//-----------------------------------------------------------------------------
// Copyright 2007 Jonathan Westhues
//
// This file is part of LDmicro.
//
// LDmicro 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.
//
// LDmicro 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 LDmicro. If not, see .
//------
//
// Routines to maintain the processor I/O list. Whenever the user changes the
// name of an element, rebuild the I/O list from the PLC program, so that new
// assigned names are automatically reflected in the I/O list. Also keep a
// list of old I/Os that have been deleted, so that if the user deletes a
// a name and then recreates it the associated settings (e.g. pin number)
// will not be forgotten. Also the dialog box for assigning I/O pins.
// Jonathan Westhues, Oct 2004
//-----------------------------------------------------------------------------
#include "linuxUI.h"
//#include
#include
#include
#include "ldmicro.h"
// I/O that we have seen recently, so that we don't forget pin assignments
// when we re-extract the list
#define MAX_IO_SEEN_PREVIOUSLY 512
static struct {
char name[MAX_NAME_LEN];
int type;
int pin;
} IoSeenPreviously[MAX_IO_SEEN_PREVIOUSLY];
static int IoSeenPreviouslyCount;
// // stuff for the dialog box that lets you choose pin assignments
// static BOOL DialogDone;
// static BOOL DialogCancel;
// static HWND IoDialog;
// static HWND PinList;
// static HWND OkButton;
// static HWND CancelButton;
// // stuff for the popup that lets you set the simulated value of an analog in
// static HWND AnalogSliderMain;
// static HWND AnalogSliderTrackbar;
// static BOOL AnalogSliderDone;
// static BOOL AnalogSliderCancel;
//-----------------------------------------------------------------------------
// Append an I/O to the I/O list if it is not in there already.
//-----------------------------------------------------------------------------
static void AppendIo(char *name, int type)
{
int i;
for(i = 0; i < Prog.io.count; i++) {
if(strcmp(Prog.io.assignment[i].name, name)==0) {
if(type != IO_TYPE_GENERAL && Prog.io.assignment[i].type ==
IO_TYPE_GENERAL)
{
Prog.io.assignment[i].type = type;
}
// already in there
return;
}
}
if(i < MAX_IO) {
Prog.io.assignment[i].type = type;
Prog.io.assignment[i].pin = NO_PIN_ASSIGNED;
strcpy(Prog.io.assignment[i].name, name);
(Prog.io.count)++;
}
}
//-----------------------------------------------------------------------------
// Move an I/O pin into the `seen previously' list. This means that if the
// user creates input Xasd, assigns it a pin, deletes, and then recreates it,
// then it will come back with the correct pin assigned.
//-----------------------------------------------------------------------------
static void AppendIoSeenPreviously(char *name, int type, int pin)
{
if(strcmp(name+1, "new")==0) return;
int i;
for(i = 0; i < IoSeenPreviouslyCount; i++) {
if(strcmp(name, IoSeenPreviously[i].name)==0 &&
type == IoSeenPreviously[i].type)
{
if(pin != NO_PIN_ASSIGNED) {
IoSeenPreviously[i].pin = pin;
}
return;
}
}
if(IoSeenPreviouslyCount >= MAX_IO_SEEN_PREVIOUSLY) {
// maybe improve later; just throw away all our old information, and
// the user might have to reenter the pin if they delete and recreate
// things
IoSeenPreviouslyCount = 0;
}
i = IoSeenPreviouslyCount;
IoSeenPreviously[i].type = type;
IoSeenPreviously[i].pin = pin;
strcpy(IoSeenPreviously[i].name, name);
IoSeenPreviouslyCount++;
}
//-----------------------------------------------------------------------------
// Walk a subcircuit, calling ourselves recursively and extracting all the
// I/O names out of it.
