_name = file_name.split(".")[0]

        print("Converting input file [{}]".format(file_name))

        print("Running mogrify...")
        start = time.time()
        subprocess.call(["mogrify", "-format", "bmp", "input-images/{}".format(file_name)])
        print("Run took [{:.2f}] seconds".format(time.time() - start))

        print("Running mkbitmap...")
        start = time.time()
        subprocess.call(["mkbitmap", "input-images/{}.bmp".format(base_name), "-x",
                         "-f", "15",
                         # "-b", "0",
                         "-o", "input-images/{}-n.bmp".format(base_name)
                         ])
        print("Run took [{:.2f}] seconds".format(time.time() - start))

        print("Running potrace...")
        start = time.time()
        subprocess.call(["potrace",
                         "-t", "20",
                         "-z", "white",
                         "-b", "svg",
                         "input-images/{}-n.bmp".format(base_name),
                         "--rotate", "0",
                         "-o", "tmp/conversion-output.svg",
                         ])
        print("Run took [{:.2f}] seconds\n".format(time.time() - start))

    def render_gcode(self):

        file = open("output/gcode-output.gcode", "r")

        largest_x    = 0
        largest_y    = 0
        smallest_x   = 300
        smallest_y   = 300
        x            = None
        y            = None

        for line in file:

            split = line.split(" ")
            command = split[0]
            operands = split[1:]

            prev_x = x
            prev_y = y

            if command == "G1":
                for operand in operands:
                    if operand.startswith("X"):
                        x = float(operand[1:])
                        if x > largest_x: largest_x = x
                        if x < smallest_x: smallest_x = x
                    elif operand.startswith("Y"):
                        y = float(operand[1:])
                        if y > largest_y: largest_y = y
                        if y < smallest_y: smallest_y = y
                    elif operand.startswith("Z{}".format(self.touch_height + self.raise_height)):

                        # signify a lift
                        if prev_x is not None and prev_y is not None and self.lift_markers:
                            self.context.arc(prev_x - self.head_x_offset, prev_y, 0.5, 0, 2*math.pi)
                            self.context.stroke()

                        prev_x = None
                        prev_y = None
                        x = None
                        y = None

            if (prev_x != x and prev_x is not None) or (prev_y != y and prev_y is not None):
                self.context.line_to(prev_x - self.head_x_offset, prev_y)
                self.context.line_to(x - self.head_x_offset, y)
                self.context.stroke()


        print("Largest  X : " + str(largest_x))
        print("Smallest X : " + str(smallest_x))

        print("Largest  Y : " + str(largest_y))
        print("Smallest Y : " + str(smallest_y))

        if largest_x > self.bed_max_x:
            print("X OVERFLOW")
        if largest_y > self.bed_max_y:
            print("Y OVERFLOW")

        if smallest_x < self.bed_min_x:
            print("X_UNDERFLOW")
        if smallest_y < self.bed_min_y:
            print("Y_UNDERFLOW")

    def convert_gcode(self):

        # read in the svg
        paths, attributes = svg2paths("tmp/conversion-output.svg")

        bounding_x_max = None
        bounding_x_min = None
        bounding_y_max = None
        bounding_y_min = None

        for path in paths:

            bbox = path.bbox()

            if bounding_x_max is None or bbox[0] > bounding_x_max:
                bounding_x_max = bbox[0]
            if bounding_x_min is None or bbox[1] < bounding_x_min:
                bounding_x_min = bbox[1]

            if bounding_y_max is None or bbox[2] > bounding_y_max:
                bounding_y_max = bbox[2]
            if bounding_y_min is None or bbox[3] > bounding_y_min:
                bounding_y_min = bbox[3]

        print("Maximum X : {}".format(bounding_x_max))
        print("Minimum Y : {}".format(bounding_x_min))
        print("Maximum X : {}".format(bounding_y_max))
        print("Minimum Y : {}".format(bounding_y_min))

        max_dim = max(bounding_x_max, bounding_x_min, bounding_y_max, bounding_y_min)
        scale = (300 - self.offset_x) / max_dim
        print("Scaling to : {}\n".format(scale))

        # Start the gcode
        gcode = ""
        gcode += self.gcode_preamble

        # Walk through the paths and create the GCODE
        for path in paths:

            previous_x = None
            previous_y = None

            for part in path:

                start = part.start
                end = part.end

                start_x = start.real * scale + self.offset_x
                start_y = start.imag * scale + self.offset_y

                end_x = end.real * scale + self.offset_x
                end_y = end.imag * scale + self.offset_y

