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/* [ICS VERSION STRING: unknown] */
// mad queries to PMA and DMA
#include "topology.h"
#include "topology_internal.h"
// TBD - fix conflict with ib_utils_openib.h
#define DBGPRINT(format, args...) if (g_verbose_file) { fprintf(g_verbose_file, format, ##args); }
#include <limits.h>
#include <opamgt_sa_priv.h>
// umadt timeouts for DMA and PMA operations
#define SEND_WAIT_TIME (100) // 100 milliseconds for sends
#define FLUSH_WAIT_TIME (100) // 100 milliseconds for sends/recv during flush
#define RESP_WAIT_TIME (100) // 100 milliseconds for response recv
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
static IB_HANDLE g_umadtHandle = NULL; /* umadt handle for DM interface queries */
#endif
static uint64 g_transId = 1234; // transaction id
static FILE *g_verbose_file = NULL; // file for verbose output
static uint64 g_mkey = 0; // m_Key for SMA operations
static int g_smaRetries = 8; // number of request/response attempts
FSTATUS send_recv_mad(MADT_HANDLE umadtHandle, IB_PATH_RECORD *pathp,
uint32 qpn, uint32 qkey, MAD* mad,
int timeout, int retries);
void setTopologyMadVerboseFile(FILE* verbose_file) {
g_verbose_file = verbose_file;
}
void setTopologyMadRetryCount(int retries) {
g_smaRetries = retries;
}
#ifdef IB_DEBUG
void DumpMad(void *addr)
{
uint32 i;
for (i=0; i<256; i++)
{
if ((i & 15) == 0) {
if (i != 0) {
DBGPRINT("\n");
}
DBGPRINT("%4.4x:", i);
}
DBGPRINT(" %2.2x", (uint32)((uint8*)addr)[i]);
}
if (i != 0) {
DBGPRINT("\n");
}
}
void StlDumpMad(void *addr)
{
uint32 i;
for (i=0; i<2048; i++)
{
if ((i & 15) == 0) {
if (i != 0) {
DBGPRINT("\n");
}
DBGPRINT("%4.4x:", i);
}
DBGPRINT(" %2.2x", (uint32)((uint8*)addr)[i]);
}
if (i != 0) {
DBGPRINT("\n");
}
}
#endif /* IB_DEBUG */
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
static FSTATUS registerUmadt(EUI64 portGuid, MADT_HANDLE *handle)
{
RegisterClassStruct Reg;
FSTATUS fstatus;
DBGPRINT("registerUmadt: Port 0x%016"PRIx64"\n", portGuid);
Reg.PortGuid = portGuid;
Reg.ClassId = 0; /* only client, don't need to specify */
Reg.ClassVersion = 0; /* only client, don't need to specify */
Reg.isResponder = FALSE;
Reg.isTrapProcessor = FALSE;
Reg.isReportProcessor = FALSE;
Reg.SendQueueSize = 5; // TBD
Reg.RecvQueueSize = 5; // TBD
Reg.NotifySendCompletion = FALSE;
DBGPRINT("register uMadt\n");
fstatus = iba_umadt_register(&Reg, handle);
if (fstatus != FSUCCESS) {
fprintf(stderr, "%s: Failed to register Port 0x%016"PRIx64" with uMadt: (fstatus=0x%x): %s\n",
g_Top_cmdname, portGuid, fstatus, FSTATUS_MSG(fstatus));
}
return fstatus;
}
static FSTATUS send_mad(MADT_HANDLE umadtHandle, IB_PATH_RECORD *pathp,
uint32 qpn, uint32 qkey, MAD* mad)
{
FSTATUS status;
MadtStruct *Mad;
MadAddrStruct Addr;
uint32 count = 1;
MadWorkCompletion *Wc;
DBGPRINT("getting buffer to send Mad\n");
status = iba_umadt_get_sendmad(umadtHandle, &count, &Mad);
if (status != FSUCCESS) {
return status;
}
DBGPRINT("sending Mad\n");
Mad->Context = 0; // TBD - for async in future
MemoryClear(&Mad->Grh, sizeof(Mad->Grh)); /* only in recv */
MemoryCopy(&Mad->IBMad, mad, sizeof(*mad));
GetGsiAddrFromPath(pathp, qpn, qkey, &Addr);
status = iba_umadt_post_send(umadtHandle, Mad, &Addr);
if (status != FSUCCESS) {
fprintf(stderr, "%s: Failed to send mad: (status=0x%x): %s\n",
g_Top_cmdname, status, FSTATUS_MSG(status));
(void)iba_umadt_release_sendmad(umadtHandle, Mad);
return status;
}
status = iba_umadt_wait_any_compl(umadtHandle, SEND_COMPLETION, SEND_WAIT_TIME);
if (status == FSUCCESS) {
status = iba_umadt_poll_send_compl(umadtHandle, &Mad, &Wc);
if (status == FSUCCESS) {
DBGPRINT("MAD Sent\n");
(void)iba_umadt_release_sendmad(umadtHandle, Mad);
}
}
return status;
}
static FSTATUS recv_mad(MADT_HANDLE umadtHandle, MAD* mad, int timeout)
{
FSTATUS status;
MadtStruct *Mad;
MadWorkCompletion *Wc;
status = iba_umadt_wait_any_compl(umadtHandle, RECV_COMPLETION, timeout);
if (status == FTIMEOUT) {
DBGPRINT("Timeout waiting for MAD Recv. timeout= %d ms\n", timeout);
return status;
}
// cleanup any send completions while here
do {
status = iba_umadt_poll_send_compl(umadtHandle, &Mad, &Wc);
if (status == FSUCCESS) {
(void)iba_umadt_release_sendmad(umadtHandle, Mad);
}
} while (status == FSUCCESS);
// get next recv from the Q
status = iba_umadt_poll_recv_compl(umadtHandle, &Mad, &Wc);
if (status != FSUCCESS) {
DBGPRINT("Poll Recv failed: %s\n", iba_fstatus_msg(status));
return status;
}
MemoryCopy(mad, &Mad->IBMad, sizeof(*mad)); // caller must byte swap
// for now ignore Work completion, only handling responses
DBGPRINT("Received a MAD\n");
status = iba_umadt_release_recvmad(umadtHandle, Mad);
if (status != FSUCCESS) {
fprintf(stderr, "%s: ReleaseRecvMad: (status=0x%x): %s\n",
