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/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/usr/devicefw/associator.C $ */
/* */
/* IBM CONFIDENTIAL */
/* */
/* COPYRIGHT International Business Machines Corp. 2011,2012 */
/* */
/* p1 */
/* */
/* Object Code Only (OCO) source materials */
/* Licensed Internal Code Source Materials */
/* IBM HostBoot Licensed Internal Code */
/* */
/* The source code for this program is not published or otherwise */
/* divested of its trade secrets, irrespective of what has been */
/* deposited with the U.S. Copyright Office. */
/* */
/* Origin: 30 */
/* */
/* IBM_PROLOG_END_TAG */
#include <algorithm>
#include <errl/errlentry.H>
#include <errl/errlmanager.H>
#include <trace/interface.H>
#include <devicefw/devfwreasoncodes.H>
#include "associator.H"
using namespace ERRORLOG;
using namespace TARGETING;
namespace DeviceFW
{
trace_desc_t* g_traceBuffer = NULL;
TRAC_INIT(&g_traceBuffer, "DevFW", KILOBYTE, TRACE::BUFFER_SLOW);
Associator::Associator() : iv_mutex()
{
TRACFCOMP(g_traceBuffer, ENTER_MRK "Associator::Associator");
mutex_init(&iv_mutex);
// Allocate first level of map (access types).
iv_routeMap = iv_associations.allocate(LAST_DRIVER_ACCESS_TYPE);
}
Associator::~Associator()
{
TRACFCOMP(g_traceBuffer, EXIT_MRK "Associator::~Associator");
}
errlHndl_t Associator::registerRoute(int64_t i_opType,
int64_t i_accType,
int64_t i_targetType,
deviceOp_t i_regRoute)
{
TRACFCOMP(g_traceBuffer, "Device route registered for (%d, %d, %d)",
i_opType, i_accType, i_targetType);
// The ranges of the parameters should all be verified by the
// compiler due to the template specializations in driverif.H.
// No assert-checks will be done here.
mutex_lock(&iv_mutex);
// Make sure we aren't doing a double registration
for( OperationType optype = FIRST_OP_TYPE;
optype < LAST_OP_TYPE;
optype = static_cast<OperationType>(optype+1) )
{
if( (WILDCARD == i_opType) || (optype == i_opType) )
{
deviceOp_t l_devRoute = findDeviceRoute( optype,
static_cast<TARGETING::TYPE>(i_targetType),
i_accType );
if( l_devRoute != NULL )
{
TRACFCOMP(g_traceBuffer, "Double registration attempted : i_opType=%d, i_accType=%d, i_targetType=0x%X, existing function=%p", i_opType, i_accType, i_targetType, l_devRoute );
/*@
* @errortype
* @moduleid DEVFW_MOD_ASSOCIATOR
* @reasoncode DEVFW_RC_DOUBLE_REGISTRATION
* @userdata1[0:31] OpType
* @userdata1[32:63] AccessType
* @userdata2 TargetType
*
* @devdesc A double registration was attempted
* with the routing framework.
*/
errlHndl_t l_errl =
new ErrlEntry(ERRL_SEV_INFORMATIONAL,
DEVFW_MOD_ASSOCIATOR,
DEVFW_RC_DOUBLE_REGISTRATION,
TWO_UINT32_TO_UINT64(i_opType, i_accType),
TO_UINT64(i_targetType)
);
mutex_unlock(&iv_mutex);
return l_errl;
}
}
}
size_t ops = 0;
AssociationData targets = AssociationData();
// Look up second level of map (op-type) or allocate fresh block.
ops = iv_associations[iv_routeMap][i_accType].offset;
if (0 == ops)
{
// space for LAST_OP_TYPE plus WILDCARD(-1).
ops = iv_associations.allocate(LAST_OP_TYPE + 1) + 1;
iv_associations[iv_routeMap][i_accType].offset = ops;
}
// Look up third level of map (access-type) or allocate fresh block.
targets = iv_associations[ops][i_opType];
if (0 == targets.offset)
{
// To conserve space only allocate 1 block for WILDCARD.
if (WILDCARD == i_targetType)
{
targets.offset = iv_associations.allocate(1);
targets.flag = true; // True flag indicates WILDCARD.
}
else
{
// Allocate full number of spaces.
targets.offset = iv_associations.allocate(TYPE_LAST_IN_RANGE+1);
}
iv_associations[ops][i_opType] = targets;
}
// Index offset to proper target type. This is now lowest level of map.
targets.offset += (i_targetType == WILDCARD ? 0 : i_targetType);
// Search function vector for entry.
opVector_t::iterator opLocation = std::find(iv_operations.begin(),
iv_operations.end(),
i_regRoute);
// Insert function into vector if not found.
if (iv_operations.end() == opLocation)
{
iv_operations.push_back(i_regRoute);
opLocation = iv_operations.end() - 1;
}
size_t opLoc = std::distance(iv_operations.begin(), opLocation);
// Set function offset into map. True flag indicates valid.
