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mirror of https://gitlab.com/kicad/code/kicad.git synced 2024-11-25 16:35:01 +00:00
kicad/pcbnew/python/plugins/PadArray.py
jean-pierre charras 8fc70d577f better QFNWizard.
2023-04-23 17:34:21 +02:00

481 lines
15 KiB
Python

# PadArray.py
#
# Copyright 2014 john <john@johndev>
#
# This program 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 2 of the License, or
# (at your option) any later version.
#
# This program 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 this program; if not, write to the Free Software
# Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
# MA 02110-1301, USA.
#
#
from __future__ import division
import math
import pcbnew
class PadMaker(object):
"""!
Useful construction functions for common types of pads, providing
sensible defaults for common pads.
"""
def __init__(self, module):
"""!
@param module: the module the pads will be part of
"""
self.module = module
def THPad(self, Vsize, Hsize, drill, shape=pcbnew.PAD_SHAPE_OVAL,
rot_degree = 0):
"""!
A basic through-hole pad of the given size and shape
@param Vsize: the vertical size of the pad
@param Hsize: the horizontal size of the pad
@param drill: the drill diameter
@param shape: the shape of the pad
@param rot_degree: the pad rotation, in degrees
"""
pad = pcbnew.PAD(self.module)
pad.SetSize(pcbnew.VECTOR2I( int(Hsize), int(Vsize) ))
pad.SetShape(shape)
pad.SetAttribute(pcbnew.PAD_ATTRIB_PTH)
pad.SetLayerSet(pad.PTHMask())
pad.SetDrillSize(pcbnew.VECTOR2I( int(drill), int(drill) ))
pad.SetOrientation( pcbnew.EDA_ANGLE( rot_degree, pcbnew.DEGREES_T ) )
return pad
def THRoundPad(self, size, drill):
"""!
A round though-hole pad. A shortcut for THPad()
@param size: pad diameter
@param drill: drill diameter
"""
pad = self.THPad(size, size, drill, shape=pcbnew.PAD_SHAPE_CIRCLE)
return pad
def NPTHRoundPad(self, drill):
"""!
A round non-plated though hole (NPTH)
@param drill: the drill diameter (equals the NPTH diameter)
"""
pad = pcbnew.PAD(self.module)
pad.SetSize(pcbnew.VECTOR2I( int(drill), int(drill) ))
pad.SetShape(pcbnew.PAD_SHAPE_CIRCLE)
pad.SetAttribute(pcbnew.PAD_ATTRIB_NPTH)
pad.SetLayerSet(pad.UnplatedHoleMask())
pad.SetDrillSize(pcbnew.VECTOR2I( int(drill), int(drill) ))
return pad
def SMDPad(self, Vsize, Hsize, shape=pcbnew.PAD_SHAPE_RECT, rot_degree=0):
"""
Create a surface-mount pad of the given size and shape
@param Vsize: the vertical size of the pad
@param Hsize: the horizontal size of the pad
@param shape: the shape of the pad
@param rot_degree: the pad rotation, in degrees
"""
pad = pcbnew.PAD(self.module)
pad.SetSize(pcbnew.VECTOR2I( int(Hsize), int(Vsize) ) )
pad.SetShape(shape)
pad.SetAttribute(pcbnew.PAD_ATTRIB_SMD)
pad.SetLayerSet(pad.SMDMask())
pad.SetOrientation( pcbnew.EDA_ANGLE( rot_degree, pcbnew.DEGREES_T ) )
return pad
def AperturePad(self, Vsize, Hsize, shape=pcbnew.PAD_SHAPE_RECT, rot_degree=0):
"""
Create a aperture pad of the given size and shape, i.e. a smd pad shape
on the solder paste and not on a copper
layer
@param Vsize: the vertical size of the aperture
@param Hsize: the horizontal size of the aperture
@param shape: the shape of the pad
@param rot_degree: the pad rotation, in degrees
"""
pad = pcbnew.PAD(self.module)
pad.SetSize(pcbnew.VECTOR2I( int(Hsize), int(Vsize) ) )
pad.SetShape(shape)
pad.SetAttribute(pcbnew.PAD_ATTRIB_SMD)
pad.SetLayerSet(pad.ApertureMask())
pad.SetOrientation( pcbnew.EDA_ANGLE( rot_degree, pcbnew.DEGREES_T ) )
return pad
def SMTRoundPad(self, size):
"""!
A round surface-mount pad. A shortcut for SMDPad()
@param size: pad diameter
"""
pad = self.SMDPad(size, size, shape=pcbnew.PAD_SHAPE_CIRCLE)
return pad
class PadArray(object):
"""!