g_Top_cmdname, status, FSTATUS_MSG(status));
}
return status;
}
static void flush_rcv(MADT_HANDLE umadtHandle, int timeout)
{
FSTATUS status;
MadtStruct *Mad;
MadWorkCompletion *Wc;
if (timeout) {
status = iba_umadt_wait_any_compl(umadtHandle, RECV_COMPLETION, timeout);
if (status == FTIMEOUT) {
return;
}
}
do {
status = iba_umadt_poll_send_compl(umadtHandle, &Mad, &Wc);
if (status == FSUCCESS) {
(void)iba_umadt_release_sendmad(umadtHandle, Mad);
}
} while (status == FSUCCESS);
do {
// get all the recv's from the Q
status = iba_umadt_poll_recv_compl(umadtHandle, &Mad, &Wc);
if (status != FSUCCESS) {
return;
}
DBGPRINT("Received a MAD\n");
status = iba_umadt_release_recvmad(umadtHandle, Mad);
if (status != FSUCCESS) {
fprintf(stderr, "%s: ReleaseRecvMad: (status=0x%x): %s\n",
g_Top_cmdname, status, FSTATUS_MSG(status));
}
} while (1);
}
FSTATUS send_recv_mad(MADT_HANDLE umadtHandle, IB_PATH_RECORD *pathp,
uint32 qpn, uint32 qkey, MAD* mad,
int timeout, int retries)
{
FSTATUS fstatus;
int attempts = retries+1;
MAD req = *mad;
do {
fstatus = send_mad(g_umadtHandle, pathp, qpn, qkey, &req);
if (fstatus == FSUCCESS) {
do {
fstatus = recv_mad(g_umadtHandle, (MAD*)mad, timeout);
if (fstatus != FSUCCESS)
{
DBGPRINT("Failed to get MAD response: %s DLID: %u\n", iba_fstatus_msg(fstatus), pathp->DLID);
break;
}
BSWAP_MAD_HEADER((MAD*)mad);
if (mad->common.TransactionID != (g_transId<<24))
DBGPRINT("Recv unexpected trans id: expected 0x%"PRIx64" got 0x%"PRIx64"\n", (g_transId<<24), mad->common.TransactionID);
} while (mad->common.TransactionID != (g_transId<<24));
}
} while (FSUCCESS != fstatus && --attempts);
BSWAP_MAD_HEADER((MAD*)mad);
return fstatus;
}
#endif
#ifdef PRODUCT_OPENIB_FF
static __inline__ void debugLogSmaRequest(const char* requestName, uint8_t* path, STL_LID dlid, STL_LID slid) {
int i;
if(path) {
DBGPRINT("Sending DR SMA %s to ", requestName);
if(slid)
DBGPRINT("slid: 0x%08x, ", slid);
DBGPRINT("path:");
for(i = 1; i <= path[0]; i++) {
DBGPRINT(" %02d", path[i]);
}
DBGPRINT("\n");
} else {
DBGPRINT("Sending SMA %s to LID 0x%x\n", requestName, dlid);
}
}
/**
* Issue a single SMA mad and get the response.
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param method Request method, likely either get or set
* @param attr Attribute type being issued for this request
* @param modifier Attribute modifier for the specified attribute
* @param buffer Pointer to attribute data
* @param bufferLen The Length of the attribute data in the buffer
* @return FSTATUS return code
*/
static FSTATUS stl_sma_send_recv_mad(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t method,
uint32_t attr,
uint32_t modifier,
uint8_t* buffer,
uint32_t bufferLength)
{
FSTATUS fstatus;
STL_SMP smp;
struct omgt_mad_addr addr;
size_t send_size;
size_t recv_size;
memset(&smp, 0, sizeof(smp));
memset(&addr, 0, sizeof(addr));
if(dlid && path == NULL) {
// LID routed only
smp.common.MgmtClass = MCLASS_SM_LID_ROUTED;
smp.common.u.NS.Status.AsReg16 = 0;
addr.lid = dlid;
} else if (!dlid && !slid && path) {
// Directed route only
addr.lid = STL_LID_PERMISSIVE;
smp.common.MgmtClass = MCLASS_SM_DIRECTED_ROUTE;
smp.common.u.DR.s.D = 0;
smp.common.u.DR.s.Status = 0;
smp.common.u.DR.HopPointer = 0;
smp.common.u.DR.HopCount = path[0];
smp.SmpExt.DirectedRoute.DrSLID = STL_LID_PERMISSIVE;
smp.SmpExt.DirectedRoute.DrDLID = STL_LID_PERMISSIVE;
memcpy(smp.SmpExt.DirectedRoute.InitPath, path, sizeof(smp.SmpExt.DirectedRoute.InitPath));
} else if (!dlid && slid && path) {
// Mixed LR-DR (initial LID route, then DR)
addr.lid = STL_LID_PERMISSIVE;
smp.common.MgmtClass = MCLASS_SM_DIRECTED_ROUTE;
smp.common.u.DR.s.D = 0;
smp.common.u.DR.s.Status = 0;
smp.common.u.DR.HopPointer = 0;
smp.common.u.DR.HopCount = path[0];
smp.SmpExt.DirectedRoute.DrSLID = slid;
smp.SmpExt.DirectedRoute.DrDLID = STL_LID_PERMISSIVE;
memcpy(smp.SmpExt.DirectedRoute.InitPath, path, sizeof(smp.SmpExt.DirectedRoute.InitPath));
} else {
DBGPRINT("ERROR: unable to route packet: slid, dlid, or path not properly specified\n");
return (FINVALID_PARAMETER);
}
smp.common.BaseVersion = STL_BASE_VERSION;
smp.common.ClassVersion = STL_SM_CLASS_VERSION;
smp.common.mr.AsReg8 = 0;
smp.common.mr.s.Method = method;
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
smp.common.TransactionID = (++g_transId)<<24;
#else
smp.common.TransactionID = (++g_transId) & 0xffffffff;
#endif
smp.common.AttributeID = attr;
smp.common.AttributeModifier = modifier;
smp.M_Key = g_mkey;
// Copy the attribute information into the SMP
memcpy(stl_get_smp_data(&smp), buffer, bufferLength);
// Determine which pkey to use (full or limited)
// Attempt to use full at all times, otherwise, can
// use the limited for queries of the local port.