                # Check to see if the endpoint of the last cycle continues and wether we need to lift the pen or not
                lift = True
                if previous_x is not None and previous_y is not None:
                    if abs(start.real - previous_x) < 30 and abs(start.imag - previous_y) < 30:
                        lift = False

                # if the pen needs to lift,
                # if lift:
                previous_x = end.real
                previous_y = end.imag

                if lift:
                    gcode += "G1 Z{}\n".format(self.raise_height + self.touch_height)
                else:
                    gcode += "# NOT LIFTING\n"

                if isinstance(part, CubicBezier):

                    nodes = np.asfortranarray([
                        [start.real, part.control1.real, part.control2.real, end.real],
                        [start.imag, part.control1.imag, part.control2.imag, end.imag],
                    ])

                    curve = bezier.Curve.from_nodes(nodes)

                    evals = []
                    pos = np.linspace(0.1, 1, 10)
                    for i in pos:
                        evals.append(curve.evaluate(i))

                    gcode += "G1 X{} Y{}\n".format(start_x, start_y)
                    gcode += "G1 Z{} \n".format(self.touch_height)

                    for i in evals:
                        x = i[0][0]
                        y = i[1][0]
                        gcode += "G1 X{} Y{}\n".format(x * scale + self.offset_x, y * scale + self.offset_y)

                if isinstance(part, Line):
                    gcode += "G1 X{} Y{}\n".format(start_x, start_y)
                    gcode += "G1 Z{} \n".format(self.touch_height)
                    gcode += "G1 X{} Y{}\n".format(end_x, end_y)

        gcode += self.gcode_end

        output_gcode = open("output/gcode-output.gcode", "w")
        output_gcode.write(gcode)
        output_gcode.close()

if __name__ == "__main__":
    GCoder()
Added UI 6 years ago			`from tkinter import Tk, Label, filedialog, Button`
			`from PIL import Image, ImageTk`
init 6 years ago			`from svgpathtools import svg2paths, Line, QuadraticBezier, CubicBezier`
Added UI 6 years ago			`import cairo, subprocess, bezier, os, math, time`
			`import numpy as np`
init 6 years ago

Added UI 6 years ago			`class GCoder(Tk):`
			`def __init__(self):`
			`super().__init__()`

			`# Setup the file structure`
			`if not os.path.exists("output"):`
			`os.makedirs("output")`

			`# Height at which the pen touches and draws on the surface`
			`self.touch_height = 20`
			`# How far to raise the pen tip to raise it off the page`
			`self.raise_height = 2`
			`# The inherent offset from true 0 we have from the pen bracket`
			`self.head_x_offset = 50`
			`# XY movement speed`
			`self.speed = 500`
			`# Weather we render lift markers`
			`self.lift_markers = True`

			`# X and Y offsets to place the image on A11 paper`
			`self.offset_x = 75 + self.head_x_offset`
			`self.offset_y = 20`

			`# Bed dimensions to fit A11 paper`
			`self.bed_max_x = 280`
			`self.bed_min_x = self.offset_x`
			`self.bed_max_y = 280`
			`self.bed_min_y = 20`
			`self.started = False`

			`self.gcode_preamble = '''`
			`G91 ; Set to relative mode for the initial pen lift`
			`G1 Z20 ; Lift head by 20`
			`G90 ; Set back to absolute position mode`
			`M107 ; Fan off`
			`M190 S0 ; Set bed temp`
			`M104 S0 ; Set nozzle temp`
			`G28 ; home all axes`
			`G0 F{1} ; Set the feed rate`
			`G1 Z{0} ; Move the pen to just above the paper`
			`'''.format(self.touch_height + self.raise_height, self.speed)`

			`self.gcode_end = '''`
			`G1 Z{0} F7000 ; Raise the pen high up so we can fit a cap onto it`
			`M104 S0 ; Set the nozzle to 0`
			`G28 X0 Y0 ; Home back to (0,0) for (x,y)`
			`M84 ; Turn off the motors`
			`'''.format(75)`

			`w, h = 300, 300`

			`self.geometry("{}x{}".format(w, h))`

			`self.surface = cairo.ImageSurface(cairo.FORMAT_ARGB32, 300, 300)`

			`self.context = cairo.Context(self.surface)`
			`self.context.scale(1, 1)`
			`self.context.set_line_width(0.4)`


			`self.button = Button(self, text="Select Image", command=self.file_select_callback)`
			`self.button.pack()`

