/*******************************************************************************
* >>>>>> "Development of a PAPI Backend for the Sun Niagara 2 Processor" <<<<<<
* -----------------------------------------------------------------------------
*
* Fabian Gorsler <fabian.gorsler@smail.inf.h-bonn-rhein-sieg.de>
*
* Hochschule Bonn-Rhein-Sieg, Sankt Augustin, Germany
* University of Applied Sciences
*
* -----------------------------------------------------------------------------
*
* File: solaris-niagara2.c
* Author: fg215045
*
* Description: This source file is the implementation of a PAPI
* component for the Sun Niagara 2 processor (aka UltraSPARC T2)
* running on Solaris 10 with libcpc 2.
* The machine for implementing this component was courtesy of RWTH
* Aachen University, Germany. Thanks to the HPC-Team at RWTH!
*
* Conventions used:
* - __cpc_*: Functions, variables, etc. related to libcpc handling
* - __sol_*: Functions, variables, etc. related to Solaris handling
* - __int_*: Functions, variables, etc. related to extensions of libcpc
* - _niagara*: Functions, variables, etc. needed by PAPI hardware dependent
* layer, i.e. the component itself
*
*
* ***** Feel free to convert this header to the PAPI default *****
*
* -----------------------------------------------------------------------------
* Created on April 23, 2009, 7:31 PM
******************************************************************************/
#include "papi.h"
#include "papi_internal.h"
#include "papi_vector.h"
#include "solaris-niagara2.h"
#include "papi_memory.h"
#include <libcpc.h>
#include <procfs.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <stdio.h>
#include <stdlib.h>
#include <strings.h>
#include <sys/lwp.h>
#include <limits.h>
#include <sys/processor.h>
#include <sys/types.h>
#include <sys/time.h>
#include <stdarg.h>
#include <libgen.h>
#include <ucontext.h>
#include <sys/regset.h>
#include <sys/utsname.h>
#include "solaris-common.h"
#include "solaris-memory.h"
#define hwd_control_state_t _niagara2_control_state_t
#define hwd_context_t _niagara2_context_t
#define hwd_register_t _niagara2_register_t
extern caddr_t _start, _end, _etext, _edata;
extern papi_vector_t _niagara2_vector;
/* Synthetic events */
int __int_setup_synthetic_event( int, hwd_control_state_t *, void * );
uint64_t __int_get_synthetic_event( int, hwd_control_state_t *, void * );
void __int_walk_synthetic_events_action_count( void );
void __int_walk_synthetic_events_action_store( void );
/* Simple error handlers for convenience */
#define __CHECK_ERR_DFLT(retval) \
if(retval != 0){ SUBDBG("RETVAL: %d\n", retval); return PAPI_ECMP;}
#define __CHECK_ERR_NULL(retval) \
if(retval == NULL){ SUBDBG("RETVAL: NULL\n"); return PAPI_ECMP;}
#define __CHECK_ERR_PAPI(retval) \
if(retval != PAPI_OK){ SUBDBG("RETVAL: %d\n", retval); return PAPI_ECMP;}
#define __CHECK_ERR_INVA(retval) \
if(retval != 0){ SUBDBG("RETVAL: %d\n", retval); return PAPI_EINVAL;}
#define __CHECK_ERR_NEGV(retval) \
if(retval < 0){ SUBDBG("RETVAL: %d\n", retval); return PAPI_ECMP;}
// PAPI defined variables
extern papi_mdi_t _papi_hwi_system_info;
// The instance of libcpc
static cpc_t *cpc = NULL;
typedef struct __t2_store
{
// Number of counters for a processing unit
int npic;
int *pic_ntv_count;
int syn_evt_count;
} __t2_store_t;
static __t2_store_t __t2_store;
static char **__t2_ntv_events;
// Variables copied from the old component
static int pid;
// Data types for utility functions
typedef struct __sol_processor_information
{
int total;
int clock;
} __sol_processor_information_t;
typedef struct __t2_pst_table
{
int papi_pst;
char *ntv_event[MAX_COUNTERS];
int ntv_ctrs;
int ntv_opcode;
} __t2_pst_table_t;
#define SYNTHETIC_EVENTS_SUPPORTED 1
/* This table structure holds all preset events */
static __t2_pst_table_t __t2_table[] = {
/* Presets defined by generic_events(3CPC) */
{PAPI_L1_DCM,
{"DC_miss", NULL}, 1, NOT_DERIVED},
{PAPI_L1_ICM,
{"IC_miss", NULL}, 1, NOT_DERIVED},
{PAPI_L2_ICM,
{"L2_imiss", NULL}, 1, NOT_DERIVED},
{PAPI_TLB_DM,
{"DTLB_miss", NULL}, 1, NOT_DERIVED},
{PAPI_TLB_IM,
{"ITLB_miss", NULL}, 1, NOT_DERIVED},
{PAPI_TLB_TL,
{"TLB_miss", NULL}, 1, NOT_DERIVED},
{PAPI_L2_LDM,
{"L2_dmiss_ld", NULL}, 1, NOT_DERIVED},
{PAPI_BR_TKN,
{"Br_taken", NULL}, 1, NOT_DERIVED},
{PAPI_TOT_INS,
{"Instr_cnt", NULL}, 1, NOT_DERIVED},
{PAPI_LD_INS,
{"Instr_ld", NULL}, 1, NOT_DERIVED},
{PAPI_SR_INS,
{"Instr_st", NULL}, 1, NOT_DERIVED},
{PAPI_BR_INS,
{"Br_completed", NULL}, 1, NOT_DERIVED},
/* Presets additionally found, should be checked twice */
{PAPI_BR_MSP,
{"Br_taken", NULL}, 1, NOT_DERIVED},
{PAPI_FP_INS,
{"Instr_FGU_arithmetic", NULL}, 1, NOT_DERIVED},
{PAPI_RES_STL,
{"Idle_strands", NULL}, 1, NOT_DERIVED},
{PAPI_SYC_INS,
{"Atomics", NULL}, 1, NOT_DERIVED},
{PAPI_L2_ICR,
{"CPU_ifetch_to_PCX", NULL}, 1, NOT_DERIVED},
{PAPI_L1_TCR,
{"CPU_ld_to_PCX", NULL}, 1, NOT_DERIVED},
{PAPI_L2_TCW,
{"CPU_st_to_PCX", NULL}, 1, NOT_DERIVED},
/* Derived presets found, should be checked twice */
{PAPI_L1_TCM,
{"IC_miss", "DC_miss"}, 2, DERIVED_ADD},
{PAPI_BR_CN,
{"Br_completed", "Br_taken"}, 2, DERIVED_ADD},
{PAPI_BR_PRC,
{"Br_completed", "Br_taken"}, 2, DERIVED_SUB},
{PAPI_LST_INS,
{"Instr_st", "Instr_ld"}, 2, DERIVED_ADD},
#ifdef SYNTHETIC_EVENTS_SUPPORTED
/* This preset does exist in order to support multiplexing */
{PAPI_TOT_CYC,
{"_syn_cycles_elapsed", "DC_miss"}, 1, NOT_DERIVED},
#endif
{0,
{NULL, NULL}, 0, 0},
};
hwi_search_t *preset_table;
#ifdef SYNTHETIC_EVENTS_SUPPORTED
enum
{
SYNTHETIC_CYCLES_ELAPSED = 1,
SYNTHETIC_RETURN_ONE,
SYNTHETIC_RETURN_TWO,
} __int_synthetic_enum;
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
typedef struct __int_synthetic_table
{
int code;
char *name;
} __int_syn_table_t;
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
static __int_syn_table_t __int_syn_table[] = {
{SYNTHETIC_CYCLES_ELAPSED, "_syn_cycles_elapsed"},
{SYNTHETIC_RETURN_ONE, "_syn_return_one"},
{SYNTHETIC_RETURN_TWO, "_syn_return_two"},
{-1, NULL},
};
#endif
////////////////////////////////////////////////////////////////////////////////
/// PAPI HWD LAYER RELATED FUNCTIONS ///////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
/* DESCRIPTION:
* -----------------------------------------------------------------------------
* Functions in this section are related to the PAPI hardware dependend layer,
* also known as "HWD". In this case the HWD layer is the interface from PAPI
* to libcpc 2/Solaris 10.
