float autocvar_cl_bobmodel_up;
float autocvar_cl_followmodel;
-float autocvar_cl_followmodel_side_speed;
-float autocvar_cl_followmodel_side_highpass;
-float autocvar_cl_followmodel_side_highpass1;
-float autocvar_cl_followmodel_side_limit;
-float autocvar_cl_followmodel_side_lowpass;
-float autocvar_cl_followmodel_up_speed;
-float autocvar_cl_followmodel_up_highpass;
-float autocvar_cl_followmodel_up_highpass1;
-float autocvar_cl_followmodel_up_limit;
-float autocvar_cl_followmodel_up_lowpass;
+float autocvar_cl_followmodel_speed = 0.3;
+float autocvar_cl_followmodel_limit = 1000;
+float autocvar_cl_followmodel_highpass1 = 0.05;
+float autocvar_cl_followmodel_highpass = 0.05;
+float autocvar_cl_followmodel_lowpass = 0.03;
float autocvar_cl_leanmodel;
-float autocvar_cl_leanmodel_side_speed;
-float autocvar_cl_leanmodel_side_highpass;
-float autocvar_cl_leanmodel_side_highpass1;
-float autocvar_cl_leanmodel_side_lowpass;
-float autocvar_cl_leanmodel_side_limit;
-float autocvar_cl_leanmodel_up_speed;
-float autocvar_cl_leanmodel_up_highpass;
-float autocvar_cl_leanmodel_up_highpass1;
-float autocvar_cl_leanmodel_up_lowpass;
-float autocvar_cl_leanmodel_up_limit;
+float autocvar_cl_leanmodel_speed = 0.3;
+float autocvar_cl_leanmodel_limit = 1000;
+float autocvar_cl_leanmodel_highpass1 = 0.2;
+float autocvar_cl_leanmodel_highpass = 0.2;
+float autocvar_cl_leanmodel_lowpass = 0.05;
+#define avg_factor(avg_time) (1 - exp(-frametime / max(0.001, avg_time)))
#define lowpass(value, frac, ref_store, ret) MACRO_BEGIN \
{ \
- float __frac = bound(0, frac, 1); \
- ret = ref_store = ref_store * (1 - __frac) + (value) * __frac; \
+ ret = ref_store = ref_store * (1 - frac) + (value) * frac; \
} MACRO_END
#define lowpass_limited(value, frac, limit, ref_store, ret) MACRO_BEGIN \
ret = (value) - __f; \
} MACRO_END
-#define lowpass3(value, fracx, fracy, fracz, ref_store, ref_out) MACRO_BEGIN \
+#define lowpass2(value, frac, ref_store, ref_out) MACRO_BEGIN \
{ \
- lowpass(value.x, fracx, ref_store.x, ref_out.x); \
- lowpass(value.y, fracy, ref_store.y, ref_out.y); \
- lowpass(value.z, fracz, ref_store.z, ref_out.z); \
+ lowpass(value.x, frac, ref_store.x, ref_out.x); \
+ lowpass(value.y, frac, ref_store.y, ref_out.y); \
} MACRO_END
-#define highpass3(value, fracx, fracy, fracz, ref_store, ref_out) MACRO_BEGIN \
+#define highpass2(value, frac, ref_store, ref_out) MACRO_BEGIN \
{ \
- highpass(value.x, fracx, ref_store.x, ref_out.x); \
- highpass(value.y, fracy, ref_store.y, ref_out.y); \
- highpass(value.z, fracz, ref_store.z, ref_out.z); \
+ highpass(value.x, frac, ref_store.x, ref_out.x); \
+ highpass(value.y, frac, ref_store.y, ref_out.y); \
} MACRO_END
-#define highpass3_limited(value, fracx, limitx, fracy, limity, fracz, limitz, ref_store, ref_out) MACRO_BEGIN \
+#define highpass2_limited(value, frac, limit, ref_store, ref_out) MACRO_BEGIN \
{ \