uint16_t pkey = omgt_get_mgmt_pkey(port, dlid, 0);
if (pkey==0) {
DBGPRINT("ERROR: Local port does not have management privileges\n");
return (FPROTECTION);
}
addr.qpn = 0;
addr.qkey = 0;
addr.pkey = pkey;
send_size = bufferLength;
send_size += stl_get_smp_header_size(&smp);
send_size = ROUNDUP_TYPE(size_t, send_size, 8);
STL_BSWAP_SMP_HEADER(&smp);
#ifdef IB_DEBUG
DBGPRINT("Sending STL MAD:\n");
DumpMad(&smp);
#endif
recv_size = sizeof(smp);
fstatus = omgt_send_recv_mad_no_alloc(port,
(uint8_t *)&smp, send_size,
&addr,
(uint8_t *)&smp, &recv_size,
RESP_WAIT_TIME,
g_smaRetries-1);
#ifdef IB_DEBUG
if (fstatus == FSUCCESS) {
DBGPRINT("Received STL MAD:\n");
StlDumpMad(&smp);
}
#endif
STL_BSWAP_SMP_HEADER(&smp);
if (smp.common.MgmtClass == MCLASS_SM_DIRECTED_ROUTE && path && memcmp(path, smp.SmpExt.DirectedRoute.InitPath, sizeof(smp.SmpExt.DirectedRoute.InitPath)) != 0) {
int i;
DBGPRINT("Response failed directed route validation, received packet with path: ");
for(i = 1; i < 64; i++) {
if(smp.SmpExt.DirectedRoute.InitPath[i] != 0) {
DBGPRINT("%d ", smp.SmpExt.DirectedRoute.InitPath[i]);
} else {
break;
}
}
DBGPRINT("\n");
fstatus = FERROR;
}
if (smp.common.u.DR.s.Status != MAD_STATUS_SUCCESS) {
DBGPRINT("SMA response with bad status: 0x%x\n", smp.common.u.DR.s.Status);
fstatus = FERROR;
} else {
memcpy(buffer, stl_get_smp_data(&smp), bufferLength);
}
return fstatus;
}
/**
* Get the NodeDesc from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pNodeDesc Pointer to allocated space to store the returned NodeDesc
* @return FSTATUS return code
*/
FSTATUS SmaGetNodeDesc(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_NODE_DESCRIPTION *pNodeDesc)
{
FSTATUS fstatus;
uint32_t bufferLength = sizeof(STL_NODE_DESCRIPTION);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(NodeDesc)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_NODE_DESCRIPTION, 0, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_NODE_DESCRIPTION((STL_NODE_DESCRIPTION*)buffer);
memcpy(pNodeDesc, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the NodeInfo from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pNodeInfo Pointer to allocated space to store the returned NodeInfo
* @return FSTATUS return code
*/
FSTATUS SmaGetNodeInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_NODE_INFO *pNodeInfo)
{
FSTATUS fstatus;
uint32_t bufferLength = sizeof(STL_NODE_INFO);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(NodeInfo)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_NODE_INFO, 0, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_NODE_INFO((STL_NODE_INFO*)buffer);
memcpy(pNodeInfo, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SwitchInfo from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pSwitchInfo Pointer to allocated space to store the returned SwitchInfo
* @return FSTATUS return code
*/
FSTATUS SmaGetSwitchInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_SWITCH_INFO *pSwitchInfo)
{
FSTATUS fstatus;
uint32_t bufferLength = sizeof(STL_SWITCH_INFO);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(SwitchInfo)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_SWITCH_INFO, 0, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SWITCH_INFO((STL_SWITCH_INFO*)buffer);
memcpy(pSwitchInfo, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the PortInfo from the requested LID/path and portNum
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param pPortInfo Pointer to allocated space to store the returned PortInfo
* @return FSTATUS return code
*/
FSTATUS SmaGetPortInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
uint8_t smConfigStarted,
STL_PORT_INFO *pPortInfo)
{
FSTATUS fstatus;
uint32 amod = 0x01000000 | portNum | (smConfigStarted ? 0x00000200 : 0x0);
char attributeName[64];
uint32_t bufferLength = sizeof(STL_PORT_INFO);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(PortInfo %u)", portNum);
debugLogSmaRequest(attributeName, path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_PORT_INFO, amod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_PORT_INFO((STL_PORT_INFO*)buffer);
memcpy(pPortInfo, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the CableInfo from the requested LID/path starting at address addr with length len
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param addr Starting address for CableInfo
* @param len Length of requested CableInfo data
* @param data Pointer to allocated space to store the returned CableInfo data
* @return FSTATUS return code
*/
FSTATUS SmaGetCableInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
uint16_t addr,
uint8_t len,
uint8_t *data)
{
FSTATUS fstatus;
uint32_t amod = (addr & 0x07ff)<<19 | (len & 0x3f)<<13 | (portNum & 0xff);
STL_CABLE_INFO *pCableInfo;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_CABLE_INFO);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(CableInfo %u)", portNum);
debugLogSmaRequest(attributeName, path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_CABLE_INFO, amod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
pCableInfo = (STL_CABLE_INFO*)buffer;
BSWAP_STL_CABLE_INFO(pCableInfo);
memcpy(data, pCableInfo->Data, len+1);
}
return fstatus;
}
/**
* Get the Partition Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param block PKey table block number
* @param pPartTable Pointer to allocated space to store the returned Partition Table information
* @return FSTATUS return code
*/
FSTATUS SmaGetPartTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
uint16_t block,
STL_PARTITION_TABLE *pPartTable)
{
FSTATUS fstatus;
uint32 attrmod = (1<<24) | (portNum<<16) | block;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_PARTITION_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(P_KeyTable %u %u)", portNum, block);
debugLogSmaRequest(attributeName, path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_PART_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_PARTITION_TABLE((STL_PARTITION_TABLE*)buffer);
memcpy(pPartTable, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the VLArb Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param part Which part of the VLArb table to retrieve
* @param pVLArbTable Pointer to allocated space to store the returned VLArb Table information