//-----------------------------------------------------------------------------
static void ExtractNamesFromCircuit(int which, void *any)
{
ElemLeaf *l = (ElemLeaf *)any;
switch(which) {
case ELEM_PARALLEL_SUBCKT: {
ElemSubcktParallel *p = (ElemSubcktParallel *)any;
int i;
for(i = 0; i < p->count; i++) {
ExtractNamesFromCircuit(p->contents[i].which,
p->contents[i].d.any);
}
break;
}
case ELEM_SERIES_SUBCKT: {
ElemSubcktSeries *s = (ElemSubcktSeries *)any;
int i;
for(i = 0; i < s->count; i++) {
ExtractNamesFromCircuit(s->contents[i].which,
s->contents[i].d.any);
}
break;
}
case ELEM_CONTACTS:
switch(l->d.contacts.name[0]) {
case 'R':
AppendIo(l->d.contacts.name, IO_TYPE_INTERNAL_RELAY);
break;
case 'Y':
AppendIo(l->d.contacts.name, IO_TYPE_DIG_OUTPUT);
break;
case 'X':
AppendIo(l->d.contacts.name, IO_TYPE_DIG_INPUT);
break;
default:
oops();
break;
}
break;
case ELEM_COIL:
AppendIo(l->d.coil.name, l->d.coil.name[0] == 'R' ?
IO_TYPE_INTERNAL_RELAY : IO_TYPE_DIG_OUTPUT);
break;
case ELEM_TON:
case ELEM_TOF:
AppendIo(l->d.timer.name, which == ELEM_TON ? IO_TYPE_TON :
IO_TYPE_TOF);
break;
case ELEM_RTO:
AppendIo(l->d.timer.name, IO_TYPE_RTO);
break;
case ELEM_MOVE:
AppendIo(l->d.move.dest, IO_TYPE_GENERAL);
break;
case ELEM_ADD:
case ELEM_SUB:
case ELEM_MUL:
case ELEM_DIV:
AppendIo(l->d.math.dest, IO_TYPE_GENERAL);
break;
case ELEM_FORMATTED_STRING:
if(strlen(l->d.fmtdStr.var) > 0) {
AppendIo(l->d.fmtdStr.var, IO_TYPE_UART_TX);
}
break;
case ELEM_UART_SEND:
AppendIo(l->d.uart.name, IO_TYPE_UART_TX);
break;
case ELEM_UART_RECV:
AppendIo(l->d.uart.name, IO_TYPE_UART_RX);
break;
case ELEM_SET_PWM:
AppendIo(l->d.setPwm.name, IO_TYPE_PWM_OUTPUT);
break;
case ELEM_CTU:
case ELEM_CTD:
case ELEM_CTC:
AppendIo(l->d.counter.name, IO_TYPE_COUNTER);
break;
case ELEM_READ_ADC:
AppendIo(l->d.readAdc.name, IO_TYPE_READ_ADC);
break;
case ELEM_SHIFT_REGISTER: {
int i;
for(i = 0; i < l->d.shiftRegister.stages; i++) {
char str[MAX_NAME_LEN+10];
sprintf(str, "%s%d", l->d.shiftRegister.name, i);
AppendIo(str, IO_TYPE_GENERAL);
}
break;
}
case ELEM_LOOK_UP_TABLE:
AppendIo(l->d.lookUpTable.dest, IO_TYPE_GENERAL);
break;
case ELEM_PIECEWISE_LINEAR:
AppendIo(l->d.piecewiseLinear.dest, IO_TYPE_GENERAL);
break;
case ELEM_PLACEHOLDER:
case ELEM_COMMENT:
case ELEM_SHORT:
case ELEM_OPEN:
case ELEM_MASTER_RELAY:
case ELEM_ONE_SHOT_RISING:
case ELEM_ONE_SHOT_FALLING:
case ELEM_EQU:
case ELEM_NEQ:
case ELEM_GRT:
case ELEM_GEQ:
case ELEM_LES:
case ELEM_LEQ:
case ELEM_RES:
case ELEM_PERSIST:
break;
default:
oops();
}
}
//-----------------------------------------------------------------------------
// Compare function to qsort() the I/O list. Group by type, then
// alphabetically within each section.