- highpass_limited(value.x, fracx, limitx, ref_store.x, ref_out.x); \
- highpass_limited(value.y, fracy, limity, ref_store.y, ref_out.y); \
- highpass_limited(value.z, fracz, limitz, ref_store.z, ref_out.z); \
+ highpass_limited(value.x, frac, limit, ref_store.x, ref_out.x); \
+ highpass_limited(value.y, frac, limit, ref_store.y, ref_out.y); \
+} MACRO_END
+
+#define lowpass3(value, frac, ref_store, ref_out) MACRO_BEGIN \
+{ \
+ lowpass(value.x, frac, ref_store.x, ref_out.x); \
+ lowpass(value.y, frac, ref_store.y, ref_out.y); \
+ lowpass(value.z, frac, ref_store.z, ref_out.z); \
+} MACRO_END
+
+#define highpass3(value, frac, ref_store, ref_out) MACRO_BEGIN \
+{ \
+ highpass(value.x, frac, ref_store.x, ref_out.x); \
+ highpass(value.y, frac, ref_store.y, ref_out.y); \
+ highpass(value.z, frac, ref_store.z, ref_out.z); \
+} MACRO_END
+
+#define highpass3_limited(value, frac, limit, ref_store, ref_out) MACRO_BEGIN \
+{ \
+ highpass_limited(value.x, frac, limit, ref_store.x, ref_out.x); \
+ highpass_limited(value.y, frac, limit, ref_store.y, ref_out.y); \
+ highpass_limited(value.z, frac, limit, ref_store.z, ref_out.z); \
} MACRO_END
void viewmodel_animate(entity this)
{
static float prevtime;
- float frametime = (time - prevtime) * STAT(MOVEVARS_TIMESCALE);
+ float frametime = (time - prevtime);
prevtime = time;
if (autocvar_chase_active) return;
}
oldonground = clonground;
- vector gunorg = '0 0 0', gunangles = '0 0 0';
- static vector gunorg_prev = '0 0 0', gunangles_prev = '0 0 0';
bool teleported = view.csqcmodel_teleported;
- // 1. if we teleported, clear the frametime... the lowpass will recover the previous value then
- if (teleported)
+ float frac;
+ if(autocvar_cl_followmodel)
{
- // try to fix the first highpass; result is NOT
- // perfect! TODO find a better fix
- gunangles_prev = view_angles;
+ vector gunorg = '0 0 0';
+ static vector gunorg_prev = '0 0 0';
+ static vector gunorg_highpass = '0 0 0';
+ static vector gunorg_adjustment_highpass;
+ static vector gunorg_adjustment_lowpass;
+
+ // if we teleported, clear the frametime... the lowpass will recover the previous value then
+ if (teleported)
+ {
+ // try to fix the first highpass; result is NOT
+ // perfect! TODO find a better fix
+ gunorg_prev = view_origin;
+ }
+
+ // for the gun origin, only keep the high frequency (non-DC) parts, which is "somewhat like velocity"
+ gunorg_highpass += gunorg_prev;
+ frac = avg_factor(autocvar_cl_followmodel_highpass1);
+ highpass3_limited(view_origin, frac, autocvar_cl_followmodel_limit, gunorg_highpass, gunorg);
gunorg_prev = view_origin;
+ gunorg_highpass -= gunorg_prev;
+
+ // calculate the RAW adjustment vectors
+ gunorg *= -autocvar_cl_followmodel_speed;
+
+ // perform highpass/lowpass on the adjustment vectors (turning velocity into acceleration!)
+ // trick: we must do the lowpass LAST, so the lowpass vector IS the final vector!