* @return FSTATUS return code
*/
FSTATUS SmaGetVLArbTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
uint8_t part,
STL_VLARB_TABLE *pVLArbTable)
{
FSTATUS fstatus;
uint32 attrmod = (1<<24) | (part<<16) | portNum;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_VLARB_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(VLArb %u %u)", part, portNum);
debugLogSmaRequest(attributeName, path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_VL_ARBITRATION, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_VLARB_TABLE((STL_VLARB_TABLE*)buffer, part);
memcpy(pVLArbTable, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SLSC Mapping Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pSLSCMap Pointer to allocated space to store the returned SLSC Mapping Table
* @return FSTATUS return code
*/
FSTATUS SmaGetSLSCMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_SLSCMAP *pSLSCMap)
{
FSTATUS fstatus;
uint32 attrmod = 0;
uint32_t bufferLength = sizeof(STL_SLSCMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(SLSCMap)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_SL_SC_MAPPING_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SLSCMAP((STL_SLSCMAP*)buffer);
memcpy(pSLSCMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SCSL Mapping Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pSCSLMap Pointer to allocated space to store the returned SCSL Mapping Table
* @return FSTATUS return code
*/
FSTATUS SmaGetSCSLMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_SCSLMAP *pSCSLMap)
{
FSTATUS fstatus;
uint32 attrmod = 0;
uint32_t bufferLength = sizeof(STL_SCSLMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(SCSLMap)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_SC_SL_MAPPING_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SCSLMAP((STL_SCSLMAP*)buffer);
memcpy(pSCSLMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SCSC Mapping Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param in_port Ingress port number for SCSC Mapping Table
* @param out_port Egress port number for SCSC Mapping Table
* @param pSCSCMap Pointer to allocated space to store the returned SCSC Mapping Table
* @return FSTATUS return code
*/
FSTATUS SmaGetSCSCMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t in_port,
uint8_t out_port,
STL_SCSCMAP *pSCSCMap)
{
FSTATUS fstatus;
uint32 attrmod = (1 << 24) | (in_port<<8) | out_port;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_SCSCMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(SCSCMap %u %u)", in_port, out_port);
debugLogSmaRequest(attributeName, path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_SC_SC_MAPPING_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SCSCMAP((STL_SCSCMAP*)buffer);
memcpy(pSCSCMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SCVL Mapping Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param pSCVLMap Pointer to allocated space to store the returned SCVL Mapping Table
* @param attr SMP Attribute value - used to select between different SCVL Mapping Tables
* @return FSTATUS return code
*/
FSTATUS SmaGetSCVLMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t port_num,
STL_SCVLMAP *pSCVLMap,
uint16_t attr)
{
FSTATUS fstatus;
uint32 attrmod = (1<<24) | port_num;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_SCVLMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(SCVLMap %u)", port_num);
debugLogSmaRequest(attributeName, path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, attr, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SCVLMAP((STL_SCVLMAP*)buffer);
memcpy(pSCVLMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the Buffer Control Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
* pBCT must be large enough to hold all BufferControlTables
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param startPort Beginning of port range for returned Buffer Control Tables
* @param endPort End of port range for returned Buffer Control Tables
* @param pBCT[] Array to store the returned Buffer Control Table(s)
* @return FSTATUS return code
*/
FSTATUS SmaGetBufferControlTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t startPort,
uint8_t endPort,
STL_BUFFER_CONTROL_TABLE pBCT[])
{
FSTATUS fstatus = FERROR;
uint8_t maxCount = path == NULL ? STL_NUM_BFRCTLTAB_BLOCKS_PER_LID_SMP : STL_NUM_BFRCTLTAB_BLOCKS_PER_DRSMP;
uint8_t block;
char attributeName[64];
const size_t bufferLength = STL_BFRCTRLTAB_PAD_SIZE * maxCount;
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(BufferControlTable %u %u)", startPort, endPort);
debugLogSmaRequest(attributeName, path, dlid, slid);
for (block = startPort; block <= endPort; block += maxCount) {
uint8_t numPorts = MIN(maxCount, (endPort - block)+1);
uint32_t amod = (numPorts << 24) | block;
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_BUFFER_CONTROL_TABLE, amod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
int i;
STL_BUFFER_CONTROL_TABLE *table = (STL_BUFFER_CONTROL_TABLE *)buffer;
for (i = 0; i < numPorts; i++) {
BSWAP_STL_BUFFER_CONTROL_TABLE(table);
pBCT[block-startPort+i] = *table;
// Handle the dissimilar sizes of Buffer Table and 8-byte pad alignment
table = (STL_BUFFER_CONTROL_TABLE *)((uint8_t *)table + STL_BFRCTRLTAB_PAD_SIZE);
}
}
}
return fstatus;
}
/**
* Get the Linear Forwarding Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Linear Forwarding Table block number
* @param pFDB Pointer to allocated space to store the returned Linear Forwarding Table
* @return FSTATUS return code
*/
FSTATUS SmaGetLinearFDBTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint16_t block,
STL_LINEAR_FORWARDING_TABLE *pFDB)
{
FSTATUS fstatus;
uint32_t modifier;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_LINEAR_FORWARDING_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(LFT %u)", block);
debugLogSmaRequest(attributeName, path, dlid, slid);
modifier = 0x01000000 + (uint32_t)block;
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_LINEAR_FWD_TABLE, modifier, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_LINEAR_FORWARDING_TABLE((STL_LINEAR_FORWARDING_TABLE*)buffer);
memcpy(pFDB, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the Multicast Forwarding Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Multicast Forwarding Table block number