******************************************************************************/
int
_niagara2_set_domain( hwd_control_state_t * ctrl, int domain )
{
int i;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Clean and set the new flag for each counter */
for ( i = 0; i < MAX_COUNTERS; i++ ) {
#ifdef DEBUG
SUBDBG( " -> %s: Setting flags for PIC#%d, old value: %p\n",
__func__, i, ctrl->flags[i] );
#endif
ctrl->flags[i] &= ~( CPC_COUNTING_DOMAINS );
#ifdef DEBUG
SUBDBG( " -> %s: +++ cleaned value: %p\n",
__func__, ctrl->flags[i] );
#endif
ctrl->flags[i] |= __cpc_domain_translator( domain );
#ifdef DEBUG
SUBDBG( " -> %s: +++ new value: %p\n",
__func__, ctrl->flags[i] );
#endif
}
/* Recreate the set */
__CHECK_ERR_PAPI( __cpc_recreate_set( ctrl ) );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_ctl( hwd_context_t * ctx, int code, _papi_int_option_t * option )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
SUBDBG( " -> %s: Option #%d requested\n", __func__, code );
#endif
/* Only these options are handled which are handled in PAPI_set_opt, as many
of the left out options are not settable, like PAPI_MAX_CPUS. */
switch ( code ) {
case PAPI_DEFDOM:
/* From papi.h: Domain for all new eventsets. Takes non-NULL option
pointer. */
_niagara2_vector.cmp_info.default_domain = option->domain.domain;
return PAPI_OK;
case PAPI_DOMAIN:
/* From papi.h: Domain for an eventset */
return _niagara2_set_domain( ctx, option->domain.domain );
case PAPI_DEFGRN:
/* From papi.h: Granularity for all new eventsets */
_niagara2_vector.cmp_info.default_granularity =
option->granularity.granularity;
return PAPI_OK;
case PAPI_GRANUL:
/* From papi.h: Granularity for an eventset */
/* Only supported granularity is PAPI_GRN_THREAD */
return PAPI_OK;
case PAPI_DEF_MPX_NS:
/* From papi.h: Multiplexing/overflowing interval in ns, same as
PAPI_DEF_ITIMER_NS */
/* From the old component */
option->itimer.ns = __sol_get_itimer_ns( option->itimer.ns );
#ifdef DEBUG
SUBDBG( " -> %s: PAPI_DEF_MPX_NS, option->itimer.ns=%d\n",
__func__, option->itimer.ns );
#endif
return PAPI_OK;
case PAPI_DEF_ITIMER: // IN THE OLD COMPONENT // USED
/* From papi.h: Option to set the type of itimer used in both software
multiplexing, overflowing and profiling */
/* These tests are taken from the old component. For Solaris 10 the
same rules apply as documented in getitimer(2). */
if ( ( option->itimer.itimer_num == ITIMER_REAL ) &&
( option->itimer.itimer_sig != SIGALRM ) ) {
#ifdef DEBUG
SUBDBG( " -> %s: PAPI_DEF_ITIMER, ITIMER_REAL needs SIGALRM\n",
__func__ );
#endif
return PAPI_EINVAL;
}
if ( ( option->itimer.itimer_num == ITIMER_VIRTUAL ) &&
( option->itimer.itimer_sig != SIGVTALRM ) ) {
#ifdef DEBUG
SUBDBG( " -> %s: PAPI_DEF_ITIMER, ITIMER_VIRTUAL needs SIGVTALRM\n",
__func__ );
#endif
return PAPI_EINVAL;
}
if ( ( option->itimer.itimer_num == ITIMER_PROF ) &&
( option->itimer.itimer_sig != SIGPROF ) ) {
#ifdef DEBUG
SUBDBG( " -> %s: PAPI_DEF_ITIMER, ITIMER_PROF needs SIGPROF\n",
__func__ );
#endif
return PAPI_EINVAL;
}
/* As in the old component defined, timer values below 0 are NOT
filtered out, but timer values greater than 0 are rounded, either to
a value which is at least itimer_res_ns or padded to a multiple of
itimer_res_ns. */
if ( option->itimer.ns > 0 ) {
option->itimer.ns = __sol_get_itimer_ns( option->itimer.ns );
#ifdef DEBUG
SUBDBG( " -> %s: PAPI_DEF_ITIMER, option->itimer.ns=%d\n",
__func__, option->itimer.ns );
#endif
}
return PAPI_OK;
case PAPI_DEF_ITIMER_NS: // IN THE OLD COMPONENT // USED
/* From papi.h: Multiplexing/overflowing interval in ns, same as
PAPI_DEF_MPX_NS */
/* From the old component */
option->itimer.ns = __sol_get_itimer_ns( option->itimer.ns );
#ifdef DEBUG
SUBDBG( " -> %s: PAPI_DEF_ITIMER_NS, option->itimer.ns=%d\n",
__func__, option->itimer.ns );
#endif
return PAPI_OK;
}
#ifdef DEBUG
SUBDBG( " -> %s: Option not found\n", __func__ );
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* This place should never be reached */
return PAPI_EINVAL;
}
void
_niagara2_dispatch_timer( int signal, siginfo_t * si, void *info )
{
EventSetInfo_t *ESI = NULL;
ThreadInfo_t *thread = NULL;
int overflow_vector = 0;
hwd_control_state_t *ctrl = NULL;
long_long results[MAX_COUNTERS];
int i;
// Hint from perf_events.c
int cidx = _niagara2_vector.cmp_info.CmpIdx;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
SUBDBG( " -> %s: Overflow handler called by signal #%d\n", __func__,
signal );
#endif
/* From the old component */
thread = _papi_hwi_lookup_thread( 0 );
ESI = ( EventSetInfo_t * ) thread->running_eventset[cidx];
/* From the old component, modified */
//
if ( ESI == NULL || ESI->master != thread || ESI->ctl_state == NULL ||
( ( ESI->state & PAPI_OVERFLOWING ) == 0 ) ) {
#ifdef DEBUG
SUBDBG( " -> %s: Problems with ESI, not necessarily serious\n",
__func__ );
if ( ESI == NULL ) {
SUBDBG( " -> %s: +++ ESI is NULL\n", __func__ );
}
if ( ESI->master != thread ) {
SUBDBG( " -> %s: +++ Thread mismatch, ESI->master=%#x thread=%#x\n",
__func__, ESI->master, thread );
}
if ( ESI->ctl_state == NULL ) {
SUBDBG( " -> %s: +++ Counter state invalid\n", __func__ );
}
if ( ( ( ESI->state & PAPI_OVERFLOWING ) == 0 ) ) {
SUBDBG
( " -> %s: +++ Overflow flag missing, ESI->overflow.flags=%#x\n",
__func__, ESI->overflow.flags );
}
#endif
return;
}
#ifdef DEBUG
printf( " -> %s: Preconditions valid, trying to read counters\n",
__func__ );
#endif
ctrl = ESI->ctl_state;
if ( _niagara2_read
( ctrl, ctrl, ( long_long ** ) & results, NOT_A_PAPI_HWD_READ )
!= PAPI_OK ) {
/* Failure */
#ifdef DEBUG
printf( "%s: Failed to read counters\n", __func__ );
#endif
return;
} else {
/* Success */
#ifdef DEBUG
SUBDBG( " -> %s: Counters read\n", __func__ );
#endif
/* Iterate over all available counters in order to detect which counter
overflowed (counter value should be 0 if an hw overflow happened),
store the position in the overflow_vector, calculte the offset and
shift (value range signed long long vs. unsigned long long). */
for ( i = 0; i < ctrl->count; i++ ) {
if ( results[i] >= 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: Overflow detected at PIC #%d\n", __func__, i );
#endif
/* Set the bit in the overflow_vector */
overflow_vector = overflow_vector | ( 1 << i );
/* hoose which method to use depending on the overflow signal. */
if ( signal == SIGEMT ) {
/* Store the counter value, but only if we have a real *
hardware overflow counting with libcpc/SIGEMT. */