+ frac = avg_factor(autocvar_cl_followmodel_highpass);
+ highpass3(gunorg, frac, gunorg_adjustment_highpass, gunorg);
+ frac = avg_factor(autocvar_cl_followmodel_lowpass);
+ lowpass3(gunorg, frac, gunorg_adjustment_lowpass, gunorg);
+
+ vector v;
+ vector forward, right = '0 0 0', up = '0 0 0';
+ MAKEVECTORS(makevectors, view_angles, forward, right, up);
+ v.x = gunorg * forward;
+ v.y = gunorg * right * -1;
+ v.z = gunorg * up;
+ this.origin += v;
+ }
+
+ if(autocvar_cl_leanmodel)
+ {
+ vector gunangles = '0 0 0';
+ static vector gunangles_prev = '0 0 0';
+ static vector gunangles_highpass = '0 0 0';
+ static vector gunangles_adjustment_highpass;
+ static vector gunangles_adjustment_lowpass;
+
+ if (teleported)
+ gunangles_prev = view_angles;
+
+ // in the highpass, we _store_ the DIFFERENCE to the actual view angles...
+ gunangles_highpass += gunangles_prev;
+ PITCH(gunangles_highpass) += 360 * floor((PITCH(view_angles) - PITCH(gunangles_highpass)) / 360 + 0.5);
+ YAW(gunangles_highpass) += 360 * floor((YAW(view_angles) - YAW(gunangles_highpass)) / 360 + 0.5);
+ ROLL(gunangles_highpass) += 360 * floor((ROLL(view_angles) - ROLL(gunangles_highpass)) / 360 + 0.5);
+ frac = avg_factor(autocvar_cl_leanmodel_highpass1);
+ highpass2_limited(view_angles, frac, autocvar_cl_leanmodel_limit, gunangles_highpass, gunangles);
+ gunangles_prev = view_angles;
+ gunangles_highpass -= gunangles_prev;
+
+ PITCH(gunangles) *= -autocvar_cl_leanmodel_speed;
+ YAW(gunangles) *= -autocvar_cl_leanmodel_speed;
+
+ // we assume here: PITCH = 0, YAW = 1, ROLL = 2
+ frac = avg_factor(autocvar_cl_leanmodel_highpass);
+ highpass2(gunangles, frac, gunangles_adjustment_highpass, gunangles);
+ frac = avg_factor(autocvar_cl_leanmodel_lowpass);
+ lowpass2(gunangles, frac, gunangles_adjustment_lowpass, gunangles);
+
+ gunangles.x = -gunangles.x; // pitch was inverted, now that actually matters
+ this.angles += gunangles;
}
- static vector gunorg_highpass = '0 0 0';
-
- // 2. for the gun origin, only keep the high frequency (non-DC) parts, which is "somewhat like velocity"
- gunorg_highpass += gunorg_prev;
- highpass3_limited(view_origin,
- frametime * autocvar_cl_followmodel_side_highpass1, autocvar_cl_followmodel_side_limit,
- frametime * autocvar_cl_followmodel_side_highpass1, autocvar_cl_followmodel_side_limit,
- frametime * autocvar_cl_followmodel_up_highpass1, autocvar_cl_followmodel_up_limit,
- gunorg_highpass, gunorg);
- gunorg_prev = view_origin;
- gunorg_highpass -= gunorg_prev;
-
- static vector gunangles_highpass = '0 0 0';
-
- // in the highpass, we _store_ the DIFFERENCE to the actual view angles...
