Fix how the lens vector is incorporated, fix formatting
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wheaney
parent
7c6d7ef84d
commit
88a97542e0
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@ -26,57 +26,60 @@ vec4 quatMul(vec4 q1, vec4 q2) {
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float s = q1.w;
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vec3 v = vec3(q2.x, q2.y, q2.z);
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float t = q2.w;
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return vec4(s*v + t*u + cross(u, v), s*t - dot(u, v));
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return vec4(s * v + t * u + cross(u, v), s * t - dot(u, v));
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}
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vec4 quatConj(vec4 q) {
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return vec4(-q.x, -q.y, -q.z, q.w);
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return vec4(-q.x, -q.y, -q.z, q.w);
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}
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vec3 applyQuaternionToVector(vec4 q, vec3 v) {
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vec4 p = quatMul(quatMul(q, vec4(v, 0)), quatConj(q));
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return p.xyz;
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vec4 p = quatMul(quatMul(q, vec4(v, 0)), quatConj(q));
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return p.xyz;
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}
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const int day_in_seconds = 24 * 60 * 60;
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vec3 applyLookAhead(
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in vec3 position,
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in vec3 velocity,
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in vec3 accel,
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in float t,
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in float t_squared) {
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return position + velocity * t + 0.5 * accel * t_squared;
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in vec3 position,
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in vec3 velocity,
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in vec3 accel,
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in float t,
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in float t_squared
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) {
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return position + velocity * t + 0.5 * accel * t_squared;
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}
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vec3 rateOfChange(
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in vec3 v1,
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in vec3 v2,
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in float delta_time) {
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return (v1 - v2) / delta_time;
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in vec3 v1,
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in vec3 v2,
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in float delta_time
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) {
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return (v1 - v2) / delta_time;
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}
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void PS_IMU_Transform(vec4 pos, vec2 texcoord, out vec4 color) {
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float texcoord_x_min = 0.0;
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float texcoord_x_max = 1.0;
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float lens_y_offset = 0.0;
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float lens_z_offset = 0.0;
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float aspect_ratio = stage_aspect_ratio;
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float texcoord_x_min = 0.0;
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float texcoord_x_max = 1.0;
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float lens_y_offset = 0.0;
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float lens_z_offset = 0.0;
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float aspect_ratio = stage_aspect_ratio;
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if (enabled && sbs_enabled) {
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if(enabled && sbs_enabled) {
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bool right_display = texcoord.x > 0.5;
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aspect_ratio /= 2;
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lens_y_offset = lens_distance_ratio / 3;
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if (right_display) lens_y_offset = -lens_y_offset;
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if (sbs_content) {
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if(right_display)
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lens_y_offset = -lens_y_offset;
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if(sbs_content) {
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// source video is SBS, left-half of the screen goes to the left lens, right-half to the right lens
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if (right_display)
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if(right_display)
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texcoord_x_min = 0.5;
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else
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texcoord_x_max = 0.5;
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}
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if (!sbs_mode_stretched) {
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if(!sbs_mode_stretched) {
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// if the content isn't stretched, assume it's centered in the middle 50% of the screen
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texcoord_x_min = max(0.25, texcoord_x_min);
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texcoord_x_max = min(0.75, texcoord_x_max);
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@ -86,7 +89,7 @@ void PS_IMU_Transform(vec4 pos, vec2 texcoord, out vec4 color) {
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texcoord.x = (texcoord.x - (right_display ? 0.5 : 0.0)) * 2;
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}
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if (!enabled || show_banner) {
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if(!enabled || show_banner) {
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// vec2 banner_size = vec2(800.0 / ReShade::ScreenSize.x, 200.0 / ReShade::ScreenSize.y); // Assuming ScreenWidth and ScreenHeight are defined
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// if (show_banner &&
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@ -103,26 +106,20 @@ void PS_IMU_Transform(vec4 pos, vec2 texcoord, out vec4 color) {
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// }
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// } else {
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// adjust texcoord back to the range that describes where the content is displayed
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float texcoord_width = texcoord_x_max - texcoord_x_min;