* @param position Desired port mask for selected block (0-3)
* @param pFDB Pointer to allocated space to store the returned Multicast Forwarding Table
* @return FSTATUS return code
*/
FSTATUS SmaGetMulticastFDBTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint32_t block,
uint8_t position,
STL_MULTICAST_FORWARDING_TABLE *pFDB)
{
FSTATUS fstatus;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_MULTICAST_FORWARDING_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(MFT %u %u)", block, position);
debugLogSmaRequest(attributeName, path, dlid, slid);
//@TODO: Enable multi-block requests from just a single block request
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_MCAST_FWD_TABLE,
(0x1<<24) | (0x3 & position)<<22 | (block & 0xfffff), buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_MULTICAST_FORWARDING_TABLE((STL_MULTICAST_FORWARDING_TABLE*)buffer);
memcpy(pFDB, buffer, bufferLength);
}
return fstatus;
}
/* Get PortGroup Table from SMA at lid
* Retry as needed
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Port Group Table block number
* @param pPGT Pointer to allocated space to store the returned Port Group Table
* @return FSTATUS return code
*/
FSTATUS SmaGetPortGroupTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint16 block,
STL_PORT_GROUP_TABLE *pPGT)
{
FSTATUS fstatus;
uint32_t modifier;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_PORT_GROUP_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(PGT %u)", block);
debugLogSmaRequest(attributeName, path, dlid, slid);
modifier = 0x01000000 + (uint32_t)block;
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_PORT_GROUP_TABLE,
modifier, buffer, bufferLength);
if (FSUCCESS == fstatus) {
BSWAP_STL_PORT_GROUP_TABLE((STL_PORT_GROUP_TABLE*)buffer);
memcpy(pPGT, buffer, bufferLength);
}
return fstatus;
}
/* Get PortGroup FDB Table from SMA at lid
* Retry as needed
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Port Group FDB Table block number
* @param pFDB Pointer to allocated space to store the returned Port Group FDB Table
* @return FSTATUS return code
*/
FSTATUS SmaGetPortGroupFDBTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint16 block,
STL_PORT_GROUP_FORWARDING_TABLE *pFDB)
{
FSTATUS fstatus;
uint32_t modifier;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_PORT_GROUP_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Get(PGFDB %u)", block);
debugLogSmaRequest(attributeName, path, dlid, slid);
modifier = 0x01000000 + (uint32_t)block;
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_PORT_GROUP_FWD_TABLE,
modifier, buffer, bufferLength);
if (FSUCCESS == fstatus) {
BSWAP_STL_PORT_GROUP_FORWARDING_TABLE((STL_PORT_GROUP_FORWARDING_TABLE*)buffer);
memcpy(pFDB, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the SwitchInfo of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pSwitchInfo Pointer to SwitchInfo to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetSwitchInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_SWITCH_INFO *pSwitchInfo)
{
FSTATUS fstatus;
uint32_t bufferLength = sizeof(STL_SWITCH_INFO);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Set(SwitchInfo)", path, dlid, slid);
memcpy(buffer, pSwitchInfo, bufferLength);
BSWAP_STL_SWITCH_INFO((STL_SWITCH_INFO*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_SWITCH_INFO, 0, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SWITCH_INFO((STL_SWITCH_INFO*)buffer);
memcpy(pSwitchInfo, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the PortInfo of the requested LID/path and portNum
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param pPortInfo Pointer to PortInfo to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetPortInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
STL_PORT_INFO *pPortInfo)
{
FSTATUS fstatus;
uint32 amod = 0x01000000 | portNum;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_PORT_INFO);
uint8_t buffer[bufferLength];
snprintf(attributeName, sizeof(attributeName), "Set(PortInfo %u)", portNum);
debugLogSmaRequest(attributeName, path, dlid, slid);
memcpy(buffer, pPortInfo, bufferLength);
BSWAP_STL_PORT_INFO((STL_PORT_INFO*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_PORT_INFO, amod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_PORT_INFO((STL_PORT_INFO*)buffer);
memcpy(pPortInfo, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the Partition Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param block PKey table block number
* @param pPartTable Pointer to Partition table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetPartTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
uint16_t block,
STL_PARTITION_TABLE *pPartTable)
{
FSTATUS fstatus;
uint32 attrmod = (1<<24) | (portNum<<16) | block;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_PARTITION_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Set(P_KeyTable %u %u)", portNum, block);
debugLogSmaRequest(attributeName, path, dlid, slid);
memcpy(buffer, pPartTable, bufferLength);
BSWAP_STL_PARTITION_TABLE((STL_PARTITION_TABLE*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_PART_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_PARTITION_TABLE((STL_PARTITION_TABLE*)buffer);
memcpy(pPartTable, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the VLArb Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param portNum Port number for desired port information
* @param part Which part of the VLArb table to write to
* @param pVLArbTable Pointer to VLArb table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetVLArbTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t portNum,
uint8_t part,
STL_VLARB_TABLE *pVLArbTable)
{
FSTATUS fstatus;
uint32 attrmod = (1<<24) | (part<<16) | portNum;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_VLARB_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Set(VLArb %u %u)", part, portNum);
debugLogSmaRequest(attributeName, path, dlid, slid);
memcpy(buffer, pVLArbTable, bufferLength);
BSWAP_STL_VLARB_TABLE((STL_VLARB_TABLE*)buffer, part);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_VL_ARBITRATION, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_VLARB_TABLE((STL_VLARB_TABLE*)buffer, part);
