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i3lock-color/unlock_indicator.c
Cassandra a6be8397ad
Merge pull request #91 from aloomis/master
Text customization for the locking and lock failed states.
2018-05-06 21:06:47 -04:00

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/*
* vim:ts=4:sw=4:expandtab
*
* © 2010 Michael Stapelberg
*
* See LICENSE for licensing information
*
*/
#include <stdbool.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <math.h>
#include <xcb/xcb.h>
#include <ev.h>
#include <cairo.h>
#include <cairo/cairo-xcb.h>
#include "i3lock.h"
#include "xcb.h"
#include "unlock_indicator.h"
#include "randr.h"
#include "tinyexpr.h"
#include "fonts.h"
/* clock stuff */
#include <time.h>
extern double circle_radius;
extern double ring_width;
#define BUTTON_RADIUS (circle_radius)
#define RING_WIDTH (ring_width)
#define BUTTON_SPACE (BUTTON_RADIUS + (RING_WIDTH / 2))
#define BUTTON_DIAMETER (2 * BUTTON_SPACE)
/*******************************************************************************
* Variables defined in i3lock.c.
******************************************************************************/
extern bool debug_mode;
/* The current position in the input buffer. Useful to determine if any
* characters of the password have already been entered or not. */
extern int input_position;
/* The lock window. */
extern xcb_window_t win;
/* The current resolution of the X11 root window. */
extern uint32_t last_resolution[2];
/* Whether the unlock indicator is enabled (defaults to true). */
extern bool unlock_indicator;
/* List of pressed modifiers, or NULL if none are pressed. */
extern char *modifier_string;
/* A Cairo surface containing the specified image (-i), if any. */
extern cairo_surface_t *img;
extern cairo_surface_t *blur_img;
extern cairo_surface_t *img_slideshow[256];
extern int slideshow_image_count;
extern int slideshow_interval;
extern bool slideshow_random_selection;
unsigned long lastCheck;
/* Whether the image should be tiled. */
extern bool tile;
/* The background color to use (in hex). */
extern char color[7];
/* indicator color options */
extern char insidevercolor[9];
extern char insidewrongcolor[9];
extern char insidecolor[9];
extern char ringvercolor[9];
extern char ringwrongcolor[9];
extern char ringcolor[9];
extern char linecolor[9];
extern char verifcolor[9];
extern char wrongcolor[9];
extern char layoutcolor[9];
extern char timecolor[9];
extern char datecolor[9];
extern char keyhlcolor[9];
extern char bshlcolor[9];
extern char separatorcolor[9];
extern int internal_line_source;
extern int screen_number;
extern float refresh_rate;
extern bool show_clock;
extern bool always_show_clock;
extern bool show_indicator;
extern int verif_align;
extern int wrong_align;
extern int time_align;
extern int date_align;
extern int layout_align;
extern int modif_align;
extern char time_format[32];
extern char date_format[32];
extern char *fonts[5];
extern char ind_x_expr[32];
extern char ind_y_expr[32];
extern char time_x_expr[32];
extern char time_y_expr[32];
extern char date_x_expr[32];
extern char date_y_expr[32];
extern char layout_x_expr[32];
extern char layout_y_expr[32];
extern char status_x_expr[32];
extern char status_y_expr[32];
extern char verif_x_expr[32];
extern char verif_y_expr[32];
extern char wrong_x_expr[32];
extern char wrong_y_expr[32];
extern char modif_x_expr[32];
extern char modif_y_expr[32];
extern double time_size;
extern double date_size;
extern double verif_size;
extern double wrong_size;
extern double modifier_size;
extern double layout_size;
extern char *verif_text;
extern char *wrong_text;
extern char *noinput_text;
extern char *lock_text;
extern char *lock_failed_text;
extern char *layout_text;
/* Whether the failed attempts should be displayed. */
extern bool show_failed_attempts;
/* Number of failed unlock attempts. */
extern int failed_attempts;
/*******************************************************************************
* Variables defined in xcb.c.
******************************************************************************/
/* The root screen, to determine the DPI. */
extern xcb_screen_t *screen;
/*******************************************************************************
* Local variables.
******************************************************************************/
/* time stuff */
static struct ev_periodic *time_redraw_tick;
/* Cache the screens visual, necessary for creating a Cairo context. */
static xcb_visualtype_t *vistype;
int current_slideshow_index = 0;
/* Maintain the current unlock/PAM state to draw the appropriate unlock
* indicator. */
unlock_state_t unlock_state;
auth_state_t auth_state;
// color arrays
rgba_t insidever16;
rgba_t insidewrong16;
rgba_t inside16;
rgba_t ringver16;
rgba_t ringwrong16;
rgba_t ring16;
rgba_t line16;
rgba_t verif16;
rgba_t wrong16;
rgba_t layout16;
rgba_t time16;
rgba_t date16;
rgba_t keyhl16;
rgba_t bshl16;
rgba_t sep16;
rgba_t bar16;
// just rgb
rgb_t rgb16;
// experimental bar stuff
#define BAR_VERT 0
#define BAR_FLAT 1
// experimental bar stuff
extern bool bar_enabled;
extern double *bar_heights;
extern double bar_step;
extern double bar_base_height;
extern double bar_periodic_step;
extern double max_bar_height;
extern double bar_position;
extern int num_bars;
extern int bar_width;
extern int bar_orientation;
extern char bar_base_color[9];
extern char bar_expr[32];
extern bool bar_bidirectional;
extern bool bar_reversed;
static cairo_font_face_t *font_faces[5] = {
NULL,
NULL,
NULL,
NULL,
NULL,
};
/*
* Returns the scaling factor of the current screen. E.g., on a 227 DPI MacBook
* Pro 13" Retina screen, the scaling factor is 227/96 = 2.36.