ctrl->preset[i] = UINT64_MAX - ctrl->threshold[i];
ctrl->hangover[i] += ctrl->threshold[i];
} else {
/* Push the value back, this time PAPI does the work. This is
software overflow handling. */
cpc_request_preset( cpc, ctrl->idx[i], ctrl->result[i] );
}
} else {
#ifdef DEBUG
SUBDBG( " -> %s: No overflow detected at PIC #%d, value=%ld\n",
__func__, i, results[i] );
#endif
/* Save the results read from the counter as we can not store the
temporary value in hardware or libcpc. */
if ( signal == SIGEMT ) {
ctrl->preset[i] += results[i];
ctrl->hangover[i] = results[i];
}
}
}
#ifdef DEBUG
SUBDBG( " -> %s: Restarting set to push values back\n", __func__ );
#endif
/* Push all values back to the counter as preset */
cpc_set_restart( cpc, ctrl->set );
}
#ifdef DEBUG
SUBDBG( " -> %s: Passing overflow to PAPI with overflow_vector=%p\n",
__func__, overflow_vector );
#endif
{
/* hw is used as pointer in the dispatching routine of PAPI and might be
changed. For safety it is not a pseudo pointer to NULL. */
int hw;
if ( signal == SIGEMT ) {
/* This is a hardware overflow */
hw = 1;
_papi_hwi_dispatch_overflow_signal( ctrl, ( caddr_t )
_niagara2_get_overflow_address
( info ), &hw, overflow_vector,
1, &thread, ESI->CmpIdx );
} else {
/* This is a software overflow */
hw = 0;
_papi_hwi_dispatch_overflow_signal( ctrl, ( caddr_t )
_niagara2_get_overflow_address
( info ), &hw, overflow_vector,
1, &thread, ESI->CmpIdx );
}
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
static inline void *
_niagara2_get_overflow_address( void *context )
{
ucontext_t *ctx = ( ucontext_t * ) context;
#ifdef DEBUG
SUBDBG( "ENTERING/LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return ( void * ) ctx->uc_mcontext.gregs[REG_PC];
}
/** Although the created set in this function will be destroyed by
* _papi_update_control_state later, at least the functionality of the
* underlying CPU driver will be tested completly.
*/
int
_niagara2_init_control_state( hwd_control_state_t * ctrl )
{
int i;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
// cpc_seterrhndlr(cpc, myapp_errfn);
/* Clear the buffer */
if ( ctrl->counter_buffer != NULL ) {
#ifdef DEBUG
SUBDBG( " -> %s: Cleaning buffer\n", __func__ );
#endif
cpc_buf_destroy( cpc, ctrl->counter_buffer );
ctrl->counter_buffer = NULL;
}
/* Clear the set */
if ( ctrl->set != NULL ) {
#ifdef DEBUG
SUBDBG( " -> %s: Cleaning set\n", __func__ );
#endif
cpc_set_destroy( cpc, ctrl->set );
ctrl->set = NULL;
}
/* Indicate this idx has no request associated, this counter is unused. */
for ( i = 0; i < MAX_COUNTERS; i++ ) {
#ifdef DEBUG
SUBDBG( " -> %s: Cleaning counter state #%d\n", __func__, i );
#endif
/* Indicate missing setup values */
ctrl->idx[i] = EVENT_NOT_SET;
ctrl->code[i].event_code = EVENT_NOT_SET;
/* No flags yet set, this is for overflow and binding */
ctrl->flags[i] = 0;
/* Preset value for counting results */
ctrl->preset[i] = DEFAULT_CNTR_PRESET;
/* Needed for overflow handling, will be set later */
ctrl->threshold[i] = 0;
ctrl->hangover[i] = 0;
#ifdef SYNTHETIC_EVENTS_SUPPORTED
ctrl->syn_hangover[i] = 0;
#endif
}
/* No counters active in this set */
ctrl->count = 0;
#ifdef SYNTHETIC_EVENTS_SUPPORTED
ctrl->syn_count = 0;
#endif
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_init_component( int cidx )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Create an instance of libcpc */
#ifdef DEBUG
SUBDBG( " -> %s: Trying to initalize libcpc\n", __func__ );
#endif
cpc = cpc_open( CPC_VER_CURRENT );
__CHECK_ERR_NULL( cpc );
#ifdef DEBUG
SUBDBG( " -> %s: Registering libcpc error handler\n", __func__ );
#endif
cpc_seterrhndlr( cpc, __cpc_error_handler );
#ifdef DEBUG
SUBDBG( " -> %s: Detecting supported PICs", __func__ );
#endif
__t2_store.npic = cpc_npic( cpc );
#ifdef DEBUG
SUBDBG( " -> %s: Storing component index, cidx=%d\n", __func__, cidx );
#endif
_niagara2_vector.cmp_info.CmpIdx = cidx;
#ifdef DEBUG
SUBDBG( " -> %s: Gathering system information for PAPI\n", __func__ );
#endif
/* Store system info in central data structure */
__CHECK_ERR_PAPI( _niagara2_get_system_info( &_papi_hwi_system_info ) );
#ifdef DEBUG
SUBDBG( " -> %s: Initializing locks\n", __func__ );
#endif
/* Set up the lock after initialization */
_niagara2_lock_init( );
// Copied from the old component, _papi_init_component()
SUBDBG( "Found %d %s %s CPUs at %d Mhz.\n",
_papi_hwi_system_info.hw_info.totalcpus,
_papi_hwi_system_info.hw_info.vendor_string,
_papi_hwi_system_info.hw_info.model_string,
_papi_hwi_system_info.hw_info.cpu_max_mhz );
/* Build native event table */
#ifdef DEBUG
SUBDBG( " -> %s: Building native event table\n", __func__ );
#endif
__CHECK_ERR_PAPI( __cpc_build_ntv_table( ) );
/* Build preset event table */
#ifdef DEBUG
SUBDBG( " -> %s: Building PAPI preset table\n", __func__ );
#endif
__CHECK_ERR_PAPI( __cpc_build_pst_table( ) );
/* Register presets and finish event related setup */
#ifdef DEBUG
SUBDBG( " -> %s: Registering presets in PAPI\n", __func__ );
#endif
__CHECK_ERR_PAPI( _papi_hwi_setup_all_presets( preset_table, NULL ) );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Everything is ok */
return PAPI_OK;
}
static void
_niagara2_lock_init( void )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Copied from old component, lock_init() */
memset( lock, 0x0, sizeof ( rwlock_t ) * PAPI_MAX_LOCK );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
int
_niagara2_ntv_code_to_bits( unsigned int EventCode, hwd_register_t * bits )
{
int event_code = EventCode & PAPI_NATIVE_AND_MASK;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
if ( event_code >= 0 &&
event_code <= _niagara2_vector.cmp_info.num_native_events ) {
return PAPI_ENOEVNT;
}
bits->event_code = event_code;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_ntv_code_to_descr( unsigned int EventCode, char *ntv_descr, int len )
{
#ifdef DEBUG
SUBDBG( "ENTERING/LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* libcpc offers no descriptions, just a link to the reference manual */
return _niagara2_ntv_code_to_name( EventCode, ntv_descr, len );
}
int
_niagara2_ntv_code_to_name( unsigned int EventCode, char *ntv_name, int len )
{
int event_code = EventCode & PAPI_NATIVE_AND_MASK;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
if ( event_code >= 0 &&
event_code <= _niagara2_vector.cmp_info.num_native_events ) {
strlcpy( ntv_name, __t2_ntv_events[event_code], len );
if ( strlen( __t2_ntv_events[event_code] ) > len - 1 ) {
