Added custom center point to rgb matrix
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7 changed files with 17 additions and 9 deletions
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@ -144,7 +144,7 @@ const led_config_t g_led_config = { {
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} };
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} };
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```
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```
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The first part, `// Key Matrix to LED Index`, tells the system what key this LED represents by using the key's electrical matrix row & col. The second part, `// LED Index to Physical Position` represents the LED's physical position on the keyboard. The first value, `x`, is between 0-224 (inclusive), and the second value, `y`, is between 0-64 (inclusive). This range is due to effect that calculate the center or halves for their animations. The easiest way to calculate these positions is imagine your keyboard is a grid, and the top left of the keyboard represents x, y coordinate 0, 0 and the bottom right of your keyboard represents 224, 64. Using this as a basis, you can use the following formula to calculate the physical position:
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The first part, `// Key Matrix to LED Index`, tells the system what key this LED represents by using the key's electrical matrix row & col. The second part, `// LED Index to Physical Position` represents the LED's physical `{ x, y }` position on the keyboard. The default expected range of values for `{ x, y }` is the inclusive range `{ 0..224, 0..64 }`. This default expected range is due to effects that calculate the center of the keyboard for their animations. The easiest way to calculate these positions is imagine your keyboard is a grid, and the top left of the keyboard represents `{ x, y }` coordinate `{ 0, 0 }` and the bottom right of your keyboard represents `{ 224, 64 }`. Using this as a basis, you can use the following formula to calculate the physical position:
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```C
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```C
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x = 224 / (NUMBER_OF_COLS - 1) * COL_POSITION
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x = 224 / (NUMBER_OF_COLS - 1) * COL_POSITION
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@ -153,6 +153,8 @@ y = 64 / (NUMBER_OF_ROWS - 1) * ROW_POSITION
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Where NUMBER_OF_COLS, NUMBER_OF_ROWS, COL_POSITION, & ROW_POSITION are all based on the physical layout of your keyboard, not the electrical layout.
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Where NUMBER_OF_COLS, NUMBER_OF_ROWS, COL_POSITION, & ROW_POSITION are all based on the physical layout of your keyboard, not the electrical layout.
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As mentioned earlier, the center of the keyboard by default is expected to be `{ 112, 32 }`, but this can be changed if you want to more accurately calculate the LED's physical `{ x, y }` positions. Keyboard designers can implement `#define RGB_MATRIX_CENTER { 112, 32 }` in their config.h file with the new center point of the keyboard, or where they want it to be allowing more possibilities for the `{ x, y }` values. Do note that the maximum value for x or y is 255, and the recommended maximum is 224 as this gives animations runoff room before they reset.
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`// LED Index to Flag` is a bitmask, whether or not a certain LEDs is of a certain type. It is recommended that LEDs are set to only 1 type.
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`// LED Index to Flag` is a bitmask, whether or not a certain LEDs is of a certain type. It is recommended that LEDs are set to only 1 type.
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## Flags
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## Flags
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@ -26,6 +26,12 @@
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#include "lib/lib8tion/lib8tion.h"
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#include "lib/lib8tion/lib8tion.h"
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#ifndef RGB_MATRIX_CENTER
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const point_t k_rgb_matrix_center = { 112, 32 };
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#else
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const point_t k_rgb_matrix_center = RGB_MATRIX_CENTER;
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#endif
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// ------------------------------------------
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// ------------------------------------------
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// -----Begin rgb effect includes macros-----
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// -----Begin rgb effect includes macros-----
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#define RGB_MATRIX_EFFECT(name)
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#define RGB_MATRIX_EFFECT(name)
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@ -9,8 +9,8 @@ bool CYCLE_OUT_IN(effect_params_t* params) {
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uint8_t time = scale16by8(g_rgb_counters.tick, rgb_matrix_config.speed / 4);
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uint8_t time = scale16by8(g_rgb_counters.tick, rgb_matrix_config.speed / 4);
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for (uint8_t i = led_min; i < led_max; i++) {
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for (uint8_t i = led_min; i < led_max; i++) {
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RGB_MATRIX_TEST_LED_FLAGS();
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RGB_MATRIX_TEST_LED_FLAGS();
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int16_t dx = g_led_config.point[i].x - 112;
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int16_t dx = g_led_config.point[i].x - k_rgb_matrix_center.x;
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int16_t dy = g_led_config.point[i].y - 32;
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int16_t dy = g_led_config.point[i].y - k_rgb_matrix_center.y;
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uint8_t dist = sqrt16(dx * dx + dy * dy);
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uint8_t dist = sqrt16(dx * dx + dy * dy);
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hsv.h = 3 * dist / 2 + time;