*
*/
static double calculate_scaling_factor(void) {
const int dpi = (double)screen->height_in_pixels * 25.4 /
(double)screen->height_in_millimeters;
return dpi / 96.0;
}
static cairo_font_face_t *get_font_face(int which) {
if (font_faces[which]) {
return font_faces[which];
}
const unsigned char *face_name = (const unsigned char *)fonts[which];
FcResult result;
/*
* Loads the default config.
* On successive calls, does no work and just returns true.
*/
if (!FcInit()) {
DEBUG("Fontconfig init failed. No text will be shown.\n");
return NULL;
}
/*
* converts a font face name to a pattern for that face name
*/
FcPattern *pattern = FcNameParse(face_name);
if (!pattern) {
DEBUG("no sans-serif font available\n");
return NULL;
}
/*
* Gets the default font for our pattern. (Gets the default sans-serif font face)
* Without these two calls, the FcFontMatch call will fail due to FcConfigGetCurrent()
* not giving it a valid/useful config.
*/
FcDefaultSubstitute(pattern);
if (!FcConfigSubstitute(FcConfigGetCurrent(), pattern, FcMatchPattern)) {
DEBUG("config sub failed?\n");
return NULL;
}
/*
* Looks up the font pattern and does some internal RenderPrepare work,
* then returns the resulting pattern that's ready for rendering.
*/
FcPattern *pattern_ready = FcFontMatch(FcConfigGetCurrent(), pattern, &result);
FcPatternDestroy(pattern);
pattern = NULL;
if (!pattern_ready) {
DEBUG("no sans-serif font available\n");
return NULL;
}
/*
* Passes the given pattern into cairo, which loads it into a cairo freetype font face.
* Increment its reference count and cache it.
*/
cairo_font_face_t *face = cairo_ft_font_face_create_for_pattern(pattern_ready);
FcPatternDestroy(pattern_ready);
font_faces[which] = cairo_font_face_reference(face);
FcFini();
return face;
}
/*
* Draws the given text onto the cairo context
*/
static void draw_text(cairo_t *ctx, text_t text) {
if (!text.show)
return;
cairo_text_extents_t extents;
cairo_set_font_face(ctx, text.font);
cairo_set_font_size(ctx, text.size);
cairo_text_extents(ctx, text.str, &extents);
double x;
switch (text.align) {
case 1:
x = text.x;
break;
case 2:
x = text.x - (extents.width + extents.x_bearing);
break;
case 0:
default:
x = text.x - ((extents.width / 2) + (extents.x_bearing / 2));
break;
}
cairo_set_source_rgba(ctx, text.color.red, text.color.green, text.color.blue, text.color.alpha);
cairo_move_to(ctx, x, text.y);
cairo_show_text(ctx, text.str);
cairo_stroke(ctx);
}
static void draw_bar(cairo_t *ctx, double x, double y, double bar_offset) {
// oh boy, here we go!
// TODO: get this to play nicely with multiple monitors
// ideally it'd intelligently span both monitors
double width, height;
double back_x = 0, back_y = 0, back_x2 = 0, back_y2 = 0, back_width = 0, back_height = 0;
for (int i = 0; i < num_bars; ++i) {
double cur_bar_height = bar_heights[i];
if (cur_bar_height > 0) {
if (unlock_state == STATE_BACKSPACE_ACTIVE) {
cairo_set_source_rgba(ctx, bshl16.red, bshl16.green, bshl16.blue, bshl16.alpha);
} else {
cairo_set_source_rgba(ctx, keyhl16.red, keyhl16.green, keyhl16.blue, keyhl16.alpha);
}
} else {
switch (auth_state) {
case STATE_AUTH_VERIFY:
case STATE_AUTH_LOCK:
cairo_set_source_rgba(ctx, ringver16.red, ringver16.green, ringver16.blue, ringver16.alpha);
break;
case STATE_AUTH_WRONG:
case STATE_I3LOCK_LOCK_FAILED:
cairo_set_source_rgba(ctx, ringwrong16.red, ringwrong16.green, ringwrong16.blue, ringwrong16.alpha);
break;
default:
cairo_set_source_rgba(ctx, bar16.red, bar16.green, bar16.blue, bar16.alpha);
break;
}
}
if (bar_orientation == BAR_VERT) {
width = (cur_bar_height <= 0 ? bar_base_height : cur_bar_height);
height = bar_width;
x = bar_offset;
y = i * bar_width;
if (bar_reversed) {
x -= width;
} else if (bar_bidirectional) {
width = (cur_bar_height <= 0 ? bar_base_height : cur_bar_height * 2);
x = bar_offset - (width / 2) + (bar_base_height / 2);
}
} else {
width = bar_width;
height = (cur_bar_height <= 0 ? bar_base_height : cur_bar_height);
x = i * bar_width;
y = bar_offset;
if (bar_reversed) {
y -= height;
} else if (bar_bidirectional) {
height = (cur_bar_height <= 0 ? bar_base_height : cur_bar_height * 2);
y = bar_offset - (height / 2) + (bar_base_height / 2);
}
}
if (cur_bar_height < bar_base_height && cur_bar_height > 0) {