//-----------------------------------------------------------------------------
static int CompareIo(const void *av, const void *bv)
{
PlcProgramSingleIo *a = (PlcProgramSingleIo *)av;
PlcProgramSingleIo *b = (PlcProgramSingleIo *)bv;
if(a->type != b->type) {
return a->type - b->type;
}
if(a->pin == NO_PIN_ASSIGNED && b->pin != NO_PIN_ASSIGNED) return 1;
if(b->pin == NO_PIN_ASSIGNED && a->pin != NO_PIN_ASSIGNED) return -1;
return strcmp(a->name, b->name);
}
//-----------------------------------------------------------------------------
// Wipe the I/O list and then re-extract it from the PLC program, taking
// care not to forget the pin assignments. Gets passed the selected item
// as an index into the list; modifies the list, so returns the new selected
// item as an index into the new list.
//-----------------------------------------------------------------------------
int GenerateIoList(int prevSel)
{
int i, j;
char selName[MAX_NAME_LEN];
if(prevSel >= 0) {
strcpy(selName, Prog.io.assignment[prevSel].name);
}
if(IoSeenPreviouslyCount > MAX_IO_SEEN_PREVIOUSLY/2) {
// flush it so there's lots of room, and we don't run out and
// forget important things
IoSeenPreviouslyCount = 0;
}
// remember the pin assignments
for(i = 0; i < Prog.io.count; i++) {
AppendIoSeenPreviously(Prog.io.assignment[i].name,
Prog.io.assignment[i].type, Prog.io.assignment[i].pin);
}
// wipe the list
Prog.io.count = 0;
// extract the new list so that it must be up to date
for(i = 0; i < Prog.numRungs; i++) {
ExtractNamesFromCircuit(ELEM_SERIES_SUBCKT, Prog.rungs[i]);
}
for(i = 0; i < Prog.io.count; i++) {
if(Prog.io.assignment[i].type == IO_TYPE_DIG_INPUT ||
Prog.io.assignment[i].type == IO_TYPE_DIG_OUTPUT ||
Prog.io.assignment[i].type == IO_TYPE_READ_ADC)
{
for(j = 0; j < IoSeenPreviouslyCount; j++) {
if(strcmp(Prog.io.assignment[i].name,
IoSeenPreviously[j].name)==0)
{
Prog.io.assignment[i].pin = IoSeenPreviously[j].pin;
break;
}
}
}
}
qsort(Prog.io.assignment, Prog.io.count, sizeof(PlcProgramSingleIo),
CompareIo);
if(prevSel >= 0) {
for(i = 0; i < Prog.io.count; i++) {
if(strcmp(Prog.io.assignment[i].name, selName)==0)
break;
}
if(i < Prog.io.count)
return i;
}
// no previous, or selected was deleted
return -1;
}
//-----------------------------------------------------------------------------
// Load the I/O list from a file. Since we are just loading pin assignments,
// put it into IoSeenPreviously so that it will get used on the next
// extraction.
//-----------------------------------------------------------------------------
BOOL LoadIoListFromFile(FILE *f)
{
char line[80];
char name[MAX_NAME_LEN];
int pin;
while(fgets(line, sizeof(line), f)) {
if(strcmp(line, "END\n")==0) {
return TRUE;
}
// Don't internationalize this! It's the file format, not UI.
if(sscanf(line, " %s at %d", name, &pin)==2) {
int type;
switch(name[0]) {
case 'X': type = IO_TYPE_DIG_INPUT; break;
case 'Y': type = IO_TYPE_DIG_OUTPUT; break;
case 'A': type = IO_TYPE_READ_ADC; break;
default: oops();
}
AppendIoSeenPreviously(name, type, pin);
}
}
return FALSE;
}
//-----------------------------------------------------------------------------
// Write the I/O list to a file. Since everything except the pin assignment
// can be extracted from the schematic, just write the Xs and Ys.
