binutils-gdb/gdb/osf-share/cma_sched.h

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/*
* (c) Copyright 1990-1996 OPEN SOFTWARE FOUNDATION, INC.
* (c) Copyright 1990-1996 HEWLETT-PACKARD COMPANY
* (c) Copyright 1990-1996 DIGITAL EQUIPMENT CORPORATION
* (c) Copyright 1991, 1992 Siemens-Nixdorf Information Systems
* To anyone who acknowledges that this file is provided "AS IS" without
* any express or implied warranty: permission to use, copy, modify, and
* distribute this file for any purpose is hereby granted without fee,
* provided that the above copyright notices and this notice appears in
* all source code copies, and that none of the names listed above be used
* in advertising or publicity pertaining to distribution of the software
* without specific, written prior permission. None of these organizations
* makes any representations about the suitability of this software for
* any purpose.
*/
/*
* Header file for priority scheduling
*/
#ifndef CMA_SCHED
#define CMA_SCHED
/*
* INCLUDE FILES
*/
/*
* CONSTANTS AND MACROS
*/
/*
* Scaling factor for integer priority calculations
*/
#define cma__c_prio_scale 8
#if _CMA_VENDOR_ == _CMA__APOLLO
/*
* FIX-ME: Apollo cc 6.8 blows contant folded "<<" and ">>"
*/
# define cma__scale_up(exp) ((exp) * 256)
# define cma__scale_dn(exp) ((exp) / 256)
#else
# define cma__scale_up(exp) ((exp) << cma__c_prio_scale)
# define cma__scale_dn(exp) ((exp) >> cma__c_prio_scale)
#endif
/*
* Min. num. of ticks between self-adjustments for priority adjusting policies.
*/
#define cma__c_prio_interval 10
/*
* Number of queues in each class of queues
*/
#define cma__c_prio_n_id 1 /* Very-low-priority class threads */
#define cma__c_prio_n_bg 8 /* Background class threads */
#define cma__c_prio_n_0 1 /* Very low priority throughput quartile */
#define cma__c_prio_n_1 2 /* Low priority throughput quartile */
#define cma__c_prio_n_2 3 /* Medium priority throughput quartile */
#define cma__c_prio_n_3 4 /* High priority throughput quartile */
#define cma__c_prio_n_rt 1 /* Real Time priority queues */
/*
* Number of queues to skip (offset) to get to the queues in this section of LA
*/
#define cma__c_prio_o_id 0
#define cma__c_prio_o_bg cma__c_prio_o_id + cma__c_prio_n_id
#define cma__c_prio_o_0 cma__c_prio_o_bg + cma__c_prio_n_bg
#define cma__c_prio_o_1 cma__c_prio_o_0 + cma__c_prio_n_0
#define cma__c_prio_o_2 cma__c_prio_o_1 + cma__c_prio_n_1
#define cma__c_prio_o_3 cma__c_prio_o_2 + cma__c_prio_n_2
#define cma__c_prio_o_rt cma__c_prio_o_3 + cma__c_prio_n_3
/*
* Ada_low: These threads are queued in the background queues, thus there
* must be enough queues to allow one queue for each Ada priority below the
* Ada default.
*/
#define cma__c_prio_o_al cma__c_prio_o_bg
/*
* Total number of ready queues, for declaration purposes
*/
#define cma__c_prio_n_tot \
cma__c_prio_n_id + cma__c_prio_n_bg + cma__c_prio_n_rt \
+ cma__c_prio_n_0 + cma__c_prio_n_1 + cma__c_prio_n_2 + cma__c_prio_n_3
/*
* Formulae for determining a thread's priority. Variable priorities (such
* as foreground and background) are scaled values.
*/
#define cma__sched_priority(tcb) \
((tcb)->sched.class == cma__c_class_fore ? cma__sched_prio_fore (tcb) \
:((tcb)->sched.class == cma__c_class_back ? cma__sched_prio_back (tcb) \
:((tcb)->sched.class == cma__c_class_rt ? cma__sched_prio_rt (tcb) \
:((tcb)->sched.class == cma__c_class_idle ? cma__sched_prio_idle (tcb) \
:(cma__bugcheck ("cma__sched_priority: unrecognized class"), 0) ))))
#define cma__sched_prio_fore(tcb) cma__sched_prio_fore_var (tcb)
#define cma__sched_prio_back(tcb) ((tcb)->sched.fixed_prio \
? cma__sched_prio_back_fix (tcb) : cma__sched_prio_back_var (tcb) )
#define cma__sched_prio_rt(tcb) ((tcb)->sched.priority)
#define cma__sched_prio_idle(tcb) ((tcb)->sched.priority)
#define cma__sched_prio_back_fix(tcb) \
(cma__g_prio_bg_min + (cma__g_prio_bg_max - cma__g_prio_bg_min) \
* ((tcb)->sched.priority + cma__c_prio_o_al - cma__c_prio_o_bg) \
/ cma__c_prio_n_bg)
/*
* FIX-ME: Enable after modeling (if we like it)
*/
#if 1
# define cma__sched_prio_fore_var(tcb) \
((cma__g_prio_fg_max + cma__g_prio_fg_min)/2)
# define cma__sched_prio_back_var(tcb) \
((cma__g_prio_bg_max + cma__g_prio_bg_min)/2)
#else
# define cma__sched_prio_back_var(tcb) cma__sched_prio_fore_var (tcb)
# if 1
/*
* Re-scale, since the division removes the scale factor.