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* It's not a real error, but at least a hint */
return PAPI_EBUF;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_ENOEVNT;
}
int
_niagara2_ntv_enum_events( unsigned int *EventCode, int modifier )
{
/* This code is very similar to the code from the old component. */
int event_code = *EventCode & PAPI_NATIVE_AND_MASK;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
if ( modifier == PAPI_ENUM_FIRST ) {
*EventCode = PAPI_NATIVE_MASK + 1;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
/* The table needs to be shifted by one position (starting index 1), as PAPI
expects native event codes not to be 0 (papi_internal.c:744). */
if ( event_code >= 1 &&
event_code <= _niagara2_vector.cmp_info.num_native_events - 1 ) {
*EventCode = *EventCode + 1;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
// If nothing found report an error
return PAPI_ENOEVNT;
}
int
_niagara2_read( hwd_context_t * ctx, hwd_control_state_t * ctrl,
long_long ** events, int flags )
{
int i;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
SUBDBG( " -> %s: called with flags=%p\n", __func__, flags );
#endif
/* Take a new sample from the PIC to the buffer */
__CHECK_ERR_DFLT( cpc_set_sample( cpc, ctrl->set, ctrl->counter_buffer ) );
/* Copy the buffer values from all active counters */
for ( i = 0; i < ctrl->count; i++ ) {
/* Retrieve the counting results of libcpc */
__CHECK_ERR_DFLT( cpc_buf_get( cpc, ctrl->counter_buffer, ctrl->idx[i],
&ctrl->result[i] ) );
/* As libcpc uses uint64_t and PAPI uses int64_t, we need to normalize
the result back to a value that PAPI can handle, otherwise the result
is not usable as its in the negative range of int64_t and the result
becomes useless for PAPI. */
if ( ctrl->threshold[i] > 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: Normalizing result on PIC#%d to %lld\n",
__func__, i, ctrl->result[i] );
#endif /* DEBUG */
/* This shifts the retrieved value back to the PAPI value range */
ctrl->result[i] = ctrl->result[i] -
( UINT64_MAX - ctrl->threshold[i] ) - 1;
/* Needed if called internally if a PIC didn't really overflow, but
was programmed in the same set. */
if ( flags != NOT_A_PAPI_HWD_READ ) {
ctrl->result[i] = ctrl->hangover[i];
}
#ifdef DEBUG
SUBDBG( " -> %s: Overflow scaling on PIC#%d:\n", __func__, i );
SUBDBG( " -> %s: +++ ctrl->result[%d]=%llu\n",
__func__, i, ctrl->result[i] );
SUBDBG( " -> %s: +++ ctrl->threshold[%d]=%lld\n",
__func__, i, ctrl->threshold[i] );
SUBDBG( " -> %s: +++ ctrl->hangover[%d]=%lld\n",
__func__, i, ctrl->hangover[i] );
#endif
}
#ifdef DEBUG
SUBDBG( " -> %s: +++ ctrl->result[%d]=%llu\n",
__func__, i, ctrl->result[i] );
#endif
}
#ifdef SYNTHETIC_EVENTS_SUPPORTED
{
int i;
const int syn_barrier = _niagara2_vector.cmp_info.num_native_events
- __t2_store.syn_evt_count;
for ( i = 0; i < ctrl->count; i++ ) {
if ( ctrl->code[i].event_code >= syn_barrier ) {
ctrl->result[i] =
__int_get_synthetic_event( ctrl->code[i].event_code
- syn_barrier, ctrl, &i );
}
}
}
#endif
/* Pass the address of the results back to the calling function */
*events = ( long_long * ) & ctrl->result[0];
#ifdef DEBUG
SUBDBG( "LEAVING: %s\n", "_papi_read" );
#endif
return PAPI_OK;
}
int
_niagara2_reset( hwd_context_t * ctx, hwd_control_state_t * ctrl )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* This does a restart of the whole set, setting the internal counters back
to the value passed as preset of the last call of cpc_set_add_request or
cpc_request_preset. */
cpc_set_restart( cpc, ctrl->set );
#ifdef SYNTHETIC_EVENTS_SUPPORTED
{
const int syn_barrier = _niagara2_vector.cmp_info.num_native_events
- __t2_store.syn_evt_count;
int i;
if ( ctrl->syn_count > 0 ) {
for ( i = 0; i < MAX_COUNTERS; i++ ) {
if ( ctrl->code[i].event_code >= syn_barrier ) {
ctrl->syn_hangover[i] +=
__int_get_synthetic_event( ctrl->code[i].event_code -
syn_barrier, ctrl, &i );
}
}
}
}
#endif
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_set_profile( EventSetInfo_t * ESI, int EventIndex, int threshold )
{
/* Seems not to be used. */
#ifdef DEBUG
SUBDBG( "ENTERING/LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_ENOSUPP;
}
int
_niagara2_set_overflow( EventSetInfo_t * ESI, int EventIndex, int threshold )
{
hwd_control_state_t *ctrl = ESI->ctl_state;
struct sigaction sigact;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
SUBDBG( " -> %s: Overflow handling for %#x on PIC#%d requested\n",
__func__, ctrl, EventIndex );
SUBDBG( " -> %s: ESI->overflow.flags=%#x\n\n", __func__, ctrl,
ESI->overflow.flags );
#endif
/* If threshold > 0, then activate hardware overflow handling, otherwise
disable it. */
if ( threshold > 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: Activating overflow handling\n", __func__ );
#endif
ctrl->preset[EventIndex] = UINT64_MAX - threshold;
ctrl->threshold[EventIndex] = threshold;
/* If SIGEMT is not yet enabled, enable it. In libcpc this means to re-
recreate the used set. In order not to break PAPI operations only the
event referred by EventIndex will be updated to use SIGEMT. */
if ( !( ctrl->flags[EventIndex] & CPC_OVF_NOTIFY_EMT ) ) {
#ifdef DEBUG
SUBDBG( " -> %s: Need to activate SIGEMT on PIC %d\n",
__func__, EventIndex );
#endif
/* Enable overflow handling */
if ( __cpc_enable_sigemt( ctrl, EventIndex ) != PAPI_OK ) {
#ifdef DEBUG
SUBDBG( " -> %s: Activating SIGEMT failed for PIC %d\n",
__func__, EventIndex );
#endif
return PAPI_ESYS;
}
}
#ifdef DEBUG
SUBDBG( " -> %s: SIGEMT activated, will install signal handler\n",
__func__ );
#endif
// FIXME: Not really sure that this construct is working
return _papi_hwi_start_signal( SIGEMT, 1, 0 );
} else {
#ifdef DEBUG
SUBDBG( " -> %s: Disabling overflow handling\n", __func__ );
#endif
/* Resetting values which were used for overflow handling */
ctrl->preset[EventIndex] = DEFAULT_CNTR_PRESET;
ctrl->flags[EventIndex] &= ~( CPC_OVF_NOTIFY_EMT );
ctrl->threshold[EventIndex] = 0;
ctrl->hangover[EventIndex] = 0;
#ifdef DEBUG
SUBDBG( " -> %s:ctrl->preset[%d]=%d, ctrl->flags[%d]=%p\n",
__func__, EventIndex, ctrl->preset[EventIndex],
EventIndex, ctrl->flags[EventIndex] );
#endif
/* Recreate the undelying set and disable the signal handler */
__CHECK_ERR_PAPI( __cpc_recreate_set( ctrl ) );
__CHECK_ERR_PAPI( _papi_hwi_stop_signal( SIGEMT ) );
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_shutdown( hwd_context_t * ctx )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
cpc_buf_destroy( cpc, ctx->counter_buffer );