if (bar_orientation == BAR_VERT) {
back_x = bar_offset + cur_bar_height;
back_y = y;
back_width = bar_base_height - cur_bar_height;
back_height = height;
if (bar_reversed) {
back_x = bar_offset - bar_base_height;
} else if (bar_bidirectional) {
back_x = bar_offset;
back_y2 = y;
back_width = (bar_base_height - (cur_bar_height * 2)) / 2;
back_x2 = bar_offset + (cur_bar_height * 2) + back_width;
}
} else {
back_x = x;
back_y = bar_offset + cur_bar_height;
back_width = width;
back_height = bar_base_height - cur_bar_height;
if (bar_reversed) {
back_y = bar_offset - bar_base_height;
} else if (bar_bidirectional) {
back_x2 = x;
back_y = bar_offset;
back_height = (bar_base_height - (cur_bar_height * 2)) / 2;
back_y2 = bar_offset + (cur_bar_height * 2) + back_height;
}
}
}
cairo_rectangle(ctx, x, y, width, height);
cairo_fill(ctx);
switch (auth_state) {
case STATE_AUTH_VERIFY:
case STATE_AUTH_LOCK:
cairo_set_source_rgba(ctx, ringver16.red, ringver16.green, ringver16.blue, ringver16.alpha);
break;
case STATE_AUTH_WRONG:
case STATE_I3LOCK_LOCK_FAILED:
cairo_set_source_rgba(ctx, ringwrong16.red, ringwrong16.green, ringwrong16.blue, ringwrong16.alpha);
break;
default:
cairo_set_source_rgba(ctx, bar16.red, bar16.green, bar16.blue, bar16.alpha);
break;
}
if (cur_bar_height > 0 && cur_bar_height < bar_base_height && ((bar_bidirectional && ((cur_bar_height * 2) < bar_base_height)) || (!bar_bidirectional && (cur_bar_height < bar_base_height)))) {
cairo_rectangle(ctx, back_x, back_y, back_width, back_height);
cairo_fill(ctx);
if (bar_bidirectional) {
cairo_rectangle(ctx, back_x2, back_y2, back_width, back_height);
cairo_fill(ctx);
}
}
}
for (int i = 0; i < num_bars; ++i) {
if (bar_heights[i] > 0)
bar_heights[i] -= bar_periodic_step;
}
}
static void draw_indic(cairo_t *ctx, double ind_x, double ind_y) {
if (unlock_indicator &&
(unlock_state >= STATE_KEY_PRESSED || auth_state > STATE_AUTH_IDLE || show_indicator)) {
/* Draw a (centered) circle with transparent background. */
cairo_set_line_width(ctx, RING_WIDTH);
cairo_arc(ctx, ind_x, ind_y, BUTTON_RADIUS, 0, 2 * M_PI);
/* Use the appropriate color for the different PAM states
* (currently verifying, wrong password, or default) */
switch (auth_state) {
case STATE_AUTH_VERIFY:
case STATE_AUTH_LOCK:
cairo_set_source_rgba(ctx, insidever16.red, insidever16.green, insidever16.blue, insidever16.alpha);
break;
case STATE_AUTH_WRONG:
case STATE_I3LOCK_LOCK_FAILED:
cairo_set_source_rgba(ctx, insidewrong16.red, insidewrong16.green, insidewrong16.blue, insidewrong16.alpha);
break;
default:
if (unlock_state == STATE_NOTHING_TO_DELETE) {
cairo_set_source_rgba(ctx, insidewrong16.red, insidewrong16.green, insidewrong16.blue, insidewrong16.alpha);
break;
}
cairo_set_source_rgba(ctx, inside16.red, inside16.green, inside16.blue, inside16.alpha);
break;
}
cairo_fill_preserve(ctx);
switch (auth_state) {
case STATE_AUTH_VERIFY:
case STATE_AUTH_LOCK:
cairo_set_source_rgba(ctx, ringver16.red, ringver16.green, ringver16.blue, ringver16.alpha);
if (internal_line_source == 1) {
line16.red = ringver16.red;
line16.green = ringver16.green;
line16.blue = ringver16.blue;
line16.alpha = ringver16.alpha;
}
break;
case STATE_AUTH_WRONG:
case STATE_I3LOCK_LOCK_FAILED:
cairo_set_source_rgba(ctx, ringwrong16.red, ringwrong16.green, ringwrong16.blue, ringwrong16.alpha);
if (internal_line_source == 1) {
line16.red = ringwrong16.red;
line16.green = ringwrong16.green;
line16.blue = ringwrong16.blue;
line16.alpha = ringwrong16.alpha;
}
break;
case STATE_AUTH_IDLE:
if (unlock_state == STATE_NOTHING_TO_DELETE) {
cairo_set_source_rgba(ctx, ringwrong16.red, ringwrong16.green, ringwrong16.blue, ringwrong16.alpha);
if (internal_line_source == 1) {
line16.red = ringwrong16.red;
line16.green = ringwrong16.green;
line16.blue = ringwrong16.blue;
line16.alpha = ringwrong16.alpha;
}
break;
}
cairo_set_source_rgba(ctx, ring16.red, ring16.green, ring16.blue, ring16.alpha);
if (internal_line_source == 1) {
line16.red = ring16.red;
line16.green = ring16.green;
line16.blue = ring16.blue;
line16.alpha = ring16.alpha;
}
break;
}
cairo_stroke(ctx);
/* Draw an inner separator line. */
if (internal_line_source != 2) { //pretty sure this only needs drawn if it's being drawn over the inside?
