#ifndef LITMUS_GPU_AFFINITY_H #define LITMUS_GPU_AFFINITY_H #include #include #include void update_gpu_estimate(struct task_struct* t, lt_t observed); gpu_migration_dist_t gpu_migration_distance(int a, int b); static inline void reset_gpu_tracker(struct task_struct* t) { t->rt_param.accum_gpu_time = 0; } static inline void start_gpu_tracker(struct task_struct* t) { t->rt_param.gpu_time_stamp = litmus_clock(); } static inline void stop_gpu_tracker(struct task_struct* t) { lt_t now = litmus_clock(); t->rt_param.accum_gpu_time += (now - t->rt_param.gpu_time_stamp); } static inline lt_t get_gpu_time(struct task_struct* t) { return t->rt_param.accum_gpu_time; } static inline lt_t get_gpu_estimate(struct task_struct* t, gpu_migration_dist_t dist) { // int i; // fpbuf_t temp = _fp_to_integer(t->rt_param.gpu_migration_est[dist].est); // lt_t val = (temp >= 0) ? temp : 0; // never allow negative estimates... lt_t val = t->rt_param.gpu_migration_est[dist].avg; // WARN_ON(temp < 0); // lower-bound a distant migration to be at least equal to the level // below it. // for(i = dist-1; (val == 0) && (i >= MIG_LOCAL); --i) { // val = _fp_to_integer(t->rt_param.gpu_migration_est[i].est); // } return ((val > 0) ? val : dist+1); } #endif