//-----------------------------------------------------------------------------
void SaveIoListToFile(FILE *f)
{
int i;
for(i = 0; i < Prog.io.count; i++) {
if(Prog.io.assignment[i].type == IO_TYPE_DIG_INPUT ||
Prog.io.assignment[i].type == IO_TYPE_DIG_OUTPUT ||
Prog.io.assignment[i].type == IO_TYPE_READ_ADC)
{
// Don't internationalize this! It's the file format, not UI.
fprintf(f, " %s at %d\n", Prog.io.assignment[i].name,
Prog.io.assignment[i].pin);
}
}
}
//-----------------------------------------------------------------------------
// Dialog proc for the popup that lets you set the value of an analog input for
// simulation.
//-----------------------------------------------------------------------------
// static LRESULT CALLBACK AnalogSliderDialogProc(HWND hwnd, UINT msg,
// WPARAM wParam, LPARAM lParam)
// {
// switch (msg) {
// case WM_CLOSE:
// case WM_DESTROY:
// AnalogSliderDone = TRUE;
// AnalogSliderCancel = TRUE;
// return 1;
// default:
// return DefWindowProc(hwnd, msg, wParam, lParam);
// }
// }
//-----------------------------------------------------------------------------
// A little toolbar-style window that pops up to allow the user to set the
// simulated value of an ADC pin.
//-----------------------------------------------------------------------------
// void ShowAnalogSliderPopup(char *name)
// {
// WNDCLASSEX wc;
// memset(&wc, 0, sizeof(wc));
// wc.cbSize = sizeof(wc);
// wc.style = CS_BYTEALIGNCLIENT | CS_BYTEALIGNWINDOW | CS_OWNDC |
// CS_DBLCLKS;
// wc.lpfnWndProc = (WNDPROC)AnalogSliderDialogProc;
// wc.hInstance = Instance;
// wc.hbrBackground = (HBRUSH)COLOR_BTNSHADOW;
// wc.lpszClassName = "LDmicroAnalogSlider";
// wc.lpszMenuName = NULL;
// wc.hCursor = LoadCursor(NULL, IDC_ARROW);
// RegisterClassEx(&wc);
// POINT pt;
// GetCursorPos(&pt);
// SWORD currentVal = GetAdcShadow(name);
// SWORD maxVal;
// if(Prog.mcu) {
// maxVal = Prog.mcu->adcMax;
// } else {
// maxVal = 1023;
// }
// if(maxVal == 0) {
// Error(_("No ADC or ADC not supported for selected micro."));
// return;
// }
// int left = pt.x - 10;
// // try to put the slider directly under the cursor (though later we might
// // realize that that would put the popup off the screen)
// int top = pt.y - (15 + (73*currentVal)/maxVal);
// RECT r;
// SystemParametersInfo(SPI_GETWORKAREA, 0, &r, 0);
// if(top + 110 >= r.bottom) {
// top = r.bottom - 110;
// }
// if(top < 0) top = 0;
// AnalogSliderMain = CreateWindowClient(0, "LDmicroAnalogSlider", "I/O Pin",