(*iv_associations[targets.offset]) = AssociationData(true, opLoc);
mutex_unlock(&iv_mutex);
return NULL;
}
errlHndl_t Associator::performOp(OperationType i_opType,
Target* i_target,
void* io_buffer, size_t& io_buflen,
int64_t i_accessType, va_list i_addr)
{
errlHndl_t l_errl = NULL;
if( NULL == i_target )
{
TRACFCOMP(g_traceBuffer, "A device driver operation was attempted on a NULL target : i_opType=%d, i_accessType=%d", i_opType, i_accessType );
/*@
* @errortype
* @moduleid DEVFW_MOD_ASSOCIATOR
* @reasoncode DEVFW_RC_NULL_TARGET
* @userdata1 OpType
* @userdata2 AccessType
*
* @devdesc A device driver operation on a NULL target.
*/
l_errl = new ErrlEntry(ERRL_SEV_INFORMATIONAL,
DEVFW_MOD_ASSOCIATOR,
DEVFW_RC_NULL_TARGET,
i_opType,
i_accessType);
return l_errl;
}
TARGETING::TYPE l_devType =
(i_target == MASTER_PROCESSOR_CHIP_TARGET_SENTINEL) ?
TYPE_PROC : i_target->getAttr<ATTR_TYPE>();
TRACDCOMP(g_traceBuffer, "Device op requested for (%d, %d, %d)",
i_opType, i_accessType, l_devType);
mutex_lock(&iv_mutex);
// Function pointer found for this route request.
deviceOp_t l_devRoute = findDeviceRoute( i_opType,
l_devType,
i_accessType );
mutex_unlock(&iv_mutex);
// Call function if one was found, create error otherwise.
if (NULL == l_devRoute)
{
TRACFCOMP(g_traceBuffer, "A device driver operation was attempted for which no driver has been registered : i_opType=%d, i_accessType=%d, l_devType=%d", i_opType, i_accessType, l_devType );
/*@
* @errortype
* @moduleid DEVFW_MOD_ASSOCIATOR
* @reasoncode DEVFW_RC_NO_ROUTE_FOUND
* @userdata1 (OpType << 32) | (AccessType)
* @userdata2 TargetType
*
* @devdesc A device driver operation was attempted for
* which no driver has been registered.
*/
l_errl = new ErrlEntry(ERRL_SEV_INFORMATIONAL,
DEVFW_MOD_ASSOCIATOR,
DEVFW_RC_NO_ROUTE_FOUND,
TWO_UINT32_TO_UINT64(i_opType, i_accessType),
TO_UINT64(l_devType)
);
}
else
{
l_errl = (*l_devRoute)(i_opType, i_target,
io_buffer, io_buflen,
i_accessType, i_addr);
}
return l_errl;
}
deviceOp_t Associator::findDeviceRoute( OperationType i_opType,
TARGETING::TYPE i_devType,
int64_t i_accessType )
{
// The ranges of the parameters should all be verified by the
// compiler due to the template specializations in driverif.H.
// e.g. i_accessType can never be negative
// No assert-checks will be done here.
// Function pointer found for this route request.
deviceOp_t l_devRoute = NULL;
// Pointer to root of the map.
const AssociationData* routeMap = iv_associations[iv_routeMap];
do
{
// Follow first level (access type), verify.
if (0 == routeMap[i_accessType].offset)
{
break;
}
const AssociationData* ops =
iv_associations[routeMap[i_accessType].offset];
// Check op type = WILDCARD registrations.
if (0 != ops[WILDCARD].offset)
{
// Check access type = WILDCARD registrations.
if (ops[WILDCARD].flag)
{
l_devRoute =
iv_operations[
iv_associations[ops[WILDCARD].offset]->offset];
break;
}
// Check access type = i_target->type registrations.
const AssociationData* targets =
iv_associations[ops[WILDCARD].offset];
if (targets[i_devType].flag)
{
l_devRoute =
iv_operations[
targets[i_devType].offset];
break;
}
}
// Check op type = i_opType registrations.
if (0 != ops[i_opType].offset)
{
// Check access type = WILDCARD registrations.
if(ops[i_opType].flag)
{
l_devRoute =
iv_operations[
iv_associations[ops[i_opType].offset]->offset];
break;
}
// Check access type = i_target->type registrations.
const AssociationData* targets =
iv_associations[ops[i_opType].offset];
if (targets[i_devType].flag)
{
l_devRoute =
iv_operations[
targets[i_devType].offset];
break;
}
}
} while(0);
return l_devRoute;
}
}
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