A class to assist in creating repetitive grids of pads
Generally, PadArrays have an internal prototypical pad, and copy this
for each pad in the array. They can also have a special pad for the
first pad, and a custom function to name the pad.
Generally, PadArray is used as a base class for more specific array
types.
"""
def __init__(self, pad):
"""!
@param pad: the prototypical pad
"""
self.firstPadNum = 1
self.pinNames = None
# this pad is more of a "context", we will use it as a source of
# pad data, but not actually add it
self.pad = pad
self.firstPad = None
def SetPinNames(self, pinNames):
"""!
Set a name for all the pins. If given, this overrides the
naming function.
@param pinNames: the name to use for all pins
"""
self.pinNames = pinNames
def SetFirstPadType(self, firstPad):
"""!
If the array has a different first pad, this is the pad that
is used
@param firstPad: the prototypical first pad
"""
self.firstPad = firstPad
def SetFirstPadInArray(self, fpNum):
"""!
Set the numbering for the first pad in the array
@param fpNum: the number for the first pad
"""
self.firstPadNum = fpNum
def AddPad(self, pad):
"""!
Add a pad to the array, under the same footprint as the main
prototype pad
@param pad: pad to add
"""
self.pad.GetParent().Add(pad)
def GetPad(self, is_first_pad, pos):
"""!
Get a pad in the array with the given position
@param is_first_pad: use the special first pad if there is one
@param pos: the pad position
"""
if (self.firstPad and is_first_pad):
pad = self.firstPad
else:
pad = self.pad
# create a new pad with same characteristics
pad = pad.Duplicate()
pad.SetPosition(pos)
return pad
def GetName(self, *args, **kwargs):
"""!
Get the pad name from the naming function, or the pre-set
pinNames parameter (set with SetPinNames)
"""
if self.pinNames is None:
return self.NamingFunction(*args, **kwargs)
return self.pinNames
def NamingFunction(self, *args, **kwargs):
"""!
Implement this as needed for each array type
"""
raise NotImplementedError;
class PadGridArray(PadArray):
"""!
A basic grid of pads
"""
def __init__(self, pad, nx, ny, px, py, centre=pcbnew.VECTOR2I(0, 0)):
"""!
@param pad: the prototypical pad of the array
@param nx: number of pads in x-direction
@param ny: number of pads in y-direction
@param px: pitch in x-direction
@param py: pitch in y-direction
@param centre: array centre point
"""
try:
super().__init__(pad)
except TypeError:
super(PadGridArray, self).__init__(pad)
self.nx = int(nx)
self.ny = int(ny)
self.px = px
self.py = py
self.centre = centre
def AlphaNameFromNumber(self, n, aIndex=1,
alphabet="ABCDEFGHIJKLMNOPQRSTUVWXYZ"):
"""!
Utility function to generate an alphabetical name:
eg. 1 - A, 2 - B, 26 - AA, etc
@param aIndex: index of 'A': 0 for 0 - A
@param n: the pad index
@param alphabet: set of allowable chars if not A-Z,
e.g. ABCDEFGHJKLMNPRTUVWY for BGA
"""
div, mod = divmod(n - aIndex, len(alphabet))
alpha = alphabet[mod]
if div > 0:
return self.AlphaNameFromNumber(div, aIndex, alphabet) + alpha
return alpha
def NamingFunction(self, x, y):
"""!
Implementation of the naming function: right to left, top-to-bottom
@param x: the pad x index
@param y: the pad y index
"""
return self.firstPadNum + (self.nx * y + x)
#relocate the pad and add it as many times as we need
def AddPadsToModule(self, dc):
"""!
Create the pads and add them to the module in the correct positions
@param dc: the drawing context
"""
pin1posX = self.centre.x - self.px * (self.nx - 1) / 2
pin1posY = self.centre.y - self.py * (self.ny - 1) / 2
for x in range(0, self.nx):
posX = pin1posX + (x * self.px)
for y in range(self.ny):
posY = pin1posY + (self.py * y)
pos = dc.TransformPoint(posX, posY)
pad = self.GetPad(x == 0 and y == 0, pos)
pad.SetName(self.GetName(x,y))
self.AddPad(pad)
class EPADGridArray(PadGridArray):
"""!
A pad grid array with a fixed name, used for things like thermal
pads and via grids.
"""
def NamingFunction(self, nx, ny):
"""!
Simply return the firstPadNum
@param nx: not used
@param ny: not used
"""
return self.firstPadNum
class PadZGridArray(PadArray):
"""!