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texcoord.x = texcoord.x * texcoord_width + texcoord_x_min;
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float texcoord_width = texcoord_x_max - texcoord_x_min;
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texcoord.x = texcoord.x * texcoord_width + texcoord_x_min;
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color = texture2D(uDesktopTexture, texcoord);
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color = texture2D(uDesktopTexture, texcoord);
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// }
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} else {
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float lens_fov_z_offset_rads = atan(lens_z_offset/screen_distance);
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float fov_z_pos = tan(half_fov_z_rads - lens_fov_z_offset_rads) * screen_distance;
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float fov_z_neg = -tan(half_fov_z_rads + lens_fov_z_offset_rads) * screen_distance;
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float fov_z_width = fov_z_pos - fov_z_neg;
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float lens_fov_y_offset_rads = atan(lens_y_offset/screen_distance);
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float fov_y_pos = tan(half_fov_y_rads - lens_fov_y_offset_rads) * screen_distance;
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float fov_y_neg = -tan(half_fov_y_rads + lens_fov_y_offset_rads) * screen_distance;
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float fov_y_width = fov_y_pos - fov_y_neg;
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float vec_x = screen_distance;
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float vec_y = -texcoord.x * fov_y_width + fov_y_pos;
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float vec_z = -texcoord.y * fov_z_width + fov_z_pos;
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vec3 texcoord_vector = vec3(vec_x, vec_y, vec_z);
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vec3 lens_vector = vec3(lens_distance_ratio, lens_y_offset, lens_z_offset);
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} else {
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float fov_y_half_width = tan(half_fov_y_rads);
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float fov_y_width = fov_y_half_width * 2;
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float fov_z_half_width = tan(half_fov_z_rads);
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float fov_z_width = fov_z_half_width * 2;
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float vec_y = -texcoord.x * fov_y_width + fov_y_half_width;
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float vec_z = -texcoord.y * fov_z_width + fov_z_half_width;
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vec3 lens_vector = vec3(lens_distance_ratio, lens_y_offset, lens_z_offset);
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vec3 texcoord_vector = vec3(1.0, vec_y, vec_z);
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// then rotate the vector using each of the snapshots provided
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vec3 rotated_vector_t0 = applyQuaternionToVector(imu_quat_data[0], texcoord_vector);
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@ -146,31 +143,30 @@ void PS_IMU_Transform(vec4 pos, vec2 texcoord, out vec4 color) {
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float look_ahead_ms_squared = pow(look_ahead_ms, 2);
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// apply most recent velocity and acceleration to most recent position to get a predicted position
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vec3 res = applyLookAhead(rotated_vector_t0, velocity_t0, accel_t0, look_ahead_ms, look_ahead_ms_squared);
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vec3 res = applyLookAhead(rotated_vector_t0, velocity_t0, accel_t0, look_ahead_ms, look_ahead_ms_squared) -
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rotated_lens_vector;
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bool looking_behind = res.x < 0.0;
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bool looking_behind = res.x < 0.0;
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// divide all values by x to scale the magnitude so x is exactly 1, and multiply by the final display distance
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// so the vector is pointing at a coordinate on the screen
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float display_distance = (sbs_enabled ? display_north_offset : 1.0) - rotated_lens_vector.x;
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res *= display_distance/res.x;
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// adjust x and y by how much our lens moved from its original offset
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res += rotated_lens_vector - lens_vector;
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res *= display_distance / res.x;
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res += rotated_lens_vector;
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// deconstruct the rotated and scaled vector back to a texcoord (just inverse operations of the first conversion
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// above)
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texcoord.x = (fov_y_pos - res.y) / fov_y_width;
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texcoord.y = (fov_z_pos - res.z) / fov_z_width;
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texcoord.x = (fov_y_half_width - res.y) / fov_y_width;
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texcoord.y = (fov_z_half_width - res.z) / fov_z_width;
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// apply the screen offsets now
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float texcoord_width = texcoord_x_max - texcoord_x_min;
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texcoord.x = texcoord.x * texcoord_width + texcoord_x_min;
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float texcoord_width = texcoord_x_max - texcoord_x_min;
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texcoord.x = texcoord.x * texcoord_width + texcoord_x_min;
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if (looking_behind || texcoord.x < texcoord_x_min || texcoord.y < 0.0 || texcoord.x > texcoord_x_max || texcoord.y > 1.0 || texcoord.x <= 0.005 && texcoord.y <= 0.005) {
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color = vec4(0, 0, 0, 1);
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} else {
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color = texture2D(uDesktopTexture, texcoord);
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}
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}
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if(looking_behind || texcoord.x < texcoord_x_min || texcoord.y < 0.0 || texcoord.x > texcoord_x_max || texcoord.y > 1.0 || texcoord.x <= 0.005 && texcoord.y <= 0.005) {
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color = vec4(0, 0, 0, 1);
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} else {
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color = texture2D(uDesktopTexture, texcoord);
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}
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}
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}
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