cairo_set_source_rgba(ctx, line16.red, line16.green, line16.blue, line16.alpha);
cairo_set_line_width(ctx, 2.0);
cairo_arc(ctx, ind_x, ind_y, BUTTON_RADIUS - 5, 0, 2 * M_PI);
cairo_stroke(ctx);
}
if (unlock_state == STATE_KEY_ACTIVE || unlock_state == STATE_BACKSPACE_ACTIVE) {
cairo_set_line_width(ctx, RING_WIDTH);
cairo_new_sub_path(ctx);
double highlight_start = (rand() % (int)(2 * M_PI * 100)) / 100.0;
cairo_arc(ctx, ind_x, ind_y, BUTTON_RADIUS,
highlight_start, highlight_start + (M_PI / 3.0));
if (unlock_state == STATE_KEY_ACTIVE) {
/* For normal keys, we use a lighter green. */
cairo_set_source_rgba(ctx, keyhl16.red, keyhl16.green, keyhl16.blue, keyhl16.alpha);
} else {
/* For backspace, we use red. */
cairo_set_source_rgba(ctx, bshl16.red, bshl16.green, bshl16.blue, bshl16.alpha);
}
cairo_stroke(ctx);
/* Draw two little separators for the highlighted part of the
* unlock indicator. */
cairo_set_source_rgba(ctx, sep16.red, sep16.green, sep16.blue, sep16.alpha);
cairo_arc(ctx, ind_x, ind_y, BUTTON_RADIUS,
highlight_start, highlight_start + (M_PI / 128.0));
cairo_stroke(ctx);
cairo_arc(ctx, ind_x, ind_y, BUTTON_RADIUS,
(highlight_start + (M_PI / 3.0)) - (M_PI / 128.0),
highlight_start + (M_PI / 3.0));
cairo_stroke(ctx);
}
}
}
/*
* Initialize all the color arrays once.
* Called once after options are parsed.
*/
/*
colorstring: 8-character RGBA string ("ff0000ff", "00000000", "ffffffff", etc)
colorstring16: array of 4 integers (r, g, b, a).
MAKE_COLORGROUPS(colorstring, colorstring16) =>
char colorstring_tmparr[4][3] = {{colorstring[0], colorstring[1], '\0'},
{colorstring[2], colorstring[3], '\0'},
{colorstring[4], colorstring[5], '\0'},
{colorstring[6], colorstring[7], '\0'}};
uint32_t colorstring16[4] = {(strtol(colorstring_tmparr[0], NULL, 16)),
(strtol(colorstring_tmparr[1], NULL, 16)),
(strtol(colorstring_tmparr[2], NULL, 16)),
(strtol(colorstring_tmparr[3], NULL, 16))};
*/
static void set_color(char *dest, const char *src, int offset) {
dest[0] = src[offset];
dest[1] = src[offset + 1];
dest[2] = '\0';
}
static void colorgen(rgba_str_t *tmp, const char *src, rgba_t *dest) {
set_color(tmp->red, src, 0);
set_color(tmp->green, src, 2);
set_color(tmp->blue, src, 4);
set_color(tmp->alpha, src, 6);
dest->red = strtol(tmp->red, NULL, 16) / 255.0;
dest->green = strtol(tmp->green, NULL, 16) / 255.0;
dest->blue = strtol(tmp->blue, NULL, 16) / 255.0;
dest->alpha = strtol(tmp->alpha, NULL, 16) / 255.0;
}
static void colorgen_rgb(rgb_str_t *tmp, const char *src, rgb_t *dest) {
set_color(tmp->red, src, 0);
set_color(tmp->green, src, 2);
set_color(tmp->blue, src, 4);
dest->red = strtol(tmp->red, NULL, 16) / 255.0;
dest->green = strtol(tmp->green, NULL, 16) / 255.0;
dest->blue = strtol(tmp->blue, NULL, 16) / 255.0;
}
void init_colors_once(void) {
/* initialize for slideshow time interval */
lastCheck = (unsigned long)time(NULL);
rgba_str_t tmp;
rgb_str_t tmp_rgb;
/* build indicator color arrays */
colorgen(&tmp, insidevercolor, &insidever16);
colorgen(&tmp, insidewrongcolor, &insidewrong16);
colorgen(&tmp, insidecolor, &inside16);
colorgen(&tmp, ringvercolor, &ringver16);
colorgen(&tmp, ringwrongcolor, &ringwrong16);
colorgen(&tmp, ringcolor, &ring16);
colorgen(&tmp, linecolor, &line16);
colorgen(&tmp, verifcolor, &verif16);
colorgen(&tmp, wrongcolor, &wrong16);
colorgen(&tmp, layoutcolor, &layout16);
colorgen(&tmp, timecolor, &time16);
colorgen(&tmp, datecolor, &date16);
colorgen(&tmp, keyhlcolor, &keyhl16);
colorgen(&tmp, bshlcolor, &bshl16);
colorgen(&tmp, separatorcolor, &sep16);
colorgen(&tmp, bar_base_color, &bar16);
colorgen_rgb(&tmp_rgb, color, &rgb16);
}
static te_expr *compile_expression(const char *const from, const char *expression, const te_variable *variables, int var_count) {
int te_err = 0;
te_expr *expr = te_compile(expression, variables, var_count, &te_err);
if (te_err) {
fprintf(stderr, "Failed to reason about '%s' given by '%s'\n", expression, from);
exit(1);
}
return expr;
}
static DrawData create_draw_data() {
DrawData draw_data;
memset(&draw_data, 0, sizeof(DrawData));
return draw_data;
}
static void draw_elements(cairo_t *const ctx, DrawData const *const draw_data) {