// WS_VISIBLE | WS_POPUP | WS_DLGFRAME,
// left, top, 30, 100, NULL, NULL, Instance, NULL);
// AnalogSliderTrackbar = CreateWindowEx(0, TRACKBAR_CLASS, "", WS_CHILD |
// TBS_AUTOTICKS | TBS_VERT | TBS_TOOLTIPS | WS_CLIPSIBLINGS | WS_VISIBLE,
// 0, 0, 30, 100, AnalogSliderMain, NULL, Instance, NULL);
// SendMessage(AnalogSliderTrackbar, TBM_SETRANGE, FALSE,
// MAKELONG(0, maxVal));
// SendMessage(AnalogSliderTrackbar, TBM_SETTICFREQ, (maxVal + 1)/8, 0);
// SendMessage(AnalogSliderTrackbar, TBM_SETPOS, TRUE, currentVal);
// EnableWindow(MainWindow, FALSE);
// ShowWindow(AnalogSliderMain, TRUE);
// SetFocus(AnalogSliderTrackbar);
// DWORD ret;
// MSG msg;
// AnalogSliderDone = FALSE;
// AnalogSliderCancel = FALSE;
// SWORD orig = GetAdcShadow(name);
// while(!AnalogSliderDone && (ret = GetMessage(&msg, NULL, 0, 0))) {
// SWORD v = (SWORD)SendMessage(AnalogSliderTrackbar, TBM_GETPOS, 0, 0);
// if(msg.message == WM_KEYDOWN) {
// if(msg.wParam == VK_RETURN) {
// AnalogSliderDone = TRUE;
// break;
// } else if(msg.wParam == VK_ESCAPE) {
// AnalogSliderDone = TRUE;
// AnalogSliderCancel = TRUE;
// break;
// }
// } else if(msg.message == WM_LBUTTONUP) {
// if(v != orig) {
// AnalogSliderDone = TRUE;
// }
// }
// SetAdcShadow(name, v);
// TranslateMessage(&msg);
// DispatchMessage(&msg);
// }
// if(!AnalogSliderCancel) {
// SWORD v = (SWORD)SendMessage(AnalogSliderTrackbar, TBM_GETPOS, 0, 0);
// SetAdcShadow(name, v);
// }
// EnableWindow(MainWindow, TRUE);
// DestroyWindow(AnalogSliderMain);
// ListView_RedrawItems(IoList, 0, Prog.io.count - 1);
// }
//-----------------------------------------------------------------------------
// Window proc for the contacts dialog box
//-----------------------------------------------------------------------------
// static LRESULT CALLBACK IoDialogProc(HWND hwnd, UINT msg, WPARAM wParam,
// LPARAM lParam)
// {
// switch (msg) {
// case WM_COMMAND: {
// HWND h = (HWND)lParam;
// if(h == OkButton && wParam == BN_CLICKED) {
// DialogDone = TRUE;
// } else if(h == CancelButton && wParam == BN_CLICKED) {
// DialogDone = TRUE;
// DialogCancel = TRUE;
// } else if(h == PinList && HIWORD(wParam) == LBN_DBLCLK) {
// DialogDone = TRUE;
// }
// break;
// }
// case WM_CLOSE:
// case WM_DESTROY:
// DialogDone = TRUE;
// DialogCancel = TRUE;
// return 1;
// default:
// return DefWindowProc(hwnd, msg, wParam, lParam);
// }
// return 1;
// }
//-----------------------------------------------------------------------------
// Create our window class; nothing exciting.
