168 lines
4.8 KiB
C
168 lines
4.8 KiB
C
// 29 march 2014
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#include "../ui.h"
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#include "uipriv.h"
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/*
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Windows and GTK+ have a limit of 2 and 3 clicks, respectively, natively supported. Fortunately, we can simulate the double/triple-click behavior to build higher-order clicks. We can use the same algorithm Windows uses on both:
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http://blogs.msdn.com/b/oldnewthing/archive/2004/10/18/243925.aspx
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For GTK+, we pull the double-click time and double-click distance, which work the same as the equivalents on Windows (so the distance is in all directions), from the GtkSettings system.
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On GTK+ this will also allow us to discard the GDK_BUTTON_2PRESS and GDK_BUTTON_3PRESS events, so the button press stream will be just like on other platforms.
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Thanks to mclasen, garnacho_, halfline, and tristan in irc.gimp.net/#gtk+.
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*/
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// x, y, xdist, ydist, and c.rect must have the same units
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// so must time, maxTime, and c.prevTime
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int clickCounterClick(clickCounter *c, int button, int x, int y, uintptr_t time, uintptr_t maxTime, int32_t xdist, int32_t ydist)
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{
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// different button than before? if so, don't count
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if (button != c->curButton)
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c->count = 0;
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// (x, y) in the allowed region for a double-click? if not, don't count
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if (x < c->rectX0)
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c->count = 0;
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if (y < c->rectY0)
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c->count = 0;
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if (x >= c->rectX1)
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c->count = 0;
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if (y >= c->rectY1)
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c->count = 0;
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// too slow? if so, don't count
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// note the below expression; time > (c.prevTime + maxTime) can overflow!
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if ((time - c->prevTime) > maxTime) // too slow; don't count
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c->count = 0;
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c->count++; // if either of the above ifs happened, this will make the click count 1; otherwise it will make the click count 2, 3, 4, 5, ...
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// now we need to update the internal structures for the next test
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c->curButton = button;
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c->prevTime = time;
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c->rectX0 = x - xdist;
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c->rectY0 = y - ydist;
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c->rectX1 = x + xdist;
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c->rectY1 = y + ydist;
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return c->count;
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}
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void clickCounterReset(clickCounter *c)
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{
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c->curButton = 0;
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c->rectX0 = 0;
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c->rectY0 = 0;
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c->rectX1 = 0;
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c->rectY1 = 0;
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c->prevTime = 0;
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c->count = 0;
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}
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/*
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For position independence across international keyboard layouts, typewriter keys are read using scancodes (which are always set 1).
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Windows provides the scancodes directly in the LPARAM.
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GTK+ provides the scancodes directly from the underlying window system via GdkEventKey.hardware_keycode.
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On X11, this is scancode + 8 (because X11 keyboard codes have a range of [8,255]).
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Wayland is guaranteed to give the same result (thanks ebassi in irc.gimp.net/#gtk+).
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On Linux, where evdev is used instead of polling scancodes directly from the keyboard, evdev's typewriter section key code constants are the same as scancodes anyway, so the rules above apply.
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Typewriter section scancodes are the same across international keyboards with some exceptions that have been accounted for (see KeyEvent's documentation); see http://www.quadibloc.com/comp/scan.htm for details.
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Non-typewriter keys can be handled safely using constants provided by the respective backend API.
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Because GTK+ keysyms may or may not obey Num Lock, we also handle the 0-9 and . keys on the numeric keypad with scancodes (they match too).
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*/
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// use uintptr_t to be safe; the size of the scancode/hardware key code field on each platform is different
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static const struct {
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uintptr_t scancode;
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char equiv;
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} scancodeKeys[] = {
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{ 0x02, '1' },
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{ 0x03, '2' },
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{ 0x04, '3' },
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{ 0x05, '4' },
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{ 0x06, '5' },
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{ 0x07, '6' },
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{ 0x08, '7' },
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{ 0x09, '8' },
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{ 0x0A, '9' },
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{ 0x0B, '0' },
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{ 0x0C, '-' },
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{ 0x0D, '=' },
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{ 0x0E, '\b' },
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{ 0x0F, '\t' },
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{ 0x10, 'q' },
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{ 0x11, 'w' },
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{ 0x12, 'e' },
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{ 0x13, 'r' },
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{ 0x14, 't' },
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{ 0x15, 'y' },
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{ 0x16, 'u' },
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{ 0x17, 'i' },
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{ 0x18, 'o' },
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{ 0x19, 'p' },
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{ 0x1A, '[' },
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{ 0x1B, ']' },
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{ 0x1C, '\n' },
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{ 0x1E, 'a' },
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{ 0x1F, 's' },
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{ 0x20, 'd' },
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{ 0x21, 'f' },
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{ 0x22, 'g' },
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{ 0x23, 'h' },
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{ 0x24, 'j' },
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{ 0x25, 'k' },
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{ 0x26, 'l' },
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{ 0x27, ';' },
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{ 0x28, '\'' },
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{ 0x29, '`' },
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{ 0x2B, '\\' },
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{ 0x2C, 'z' },
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{ 0x2D, 'x' },
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{ 0x2E, 'c' },
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{ 0x2F, 'v' },
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{ 0x30, 'b' },
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{ 0x31, 'n' },
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{ 0x32, 'm' },
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{ 0x33, ',' },
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{ 0x34, '.' },
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{ 0x35, '/' },
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{ 0x39, ' ' },
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{ 0xFFFF, 0 },
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};
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static const struct {
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uintptr_t scancode;
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uiExtKey equiv;
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} scancodeExtKeys[] = {
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{ 0x47, uiExtKeyN7 },
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{ 0x48, uiExtKeyN8 },
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{ 0x49, uiExtKeyN9 },
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{ 0x4B, uiExtKeyN4 },
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{ 0x4C, uiExtKeyN5 },
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{ 0x4D, uiExtKeyN6 },
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{ 0x4F, uiExtKeyN1 },
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{ 0x50, uiExtKeyN2 },
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{ 0x51, uiExtKeyN3 },
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{ 0x52, uiExtKeyN0 },
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{ 0x53, uiExtKeyNDot },
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{ 0xFFFF, 0 },
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};
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int fromScancode(uintptr_t scancode, uiAreaKeyEvent *ke)
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{
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int i;
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for (i = 0; scancodeKeys[i].scancode != 0xFFFF; i++)
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if (scancodeKeys[i].scancode == scancode) {
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ke->Key = scancodeKeys[i].equiv;
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return 1;
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}
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for (i = 0; scancodeExtKeys[i].scancode != 0xFFFF; i++)
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if (scancodeExtKeys[i].scancode == scancode) {
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ke->ExtKey = scancodeExtKeys[i].equiv;
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return 1;
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}
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return 0;
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}
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