// indicator stuff
if (!bar_enabled) {
draw_indic(ctx, draw_data->indicator_x, draw_data->indicator_y);
} else {
if (unlock_state == STATE_KEY_ACTIVE ||
unlock_state == STATE_BACKSPACE_ACTIVE) {
// note: might be biased to cause more hits on lower indices
// maybe see about doing ((double) rand() / RAND_MAX) * num_bars
int index = rand() % num_bars;
bar_heights[index] = max_bar_height;
for (int i = 0; i < ((max_bar_height / bar_step) + 1); ++i) {
int low_ind = index - i;
while (low_ind < 0) {
low_ind += num_bars;
}
int high_ind = (index + i) % num_bars;
int tmp_height = max_bar_height - (bar_step * i);
if (tmp_height < 0)
tmp_height = 0;
if (bar_heights[low_ind] < tmp_height)
bar_heights[low_ind] = tmp_height;
if (bar_heights[high_ind] < tmp_height)
bar_heights[high_ind] = tmp_height;
if (tmp_height == 0)
break;
}
}
draw_bar(ctx, draw_data->bar_x, draw_data->bar_y, draw_data->bar_offset);
}
draw_text(ctx, draw_data->status_text);
draw_text(ctx, draw_data->keylayout_text);
draw_text(ctx, draw_data->mod_text);
draw_text(ctx, draw_data->time_text);
draw_text(ctx, draw_data->date_text);
}
/*
* Draws global image with fill color onto a pixmap with the given
* resolution and returns it.
*
*/
xcb_pixmap_t draw_image(uint32_t *resolution) {
const double scaling_factor = calculate_scaling_factor();
xcb_pixmap_t bg_pixmap = XCB_NONE;
if (!vistype)
vistype = get_root_visual_type(screen);
bg_pixmap = create_bg_pixmap(conn, screen, resolution, color);
/* Initialize cairo: Create one in-memory surface to render the unlock
* indicator on, create one XCB surface to actually draw (one or more,
* depending on the amount of screens) unlock indicators on.
* create two more surfaces for time and date display
*/
cairo_surface_t *output = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, resolution[0], resolution[1]);
cairo_t *ctx = cairo_create(output);
cairo_scale(ctx, scaling_factor, scaling_factor);
// cairo_set_font_face(ctx, get_font_face(0));
cairo_surface_t *xcb_output = cairo_xcb_surface_create(conn, bg_pixmap, vistype, resolution[0], resolution[1]);
cairo_t *xcb_ctx = cairo_create(xcb_output);
/*update image according to the slideshow_interval*/
if (slideshow_image_count > 0) {
unsigned long now = (unsigned long)time(NULL);
if (img == NULL || now - lastCheck >= slideshow_interval) {
if (slideshow_random_selection) {
img = img_slideshow[rand() % slideshow_image_count];
} else {
img = img_slideshow[current_slideshow_index++];
if (current_slideshow_index >= slideshow_image_count) {
current_slideshow_index = 0;
}
}
lastCheck = now;
}
}
if (blur_img || img) {
if (blur_img) {
cairo_set_source_surface(xcb_ctx, blur_img, 0, 0);
cairo_paint(xcb_ctx);
} else { // img can no longer be non-NULL if blur_img is not null
if (!tile) {
cairo_set_source_surface(xcb_ctx, img, 0, 0);
cairo_paint(xcb_ctx);
} else {
/* create a pattern and fill a rectangle as big as the screen */
cairo_pattern_t *pattern;
pattern = cairo_pattern_create_for_surface(img);
cairo_set_source(xcb_ctx, pattern);
cairo_pattern_set_extend(pattern, CAIRO_EXTEND_REPEAT);
cairo_rectangle(xcb_ctx, 0, 0, resolution[0], resolution[1]);
cairo_fill(xcb_ctx);
cairo_pattern_destroy(pattern);
}
}
} else {
cairo_set_source_rgb(xcb_ctx, rgb16.red, rgb16.green, rgb16.blue);
cairo_rectangle(xcb_ctx, 0, 0, resolution[0], resolution[1]);
cairo_fill(xcb_ctx);
}
/*
* gen text
* calc vars
* process if keystroke or not
* draw indicator
* draw text
*/
DrawData draw_data = create_draw_data();
if (unlock_indicator &&
(unlock_state >= STATE_KEY_PRESSED || auth_state > STATE_AUTH_IDLE || show_indicator)) {
switch (auth_state) {
case STATE_AUTH_VERIFY:
draw_data.status_text.show = true;
strncpy(draw_data.status_text.str, verif_text, sizeof(draw_data.status_text.str));
draw_data.status_text.font = get_font_face(VERIF_FONT);
draw_data.status_text.color = verif16;
draw_data.status_text.size = verif_size;
draw_data.status_text.align = verif_align;
break;
case STATE_AUTH_LOCK:
draw_data.status_text.show = true;
strncpy(draw_data.status_text.str, lock_text, sizeof(draw_data.status_text.str));