memcpy(pVLArbTable, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the SLSC Mapping Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pSLSCMap Pointer to SLSC Mapping Table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetSLSCMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_SLSCMAP *pSLSCMap)
{
FSTATUS fstatus;
uint32 attrmod = 0;
uint32_t bufferLength = sizeof(STL_SLSCMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Set(SLSCMap)", path, dlid, slid);
memcpy(buffer, pSLSCMap, bufferLength);
BSWAP_STL_SLSCMAP((STL_SLSCMAP*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_SL_SC_MAPPING_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SLSCMAP((STL_SLSCMAP*)buffer);
memcpy(pSLSCMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the SCSL Mapping Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pSCSLMap Pointer to SCSL Mapping Table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetSCSLMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_SCSLMAP *pSCSLMap)
{
FSTATUS fstatus;
uint32 attrmod = 0;
uint32_t bufferLength = sizeof(STL_SCSLMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Set(SCSLMap)", path, dlid, slid);
memcpy(buffer, pSCSLMap, bufferLength);
BSWAP_STL_SCSLMAP((STL_SCSLMAP*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_SC_SL_MAPPING_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SCSLMAP((STL_SCSLMAP*)buffer);
memcpy(pSCSLMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the SCSC Mapping Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param in_port Ingress port number for SCSC Mapping Table
* @param out_port Egress port number for SCSC Mapping Table
* @param pSCSCMap Pointer to SCSC Mapping Table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetSCSCMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t in_port,
uint8_t out_port,
STL_SCSCMAP *pSCSCMap)
{
FSTATUS fstatus;
uint32 attrmod = (1 << 24) | (in_port<<8) | out_port;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_SCSCMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Set(SCSCMap %u %u)", in_port, out_port);
debugLogSmaRequest(attributeName, path, dlid, slid);
memcpy(buffer, pSCSCMap, bufferLength);
BSWAP_STL_SCSCMAP((STL_SCSCMAP*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_SC_SC_MAPPING_TABLE, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SCSCMAP((STL_SCSCMAP*)buffer);
memcpy(pSCSCMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the SCVL Mapping Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param asyncUpdate Asynchronous update
* @param allPorts All ports starting at portNum
* @param portNum Port number for desired port information
* @param pSCVLMap Pointer to SCVL Mapping Table to set. Will be overwritten with response
* @param attr SMP Attribute value - used to select between different SCVL Mapping Tables
* @return FSTATUS return code
*/
FSTATUS SmaSetSCVLMappingTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
boolean asyncUpdate,
boolean allPorts,
uint8_t portNum,
STL_SCVLMAP *pSCVLMap,
uint16_t attr)
{
FSTATUS fstatus;
uint32 attrmod = (1<<24) | portNum;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_SCVLMAP);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
if (allPorts)
attrmod |= 1 << 8;
if (asyncUpdate)
attrmod |= 1 << 12;
snprintf(attributeName, sizeof(attributeName), "Set(SCVLMap %u)", portNum);
debugLogSmaRequest(attributeName, path, dlid, slid);
memcpy(buffer, pSCVLMap, bufferLength);
BSWAP_STL_SCVLMAP((STL_SCVLMAP*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, attr, attrmod, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_SCVLMAP((STL_SCVLMAP*)buffer);
memcpy(pSCVLMap, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the Buffer Control Table from the requested LID/path
* Retry as needed if unable to send or don't get a response
* pBCT must be large enough to hold all BufferControlTables
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param startPort Beginning of port range for returned Buffer Control Tables
* @param endPort End of port range for returned Buffer Control Tables
* @param pBCT[] Array of Buffer Control Table(s) to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetBufferControlTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint8_t startPort,
uint8_t endPort,
STL_BUFFER_CONTROL_TABLE pBCT[])
{
FSTATUS fstatus = FERROR;
uint8_t maxCount = (path == NULL ? STL_NUM_BFRCTLTAB_BLOCKS_PER_LID_SMP : STL_NUM_BFRCTLTAB_BLOCKS_PER_DRSMP);
uint8_t block;
int i;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_BUFFER_CONTROL_TABLE) * maxCount;
uint8_t buffer[bufferLength];
uint8_t* data = buffer;
STL_BUFFER_CONTROL_TABLE *table = (STL_BUFFER_CONTROL_TABLE *)data;
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Set(BufferControlTable %u %u)", startPort, endPort);
debugLogSmaRequest(attributeName, path, dlid, slid);
for (block = startPort; block <= endPort; block += maxCount) {
uint8_t numPorts = MIN(maxCount, (endPort - block)+1);
uint32_t amod = (numPorts << 24) | block;
for (i = 0; i < numPorts; i++) {
memcpy(table, &pBCT[block-startPort+i], sizeof(STL_BUFFER_CONTROL_TABLE));
BSWAP_STL_BUFFER_CONTROL_TABLE(table);
// Handle the dissimilar sizes of Buffer Table and 8-byte pad alignment
data += STL_BFRCTRLTAB_PAD_SIZE;
table = (STL_BUFFER_CONTROL_TABLE *)(data);
}
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_BUFFER_CONTROL_TABLE, amod, buffer, sizeof(STL_BUFFER_CONTROL_TABLE));
if (fstatus == FSUCCESS) {
data = buffer;
table = (STL_BUFFER_CONTROL_TABLE*)data;
for (i = 0; i < numPorts; i++) {
BSWAP_STL_BUFFER_CONTROL_TABLE(table);
memcpy(&pBCT[block-startPort+i], table, sizeof(STL_BUFFER_CONTROL_TABLE));
// Handle the dissimilar sizes of Buffer Table and 8-byte pad alignment
data += STL_BFRCTRLTAB_PAD_SIZE;
table = (STL_BUFFER_CONTROL_TABLE *)(data);
}
}
}
return fstatus;
}
/**
* Set the Linear Forwarding Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Linear Forwarding Table block number
* @param pFDB Pointer to Linear Forwarding Table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetLinearFDBTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint16_t block,
STL_LINEAR_FORWARDING_TABLE *pFDB)
{
FSTATUS fstatus;
uint32_t modifier;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_LINEAR_FORWARDING_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Set(LFT %u)", block);