cpc_set_destroy( cpc, ctx->set );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_shutdown_global( void )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Free allocated memory */
// papi_calloc in __cpc_build_ntv_table
papi_free( __t2_store.pic_ntv_count );
// papi_calloc in __cpc_build_ntv_table
papi_free( __t2_ntv_events );
// papi_calloc in __cpc_build_pst_table
papi_free( preset_table );
/* Shutdown libcpc */
// cpc_open in _papi_init_component
cpc_close( cpc );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_start( hwd_context_t * ctx, hwd_control_state_t * ctrl )
{
int retval;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
SUBDBG( " -> %s: Starting EventSet %p\n", __func__, ctrl );
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
{
#ifdef DEBUG
SUBDBG( " -> %s: Event count: ctrl->count=%d, ctrl->syn_count=%d\n",
__func__, ctrl->count, ctrl->syn_count );
#endif
if ( ctrl->count > 0 && ctrl->count == ctrl->syn_count ) {
ctrl->idx[0] = cpc_set_add_request( cpc, ctrl->set, "Instr_cnt",
ctrl->preset[0], ctrl->flags[0],
0, NULL );
ctrl->counter_buffer = cpc_buf_create( cpc, ctrl->set );
}
}
#endif
#ifdef DEBUG
{
int i;
for ( i = 0; i < MAX_COUNTERS; i++ ) {
SUBDBG( " -> %s: Flags for PIC#%d: ctrl->flags[%d]=%d\n", __func__,
i, i, ctrl->flags[i] );
}
}
#endif
__CHECK_ERR_DFLT( cpc_bind_curlwp( cpc, ctrl->set, CPC_BIND_LWP_INHERIT ) );
/* Ensure the set is working properly */
retval = cpc_set_sample( cpc, ctrl->set, ctrl->counter_buffer );
if ( retval != 0 ) {
printf( "%s: cpc_set_sample failed, return=%d, errno=%d\n",
__func__, retval, errno );
return PAPI_ECMP;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_stop( hwd_context_t * ctx, hwd_control_state_t * ctrl )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
__CHECK_ERR_DFLT( cpc_unbind( cpc, ctrl->set ) );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_update_control_state( hwd_control_state_t * ctrl,
NativeInfo_t * native, int count,
hwd_context_t * ctx )
{
int i;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Delete everything as we can't change an existing set */
if ( ctrl->counter_buffer != NULL ) {
__CHECK_ERR_DFLT( cpc_buf_destroy( cpc, ctrl->counter_buffer ) );
}
if ( ctrl->set != NULL ) {
__CHECK_ERR_DFLT( cpc_set_destroy( cpc, ctrl->set ) );
}
for ( i = 0; i < MAX_COUNTERS; i++ ) {
ctrl->idx[i] = EVENT_NOT_SET;
}
/* New setup */
ctrl->set = cpc_set_create( cpc );
__CHECK_ERR_NULL( ctrl->set );
ctrl->count = count;
ctrl->syn_count = 0;
for ( i = 0; i < count; i++ ) {
/* Store the active event */
ctrl->code[i].event_code = native[i].ni_event & PAPI_NATIVE_AND_MASK;
ctrl->flags[i] = __cpc_domain_translator( PAPI_DOM_USER );
ctrl->preset[i] = DEFAULT_CNTR_PRESET;
#ifdef DEBUG
SUBDBG
( " -> %s: EventSet@%p/PIC#%d - ntv request >>%s<< (%d), flags=%#x\n",
__func__, ctrl, i, __t2_ntv_events[ctrl->code[i].event_code],
ctrl->code[i].event_code, ctrl->flags[i] );
#endif
/* Store the counter position (???) */
native[i].ni_position = i;
#ifdef SYNTHETIC_EVENTS_SUPPORTED
{
int syn_code = ctrl->code[i].event_code -
( _niagara2_vector.cmp_info.num_native_events
- __t2_store.syn_evt_count ) - 1;
/* Check if the event code is bigger than the CPC provided events. */
if ( syn_code >= 0 ) {
#ifdef DEBUG
SUBDBG
( " -> %s: Adding synthetic event %#x (%s) on position %d\n",
__func__, native[i].ni_event,
__t2_ntv_events[ctrl->code[i].event_code], i );
#endif
/* Call the setup routine */
__int_setup_synthetic_event( syn_code, ctrl, NULL );
/* Clean the hangover count as this event is new */
ctrl->syn_hangover[i] = 0;
/* Register this event as being synthetic, as an event set only
based on synthetic events can not be actived through libcpc */
ctrl->syn_count++;
/* Jump to next iteration */
continue;
}
}
#endif
#ifdef DEBUG
SUBDBG( " -> %s: Adding native event %#x (%s) on position %d\n",
__func__, native[i].ni_event,
__t2_ntv_events[ctrl->code[i].event_code], i );
#endif
/* Pass the event as request to libcpc */
ctrl->idx[i] = cpc_set_add_request( cpc, ctrl->set,
__t2_ntv_events[ctrl->code[i].
event_code],
ctrl->preset[i], ctrl->flags[i], 0,
NULL );
__CHECK_ERR_NEGV( ctrl->idx[i] );
}
#ifdef DEBUG
if ( i == 0 ) {
SUBDBG( " -> %s: nothing added\n", __func__ );
}
#endif
ctrl->counter_buffer = cpc_buf_create( cpc, ctrl->set );
__CHECK_ERR_NULL( ctrl->counter_buffer );
/* Finished the new setup */
/* Linking to context (same data type by typedef!) */
ctx = ctrl;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
int
_niagara2_update_shlib_info( papi_mdi_t *mdi )
{
char *file = "/proc/self/map";
char *resolve_pattern = "/proc/self/path/%s";
char lastobject[PRMAPSZ];
char link[PAPI_HUGE_STR_LEN];
char path[PAPI_HUGE_STR_LEN];
prmap_t mapping;
int fd, count = 0, total = 0, position = -1, first = 1;
caddr_t t_min, t_max, d_min, d_max;
PAPI_address_map_t *pam, *cur;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
fd = open( file, O_RDONLY );
if ( fd == -1 ) {
return PAPI_ESYS;
}
memset( lastobject, 0, PRMAPSZ );
#ifdef DEBUG
SUBDBG( " -> %s: Preprocessing memory maps from procfs\n", __func__ );
#endif
/* Search through the list of mappings in order to identify a) how many
mappings are available and b) how many unique mappings are available. */
while ( read( fd, &mapping, sizeof ( prmap_t ) ) > 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: Found a new memory map entry\n", __func__ );
#endif
/* Another entry found, just the total count of entries. */
total++;
/* Is the mapping accessible and not anonymous? */
if ( mapping.pr_mflags & ( MA_READ | MA_WRITE | MA_EXEC ) &&
!( mapping.pr_mflags & MA_ANON ) ) {
/* Test if a new library has been found. If a new library has been
found a new entry needs to be counted. */
if ( strcmp( lastobject, mapping.pr_mapname ) != 0 ) {
strncpy( lastobject, mapping.pr_mapname, PRMAPSZ );
count++;
#ifdef DEBUG
SUBDBG( " -> %s: Memory mapping entry valid for %s\n", __func__,
mapping.pr_mapname );
#endif
}
}
}
#ifdef DEBUG
SUBDBG( " -> %s: Preprocessing done, starting to analyze\n", __func__ );
#endif
/* Start from the beginning, now fill in the found mappings */
if ( lseek( fd, 0, SEEK_SET ) == -1 ) {
return PAPI_ESYS;
}
memset( lastobject, 0, PRMAPSZ );
/* Allocate memory */
pam =
( PAPI_address_map_t * ) papi_calloc( count,
sizeof ( PAPI_address_map_t ) );
while ( read( fd, &mapping, sizeof ( prmap_t ) ) > 0 ) {
if ( mapping.pr_mflags & MA_ANON ) {
#ifdef DEBUG
SUBDBG
( " -> %s: Anonymous mapping (MA_ANON) found for %s, skipping\n",