//-----------------------------------------------------------------------------
// static BOOL MakeWindowClass()
// {
// WNDCLASSEX wc;
// memset(&wc, 0, sizeof(wc));
// wc.cbSize = sizeof(wc);
// wc.style = CS_BYTEALIGNCLIENT | CS_BYTEALIGNWINDOW | CS_OWNDC |
// CS_DBLCLKS;
// wc.lpfnWndProc = (WNDPROC)IoDialogProc;
// wc.hInstance = Instance;
// wc.hbrBackground = (HBRUSH)COLOR_BTNSHADOW;
// wc.lpszClassName = "LDmicroIo";
// wc.lpszMenuName = NULL;
// wc.hCursor = LoadCursor(NULL, IDC_ARROW);
// wc.hIcon = (HICON)LoadImage(Instance, MAKEINTRESOURCE(4000),
// IMAGE_ICON, 32, 32, 0);
// wc.hIconSm = (HICON)LoadImage(Instance, MAKEINTRESOURCE(4000),
// IMAGE_ICON, 16, 16, 0);
// return RegisterClassEx(&wc);
// }
// static void MakeControls(void)
// {
// HWND textLabel = CreateWindowEx(0, WC_STATIC, _("Assign:"),
// WS_CHILD | WS_CLIPSIBLINGS | WS_VISIBLE,
// 6, 1, 80, 17, IoDialog, NULL, Instance, NULL);
// NiceFont(textLabel);
// PinList = CreateWindowEx(WS_EX_CLIENTEDGE, WC_LISTBOX, "",
// WS_CHILD | WS_TABSTOP | WS_CLIPSIBLINGS | WS_VISIBLE | WS_VSCROLL |
// LBS_NOTIFY, 6, 18, 95, 320, IoDialog, NULL, Instance, NULL);
// FixedFont(PinList);
// OkButton = CreateWindowEx(0, WC_BUTTON, _("OK"),
// WS_CHILD | WS_TABSTOP | WS_CLIPSIBLINGS | WS_VISIBLE | BS_DEFPUSHBUTTON,
// 6, 325, 95, 23, IoDialog, NULL, Instance, NULL);
// NiceFont(OkButton);
// CancelButton = CreateWindowEx(0, WC_BUTTON, _("Cancel"),
// WS_CHILD | WS_TABSTOP | WS_CLIPSIBLINGS | WS_VISIBLE,
// 6, 356, 95, 23, IoDialog, NULL, Instance, NULL);
// NiceFont(CancelButton);
// }
// void ShowIoDialog(int item)
// {
// if(!Prog.mcu) {
// MessageBox(MainWindow,
// _("No microcontroller has been selected. You must select a "
// "microcontroller before you can assign I/O pins.\r\n\r\n"
// "Select a microcontroller under the Settings menu and try "
// "again."), _("I/O Pin Assignment"), MB_OK | MB_ICONWARNING);
// return;
// }
// if(Prog.mcu->whichIsa == ISA_ANSIC) {
// Error(_("Can't specify I/O assignment for ANSI C target; compile and "
// "see comments in generated source code."));
// return;
// }
// if(Prog.mcu->whichIsa == ISA_INTERPRETED) {
// Error(_("Can't specify I/O assignment for interpretable target; see "
// "comments in reference implementation of interpreter."));
// return;
// }
// if(Prog.io.assignment[item].name[0] != 'X' &&
// Prog.io.assignment[item].name[0] != 'Y' &&
// Prog.io.assignment[item].name[0] != 'A')
// {
// Error(_("Can only assign pin number to input/output pins (Xname or "
// "Yname or Aname)."));
// return;
// }
// if(Prog.io.assignment[item].name[0] == 'A' && Prog.mcu->adcCount == 0) {
// Error(_("No ADC or ADC not supported for this micro."));
// return;
// }
// if(strcmp(Prog.io.assignment[item].name+1, "new")==0) {
// Error(_("Rename I/O from default name ('%s') before assigning "
// "MCU pin."), Prog.io.assignment[item].name);
// return;
// }
// MakeWindowClass();
// // We need the TOOLWINDOW style, or else the window will be forced to
// // a minimum width greater than our current width. And without the
// // APPWINDOW style, it becomes impossible to get the window back (by
// // Alt+Tab or taskbar).
