minix/kernel/profile.c
Ben Gras cbcdb838f1 various coverity-inspired fixes
. some strncpy/strcpy to strlcpy conversions
	. new <minix/param.h> to avoid including other minix headers
	  that have colliding definitions with library and commands code,
	  causing parse warnings
	. removed some dead code / assignments
2012-07-16 14:00:56 +02:00

225 lines
5.7 KiB
C

/*
* This file contains several functions and variables used for system
* profiling.
*
* Statistical Profiling:
* The interrupt handler for profiling clock.
*
* Call Profiling:
* The table used for profiling data and a function to get its size.
*
* The function used by kernelspace processes to register the locations
* of their control struct and profiling table.
*
* Changes:
* 14 Aug, 2006 Created, (Rogier Meurs)
*/
#include <minix/config.h>
#include "kernel.h"
#include "profile.h"
#include "proc.h"
#include <minix/profile.h>
#include <minix/portio.h>
#if SPROFILE
#include <string.h>
#include "watchdog.h"
char sprof_sample_buffer[SAMPLE_BUFFER_SIZE];
/* Function prototype for the profiling clock handler. */
static int profile_clock_handler(irq_hook_t *hook);
/* A hook for the profiling clock interrupt handler. */
static irq_hook_t profile_clock_hook;
/*===========================================================================*
* init_profile_clock *
*===========================================================================*/
void init_profile_clock(u32_t freq)
{
int irq;
if((irq = arch_init_profile_clock(freq)) >= 0) {
/* Register interrupt handler for statistical system profiling. */
profile_clock_hook.proc_nr_e = CLOCK;
put_irq_handler(&profile_clock_hook, irq, profile_clock_handler);
enable_irq(&profile_clock_hook);
}
}
/*===========================================================================*
* profile_clock_stop *
*===========================================================================*/
void stop_profile_clock()
{
arch_stop_profile_clock();
/* Unregister interrupt handler. */
disable_irq(&profile_clock_hook);
rm_irq_handler(&profile_clock_hook);
}
static void sprof_save_sample(struct proc * p, void * pc)
{
struct sprof_sample *s;
s = (struct sprof_sample *) (sprof_sample_buffer + sprof_info.mem_used);
s->proc = p->p_endpoint;
s->pc = pc;
sprof_info.mem_used += sizeof(struct sprof_sample);
}
static void sprof_save_proc(struct proc * p)
{
struct sprof_proc * s;
s = (struct sprof_proc *) (sprof_sample_buffer + sprof_info.mem_used);
s->proc = p->p_endpoint;
strcpy(s->name, p->p_name);
sprof_info.mem_used += sizeof(struct sprof_proc);
}
static void profile_sample(struct proc * p, void * pc)
{
/* This executes on every tick of the CMOS timer. */
/* Are we profiling, and profiling memory not full? */
if (!sprofiling || sprof_info.mem_used == -1)
return;
/* Check if enough memory available before writing sample. */
if (sprof_info.mem_used + sizeof(sprof_info) +
2*sizeof(struct sprof_sample) +
2*sizeof(struct sprof_sample) > sprof_mem_size) {
sprof_info.mem_used = -1;
return;
}
/* Runnable system process? */
if (p->p_endpoint == IDLE)
sprof_info.idle_samples++;
else if (p->p_endpoint == KERNEL ||
(priv(p)->s_flags & SYS_PROC && proc_is_runnable(p))) {
if (!(p->p_misc_flags & MF_SPROF_SEEN)) {
p->p_misc_flags |= MF_SPROF_SEEN;
sprof_save_proc(p);
}
sprof_save_sample(p, pc);
sprof_info.system_samples++;
} else {
/* User process. */
sprof_info.user_samples++;
}
sprof_info.total_samples++;
}
/*===========================================================================*
* profile_clock_handler *
*===========================================================================*/
static int profile_clock_handler(irq_hook_t *hook)
{
struct proc * p;
p = get_cpulocal_var(proc_ptr);
profile_sample(p, (void *) p->p_reg.pc);
/* Acknowledge interrupt if necessary. */
arch_ack_profile_clock();
return(1); /* reenable interrupts */
}
void nmi_sprofile_handler(struct nmi_frame * frame)
{
struct proc * p = get_cpulocal_var(proc_ptr);
/*
* test if the kernel was interrupted. If so, save first a sample fo
* kernel and than for the current process, otherwise save just the
* process
*/
if (nmi_in_kernel(frame)) {
struct proc *kern;
/*
* if we sample kernel, check if IDLE is scheduled. If so,
* account for idle time rather than taking kernel sample
*/
if (p->p_endpoint == IDLE) {
sprof_info.idle_samples++;
sprof_info.total_samples++;
return;
}
kern = proc_addr(KERNEL);
profile_sample(kern, (void *) frame->pc);
}
else
profile_sample(p, (void *) frame->pc);
}
#endif /* SPROFILE */
#if CPROFILE
/*
* The following variables and functions are used by the procentry/
* procentry syslib functions when linked with kernelspace processes.
* For userspace processes, the same variables and function are defined
* elsewhere. This enables different functionality and variable sizes,
* which is needed is a few cases.
*/
/* A small table is declared for the kernelspace processes. */
struct cprof_tbl_s cprof_tbl[CPROF_TABLE_SIZE_KERNEL];
/* Function that returns table size. */
int profile_get_tbl_size(void)
{
return CPROF_TABLE_SIZE_KERNEL;
}
/* Function that returns on which execution of procentry to announce. */
int profile_get_announce(void)
{
return CPROF_ACCOUNCE_KERNEL;
}
/*
* The kernel "announces" its control struct and table locations
* to itself through this function.
*/
void profile_register(ctl_ptr, tbl_ptr)
void *ctl_ptr;
void *tbl_ptr;
{
int proc_nr;
vir_bytes vir_dst;
struct proc *rp;
if(cprof_procs_no >= NR_SYS_PROCS)
return;
/* Store process name, control struct, table locations. */
rp = proc_addr(SYSTEM);
cprof_proc_info[cprof_procs_no].endpt = rp->p_endpoint;
cprof_proc_info[cprof_procs_no].name = rp->p_name;
cprof_proc_info[cprof_procs_no].ctl_v = (vir_bytes) ctl_ptr;
cprof_proc_info[cprof_procs_no].buf_v = (vir_bytes) tbl_ptr;
cprof_procs_no++;
}
#endif