draw_data.status_text.font = get_font_face(VERIF_FONT);
draw_data.status_text.color = verif16;
draw_data.status_text.size = verif_size;
draw_data.status_text.align = verif_align;
break;
case STATE_AUTH_WRONG:
draw_data.status_text.show = true;
strncpy(draw_data.status_text.str, wrong_text, sizeof(draw_data.status_text.str));
draw_data.status_text.font = get_font_face(WRONG_FONT);
draw_data.status_text.color = wrong16;
draw_data.status_text.size = wrong_size;
draw_data.status_text.align = wrong_align;
break;
case STATE_I3LOCK_LOCK_FAILED:
draw_data.status_text.show = true;
strncpy(draw_data.status_text.str, lock_failed_text, sizeof(draw_data.status_text.str));
draw_data.status_text.font = get_font_face(WRONG_FONT);
draw_data.status_text.color = wrong16;
draw_data.status_text.size = wrong_size;
draw_data.status_text.align = wrong_align;
break;
default:
if (unlock_state == STATE_NOTHING_TO_DELETE) {
draw_data.status_text.show = true;
strncpy(draw_data.status_text.str, noinput_text, sizeof(draw_data.status_text.str));
draw_data.status_text.font = get_font_face(WRONG_FONT);
draw_data.status_text.color = wrong16;
draw_data.status_text.size = wrong_size;
draw_data.status_text.align = wrong_align;
break;
}
if (show_failed_attempts && failed_attempts > 0) {
draw_data.status_text.show = true;
draw_data.status_text.font = get_font_face(WRONG_FONT);
draw_data.status_text.color = wrong16;
draw_data.status_text.size = wrong_size;
draw_data.status_text.align = wrong_align;
// TODO: variable for this
draw_data.status_text.size = 32.0;
if (failed_attempts > 999) {
strncpy(draw_data.status_text.str, "> 999", sizeof(draw_data.status_text.str));
} else {
snprintf(draw_data.status_text.str, sizeof(draw_data.status_text.str), "%d", failed_attempts);
}
}
break;
}
}
if (modifier_string) {
draw_data.mod_text.show = true;
strncpy(draw_data.mod_text.str, modifier_string, sizeof(draw_data.mod_text.str));
draw_data.mod_text.size = modifier_size;
draw_data.mod_text.font = get_font_face(WRONG_FONT);
draw_data.mod_text.align = modif_align;
draw_data.mod_text.color = wrong16;
}
if (layout_text) {
draw_data.keylayout_text.show = true;
strncpy(draw_data.keylayout_text.str, layout_text, sizeof(draw_data.keylayout_text.str));
draw_data.keylayout_text.size = layout_size;
draw_data.keylayout_text.font = get_font_face(LAYOUT_FONT);
draw_data.keylayout_text.color = layout16;
draw_data.keylayout_text.align = layout_align;
}
if (show_clock && (!draw_data.status_text.show || always_show_clock)) {
time_t rawtime;
struct tm *timeinfo;
time(&rawtime);
timeinfo = localtime(&rawtime);
strftime(draw_data.time_text.str, 40, time_format, timeinfo);
if (*draw_data.time_text.str) {
draw_data.time_text.show = true;
draw_data.time_text.size = time_size;
draw_data.time_text.color = time16;
draw_data.time_text.font = get_font_face(TIME_FONT);
draw_data.time_text.align = time_align;
}
strftime(draw_data.date_text.str, 40, date_format, timeinfo);
if (*draw_data.date_text.str) {
draw_data.date_text.show = true;
draw_data.date_text.size = date_size;
draw_data.date_text.color = date16;
draw_data.date_text.font = get_font_face(DATE_FONT);
draw_data.date_text.align = date_align;
}
}
// initialize positioning vars
double screen_x = 0, screen_y = 0,
width = 0, height = 0;
double radius = (circle_radius + ring_width);
int button_diameter_physical = ceil(scaling_factor * BUTTON_DIAMETER);
DEBUG("scaling_factor is %f, physical diameter is %d px\n",
scaling_factor, button_diameter_physical);
// variable mapping for evaluating the clock position expression
const unsigned int vars_size = 11;
te_variable vars[] =
{{"w", &width},
{"h", &height},
{"x", &screen_x},
{"y", &screen_y},
{"ix", &draw_data.indicator_x},
{"iy", &draw_data.indicator_y},
{"tx", &draw_data.time_text.x},
{"ty", &draw_data.time_text.y},
{"dx", &draw_data.date_text.x},
{"dy", &draw_data.date_text.y},
{"r", &radius}};
te_expr *te_ind_x_expr = compile_expression("--indpos", ind_x_expr, vars, vars_size);
te_expr *te_ind_y_expr = compile_expression("--indpos", ind_y_expr, vars, vars_size);
te_expr *te_time_x_expr = compile_expression("--timepos", time_x_expr, vars, vars_size);