// IoDialog = CreateWindowClient(WS_EX_TOOLWINDOW | WS_EX_APPWINDOW,
// "LDmicroIo", _("I/O Pin"),
// WS_OVERLAPPED | WS_SYSMENU,
// 100, 100, 107, 387, NULL, NULL, Instance, NULL);
// MakeControls();
// SendMessage(PinList, LB_ADDSTRING, 0, (LPARAM)_("(no pin)"));
// int i;
// for(i = 0; i < Prog.mcu->pinCount; i++) {
// int j;
// for(j = 0; j < Prog.io.count; j++) {
// if(j == item) continue;
// if(Prog.io.assignment[j].pin == Prog.mcu->pinInfo[i].pin) {
// goto cant_use_this_io;
// }
// }
// if(UartFunctionUsed() && Prog.mcu &&
// ((Prog.mcu->pinInfo[i].pin == Prog.mcu->uartNeeds.rxPin) ||
// (Prog.mcu->pinInfo[i].pin == Prog.mcu->uartNeeds.txPin)))
// {
// goto cant_use_this_io;
// }
// if(PwmFunctionUsed() &&
// Prog.mcu->pinInfo[i].pin == Prog.mcu->pwmNeedsPin)
// {
// goto cant_use_this_io;
// }
// if(Prog.io.assignment[item].name[0] == 'A') {
// for(j = 0; j < Prog.mcu->adcCount; j++) {
// if(Prog.mcu->adcInfo[j].pin == Prog.mcu->pinInfo[i].pin) {
// // okay; we know how to connect it up to the ADC
// break;
// }
// }
// if(j == Prog.mcu->adcCount) {
// goto cant_use_this_io;
// }
// }
// char buf[40];
// if(Prog.mcu->pinCount <= 21) {
// sprintf(buf, "%3d %c%c%d", Prog.mcu->pinInfo[i].pin,
// Prog.mcu->portPrefix, Prog.mcu->pinInfo[i].port,
// Prog.mcu->pinInfo[i].bit);
// } else {
// sprintf(buf, "%3d %c%c%d", Prog.mcu->pinInfo[i].pin,
// Prog.mcu->portPrefix, Prog.mcu->pinInfo[i].port,
// Prog.mcu->pinInfo[i].bit);
// }
// SendMessage(PinList, LB_ADDSTRING, 0, (LPARAM)buf);
// cant_use_this_io:;
// }
// EnableWindow(MainWindow, FALSE);
// ShowWindow(IoDialog, TRUE);
// SetFocus(PinList);
// MSG msg;
// DWORD ret;
// DialogDone = FALSE;
// DialogCancel = FALSE;
// while((ret = GetMessage(&msg, NULL, 0, 0)) && !DialogDone) {
// if(msg.message == WM_KEYDOWN) {
// if(msg.wParam == VK_RETURN) {
// DialogDone = TRUE;
// break;
// } else if(msg.wParam == VK_ESCAPE) {
// DialogDone = TRUE;
// DialogCancel = TRUE;
// break;
// }
// }
// if(IsDialogMessage(IoDialog, &msg)) continue;
// TranslateMessage(&msg);
// DispatchMessage(&msg);
// }
// if(!DialogCancel) {
// int sel = SendMessage(PinList, LB_GETCURSEL, 0, 0);
// char pin[16];
// SendMessage(PinList, LB_GETTEXT, (WPARAM)sel, (LPARAM)pin);
// if(strcmp(pin, _("(no pin)"))==0) {
// int i;
// for(i = 0; i < IoSeenPreviouslyCount; i++) {
// if(strcmp(IoSeenPreviously[i].name,
// Prog.io.assignment[item].name)==0)
// {
// IoSeenPreviously[i].pin = NO_PIN_ASSIGNED;
// }
// }
// Prog.io.assignment[item].pin = NO_PIN_ASSIGNED;
// } else {
// Prog.io.assignment[item].pin = atoi(pin);
// // Only one name can be bound to each pin; make sure that there's
// // not another entry for this pin in the IoSeenPreviously list,
// // that might get used if the user creates a new pin with that
// // name.
// int i;
// for(i = 0; i < IoSeenPreviouslyCount; i++) {
// if(IoSeenPreviously[i].pin == atoi(pin)) {
// IoSeenPreviously[i].pin = NO_PIN_ASSIGNED;
// }
// }
// }
// }
// EnableWindow(MainWindow, TRUE);
// DestroyWindow(IoDialog);
// return;
// }
//-----------------------------------------------------------------------------
// Called in response to a notify for the listview. Handles click, text-edit
// operations etc., but also gets called to find out what text to display
// where (LPSTR_TEXTCALLBACK); that way we don't have two parallel copies of
// the I/O list to keep in sync.