			`self.mainloop()`

			`def file_select_callback(self):`
			`filepath = filedialog.askopenfilename(initialdir=".", title="Select file",`
			`filetypes=(("jpeg files", ".jpg"), ("all files", ".*")))`
			`if len(filepath) is 0:`
			`return`

			`self.context.rectangle(0, 0, 300, 300)`
			`self.context.set_source_rgba(1, 1, 1, 1.0)`
			`self.context.fill()`

			`self.context.set_source_rgba(0, 0, 0, 1.0)`

			`filename = os.path.basename(filepath)`
			`self.convert_image(filename)`
			`self.convert_gcode()`
			`self.render_gcode()`

			`self._image_ref = ImageTk.PhotoImage(`
			`Image.frombuffer("RGBA", (300, 300), self.surface.get_data().tobytes(), "raw", "BGRA", 0, 1))`
			`self.label = Label(self, image=self._image_ref)`
			`self.label.pack(expand=True, fill="both")`

			`def convert_image(self, file_name):`

			`base_name = file_name.split(".")[0]`

			`print("Converting input file [{}]".format(file_name))`

			`print("Running mogrify...")`
			`start = time.time()`
			`subprocess.call(["mogrify", "-format", "bmp", "input-images/{}".format(file_name)])`
			`print("Run took [{:.2f}] seconds".format(time.time() - start))`

			`print("Running mkbitmap...")`
			`start = time.time()`
			`subprocess.call(["mkbitmap", "input-images/{}.bmp".format(base_name), "-x",`
			`"-f", "15",`
			`# "-b", "0",`
			`"-o", "input-images/{}-n.bmp".format(base_name)`
			`])`
			`print("Run took [{:.2f}] seconds".format(time.time() - start))`

			`print("Running potrace...")`
			`start = time.time()`
			`subprocess.call(["potrace",`
			`"-t", "20",`
			`"-z", "white",`
			`"-b", "svg",`
			`"input-images/{}-n.bmp".format(base_name),`
			`"--rotate", "0",`
			`"-o", "tmp/conversion-output.svg",`
			`])`
			`print("Run took [{:.2f}] seconds\n".format(time.time() - start))`

			`def render_gcode(self):`

			`file = open("output/gcode-output.gcode", "r")`

			`largest_x = 0`
			`largest_y = 0`
			`smallest_x = 300`
			`smallest_y = 300`
			`x = None`
			`y = None`

			`for line in file:`

			`split = line.split(" ")`
			`command = split[0]`
			`operands = split[1:]`
init 6 years ago
Added UI 6 years ago			`prev_x = x`
			`prev_y = y`
init 6 years ago
Added UI 6 years ago			`if command == "G1":`
			`for operand in operands:`
			`if operand.startswith("X"):`
			`x = float(operand[1:])`
			`if x > largest_x: largest_x = x`
			`if x < smallest_x: smallest_x = x`
			`elif operand.startswith("Y"):`
			`y = float(operand[1:])`
			`if y > largest_y: largest_y = y`
			`if y < smallest_y: smallest_y = y`
			`elif operand.startswith("Z{}".format(self.touch_height + self.raise_height)):`
init 6 years ago
Added UI 6 years ago			`# signify a lift`
			`if prev_x is not None and prev_y is not None and self.lift_markers:`
			`self.context.arc(prev_x - self.head_x_offset, prev_y, 0.5, 0, 2*math.pi)`
			`self.context.stroke()`
init 6 years ago
Added UI 6 years ago			`prev_x = None`
			`prev_y = None`
			`x = None`
			`y = None`

			`if (prev_x != x and prev_x is not None) or (prev_y != y and prev_y is not None):`
			`self.context.line_to(prev_x - self.head_x_offset, prev_y)`
			`self.context.line_to(x - self.head_x_offset, y)`
			`self.context.stroke()`


			`print("Largest X : " + str(largest_x))`
			`print("Smallest X : " + str(smallest_x))`
init 6 years ago
Added UI 6 years ago			`print("Largest Y : " + str(largest_y))`
			`print("Smallest Y : " + str(smallest_y))`

			`if largest_x > self.bed_max_x:`
			`print("X OVERFLOW")`
			`if largest_y > self.bed_max_y:`
			`print("Y OVERFLOW")`

			`if smallest_x < self.bed_min_x:`
			`print("X_UNDERFLOW")`
			`if smallest_y < self.bed_min_y:`
			`print("Y_UNDERFLOW")`

			`def convert_gcode(self):`

			`# read in the svg`
			`paths, attributes = svg2paths("tmp/conversion-output.svg")`

