mirror of
git://projects.qi-hardware.com/fped.git
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322 lines
8.8 KiB
C
322 lines
8.8 KiB
C
/*
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* geda.c - Dump objects in the gEDA PCB board/module format
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*
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* Written 2009, 2011 by Werner Almesberger, and 2016 by Erich Heinzle
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* Copyright 2009, 2011 by Werner Almesberger
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* Copyright 2016, Erich Heinzle
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*/
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#include <stdlib.h>
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#include <stdio.h>
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#include <assert.h>
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#include "coord.h"
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#include "inst.h"
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#include "geda.h"
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static void geda_centric(struct coord a, struct coord b,
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struct coord *center, struct coord *size)
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{
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struct coord min, max;
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min.x = units_to_geda(a.x);
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min.y = units_to_geda(a.y);
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max.x = units_to_geda(b.x);
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max.y = units_to_geda(b.y);
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sort_coord(&min, &max);
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size->x = max.x-min.x;
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size->y = max.y-min.y;
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center->x = (min.x+max.x)/2;
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center->y = -(min.y+max.y)/2;
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}
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static unit_type geda_pad_width(struct coord size)
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{
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if (size.x >= size.y) {
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return size.y;
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} else {
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return size.x;
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}
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}
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static void geda_pad_start_finish(struct coord a, struct coord b,
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struct coord *start, struct coord *finish)
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{
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struct coord size, center, min, max;
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min.x = units_to_geda(a.x);
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min.y = units_to_geda(a.y);
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max.x = units_to_geda(b.x);
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max.y = units_to_geda(b.y);
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sort_coord(&min, &max);
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size.x = max.x-min.x;
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size.y = max.y-min.y;
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center.x = (min.x+max.x)/2;
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center.y = -(min.y+max.y)/2;
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/* gEDA pads are drawn as a line, of a certain thickness */
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if (size.x >= size.y) { /* wider than tall, width = size.y */
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start->x = min.x + size.y/2;
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start->y = -center.y;
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finish->x = max.x - size.y/2;
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finish->y = -center.y;
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} else { /* taller than wide, width = size.x */
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start->y = (min.y + size.x/2);
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start->x = center.x;
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finish->y = (max.y - size.x/2);
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finish->x = center.x;
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}
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}
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static void do_geda_drill(FILE *file, const struct inst *pad, struct coord *padSize)
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{
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const struct inst *hole = pad->u.pad.hole;
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struct coord center, size;
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if (!hole)
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return;
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geda_centric(hole->base, hole->u.hole.other, ¢er, &size);
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fprintf(file, "%d %d ", center.x, -center.y); /* x,y position of hole */
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if (padSize->x <= padSize->y) { /* sort out diameter of copper annulus, remembering obrounds*/
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fprintf(file, "%d ", padSize->x);
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} else {
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fprintf(file, "%d ", padSize->y);
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}
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fprintf(file, "100 100 %d", size.x); /* default copper clearance, mask, then drill size */
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}
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static void geda_pad(FILE *file, const struct inst *inst)
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{
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struct coord center, size, start, finish;
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geda_centric(inst->base, inst->u.pad.other, ¢er, &size);
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if (inst->u.pad.hole) { /* pin */
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/* Pin[X Y Thickness Clearance Mask Drill Name Number SFlags] */
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fprintf(file, "\tPin[");
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do_geda_drill(file, inst, &size); /* need pad size to figure out annulus */
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fprintf(file, " \"%s\" \"%s\"", inst->u.pad.name, inst->u.pad.name);
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if (inst->obj->u.pad.rounded) { /* round pin */
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fprintf(file, " \"\"]\n");
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} else { /* square pad, ignore octagonal for now */