//-----------------------------------------------------------------------------
// void IoListProc(NMHDR *h)
// {
// switch(h->code) {
// case LVN_GETDISPINFO: {
// NMLVDISPINFO *i = (NMLVDISPINFO *)h;
// int item = i->item.iItem;
// switch(i->item.iSubItem) {
// case LV_IO_PIN:
// // Don't confuse people by displaying bogus pin assignments
// // for the C target.
// if(Prog.mcu && (Prog.mcu->whichIsa == ISA_ANSIC ||
// Prog.mcu->whichIsa == ISA_INTERPRETED) )
// {
// strcpy(i->item.pszText, "");
// break;
// }
// PinNumberForIo(i->item.pszText,
// &(Prog.io.assignment[item]));
// break;
// case LV_IO_TYPE: {
// char *s = IoTypeToString(Prog.io.assignment[item].type);
// strcpy(i->item.pszText, s);
// break;
// }
// case LV_IO_NAME:
// strcpy(i->item.pszText, Prog.io.assignment[item].name);
// break;
// case LV_IO_PORT: {
// // Don't confuse people by displaying bogus pin assignments
// // for the C target.
// if(Prog.mcu && Prog.mcu->whichIsa == ISA_ANSIC) {
// strcpy(i->item.pszText, "");
// break;
// }
// int type = Prog.io.assignment[item].type;
// if(type != IO_TYPE_DIG_INPUT && type != IO_TYPE_DIG_OUTPUT
// && type != IO_TYPE_READ_ADC)
// {
// strcpy(i->item.pszText, "");
// break;
// }
// int pin = Prog.io.assignment[item].pin;
// if(pin == NO_PIN_ASSIGNED || !Prog.mcu) {
// strcpy(i->item.pszText, "");
// break;
// }
// if(UartFunctionUsed() && Prog.mcu) {
// if((Prog.mcu->uartNeeds.rxPin == pin) ||
// (Prog.mcu->uartNeeds.txPin == pin))
// {
// strcpy(i->item.pszText, _(""));
// break;
// }
// }
// if(PwmFunctionUsed() && Prog.mcu) {
// if(Prog.mcu->pwmNeedsPin == pin) {
// strcpy(i->item.pszText, _(""));
// break;
// }
// }
// int j;
// for(j = 0; j < Prog.mcu->pinCount; j++) {
// if(Prog.mcu->pinInfo[j].pin == pin) {
// sprintf(i->item.pszText, "%c%c%d",
// Prog.mcu->portPrefix,
// Prog.mcu->pinInfo[j].port,
// Prog.mcu->pinInfo[j].bit);
// break;
// }
// }
// if(j == Prog.mcu->pinCount) {
// sprintf(i->item.pszText, _(""));
// }
// break;
// }
// case LV_IO_STATE: {
// if(InSimulationMode) {
// char *name = Prog.io.assignment[item].name;
// DescribeForIoList(name, i->item.pszText);
// } else {
// strcpy(i->item.pszText, "");
// }
// break;
// }
// }
// break;
// }
// case LVN_ITEMACTIVATE: {
// NMITEMACTIVATE *i = (NMITEMACTIVATE *)h;
// if(InSimulationMode) {
// char *name = Prog.io.assignment[i->iItem].name;
// if(name[0] == 'X') {
// SimulationToggleContact(name);
// } else if(name[0] == 'A') {
// ShowAnalogSliderPopup(name);
// }
// } else {
// UndoRemember();
// ShowIoDialog(i->iItem);
// ProgramChanged();
// InvalidateRect(MainWindow, NULL, FALSE);
// }
// break;
// }
// }
// }