- gunangles_highpass += gunangles_prev;
- PITCH(gunangles_highpass) += 360 * floor((PITCH(view_angles) - PITCH(gunangles_highpass)) / 360 + 0.5);
- YAW(gunangles_highpass) += 360 * floor((YAW(view_angles) - YAW(gunangles_highpass)) / 360 + 0.5);
- ROLL(gunangles_highpass) += 360 * floor((ROLL(view_angles) - ROLL(gunangles_highpass)) / 360 + 0.5);
- highpass3_limited(view_angles,
- frametime * autocvar_cl_leanmodel_up_highpass1, autocvar_cl_leanmodel_up_limit,
- frametime * autocvar_cl_leanmodel_side_highpass1, autocvar_cl_leanmodel_side_limit,
- 0, 0,
- gunangles_highpass, gunangles);
- gunangles_prev = view_angles;
- gunangles_highpass -= gunangles_prev;
-
- // 3. calculate the RAW adjustment vectors
- gunorg.x *= (autocvar_cl_followmodel ? -autocvar_cl_followmodel_side_speed : 0);
- gunorg.y *= (autocvar_cl_followmodel ? -autocvar_cl_followmodel_side_speed : 0);
- gunorg.z *= (autocvar_cl_followmodel ? -autocvar_cl_followmodel_up_speed : 0);
-
- PITCH(gunangles) *= (autocvar_cl_leanmodel ? -autocvar_cl_leanmodel_up_speed : 0);
- YAW(gunangles) *= (autocvar_cl_leanmodel ? -autocvar_cl_leanmodel_side_speed : 0);
- ROLL(gunangles) = 0;
-
- static vector gunorg_adjustment_highpass;
- static vector gunorg_adjustment_lowpass;
- static vector gunangles_adjustment_highpass;
- static vector gunangles_adjustment_lowpass;
-
- // 4. perform highpass/lowpass on the adjustment vectors (turning velocity into acceleration!)
- // trick: we must do the lowpass LAST, so the lowpass vector IS the final vector!
- highpass3(gunorg,
- frametime * autocvar_cl_followmodel_side_highpass,
- frametime * autocvar_cl_followmodel_side_highpass,
- frametime * autocvar_cl_followmodel_up_highpass,
- gunorg_adjustment_highpass, gunorg);
- lowpass3(gunorg,
- frametime * autocvar_cl_followmodel_side_lowpass,
- frametime * autocvar_cl_followmodel_side_lowpass,
- frametime * autocvar_cl_followmodel_up_lowpass,
- gunorg_adjustment_lowpass, gunorg);
- // we assume here: PITCH = 0, YAW = 1, ROLL = 2
- highpass3(gunangles,
- frametime * autocvar_cl_leanmodel_up_highpass,
- frametime * autocvar_cl_leanmodel_side_highpass,
- 0,
- gunangles_adjustment_highpass, gunangles);
- lowpass3(gunangles,
- frametime * autocvar_cl_leanmodel_up_lowpass,
- frametime * autocvar_cl_leanmodel_side_lowpass,
- 0,
- gunangles_adjustment_lowpass, gunangles);
float xyspeed = bound(0, vlen(vec2(view.velocity)), 400);
// vertical view bobbing code
// Sajt: I tried to smooth out the transitions between bob and no bob, which works
// for the most part, but for some reason when you go through a message trigger or
// pick up an item or anything like that it will momentarily jolt the gun.
- vector forward, right = '0 0 0', up = '0 0 0';
float bspeed;
float t = 1;
float s = time * autocvar_cl_bobmodel_speed;
t *= 5;
}
bspeed = xyspeed * 0.01;
- MAKEVECTORS(makevectors, view_angles, forward, right, up);
- float bobr = bspeed * autocvar_cl_bobmodel_side * autocvar_cl_viewmodel_scale * sin(s) * t;
- gunorg += bobr * right;
- float bobu = bspeed * autocvar_cl_bobmodel_up * autocvar_cl_viewmodel_scale * cos(s * 2) * t;
- gunorg += bobu * up;
- }
- vector v = rotate(gunorg, YAW(view_angles) * DEG2RAD); // rotate world coordinates to relative ones
- v.z = gunorg.z;
- this.origin += v;
- gunangles.x = -gunangles.x; // pitch was inverted, now that actually matters
- this.angles += gunangles;
+ vector gunorg = '0 0 0';
+ gunorg.y += bspeed * autocvar_cl_bobmodel_side * autocvar_cl_viewmodel_scale * sin(s) * t;
+ gunorg.z += bspeed * autocvar_cl_bobmodel_up * autocvar_cl_viewmodel_scale * cos(s * 2) * t;
+
+ this.origin += gunorg;
+ }
}
.vector viewmodel_origin, viewmodel_angles;