debugLogSmaRequest(attributeName, path, dlid, slid);
modifier = 0x01000000 + (uint32_t)block;
memcpy(buffer, pFDB, bufferLength);
BSWAP_STL_LINEAR_FORWARDING_TABLE((STL_LINEAR_FORWARDING_TABLE*)buffer);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_LINEAR_FWD_TABLE, modifier, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_LINEAR_FORWARDING_TABLE((STL_LINEAR_FORWARDING_TABLE*)buffer);
memcpy(pFDB, buffer, bufferLength);
}
return fstatus;
}
/**
* Set the Multicast Forwarding Table of the requested LID/path
* Retry as needed if unable to send or don't get a response
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Multicast Forwarding Table block number
* @param position Desired port mask for selected block (0-3)
* @param pFDB Pointer to Multicast Forwarding Table to set. Will be overwritten with response
* @return FSTATUS return code
*/
FSTATUS SmaSetMulticastFDBTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint32_t block,
uint8_t position,
STL_MULTICAST_FORWARDING_TABLE *pFDB)
{
FSTATUS fstatus;
char attributeName[64];
uint32_t bufferLength = sizeof(STL_MULTICAST_FORWARDING_TABLE);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
snprintf(attributeName, sizeof(attributeName), "Set(MFT %u %u)", block, position);
debugLogSmaRequest(attributeName, path, dlid, slid);
memcpy(buffer, pFDB, bufferLength);
BSWAP_STL_MULTICAST_FORWARDING_TABLE((STL_MULTICAST_FORWARDING_TABLE*)buffer);
//@TODO: Enable multi-block requests from just a single block request
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_SET, STL_MCLASS_ATTRIB_ID_MCAST_FWD_TABLE,
(0x1<<24) | (0x3 & position)<<22 | (block & 0xfffff), buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_MULTICAST_FORWARDING_TABLE((STL_MULTICAST_FORWARDING_TABLE*)buffer);
memcpy(pFDB, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SmaGetCongestionInfo from the requested LID/path
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param pCongestionInfo Pointer to allocated space to store the returned CongestionInfo
* @return FSTATUS return code
*/
FSTATUS SmaGetCongestionInfo(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
STL_CONGESTION_INFO *pCongestionInfo)
{
FSTATUS fstatus;
uint32_t bufferLength = sizeof(STL_CONGESTION_INFO);
uint8_t buffer[bufferLength];
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(CongestionInfo)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_CONGESTION_INFO, 0, buffer, bufferLength);
if (fstatus == FSUCCESS) {
BSWAP_STL_CONGESTION_INFO((STL_CONGESTION_INFO*)buffer);
memcpy(pCongestionInfo, buffer, bufferLength);
}
return fstatus;
}
/**
* Get the SmaGetHFICongestionControlTable from the requested LID/path
*
* @param port The omgt_port to communicate with the fabric
* @param dlid Destination LID to send packet to
* @param slid Source LID of mixed LRDR packet. Path describes hops after reaching this LID
* @param path Directed route path to destination
* @param block Starting block value
* @param numBlocks Number of blocks in table
* @return FSTATUS return code
*/
/* Maximum HFICCT size that can fit in a MAD packet */
#define HFICCTI_MAX_BLOCK 14
FSTATUS SmaGetHFICongestionControlTable(struct omgt_port *port,
STL_LID dlid,
STL_LID slid,
uint8_t* path,
uint16_t block,
uint16_t numBlocks,
STL_HFI_CONGESTION_CONTROL_TABLE *pHfiCongestionControl)
{
FSTATUS fstatus;
if (numBlocks < 1 || numBlocks > HFICCTI_MAX_BLOCK)
return FERROR;
uint32_t bufferLength = sizeof(STL_HFI_CONGESTION_CONTROL_TABLE) +
sizeof(STL_HFI_CONGESTION_CONTROL_TABLE_BLOCK) * (numBlocks - 1);
uint8_t buffer[bufferLength];
uint32_t amod = (numBlocks<<24) | (block & 0xff);
memset(buffer, 0, bufferLength);
debugLogSmaRequest("Get(HFICongestionControlTable)", path, dlid, slid);
fstatus = stl_sma_send_recv_mad(port, dlid, slid, path, MMTHD_GET, STL_MCLASS_ATTRIB_ID_HFI_CONGESTION_CONTROL_TABLE, amod, buffer, bufferLength);
if (fstatus != FSUCCESS)
return fstatus;
BSWAP_STL_HFI_CONGESTION_CONTROL_TABLE((STL_HFI_CONGESTION_CONTROL_TABLE*)buffer, numBlocks);
memcpy(pHfiCongestionControl, buffer, bufferLength);
return FSUCCESS;
}
#endif // PRODUCT_OPENIB_FF
/* process a PMA class port info or redirection required response
* save capability mask and update redirectp as needed
*/
static FSTATUS ProcessPmaClassPortInfo(PortData* portp, STL_CLASS_PORT_INFO *classp,
IB_PATH_RECORD *orig_pathp)
{
portp->PmaGotClassPortInfo = 1;
BSWAP_STL_CLASS_PORT_INFO(classp);
DBGPRINT("PMA ClassPortInfo.CapMask = 0x%x\n", classp->CapMask);
return FSUCCESS;
}
/* issue a single PMA mad and get the response.
* Retry as needed if unable to send or don't get a response
*/
static FSTATUS stl_pm_send_recv_mad(struct omgt_port *port, IB_PATH_RECORD *pathp,
uint32 qpn, uint32 qkey, uint8 method, uint32 attr, uint32 modifier, STL_PERF_MAD *mad)
{
FSTATUS fstatus;
struct omgt_mad_addr addr;
size_t recv_size;
memset(&addr, 0, sizeof(addr));
addr.lid = pathp->DLID;
addr.qpn = qpn;
addr.qkey = qkey;
addr.pkey = pathp->P_Key;
addr.sl = pathp->u2.s.SL;
mad->common.BaseVersion = STL_BASE_VERSION;
mad->common.MgmtClass = MCLASS_PERF;
mad->common.ClassVersion = STL_PM_CLASS_VERSION;
mad->common.mr.AsReg8 = 0;
mad->common.mr.s.Method = method;
mad->common.u.NS.Status.AsReg16 = 0;
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
mad->common.TransactionID = (++g_transId)<<24;
#else
mad->common.TransactionID = (++g_transId) & 0xffffffff;
#endif
mad->common.AttributeID = attr;
mad->common.AttributeModifier = modifier;
// rest of fields should be ignored for a Get, zero'ed above
BSWAP_MAD_HEADER((MAD*)mad);
#ifdef IB_DEBUG
DBGPRINT("Sending MAD:\n");
DumpMad(mad);
#endif
ASSERT(pathp->DLID);
recv_size = sizeof(*mad);
fstatus = omgt_send_recv_mad_no_alloc(port,
(uint8_t *)mad, sizeof(*mad),
&addr,
(uint8_t *)mad, &recv_size,
RESP_WAIT_TIME,
g_smaRetries-1);
#ifdef IB_DEBUG
if (fstatus == FSUCCESS) {
DBGPRINT("Received MAD:\n");
DumpMad(mad);
}
#endif
BSWAP_MAD_HEADER((MAD*)mad);
//DBGPRINT("send_recv_mad fstatus=%s\n", iba_fstatus_msg(fstatus));
return fstatus;
}
/* issue a single PMA request and get the response.
* Retry as needed if unable to send or don't get a response
* portp is the port to issue PMA request to (can be port 0 of switch), it need
* not match portNum.