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hsv.h = 3 * dist / 2 + time;
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RGB rgb = hsv_to_rgb(hsv);
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RGB rgb = hsv_to_rgb(hsv);
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@ -9,8 +9,8 @@ bool CYCLE_OUT_IN_DUAL(effect_params_t* params) {
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uint8_t time = scale16by8(g_rgb_counters.tick, rgb_matrix_config.speed / 4);
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uint8_t time = scale16by8(g_rgb_counters.tick, rgb_matrix_config.speed / 4);
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for (uint8_t i = led_min; i < led_max; i++) {
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for (uint8_t i = led_min; i < led_max; i++) {
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RGB_MATRIX_TEST_LED_FLAGS();
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RGB_MATRIX_TEST_LED_FLAGS();
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int16_t dx = 56 - abs8(g_led_config.point[i].x - 112);
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int16_t dx = (k_rgb_matrix_center.x / 2) - abs8(g_led_config.point[i].x - k_rgb_matrix_center.x);
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int16_t dy = g_led_config.point[i].y - 32;
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int16_t dy = g_led_config.point[i].y - k_rgb_matrix_center.y;
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uint8_t dist = sqrt16(dx * dx + dy * dy);
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uint8_t dist = sqrt16(dx * dx + dy * dy);
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hsv.h = 3 * dist + time;
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hsv.h = 3 * dist + time;
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RGB rgb = hsv_to_rgb(hsv);
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RGB rgb = hsv_to_rgb(hsv);
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@ -11,7 +11,7 @@ bool DUAL_BEACON(effect_params_t* params) {
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int8_t sin_value = sin8(time) - 128;
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int8_t sin_value = sin8(time) - 128;
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for (uint8_t i = led_min; i < led_max; i++) {
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for (uint8_t i = led_min; i < led_max; i++) {
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RGB_MATRIX_TEST_LED_FLAGS();
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RGB_MATRIX_TEST_LED_FLAGS();
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hsv.h = ((g_led_config.point[i].y - 32) * cos_value + (g_led_config.point[i].x - 112) * sin_value) / 128 + rgb_matrix_config.hue;
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hsv.h = ((g_led_config.point[i].y - k_rgb_matrix_center.y) * cos_value + (g_led_config.point[i].x - k_rgb_matrix_center.x) * sin_value) / 128 + rgb_matrix_config.hue;
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RGB rgb = hsv_to_rgb(hsv);
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RGB rgb = hsv_to_rgb(hsv);
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rgb_matrix_set_color(i, rgb.r, rgb.g, rgb.b);
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rgb_matrix_set_color(i, rgb.r, rgb.g, rgb.b);
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}
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}
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@ -11,7 +11,7 @@ bool RAINBOW_BEACON(effect_params_t* params) {
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int16_t sin_value = 2 * (sin8(time) - 128);
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int16_t sin_value = 2 * (sin8(time) - 128);
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for (uint8_t i = led_min; i < led_max; i++) {
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for (uint8_t i = led_min; i < led_max; i++) {
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RGB_MATRIX_TEST_LED_FLAGS();
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RGB_MATRIX_TEST_LED_FLAGS();
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hsv.h = ((g_led_config.point[i].y - 32) * cos_value + (g_led_config.point[i].x - 112) * sin_value) / 128 + rgb_matrix_config.hue;
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hsv.h = ((g_led_config.point[i].y - k_rgb_matrix_center.y) * cos_value + (g_led_config.point[i].x - k_rgb_matrix_center.x) * sin_value) / 128 + rgb_matrix_config.hue;
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RGB rgb = hsv_to_rgb(hsv);
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RGB rgb = hsv_to_rgb(hsv);
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rgb_matrix_set_color(i, rgb.r, rgb.g, rgb.b);
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rgb_matrix_set_color(i, rgb.r, rgb.g, rgb.b);
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}
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}
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@ -11,7 +11,7 @@ bool PINWHEELS(effect_params_t* params) {
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int16_t sin_value = 3 * (sin8(time) - 128);
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int16_t sin_value = 3 * (sin8(time) - 128);
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for (uint8_t i = led_min; i < led_max; i++) {
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for (uint8_t i = led_min; i < led_max; i++) {
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RGB_MATRIX_TEST_LED_FLAGS();
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RGB_MATRIX_TEST_LED_FLAGS();
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hsv.h = ((g_led_config.point[i].y - 32) * cos_value + (56 - abs8(g_led_config.point[i].x - 112)) * sin_value) / 128 + rgb_matrix_config.hue;
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hsv.h = ((g_led_config.point[i].y - k_rgb_matrix_center.y) * cos_value + (56 - abs8(g_led_config.point[i].x - k_rgb_matrix_center.x)) * sin_value) / 128 + rgb_matrix_config.hue;
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RGB rgb = hsv_to_rgb(hsv);
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RGB rgb = hsv_to_rgb(hsv);
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rgb_matrix_set_color(i, rgb.r, rgb.g, rgb.b);
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rgb_matrix_set_color(i, rgb.r, rgb.g, rgb.b);
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}
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}
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