A staggered pin array
"""
def __init__(self, pad, pad_count, line_count, line_pitch,
pad_pitch, centre=pcbnew.VECTOR2I(0, 0)):
"""!
@param pad: the prototypical pad
@param pad_count: total pad count
@param line_count: number of staggered lines
@param line_pitch: distance between lines
@param pad_pitch: distance between pads in a line
@param centre: array centre point
"""
super(PadZGridArray, self).__init__(pad)
self.pad_count = int(pad_count)
self.line_count = int(line_count)
self.line_pitch = line_pitch
self.pad_pitch = pad_pitch
self.centre = centre
def NamingFunction(self, pad_pos):
"""!
Naming just increased with pad index in array
"""
return self.firstPadNum + pad_pos
def AddPadsToModule(self, dc):
"""!
Create the pads and add them to the module in the correct positions
@param dc: the drawing context
"""
pin1posX = self.centre.x - self.pad_pitch * (self.pad_count - 1) / 2
pin1posY = self.centre.y + self.line_pitch * (self.line_count - 1) / 2
line = 0
for padnum in range(0, self.pad_count):
posX = pin1posX + (padnum * self.pad_pitch)
posY = pin1posY - (self.line_pitch * line)
pos = dc.TransformPoint(posX, posY)
pad = self.GetPad(padnum == 0, pos)
pad.SetName(self.GetName(padnum))
self.AddPad(pad)
line += 1
if line >= self.line_count:
line = 0
class PadLineArray(PadGridArray):
"""!
Shortcut cases for a single-row grid array. Can be used for
constructing sections of larger footprints.
"""
def __init__(self, pad, n, pitch, isVertical,
centre=pcbnew.VECTOR2I(0, 0)):
"""!
@param pad: the prototypical pad
@param n: number of pads in array
@param pitch: distance between pad centres
@param isVertical: horizontal or vertical array (can also use the
drawing contexts transforms for more control)
@param centre: array centre
"""
if isVertical:
super(PadLineArray, self).__init__(pad, 1, n, 0, pitch, centre)
else:
super(PadLineArray, self).__init__(pad, n, 1, pitch, 0, centre)
class PadCircleArray(PadArray):
"""!
Circular pad array
"""
def __init__(self, pad, n, r, angle_offset=0, centre=pcbnew.VECTOR2I(0, 0),
clockwise=True, padRotationEnable=False, padRotationOffset=0):
"""!
@param pad: the prototypical pad
@param n: number of pads in array
@param r: the circle radius
@param angle_offset: angle of the first pad
@param centre: array centre point
@param clockwise: array increases in a clockwise direction
@param padRotationEnable: also rotate pads when placing
@param padRotationOffset: rotation of first pad
"""
super(PadCircleArray, self).__init__(pad)
self.n = int(n)
self.r = r
self.angle_offset = angle_offset
self.centre = centre
self.clockwise = clockwise
self.padRotationEnable = padRotationEnable
self.padRotationOffset = padRotationOffset
def NamingFunction(self, n):
"""!
Naming around the circle, CW or CCW according to the clockwise flag
"""
return str(self.firstPadNum + n)
def AddPadsToModule(self, dc):
"""!
Create the pads and add them to the module in the correct positions
@param dc: the drawing context
"""
for pin in range(0, self.n):
angle = self.angle_offset + (360 / self.n) * pin
if not self.clockwise:
angle = -angle
pos_x = math.sin(angle * math.pi / 180) * self.r
pos_y = -math.cos(angle * math.pi / 180) * self.r
pos = dc.TransformPoint(pos_x, pos_y)
pad = self.GetPad(pin == 0, pos)
padAngle = self.padRotationOffset
if self.padRotationEnable:
padAngle -=angle
pad.SetOrientation( pcbnew.EDA_ANGLE( padAngle, pcbnew.DEGREES_T ) )
pad.SetName(self.GetName(pin))
self.AddPad(pad)
class PadCustomArray(PadArray):
"""!
Layout pads according to a custom array of [x,y] data
"""
def __init__(self, pad, array):
"""!
@param pad: the prototypical pad
@param array: the position data array
"""
super(PadCustomArray, self).__init__(pad)
self.array = array
def NamingFunction(self, n):
"""!
Simple increment along the given array
@param n: the pad index in the array
"""
return str(self.firstPadNum + n)
def AddPadsToModule(self, dc):
"""!
Create the pads and add them to the module in the correct positions
@param dc: the drawing context
"""
for i in range(len(self.array)):
pos = dc.TransformPoint(self.array[i][0], self.array[i][1])
pad = self.GetPad(i == 0, pos)
pad.SetName(self.GetName(i))
self.AddPad(pad)