__func__, mapping.pr_mapname );
#endif
continue;
}
/* Check for a new entry */
if ( strcmp( mapping.pr_mapname, lastobject ) != 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: Analyzing mapping for %s\n", __func__,
mapping.pr_mapname );
#endif
cur = &( pam[++position] );
strncpy( lastobject, mapping.pr_mapname, PRMAPSZ );
snprintf( link, PAPI_HUGE_STR_LEN, resolve_pattern, lastobject );
memset( path, 0, PAPI_HUGE_STR_LEN );
readlink( link, path, PAPI_HUGE_STR_LEN );
strncpy( cur->name, path, PAPI_HUGE_STR_LEN );
#ifdef DEBUG
SUBDBG( " -> %s: Resolved name for %s: %s\n", __func__,
mapping.pr_mapname, cur->name );
#endif
}
if ( mapping.pr_mflags & MA_READ ) {
/* Data (MA_WRITE) or text (MA_READ) segment? */
if ( mapping.pr_mflags & MA_WRITE ) {
cur->data_start = ( caddr_t ) mapping.pr_vaddr;
cur->data_end =
( caddr_t ) ( mapping.pr_vaddr + mapping.pr_size );
if ( strcmp
( cur->name,
_papi_hwi_system_info.exe_info.fullname ) == 0 ) {
_papi_hwi_system_info.exe_info.address_info.data_start =
cur->data_start;
_papi_hwi_system_info.exe_info.address_info.data_end =
cur->data_end;
}
if ( first )
d_min = cur->data_start;
if ( first )
d_max = cur->data_end;
if ( cur->data_start < d_min ) {
d_min = cur->data_start;
}
if ( cur->data_end > d_max ) {
d_max = cur->data_end;
}
} else if ( mapping.pr_mflags & MA_EXEC ) {
cur->text_start = ( caddr_t ) mapping.pr_vaddr;
cur->text_end =
( caddr_t ) ( mapping.pr_vaddr + mapping.pr_size );
if ( strcmp
( cur->name,
_papi_hwi_system_info.exe_info.fullname ) == 0 ) {
_papi_hwi_system_info.exe_info.address_info.text_start =
cur->text_start;
_papi_hwi_system_info.exe_info.address_info.text_end =
cur->text_end;
}
if ( first )
t_min = cur->text_start;
if ( first )
t_max = cur->text_end;
if ( cur->text_start < t_min ) {
t_min = cur->text_start;
}
if ( cur->text_end > t_max ) {
t_max = cur->text_end;
}
}
}
first = 0;
}
close( fd );
/* During the walk of shared objects the upper and lower bound of the
segments could be discovered. The bounds are stored in the PAPI info
structure. The information is important for the profiling functions of
PAPI. */
/* This variant would pass the addresses of all text and data segments
_papi_hwi_system_info.exe_info.address_info.text_start = t_min;
_papi_hwi_system_info.exe_info.address_info.text_end = t_max;
_papi_hwi_system_info.exe_info.address_info.data_start = d_min;
_papi_hwi_system_info.exe_info.address_info.data_end = d_max;
*/
#ifdef DEBUG
SUBDBG( " -> %s: Analysis of memory maps done, results:\n", __func__ );
SUBDBG( " -> %s: text_start=%#x, text_end=%#x, text_size=%lld\n", __func__,
_papi_hwi_system_info.exe_info.address_info.text_start,
_papi_hwi_system_info.exe_info.address_info.text_end,
_papi_hwi_system_info.exe_info.address_info.text_end
- _papi_hwi_system_info.exe_info.address_info.text_start );
SUBDBG( " -> %s: data_start=%#x, data_end=%#x, data_size=%lld\n", __func__,
_papi_hwi_system_info.exe_info.address_info.data_start,
_papi_hwi_system_info.exe_info.address_info.data_end,
_papi_hwi_system_info.exe_info.address_info.data_end
- _papi_hwi_system_info.exe_info.address_info.data_start );
#endif
/* Store the map read and the total count of shlibs found */
_papi_hwi_system_info.shlib_info.map = pam;
_papi_hwi_system_info.shlib_info.count = count;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
//////////////////////////////////////////////////////////////////////////////////
/// UTILITY FUNCTIONS FOR ACCESS TO LIBCPC AND SOLARIS /////////////////////////
////////////////////////////////////////////////////////////////////////////////
/* DESCRIPTION:
* -----------------------------------------------------------------------------
* The following functions are for accessing libcpc 2 and Solaris related stuff
* needed for PAPI.
******************************************************************************/
static inline int
__cpc_build_ntv_table( void )
{
int i, tmp;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
__t2_store.pic_ntv_count = papi_calloc( __t2_store.npic, sizeof ( int ) );
__CHECK_ERR_NULL( __t2_store.pic_ntv_count );
#ifdef DEBUG
SUBDBG( " -> %s: Checking PICs for functionality\n", __func__ );
#endif
for ( i = 0; i < __t2_store.npic; i++ ) {
cpc_walk_events_pic( cpc, i, NULL, __cpc_walk_events_pic_action_count );
#ifdef DEBUG
SUBDBG( " -> %s: Found %d events on PIC#%d\n", __func__,
__t2_store.pic_ntv_count[i], i );
#endif
}
tmp = __t2_store.pic_ntv_count[0];
/* There should be at least one counter... */
if ( tmp == 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: PIC#0 has 0 events\n", __func__ );
#endif
return PAPI_ECMP;
}
/* Check if all PICs have the same number of counters */
for ( i = 0; i < __t2_store.npic; i++ ) {
if ( __t2_store.pic_ntv_count[i] != tmp ) {
#ifdef DEBUG
SUBDBG( " -> %s: PIC#%d has %d events, should have %d\n",
__func__, i, __t2_store.pic_ntv_count[i], tmp );
#endif
return PAPI_ECMP;
}
}
/* Count synthetic events which add functionality to libcpc */
#ifdef SYNTHETIC_EVENTS_SUPPORTED
__t2_store.syn_evt_count = 0;
__int_walk_synthetic_events_action_count( );
#endif
/* Store the count of events available in central data structure */
#ifndef SYNTHETIC_EVENTS_SUPPORTED
_niagara2_vector.cmp_info.num_native_events = __t2_store.pic_ntv_count[0];
#else
_niagara2_vector.cmp_info.num_native_events =
__t2_store.pic_ntv_count[0] + __t2_store.syn_evt_count;
#endif
/* Allocate memory for storing all events found, including the first empty
slot */
__t2_ntv_events =
papi_calloc( _niagara2_vector.cmp_info.num_native_events + 1,
sizeof ( char * ) );
__t2_ntv_events[0] = "THIS IS A BUG!";
tmp = 1;
cpc_walk_events_pic( cpc, 0, ( void * ) &tmp,
__cpc_walk_events_pic_action_store );
#ifdef SYNTHETIC_EVENTS_SUPPORTED
__int_walk_synthetic_events_action_store( );
#endif
#ifdef DEBUG
for ( i = 1; i < __t2_store.pic_ntv_count[0]; i++ ) {
SUBDBG( " -> %s: Event #%d: %s\n", __func__, i, __t2_ntv_events[i] );
}
#endif
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
/* Return event code for event_name */
static inline int
__cpc_search_ntv_event( char *event_name, int *event_code )
{
int i;
for ( i = 0; i < _niagara2_vector.cmp_info.num_native_events; i++ ) {
if ( strcmp( event_name, __t2_ntv_events[i] ) == 0 ) {
*event_code = i;
return PAPI_OK;
}
}
return PAPI_ENOEVNT;
}
static inline int
__cpc_build_pst_table( void )
{
int num_psts, i, j, event_code, pst_events;
hwi_search_t tmp;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