			`bounding_x_max = None`
			`bounding_x_min = None`
			`bounding_y_max = None`
			`bounding_y_min = None`

			`for path in paths:`

			`bbox = path.bbox()`

			`if bounding_x_max is None or bbox[0] > bounding_x_max:`
			`bounding_x_max = bbox[0]`
			`if bounding_x_min is None or bbox[1] < bounding_x_min:`
			`bounding_x_min = bbox[1]`

			`if bounding_y_max is None or bbox[2] > bounding_y_max:`
			`bounding_y_max = bbox[2]`
			`if bounding_y_min is None or bbox[3] > bounding_y_min:`
			`bounding_y_min = bbox[3]`
init 6 years ago
Added UI 6 years ago			`print("Maximum X : {}".format(bounding_x_max))`
			`print("Minimum Y : {}".format(bounding_x_min))`
			`print("Maximum X : {}".format(bounding_y_max))`
			`print("Minimum Y : {}".format(bounding_y_min))`
init 6 years ago
Added UI 6 years ago			`max_dim = max(bounding_x_max, bounding_x_min, bounding_y_max, bounding_y_min)`
			`scale = (300 - self.offset_x) / max_dim`
			`print("Scaling to : {}\n".format(scale))`
init 6 years ago
Added UI 6 years ago			`# Start the gcode`
			`gcode = ""`
			`gcode += self.gcode_preamble`
init 6 years ago
Added UI 6 years ago			`# Walk through the paths and create the GCODE`
			`for path in paths:`
init 6 years ago
Added UI 6 years ago			`previous_x = None`
			`previous_y = None`
init 6 years ago
Added UI 6 years ago			`for part in path:`
init 6 years ago
Added UI 6 years ago			`start = part.start`
			`end = part.end`
init 6 years ago
Added UI 6 years ago			`start_x = start.real * scale + self.offset_x`
			`start_y = start.imag * scale + self.offset_y`
init 6 years ago
Added UI 6 years ago			`end_x = end.real * scale + self.offset_x`
			`end_y = end.imag * scale + self.offset_y`
init 6 years ago
Added UI 6 years ago			`# Check to see if the endpoint of the last cycle continues and wether we need to lift the pen or not`
			`lift = True`
			`if previous_x is not None and previous_y is not None:`
			`if abs(start.real - previous_x) < 30 and abs(start.imag - previous_y) < 30:`
			`lift = False`
init 6 years ago
Added UI 6 years ago			`# if the pen needs to lift,`
			`# if lift:`
			`previous_x = end.real`
			`previous_y = end.imag`
init 6 years ago
Added UI 6 years ago			`if lift:`
			`gcode += "G1 Z{}\n".format(self.raise_height + self.touch_height)`
			`else:`
			`gcode += "# NOT LIFTING\n"`
init 6 years ago
Added UI 6 years ago			`if isinstance(part, CubicBezier):`
init 6 years ago
Added UI 6 years ago			`nodes = np.asfortranarray([`
			`[start.real, part.control1.real, part.control2.real, end.real],`
			`[start.imag, part.control1.imag, part.control2.imag, end.imag],`
			`])`
init 6 years ago
Added UI 6 years ago			`curve = bezier.Curve.from_nodes(nodes)`
init 6 years ago
Added UI 6 years ago			`evals = []`
			`pos = np.linspace(0.1, 1, 10)`
			`for i in pos:`
			`evals.append(curve.evaluate(i))`
init 6 years ago
Added UI 6 years ago			`gcode += "G1 X{} Y{}\n".format(start_x, start_y)`
			`gcode += "G1 Z{} \n".format(self.touch_height)`
init 6 years ago
Added UI 6 years ago			`for i in evals:`
			`x = i[0][0]`
			`y = i[1][0]`
			`gcode += "G1 X{} Y{}\n".format(x * scale + self.offset_x, y * scale + self.offset_y)`
init 6 years ago
Added UI 6 years ago			`if isinstance(part, Line):`
			`gcode += "G1 X{} Y{}\n".format(start_x, start_y)`
			`gcode += "G1 Z{} \n".format(self.touch_height)`
			`gcode += "G1 X{} Y{}\n".format(end_x, end_y)`
init 6 years ago
Added UI 6 years ago			`gcode += self.gcode_end`
init 6 years ago
Added UI 6 years ago			`output_gcode = open("output/gcode-output.gcode", "w")`
			`output_gcode.write(gcode)`
			`output_gcode.close()`
init 6 years ago
Added UI 6 years ago			`if __name__ == "__main__":`
			`GCoder()`
init 6 years ago