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fprintf(file, " \"square\"]\n");
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}
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} else { /* SMD */
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/* Pad[X1 Y1 X2 Y2 Thickness Clearance Mask Name Number SFlags] */
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geda_pad_start_finish(inst->base, inst->u.pad.other, &start, &finish);
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fprintf(file, "\tPad[%d %d %d %d %d 100 100 \"%s\" \"%s\" \"square\"]\n", start.x, -start.y, finish.x, -finish.y, geda_pad_width(size), inst->u.pad.name, inst->u.pad.name);
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}
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}
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static void geda_hole(FILE *file, const struct inst *inst)
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{
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struct coord center, size;
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if (inst->u.hole.pad)
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return;
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geda_centric(inst->base, inst->u.hole.other, ¢er, &size);
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/* Pin[X Y Thickness Clearance Mask Drill Name Number SFlags] */
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fprintf(file, "\tPin[%d %d", center.x, center.y);
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if (size.x <= size.y) { /* see which obround dimension is smallest */
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fprintf(file, " %d 100 100 %d", size.x, size.x);
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/* obround hole turned into round hole of diameter size.x */
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} else {
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fprintf(file, " %d 100 100 %d", size.y, size.y);
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/* obround hole turned into round hole of diameter size.y */
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}
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fprintf(file, " \"\" \"\" \"hole\"]\n");
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}
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static void geda_line(FILE *file, const struct inst *inst)
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{
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/*
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* Xstart, Ystart, Xend, Yend, Width
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*/
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fprintf(file, "\tElementLine[%d %d %d %d %d]\n",
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units_to_geda(inst->base.x),
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-units_to_geda(inst->base.y),
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units_to_geda(inst->u.rect.end.x),
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-units_to_geda(inst->u.rect.end.y),
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units_to_geda(inst->u.rect.width));
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}
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static void geda_rect(FILE *file, const struct inst *inst)
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{
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unit_type xa, ya, xb, yb;
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unit_type width;
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xa = units_to_geda(inst->base.x);
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ya = units_to_geda(inst->base.y);
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xb = units_to_geda(inst->u.rect.end.x);
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yb = units_to_geda(inst->u.rect.end.y);
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width = units_to_geda(inst->u.rect.width);
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fprintf(file, "\tElementLine[%d %d %d %d %d]\n",
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xa, -ya, xa, -yb, width);
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fprintf(file, "\tElementLine[%d %d %d %d %d]\n",
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xa, -yb, xb, -yb, width);
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fprintf(file, "\tElementLine[%d %d %d %d %d]\n",
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xb, -yb, xb, -ya, width);
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fprintf(file, "\tElementLine[%d %d %d %d %d]\n",
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xb, -ya, xa, -ya, width);
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}
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static void geda_circ(FILE *file, const struct inst *inst)
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{
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/*
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* Xcenter, Ycenter, Width, Height, startAngle, stopAngle, Width
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*/
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fprintf(file, "\tElementArc[ %d %d %d %d 0 360 %d]\n",
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units_to_geda(inst->base.x),
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-units_to_geda(inst->base.y),
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units_to_geda(inst->u.arc.r),
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units_to_geda(inst->u.arc.r),
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units_to_geda(inst->u.arc.width));
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}
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static void geda_arc(FILE *file, const struct inst *inst)
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{
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double b;
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/*
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* Xcenter, Ycenter, Width, Height, startAngle, stopAngle, Width
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*/
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b = inst->u.arc.a1 - 180;
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while (b <= 0)
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b += 360;
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while (b > 360)
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b -= 360;
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fprintf(file, "\tElementArc[%d %d %d %d %d %d %d]\n",
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units_to_geda(inst->base.x),
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-units_to_geda(inst->base.y),
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units_to_geda(inst->u.arc.r),
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units_to_geda(inst->u.arc.r),
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(int) b,
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(int) (inst->u.arc.a2-inst->u.arc.a1),
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units_to_geda(inst->u.arc.width));
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}
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static void geda_layout_header(FILE *file)
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{