te_expr *te_time_y_expr = compile_expression("--timepos", time_y_expr, vars, vars_size);
te_expr *te_date_x_expr = compile_expression("--datepos", date_x_expr, vars, vars_size);
te_expr *te_date_y_expr = compile_expression("--datepos", date_y_expr, vars, vars_size);
te_expr *te_layout_x_expr = compile_expression("--layoutpos", layout_x_expr, vars, vars_size);
te_expr *te_layout_y_expr = compile_expression("--layoutpos", layout_y_expr, vars, vars_size);
te_expr *te_status_x_expr = compile_expression("--statuspos", status_x_expr, vars, vars_size);
te_expr *te_status_y_expr = compile_expression("--statuspos", status_y_expr, vars, vars_size);
te_expr *te_verif_x_expr = compile_expression("--verifpos", verif_x_expr, vars, vars_size);
te_expr *te_verif_y_expr = compile_expression("--verifpos", verif_y_expr, vars, vars_size);
te_expr *te_wrong_x_expr = compile_expression("--wrongpos", wrong_x_expr, vars, vars_size);
te_expr *te_wrong_y_expr = compile_expression("--wrongpos", wrong_y_expr, vars, vars_size);
te_expr *te_modif_x_expr = compile_expression("--modifpos", modif_x_expr, vars, vars_size);
te_expr *te_modif_y_expr = compile_expression("--modifpos", modif_y_expr, vars, vars_size);
te_expr *te_bar_expr = compile_expression("--bar-position", bar_expr, vars, vars_size);
if (xr_screens > 0) {
if (screen_number < 0 || screen_number > xr_screens) {
screen_number = 0;
}
int current_screen = screen_number == 0 ? 0 : screen_number - 1;
const int end_screen = screen_number == 0 ? xr_screens : screen_number;
for (; current_screen < end_screen; current_screen++) {
draw_data.indicator_x = 0;
draw_data.indicator_y = 0;
draw_data.time_text.x = 0;
draw_data.time_text.y = 0;
draw_data.date_text.x = 0;
draw_data.date_text.y = 0;
width = xr_resolutions[current_screen].width / scaling_factor;
height = xr_resolutions[current_screen].height / scaling_factor;
screen_x = xr_resolutions[current_screen].x / scaling_factor;
screen_y = xr_resolutions[current_screen].y / scaling_factor;
if (te_ind_x_expr && te_ind_y_expr) {
draw_data.indicator_x = te_eval(te_ind_x_expr);
draw_data.indicator_y = te_eval(te_ind_y_expr);
} else {
draw_data.indicator_x = screen_x + width / 2;
draw_data.indicator_y = screen_y + height / 2;
}
draw_data.bar_x = draw_data.indicator_x - (button_diameter_physical / 2);
draw_data.bar_y = draw_data.indicator_y - (button_diameter_physical / 2);
draw_data.bar_offset = te_eval(te_bar_expr);
draw_data.time_text.x = te_eval(te_time_x_expr);
draw_data.time_text.y = te_eval(te_time_y_expr);
draw_data.date_text.x = te_eval(te_date_x_expr);
draw_data.date_text.y = te_eval(te_date_y_expr);
draw_data.keylayout_text.x = te_eval(te_layout_x_expr);
draw_data.keylayout_text.y = te_eval(te_layout_y_expr);
switch (auth_state) {
case STATE_AUTH_VERIFY:
case STATE_AUTH_LOCK:
draw_data.status_text.x = te_eval(te_verif_x_expr);
draw_data.status_text.y = te_eval(te_verif_y_expr);
break;
case STATE_AUTH_WRONG:
case STATE_I3LOCK_LOCK_FAILED:
draw_data.status_text.x = te_eval(te_wrong_x_expr);
draw_data.status_text.y = te_eval(te_wrong_y_expr);
break;
default:
draw_data.status_text.x = te_eval(te_status_x_expr);
draw_data.status_text.y = te_eval(te_status_y_expr);
break;
}
draw_data.mod_text.x = te_eval(te_modif_x_expr);
draw_data.mod_text.y = te_eval(te_modif_y_expr);
DEBUG("Indicator at %fx%f on screen %d\n", draw_data.indicator_x, draw_data.indicator_y, current_screen + 1);
DEBUG("Bar at %fx%f on screen %d\n", draw_data.bar_x, draw_data.bar_y, current_screen + 1);
DEBUG("Time at %fx%f on screen %d\n", draw_data.time_text.x, draw_data.time_text.y, current_screen + 1);
DEBUG("Date at %fx%f on screen %d\n", draw_data.date_text.x, draw_data.date_text.y, current_screen + 1);
DEBUG("Layout at %fx%f on screen %d\n", draw_data.keylayout_text.x, draw_data.keylayout_text.y, current_screen + 1);
DEBUG("Status at %fx%f on screen %d\n", draw_data.status_text.x, draw_data.status_text.y, current_screen + 1);
DEBUG("Mod at %fx%f on screen %d\n", draw_data.mod_text.x, draw_data.mod_text.y, current_screen + 1);
// scale_draw_data(&draw_data, scaling_factor);
draw_elements(ctx, &draw_data);
