1 #ifndef PLAYER_COMMON_C
2 #define PLAYER_COMMON_C
11 VG_STATIC
void player_vector_angles( v3f angles
, v3f v
, float C
, float k
)
13 float yaw
= atan2f( v
[0], -v
[2] ),
28 VG_STATIC
float player_get_heading_yaw( player_instance
*player
)
31 q_mulv( player
->rb
.q
, (v3f
){ 0.0f
,0.0f
,1.0f
}, xz
);
32 m3x3_mulv( player
->invbasis
, xz
, xz
);
33 return atan2f( xz
[0], xz
[2] );
36 VG_STATIC
void player_camera_portal_correction( player_instance
*player
)
38 if( player
->gate_waiting
){
39 /* construct plane equation for reciever gate */
41 q_mulv( player
->gate_waiting
->q
[1], (v3f
){0.0f
,0.0f
,1.0f
}, plane
);
42 plane
[3] = v3_dot( plane
, player
->gate_waiting
->co
[1] );
44 /* check camera polarity */
45 if( v3_dot( player
->cam
.pos
, plane
) < plane
[3] ) {
46 vg_success( "Plane cleared\n" );
47 player_apply_transport_to_cam( player
->gate_waiting
->transport
);
48 player
->gate_waiting
= NULL
;
49 player
->viewable_world
= get_active_world();
52 /* de-transform camera and player back */
54 m4x3_invert_affine( player
->gate_waiting
->transport
, inverse
);
55 m4x3_mulv( inverse
, player
->cam
.pos
, player
->cam
.pos
);
57 struct skeleton
*sk
= &player
->playeravatar
->sk
;
58 skeleton_apply_transform( sk
, inverse
);
63 static v3f TEMP_TPV_EXTRA
;
65 VG_STATIC
void player__cam_iterate( player_instance
*player
)
67 struct player_avatar
*av
= player
->playeravatar
;
69 if( player
->subsystem
== k_player_subsystem_walk
){
70 v3_copy( (v3f
){-0.1f
,1.8f
,0.0f
}, player
->fpv_viewpoint
);
71 v3_copy( (v3f
){0.0f
,0.0f
,0.0f
}, player
->fpv_offset
);
72 v3_copy( (v3f
){0.0f
,1.4f
,0.0f
}, player
->tpv_offset
);
75 v3_copy( (v3f
){-0.15f
,1.75f
,0.0f
}, player
->fpv_viewpoint
);
77 v3_copy( (v3f
){-0.35f
,0.0f
,0.0f
}, player
->fpv_offset
);
79 v3_copy( (v3f
){0.0f
,0.0f
,0.0f
}, player
->fpv_offset
);
80 v3_copy( (v3f
){0.0f
,1.4f
,0.0f
}, player
->tpv_offset
);
81 v3_add( TEMP_TPV_EXTRA
, player
->tpv_offset
, player
->tpv_offset
);
84 player
->cam_velocity_constant
= 0.25f
;
85 player
->cam_velocity_coefficient
= 0.7f
;
89 player
->cam_velocity_influence_smooth
= vg_lerpf(
90 player
->cam_velocity_influence_smooth
,
91 player
->cam_velocity_influence
,
92 vg
.time_frame_delta
* 8.0f
);
94 player
->cam_velocity_coefficient_smooth
= vg_lerpf(
95 player
->cam_velocity_coefficient_smooth
,
96 player
->cam_velocity_coefficient
,
97 vg
.time_frame_delta
* 8.0f
);
99 player
->cam_velocity_constant_smooth
= vg_lerpf(
100 player
->cam_velocity_constant_smooth
,
101 player
->cam_velocity_constant
,
102 vg
.time_frame_delta
* 8.0f
);
104 enum camera_mode target_mode
= player
->camera_mode
;
106 if( player
->subsystem
== k_player_subsystem_dead
)
107 target_mode
= k_cam_thirdperson
;
109 player
->camera_type_blend
=
110 vg_lerpf( player
->camera_type_blend
,
111 (target_mode
== k_cam_firstperson
)? 1.0f
: 0.0f
,
112 5.0f
* vg
.time_frame_delta
);
114 v3_lerp( player
->fpv_viewpoint_smooth
, player
->fpv_viewpoint
,
115 vg
.time_frame_delta
* 8.0f
, player
->fpv_viewpoint_smooth
);
117 v3_lerp( player
->fpv_offset_smooth
, player
->fpv_offset
,
118 vg
.time_frame_delta
* 8.0f
, player
->fpv_offset_smooth
);
120 v3_lerp( player
->tpv_offset_smooth
, player
->tpv_offset
,
121 vg
.time_frame_delta
* 8.0f
, player
->tpv_offset_smooth
);
123 /* fov -- simple blend */
124 float fov_skate
= vg_lerpf( 97.0f
, 135.0f
, cl_fov
),
125 fov_walk
= vg_lerpf( 90.0f
, 110.0f
, cl_fov
);
127 player
->cam
.fov
= vg_lerpf( fov_walk
, fov_skate
, player
->camera_type_blend
);
130 * first person camera
134 v3f fpv_pos
, fpv_offset
;
135 m4x3_mulv( av
->sk
.final_mtx
[ av
->id_head
-1 ],
136 player
->fpv_viewpoint_smooth
, fpv_pos
);
137 m3x3_mulv( player
->rb
.to_world
, player
->fpv_offset_smooth
, fpv_offset
);
138 v3_add( fpv_offset
, fpv_pos
, fpv_pos
);
142 v3_lerp( player
->cam_velocity_smooth
, player
->rb
.v
, 4.0f
*vg
.time_frame_delta
,
143 player
->cam_velocity_smooth
);
146 m3x3_mulv( player
->invbasis
, player
->cam_velocity_smooth
, velocity_local
);
147 player_vector_angles( velocity_angles
, velocity_local
,
148 player
->cam_velocity_coefficient_smooth
,
149 player
->cam_velocity_constant_smooth
);
151 float inf_fpv
= player
->cam_velocity_influence_smooth
*
152 player
->camera_type_blend
,
153 inf_tpv
= player
->cam_velocity_influence_smooth
*
154 (1.0f
-player
->camera_type_blend
);
156 camera_lerp_angles( player
->angles
, velocity_angles
,
161 * Third person camera
164 /* no idea what this technique is called, it acts like clamped position based
165 * on some derivative of where the final camera would end up ....