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fprintf(file, "# release: pcb 20110918\n\n");
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fprintf(file, "# To read pcb files, the pcb version (or the git source date) must be >= the file version\n");
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fprintf(file, "FileVersion[20070407]\n\n");
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fprintf(file, "PCB[\"\" 600000 500000]\n\n");
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fprintf(file, "Grid[2500.0 0 0 1]\n");
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fprintf(file, "Cursor[2500 62500 0.000000]\n");
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fprintf(file, "PolyArea[3100.006200]\n");
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fprintf(file, "Thermal[0.500000]\n");
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fprintf(file, "DRC[1200 900 1000 700 1500 1000]\n");
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fprintf(file, "Flags(\"nameonpcb,clearnew,snappin\")\n");
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fprintf(file, "Groups(\"1,3,4,c:2,5,6,s:7:8\")\n");
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fprintf(file, "Styles[\"Signal,1000,7874,3150,2000:Power,2000,8661,3937,2000:Fat,8000,13780,4724,2500:Sig-tight,1000,6400,3150,1200\"]\n\n");
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fprintf(file, "Attribute(\"PCB::grid::unit\" \"mil\")");
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}
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static void geda_layout_footer(FILE *file)
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{
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fprintf(file, "Layer(1 \"component\")\n(\n)\n");
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fprintf(file, "Layer(2 \"solder\")\n(\n)\n");
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fprintf(file, "Layer(3 \"comp-GND\")\n(\n)\n");
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fprintf(file, "Layer(4 \"comp-power\")\n(\n)\n");
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fprintf(file, "Layer(5 \"sold-GND\")\n(\n)\n");
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fprintf(file, "Layer(6 \"sold-power\")\n(\n)\n");
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fprintf(file, "Layer(7 \"signal3\")\n(\n)\n");
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fprintf(file, "Layer(8 \"outline\")\n(\n)\n");
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fprintf(file, "Layer(9 \"silk\")\n(\n)\n");
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fprintf(file, "Layer(10 \"silk\")\n(\n)\n");
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}
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static void geda_inst(FILE *file, enum inst_prio prio, const struct inst *inst)
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{
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switch (prio) {
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case ip_pad_copper:
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case ip_pad_special:
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geda_pad(file, inst);
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break;
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case ip_hole:
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geda_hole(file, inst); /* obround is exported as a round circle */
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break;
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case ip_line:
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geda_line(file, inst);
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break;
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case ip_rect:
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geda_rect(file, inst);
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break;
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case ip_circ:
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geda_circ(file, inst);
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break;
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case ip_arc:
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geda_arc(file, inst);
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break;
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default:
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/*
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* Don't try to export vectors, frame references, or
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* measurements.
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*/
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break;
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}
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}
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static void geda_module(FILE *file, const struct pkg *pkg, time_t now)
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{
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enum inst_prio prio;
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const struct inst *inst;
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fprintf(file, "# Footprint generated by FPED utility\n");
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fprintf(file, "Element[\"\" \"%s\" \"\" \"\" 0 0 -25590 -14874 0 100 \"\"]\n", pkg->name);
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fprintf(file, "(\n");
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FOR_INST_PRIOS_UP(prio) {
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for (inst = pkgs->insts[prio]; inst; inst = inst->next)
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geda_inst(file, prio, inst);
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for (inst = pkg->insts[prio]; inst; inst = inst->next)
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geda_inst(file, prio, inst);
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}
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fprintf(file, ")\n\n"); /* extra newline between elements */
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}
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int geda(FILE *file, const char *one)
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{
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const struct pkg *pkg;
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time_t now = time(NULL);
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assert(!one);
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geda_layout_header(file); /* we place one or more elements in a layout file */
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for (pkg = pkgs; pkg; pkg = pkg->next)
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if (pkg->name)
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fprintf(file, "# %s\n", pkg->name);
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for (pkg = pkgs; pkg; pkg = pkg->next)
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if (pkg->name)
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geda_module(file, pkg, now);
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geda_layout_footer(file);
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fflush(file);
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return !ferror(file);
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}
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