num_psts = 0;
while ( __t2_table[num_psts].papi_pst != 0 ) {
num_psts++;
}
#ifdef DEBUG
SUBDBG( " -> %s: Found %d presets\n", __func__, num_psts );
#endif
preset_table = papi_calloc( num_psts + 1, sizeof ( hwi_search_t ) );
__CHECK_ERR_NULL( preset_table );
pst_events = 0;
for ( i = 0; i < num_psts; i++ ) {
memset( &tmp, PAPI_NULL, sizeof ( tmp ) );
/* Mark counters as unused. If they are needed, they will be overwritten
later. See papi_preset.c:51 for more details. */
for ( j = 0; j < PAPI_EVENTS_IN_DERIVED_EVENT; j++ ) {
tmp.data.native[j] = PAPI_NULL;
}
tmp.event_code = __t2_table[i].papi_pst;
tmp.data.derived = __t2_table[i].ntv_opcode;
tmp.data.operation[0] = '\0';
switch ( __t2_table[i].ntv_opcode ) {
case DERIVED_ADD:
tmp.data.operation[0] = '+';
break;
case DERIVED_SUB:
tmp.data.operation[0] = '-';
break;
}
for ( j = 0; j < __t2_table[i].ntv_ctrs; j++ ) {
if ( __cpc_search_ntv_event
( __t2_table[i].ntv_event[j], &event_code )
>= PAPI_OK ) {
tmp.data.native[j] = event_code;
} else {
continue;
}
}
#ifdef DEBUG
SUBDBG( " -> %s: pst row %d - event_code=%d\n",
__func__, i, tmp.event_code );
SUBDBG( " -> %s: pst row %d - data.derived=%d, data.operation=%c\n",
__func__, i, tmp.data.derived, tmp.data.operation[0] );
SUBDBG( " -> %s: pst row %d - native event codes:\n", __func__, i );
{
int d_i;
for ( d_i = 0; d_i < PAPI_EVENTS_IN_DERIVED_EVENT; d_i++ ) {
SUBDBG( " -> %s: pst row %d - +++ data.native[%d]=%d\n",
__func__, i, d_i, tmp.data.native[d_i] );
}
}
#endif
memcpy( &preset_table[i], &tmp, sizeof ( tmp ) );
pst_events++;
}
// Check!
memset( &preset_table[num_psts], 0, sizeof ( hwi_search_t ) );
_niagara2_vector.cmp_info.num_preset_events = pst_events;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
static inline int
__cpc_recreate_set( hwd_control_state_t * ctrl )
{
#ifdef SYNTHETIC_EVENTS_SUPPORTED
const int syn_barrier = _niagara2_vector.cmp_info.num_native_events
- __t2_store.syn_evt_count;
#endif
int i;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Destroy the old buffer and the old set if they exist, we need to do a full
recreate as changing flags or events through libcpc is not possible */
if ( ctrl->counter_buffer != NULL ) {
__CHECK_ERR_DFLT( cpc_buf_destroy( cpc, ctrl->counter_buffer ) );
}
if ( ctrl->set != NULL ) {
__CHECK_ERR_DFLT( cpc_set_destroy( cpc, ctrl->set ) );
}
/* Create a new set */
ctrl->set = cpc_set_create( cpc );
__CHECK_ERR_NULL( ctrl->set );
for ( i = 0; i < ctrl->count; i++ ) {
#ifdef DEBUG
SUBDBG( " -> %s: Adding native event %#x (%s) on position %d\n",
__func__, ctrl->code[i].event_code,
__t2_ntv_events[ctrl->code[i].event_code], i );
SUBDBG( " -> %s: Event setup: ctrl->code[%d].event_code=%#x\n",
__func__, i, ctrl->code[i].event_code );
SUBDBG( " -> %s: Event setup: ctrl->preset[%d]=%d\n",
__func__, i, ctrl->preset[i] );
SUBDBG( " -> %s: Event setup: ctrl->flags[%d]=%#x\n",
__func__, i, ctrl->flags[i] );
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
/* Ensure that synthetic events are skipped */
if ( ctrl->code[i].event_code >= syn_barrier ) {
#ifdef DEBUG
SUBDBG( " -> %s: Skipping counter %d, synthetic event found\n",
__func__, i );
#endif
/* Next iteration */
continue;
}
#endif
ctrl->idx[i] = cpc_set_add_request( cpc, ctrl->set,
__t2_ntv_events[ctrl->code[i].
event_code],
ctrl->preset[i], ctrl->flags[i], 0,
NULL );
__CHECK_ERR_NEGV( ctrl->idx[i] );
}
ctrl->counter_buffer = cpc_buf_create( cpc, ctrl->set );
__CHECK_ERR_NULL( ctrl->counter_buffer );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
}
static inline int
__cpc_domain_translator( const int papi_domain )
{
int domain = 0;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
SUBDBG( " -> %s: papi_domain=%d requested\n", __func__, papi_domain );
#endif
if ( papi_domain & PAPI_DOM_USER ) {
#ifdef DEBUG
SUBDBG( " -> %s: Domain PAPI_DOM_USER/CPC_COUNT_USER selected\n",
__func__ );
#endif
domain |= CPC_COUNT_USER;
}
if ( papi_domain & PAPI_DOM_KERNEL ) {
#ifdef DEBUG
SUBDBG( " -> %s: Domain PAPI_DOM_KERNEL/CPC_COUNT_SYSTEM selected\n",
__func__ );
#endif
domain |= CPC_COUNT_SYSTEM;
}
if ( papi_domain & PAPI_DOM_SUPERVISOR ) {
#ifdef DEBUG
SUBDBG( " -> %s: Domain PAPI_DOM_SUPERVISOR/CPC_COUNT_HV selected\n",
__func__ );
#endif
domain |= CPC_COUNT_HV;
}
#ifdef DEBUG
SUBDBG( " -> %s: domain=%d\n", __func__, domain );
#endif
return domain;
}
void
__cpc_error_handler( const char *fn, int subcode, const char *fmt, va_list ap )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* From the libcpc manpages */
fprintf( stderr, "ERROR - libcpc error handler in %s() called!\n", fn );
vfprintf( stderr, fmt, ap );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
static inline int
__cpc_enable_sigemt( hwd_control_state_t * ctrl, int position )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
if ( position >= MAX_COUNTERS ) {
#ifdef DEBUG
SUBDBG( " -> %s: Position of the counter does not exist\n", __func__ );
#endif
return PAPI_EINVAL;
}
ctrl->flags[position] = ctrl->flags[position] | CPC_OVF_NOTIFY_EMT;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return __cpc_recreate_set( ctrl );
}
void
__cpc_walk_events_pic_action_count( void *arg, uint_t picno, const char *event )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
__t2_store.pic_ntv_count[picno]++;
#ifdef DEBUG
SUBDBG
( " -> %s: Found one native event on PIC#%d (now totally %d events)\n",
__func__, picno, __t2_store.pic_ntv_count[picno] );
#endif
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
void
__cpc_walk_events_pic_action_store( void *arg, uint_t picno, const char *event )
{
int *tmp = ( int * ) arg;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
__t2_ntv_events[*tmp] = papi_strdup( event );
#ifdef DEBUG
SUBDBG( " -> %s: Native event >>%s<< registered\n",
__func__, __t2_ntv_events[*tmp] );
#endif
*tmp = *tmp + 1;
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
static inline int
__sol_get_processor_clock( void )
{
processor_info_t pinfo;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
// Fetch information from the first processor in the system
if ( processor_info( getcpuid( ), &pinfo ) == 0 ) {
#ifdef DEBUG
SUBDBG( " -> %s: Clock at %d MHz\n", __func__, pinfo.pi_clock );
#endif
return pinfo.pi_clock;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_ESYS;
}
/* This function either increases the ns supplied to itimer_res_ns or pads it up
* to a multiple of itimer_res_ns if the value is bigger than itimer_res_ns.