167 * it is done in the local basis then transformed back */
170 v3_muls( player
->rb
.v
, 0.4f
*vg
.time_frame_delta
, future
);
171 m3x3_mulv( player
->invbasis
, future
, future
);
173 v3f camera_follow_dir
=
174 { -sinf( player
->angles
[0] ) * cosf( player
->angles
[1] ),
175 sinf( player
->angles
[1] ),
176 cosf( player
->angles
[0] ) * cosf( player
->angles
[1] ) };
179 v3_sub( camera_follow_dir
, future
, v0
);
182 v3_copy( player
->angles
, follow_angles
);
183 follow_angles
[0] = atan2f( -v0
[0], v0
[2] );
184 follow_angles
[1] = 0.3f
+ velocity_angles
[1] * 0.2f
;
186 float ya
= atan2f( -velocity_local
[1], 30.0f
);
188 follow_angles
[1] = 0.3f
+ ya
;
189 camera_lerp_angles( player
->angles
, follow_angles
,
195 rb_extrapolate( &player
->rb
, pco
, pq
);
196 v3_lerp( player
->tpv_lpf
, pco
, 20.0f
*vg
.time_frame_delta
, player
->tpv_lpf
);
198 /* now move into world */
200 m3x3_mulv( player
->basis
, camera_follow_dir
, camera_follow_dir
);
201 v3f tpv_pos
, tpv_offset
;
203 v3_muladds( player
->tpv_lpf
, camera_follow_dir
, 1.8f
, tpv_pos
);
204 q_mulv( pq
, player
->tpv_offset_smooth
, tpv_offset
);
205 v3_add( tpv_offset
, tpv_pos
, tpv_pos
);
206 v3_muladds( tpv_pos
, player
->cam_velocity_smooth
, -0.025f
, tpv_pos
);
211 v3_lerp( tpv_pos
, fpv_pos
, player
->camera_type_blend
, player
->cam
.pos
);
212 v3_copy( player
->angles
, player
->cam
.angles
);
214 float Fd
= -player
->cam_land_punch_v
* k_cam_damp
,
215 Fs
= -player
->cam_land_punch
* k_cam_spring
;
216 player
->cam_land_punch
+= player
->cam_land_punch_v
* vg
.time_frame_delta
;
217 player
->cam_land_punch_v
+= ( Fd
+ Fs
) * vg
.time_frame_delta
;
218 player
->cam
.angles
[1] += player
->cam_land_punch
;
220 /* override camera */
221 player
->cam
.angles
[0] =
222 vg_alerpf( player
->cam
.angles
[0], player
->cam_override_angles
[0],
223 player
->cam_override_strength
);
224 player
->cam
.angles
[1] =
225 vg_lerpf ( player
->cam
.angles
[1], player
->cam_override_angles
[1],
226 player
->cam_override_strength
);
227 v3_lerp( player
->cam
.pos
, player
->cam_override_pos
,
228 player
->cam_override_strength
, player
->cam
.pos
);
230 /* portal transitions */
231 player_camera_portal_correction( player
);
234 VG_STATIC
void player_look( player_instance
*player
, v3f angles
)
239 v2_copy( vg
.mouse_delta
, mouse_input
);
241 mouse_input
[1] *= -1.0f
;
242 v2_muladds( angles
, mouse_input
, 0.0025f
, angles
);
244 if( vg_input
.controller_should_use_trackpad_look
){
245 static v2f last_input
;
247 static v2f vel_smooth
;
249 v2f input
= { player
->input_js2h
->axis
.value
,
250 player
->input_js2v
->axis
.value
};
255 if( (v2_length2(last_input
) > 0.001f
) && (v2_length2(input
) > 0.001f
) ){
256 v2_sub( input
, last_input
, vel
);
257 v2_muls( vel
, 1.0f
/vg
.time_delta
, vel
);
263 v2_lerp( vel_smooth
, vel
, vg
.time_delta
*8.0f
, vel_smooth
);
265 v2_muladds( angles
, vel_smooth
, vg
.time_delta
, angles
);
266 v2_copy( input
, last_input
);
269 angles
[0] += player
->input_js2h
->axis
.value
* vg
.time_delta
* 4.0f
;
271 float input_y
= player
->input_js2v
->axis
.value
* vg
.time_delta
* 4.0f
;
275 angles
[1] += input_y
;
278 angles
[1] = vg_clampf( angles
[1], -VG_PIf
*0.5f
, VG_PIf
*0.5f
);
281 #endif /* PLAYER_COMMON_C */