}
} else {
/* We have no information about the screen sizes/positions, so we just
* place the unlock indicator in the middle of the X root window and
* hope for the best. */
width = last_resolution[0] / scaling_factor;
height = last_resolution[1] / scaling_factor;
draw_data.indicator_x = width / 2;
draw_data.indicator_y = height / 2;
draw_data.bar_x = draw_data.indicator_x - (button_diameter_physical / 2);
draw_data.bar_y = draw_data.indicator_y - (button_diameter_physical / 2);
draw_data.time_text.x = te_eval(te_time_x_expr);
draw_data.time_text.y = te_eval(te_time_y_expr);
draw_data.date_text.x = te_eval(te_date_x_expr);
draw_data.date_text.y = te_eval(te_date_y_expr);
draw_data.keylayout_text.x = te_eval(te_layout_x_expr);
draw_data.keylayout_text.y = te_eval(te_layout_y_expr);
switch (auth_state) {
case STATE_AUTH_VERIFY:
case STATE_AUTH_LOCK:
draw_data.status_text.x = te_eval(te_verif_x_expr);
draw_data.status_text.y = te_eval(te_verif_y_expr);
break;
case STATE_AUTH_WRONG:
case STATE_I3LOCK_LOCK_FAILED:
draw_data.status_text.x = te_eval(te_wrong_x_expr);
draw_data.status_text.y = te_eval(te_wrong_y_expr);
break;
default:
draw_data.status_text.x = te_eval(te_status_x_expr);
draw_data.status_text.y = te_eval(te_status_y_expr);
break;
}
draw_data.mod_text.x = te_eval(te_modif_x_expr);
draw_data.mod_text.y = te_eval(te_modif_y_expr);
DEBUG("Indicator at %fx%f\n", draw_data.indicator_x, draw_data.indicator_y);
DEBUG("Bar at %fx%f\n", draw_data.bar_x, draw_data.bar_y);
DEBUG("Time at %fx%f\n", draw_data.time_text.x, draw_data.time_text.y);
DEBUG("Date at %fx%f\n", draw_data.date_text.x, draw_data.date_text.y);
DEBUG("Layout at %fx%f\n", draw_data.keylayout_text.x, draw_data.keylayout_text.y);
DEBUG("Status at %fx%f\n", draw_data.status_text.x, draw_data.status_text.y);
DEBUG("Mod at %fx%f\n", draw_data.mod_text.x, draw_data.mod_text.y);
draw_elements(ctx, &draw_data);
}
te_free(te_ind_x_expr);
te_free(te_ind_y_expr);
te_free(te_time_x_expr);
te_free(te_time_y_expr);
te_free(te_date_x_expr);
te_free(te_date_y_expr);
te_free(te_layout_x_expr);
te_free(te_layout_y_expr);
te_free(te_status_x_expr);
te_free(te_status_y_expr);
te_free(te_verif_x_expr);
te_free(te_verif_y_expr);
te_free(te_wrong_x_expr);
te_free(te_wrong_y_expr);
te_free(te_modif_x_expr);
te_free(te_modif_y_expr);
te_free(te_bar_expr);
cairo_set_source_surface(xcb_ctx, output, 0, 0);
cairo_rectangle(xcb_ctx, 0, 0, resolution[0], resolution[1]);
cairo_fill(xcb_ctx);
cairo_surface_destroy(xcb_output);
cairo_surface_destroy(output);
cairo_destroy(ctx);
cairo_destroy(xcb_ctx);
return bg_pixmap;
}
/*
* Calls draw_image on a new pixmap and swaps that with the current pixmap
*
*/
void redraw_screen(void) {
DEBUG("redraw_screen(unlock_state = %d, auth_state = %d) @ [%lu]\n", unlock_state, auth_state, (unsigned long)time(NULL));
xcb_pixmap_t bg_pixmap = draw_image(last_resolution);
xcb_change_window_attributes(conn, win, XCB_CW_BACK_PIXMAP, (uint32_t[1]){bg_pixmap});
/* XXX: Possible optimization: Only update the area in the middle of the
* screen instead of the whole screen. */
xcb_clear_area(conn, 0, win, 0, 0, last_resolution[0], last_resolution[1]);
xcb_free_pixmap(conn, bg_pixmap);
xcb_flush(conn);
}
/*
* Hides the unlock indicator completely when there is no content in the
* password buffer.
*
*/
void clear_indicator(void) {
if (input_position == 0) {
unlock_state = STATE_STARTED;
} else
unlock_state = STATE_KEY_PRESSED;
redraw_screen();
}
void *start_time_redraw_tick_pthread(void *arg) {
struct timespec *ts = (struct timespec *)arg;
while (1) {
nanosleep(ts, NULL);
redraw_screen();
}
return NULL;
}
static void time_redraw_cb(struct ev_loop *loop, ev_periodic *w, int revents) {
redraw_screen();
}
void start_time_redraw_tick(struct ev_loop *main_loop) {
if (time_redraw_tick) {
ev_periodic_set(time_redraw_tick, 0., refresh_rate, 0);
ev_periodic_again(main_loop, time_redraw_tick);
} else {
if (!(time_redraw_tick = calloc(sizeof(struct ev_periodic), 1))) {
return;
}
ev_periodic_init(time_redraw_tick, time_redraw_cb, 0., refresh_rate, 0);
ev_periodic_start(main_loop, time_redraw_tick);
}
}