*
* The source is taken from the old component.
*/
static inline int
__sol_get_itimer_ns( int ns )
{
if ( ns < _papi_os_info.itimer_res_ns ) {
return _papi_os_info.itimer_res_ns;
} else {
int leftover_ns = ns % _papi_os_info.itimer_res_ns;
return ns + leftover_ns;
}
}
static inline lwpstatus_t *
__sol_get_lwp_status( const pid_t pid, const lwpid_t lwpid )
{
char *pattern = "/proc/%d/lwp/%d/lwpstatus";
char filename[PAPI_MIN_STR_LEN];
int fd;
static lwpstatus_t lwp;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
memset( &lwp, 0, sizeof ( lwp ) );
snprintf( filename, PAPI_MIN_STR_LEN, pattern, pid, lwpid );
fd = open( filename, O_RDONLY );
if ( fd == -1 )
return NULL;
read( fd, ( void * ) &lwp, sizeof ( lwp ) );
close( fd );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return &lwp;
}
static inline psinfo_t *
__sol_get_proc_info( const pid_t pid )
{
char *pattern = "/proc/%d/psinfo";
char filename[PAPI_MIN_STR_LEN];
int fd;
static psinfo_t proc;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
memset( &proc, 0, sizeof ( proc ) );
snprintf( filename, PAPI_MIN_STR_LEN, pattern, pid );
fd = open( filename, O_RDONLY );
if ( fd == -1 )
return NULL;
read( fd, ( void * ) &proc, sizeof ( proc ) );
close( fd );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return &proc;
}
static inline pstatus_t *
__sol_get_proc_status( const pid_t pid )
{
char *pattern = "/proc/%d/status";
char filename[PAPI_MIN_STR_LEN];
int fd;
static pstatus_t proc;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
memset( &proc, 0, sizeof ( proc ) );
snprintf( filename, PAPI_MIN_STR_LEN, pattern, pid );
fd = open( filename, O_RDONLY );
if ( fd == -1 )
return NULL;
read( fd, ( void * ) &proc, sizeof ( proc ) );
close( fd );
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return &proc;
}
/* This function handles synthetic events and returns their result. Synthetic
* events are events retrieved from outside of libcpc, e.g. all events which
* can not be retrieved using cpc_set_add_request/cpc_buf_get. */
#ifdef SYNTHETIC_EVENTS_SUPPORTED
uint64_t
__int_get_synthetic_event( int code, hwd_control_state_t * ctrl, void *arg )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
switch ( code ) {
case SYNTHETIC_CYCLES_ELAPSED:
/* Return the count of ticks this set was bound. If a reset of the set
has been executed the last count will be subtracted. */
{
int *i = ( int * ) arg;
return cpc_buf_tick( cpc,
ctrl->counter_buffer ) - ctrl->syn_hangover[*i];
}
case SYNTHETIC_RETURN_ONE:
// The name says it - only for testing purposes.
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return 1;
case SYNTHETIC_RETURN_TWO:
// The name says it - only for testing purposes.
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return 2;
default:
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_EINVAL;
}
}
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
int
__int_setup_synthetic_event( int code, hwd_control_state_t * ctrl, void *arg )
{
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
switch ( code ) {
case SYNTHETIC_CYCLES_ELAPSED:
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_OK;
default:
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
return PAPI_EINVAL;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
void
__int_walk_synthetic_events_action_count( void )
{
int i = 0;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
/* Count all synthetic events in __int_syn_table, the last event is marked
with an event code of -1. */
while ( __int_syn_table[i].code != -1 ) {
__t2_store.syn_evt_count++;
i++;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
#endif
#ifdef SYNTHETIC_EVENTS_SUPPORTED
void
__int_walk_synthetic_events_action_store( void )
{
/* The first index of a synthetic event starts after last native event */
int i = 0;
int offset = _niagara2_vector.cmp_info.num_native_events + 1 -
__t2_store.syn_evt_count;
#ifdef DEBUG
SUBDBG( "ENTERING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
while ( i < __t2_store.syn_evt_count ) {
__t2_ntv_events[i + offset] = papi_strdup( __int_syn_table[i].name );
i++;
}
#ifdef DEBUG
SUBDBG( "LEAVING FUNCTION >>%s<< at %s:%d\n", __func__, __FILE__,
__LINE__ );
#endif
}
#endif
papi_vector_t _niagara2_vector = {
/************* COMPONENT CAPABILITIES/INFORMATION/ETC ************************/
.cmp_info = {
.name = "solaris-niagara2",
.description = "Solaris Counters",
.num_cntrs = MAX_COUNTERS,
.num_mpx_cntrs = MAX_COUNTERS,
.default_domain = PAPI_DOM_USER,
.available_domains = ( PAPI_DOM_USER | PAPI_DOM_KERNEL
| PAPI_DOM_SUPERVISOR ),
.default_granularity = PAPI_GRN_THR,
.available_granularities = PAPI_GRN_THR,
.fast_real_timer = 1,
.fast_virtual_timer = 1,
.attach = 1,
.attach_must_ptrace = 1,
.hardware_intr = 1,
.hardware_intr_sig = SIGEMT,
.precise_intr = 1,
}
,
/************* COMPONENT DATA STRUCTURE SIZES ********************************/
.size = {
.context = sizeof ( hwd_context_t ),
.control_state = sizeof ( hwd_control_state_t ),
.reg_value = sizeof ( hwd_register_t ),
.reg_alloc = sizeof ( niagara2_reg_alloc_t ),
}
,
/************* COMPONENT INTERFACE FUNCTIONS *********************************/
.init_control_state = _niagara2_init_control_state,
.start = _niagara2_start,
.stop = _niagara2_stop,
.read = _niagara2_read,
.write = NULL, /* NOT IMPLEMENTED */
.shutdown_thread = _niagara2_shutdown,
.shutdown_component = _niagara2_shutdown_global,
.ctl = _niagara2_ctl,
.update_control_state = _niagara2_update_control_state,
.set_domain = _niagara2_set_domain,
.reset = _niagara2_reset,
.set_overflow = _niagara2_set_overflow,
.set_profile = _niagara2_set_profile,
.stop_profiling = NULL, /* NOT IMPLEMENTED */
.ntv_enum_events = _niagara2_ntv_enum_events,
.ntv_name_to_code = NULL, /* NOT IMPLEMENTED */
.ntv_code_to_name = _niagara2_ntv_code_to_name,
.ntv_code_to_descr = _niagara2_ntv_code_to_descr,
.ntv_code_to_bits = _niagara2_ntv_code_to_bits,
.init_component = _niagara2_init_component,
.dispatch_timer = _niagara2_dispatch_timer,
};
papi_os_vector_t _papi_os_vector = {
.get_memory_info = _niagara2_get_memory_info,
.get_dmem_info = _solaris_get_dmem_info,
.get_real_usec = _solaris_get_real_usec,
.get_real_cycles = _solaris_get_real_cycles,
.get_virt_usec = _solaris_get_virt_usec,
.update_shlib_info = _solaris_update_shlib_info,
.get_system_info = _solaris_get_system_info,
};