* Scale and multiply before dividing to avoid loss of precision.
*/
# define cma__sched_prio_fore_var(tcb) \
((cma__g_vp_count * cma__scale_up((tcb)->sched.tot_time)) \
/ (tcb)->sched.cpu_time)
# else
/*
* Re-scale, since the division removes the scale factor.
* Scale and multiply before dividing to avoid loss of precision.
* Left shift the numerator to multiply by two.
*/
# define cma__sched_prio_fore_var(tcb) \
(((cma__g_vp_count * cma__scale_up((tcb)->sched.tot_time) \
* (tcb)->sched.priority * cma__g_init_frac_sum) << 1) \
/ ((tcb)->sched.cpu_time * (tcb)->sched.priority * cma__g_init_frac_sum \
+ (tcb)->sched.tot_time))
# endif
#endif
/*
* Update weighted-averaged, scaled tick counters
*/
#define cma__sched_update_time(ave, new) \
(ave) = (ave) - ((cma__scale_dn((ave)) - (new)) << (cma__c_prio_scale - 4))
#define cma__sched_parameterize(tcb, policy) { \
switch (policy) { \
case cma_c_sched_fifo : { \
(tcb)->sched.rtb = cma_c_true; \
(tcb)->sched.spp = cma_c_true; \
(tcb)->sched.fixed_prio = cma_c_true; \
(tcb)->sched.class = cma__c_class_rt; \
break; \
} \
case cma_c_sched_rr : { \
(tcb)->sched.rtb = cma_c_false; \
(tcb)->sched.spp = cma_c_true; \
(tcb)->sched.fixed_prio = cma_c_true; \
(tcb)->sched.class = cma__c_class_rt; \
break; \
} \
case cma_c_sched_throughput : { \
(tcb)->sched.rtb = cma_c_false; \
(tcb)->sched.spp = cma_c_false; \
(tcb)->sched.fixed_prio = cma_c_false; \
(tcb)->sched.class = cma__c_class_fore; \
break; \
} \
case cma_c_sched_background : { \
(tcb)->sched.rtb = cma_c_false; \
(tcb)->sched.spp = cma_c_false; \
(tcb)->sched.fixed_prio = cma_c_false; \
(tcb)->sched.class = cma__c_class_back; \
break; \
} \
case cma_c_sched_ada_low : { \
(tcb)->sched.rtb = cma_c_false; \
(tcb)->sched.spp = cma_c_true; \
(tcb)->sched.fixed_prio = cma_c_true; \
(tcb)->sched.class = cma__c_class_back; \
break; \
} \
case cma_c_sched_idle : { \
(tcb)->sched.rtb = cma_c_false; \
(tcb)->sched.spp = cma_c_false; \
(tcb)->sched.fixed_prio = cma_c_false; \
(tcb)->sched.class = cma__c_class_idle; \
break; \
} \
default : { \
cma__bugcheck ("cma__sched_parameterize: bad scheduling Policy"); \
break; \
} \
} \
}
/*
* TYPEDEFS
*/
/*
* Scheduling classes
*/
typedef enum CMA__T_SCHED_CLASS {
cma__c_class_rt,
cma__c_class_fore,
cma__c_class_back,
cma__c_class_idle
} cma__t_sched_class;
/*
* GLOBAL DATA
*/
/*
* Minimuma and maximum prioirities, for foreground and background threads,
* as of the last time the scheduler ran. (Scaled once.)
*/
extern cma_t_integer cma__g_prio_fg_min;
extern cma_t_integer cma__g_prio_fg_max;
extern cma_t_integer cma__g_prio_bg_min;
extern cma_t_integer cma__g_prio_bg_max;
/*
* The "m" values are the slopes of the four sections of linear approximation.
*
* cma__g_prio_m_I = 4*N(I)/cma__g_prio_range (Scaled once.)
*/
extern cma_t_integer cma__g_prio_m_0,
cma__g_prio_m_1,
cma__g_prio_m_2,
cma__g_prio_m_3;
/*
* The "b" values are the intercepts of the four sections of linear approx.
* (Not scaled.)
*
* cma__g_prio_b_I = -N(I)*(I*prio_max + (4-I)*prio_min)/prio_range + prio_o_I
*/
extern cma_t_integer cma__g_prio_b_0,
cma__g_prio_b_1,
cma__g_prio_b_2,
cma__g_prio_b_3;
/*
* The "p" values are the end points of the four sections of linear approx.
*
* cma__g_prio_p_I = cma__g_prio_fg_min + (I/4)*cma__g_prio_range
*
* [cma__g_prio_p_0 is not defined since it is not used (also, it is the same
* as cma__g_prio_fg_min).] (Scaled once.)
*/
extern cma_t_integer cma__g_prio_p_1,
cma__g_prio_p_2,
cma__g_prio_p_3;
/*
* Points to the next queue for the dispatcher to check for ready threads.
*/
extern cma_t_integer cma__g_next_ready_queue;
/*
* Points to the queues of virtual processors (for preempt victim search)
*/
extern cma__t_queue cma__g_run_vps;
extern cma__t_queue cma__g_susp_vps;
extern cma_t_integer cma__g_vp_count;
/*
* INTERNAL INTERFACES
*/
#endif