* Handle PMA redirection (currently not supported) here.
*/
static FSTATUS stl_pm_send_recv(struct omgt_port *port, PortData *portp, uint8 method,
uint32 attr, uint32 modifier, STL_PERF_MAD *req, STL_PERF_MAD *resp)
{
FSTATUS fstatus;
int attempts = 2; // only a single 2nd attempt with redirection
do {
IB_PATH_RECORD *pathp;
uint32 qpn;
uint32 qkey;
pathp = portp->pathp;
qpn = 1;
qkey = QP1_WELL_KNOWN_Q_KEY;
*resp = *req;
//DBGPRINT("LID=0x%x SL=%d PKey=0x%x\n", pathp->DLID, pathp->u2.s.SL, pathp->P_Key);
fstatus = stl_pm_send_recv_mad(port, pathp, qpn, qkey, method, attr, modifier, resp);
if (FSUCCESS != fstatus) {
//DBGPRINT("pm_send_recv_mad fstatus=%s\n", iba_fstatus_msg(fstatus));
goto fail;
}
if (resp->common.u.NS.Status.AsReg16 != MAD_STATUS_SUCCESS) {
DBGPRINT("PMA response with bad status: 0x%x\n", resp->common.u.NS.Status.AsReg16);
fstatus = FERROR;
goto fail;
}
} while (FSUCCESS != fstatus && --attempts);
fail:
return fstatus;
}
/* Get STL Class Port Info from PMA at portp
* Retry and handle redirection as needed
* portp is the port to issue PMA request to (can be port 0 of switch)
* The portp is updated with the CLASS_PORT_INFO redirect and PMA CapMask
*/
FSTATUS STLPmGetClassPortInfo(struct omgt_port *port, PortData *portp)
{
STL_PERF_MAD req;
STL_PERF_MAD resp;
FSTATUS fstatus;
if (portp->PmaGotClassPortInfo)
return FSUCCESS; // if we already have, no use asking again
MemoryClear(&req, sizeof(req));
DBGPRINT("Sending PM Get(ClassPortInfo) to LID 0x%08x Node 0x%016"PRIx64"\n",
portp->pathp->DLID,
portp->nodep->NodeInfo.NodeGUID);
DBGPRINT(" Name: %.*s\n",
NODE_DESCRIPTION_ARRAY_SIZE,
(char*)portp->nodep->NodeDesc.NodeString);
fstatus = stl_pm_send_recv(port, portp, MMTHD_GET, STL_PM_ATTRIB_ID_CLASS_PORTINFO,
0, &req, &resp);
if (FSUCCESS != fstatus)
goto fail;
fstatus = ProcessPmaClassPortInfo(portp, (STL_CLASS_PORT_INFO*)&(resp.PerfData),
portp->pathp);
fail:
return fstatus;
}
/* Get Port counters from PMA at portp for given PortNum
* Retry and handle redirection as needed
* portp is the port to issue PMA request to (can be port 0 of switch), it need
*/
FSTATUS STLPmGetPortStatus(struct omgt_port *port, PortData *portp, uint8 portNum,
STL_PORT_STATUS_RSP *pPortStatus)
{
STL_PERF_MAD req;
STL_PERF_MAD resp;
STL_PORT_STATUS_REQ* p = (STL_PORT_STATUS_REQ *)&(req.PerfData);
FSTATUS fstatus;
MemoryClear(&req, sizeof(req));
// rest of fields should be ignored for a Get, zero'ed above
p->PortNumber = portNum;
p->VLSelectMask = 0x8001; // only do VLs 15 and 0 for now, we will ignore VL counters for now
BSWAP_STL_PORT_STATUS_REQ(p);
DBGPRINT("Sending STL PM Get(PortStatus %d) to LID 0x%04x Node 0x%016"PRIx64"\n",
portNum, portp->pathp->DLID,
portp->nodep->NodeInfo.NodeGUID);
DBGPRINT(" Name: %.*s\n",
NODE_DESCRIPTION_ARRAY_SIZE,
(char*)portp->nodep->NodeDesc.NodeString);
fstatus = stl_pm_send_recv(port, portp, MMTHD_GET, STL_PM_ATTRIB_ID_PORT_STATUS,
0x01000000, &req, &resp);
if (FSUCCESS != fstatus)
goto fail;
BSWAP_STL_PORT_STATUS_RSP((STL_PORT_STATUS_RSP *)resp.PerfData);
*pPortStatus = *(STL_PORT_STATUS_RSP *)resp.PerfData;
DBGPRINT("SendPkts=0x%16"PRIx64"\n", pPortStatus->PortXmitPkts);
fail:
return fstatus;
}
/* Clear port counters issued to PMA at portp.
* portp is the port to issue the PMA request to (can be port 0,
* thought lastPortIndex MUST be 0 in this case - see below).
*
* If lastPortIndex > 0, then it's assumed portp is
* switch port 0, and send a ClearPortCounters for all ports up to lastPortIndex.
* Otherwise assume this is an HFI, and only clear the port at portp.
* Retry and handle redirection as needed
* If thresholds is non-NULL, only counters with non-zero threshold are cleared
* otherwise all counters are cleared
*/
FSTATUS STLPmClearPortCounters(struct omgt_port *port, PortData *portp, uint8 lastPortIndex,
uint32 counterselect)
{
STL_PERF_MAD req;
STL_PERF_MAD resp;
STL_CLEAR_PORT_STATUS* p = (STL_CLEAR_PORT_STATUS *)&(req.PerfData);
FSTATUS fstatus;
uint8_t i;
char debugStr[64] = {'\0'};
MemoryClear(&req, sizeof(req));
for (i = 0; i < (lastPortIndex / 64); ++i)
p->PortSelectMask[3 - i] = ~(0ULL);
if (lastPortIndex)
p->PortSelectMask[3 - i] = (1ULL<<(lastPortIndex + 1)) - 1; // All ports up to lastPortIndex masked.
else
p->PortSelectMask[3] = 1<<portp->PortNum; // HFI Case.
p->CounterSelectMask.AsReg32 = counterselect;
if (g_verbose_file) {
if (lastPortIndex)
sprintf(debugStr, "port range [%d-%d]", portp->PortNum, lastPortIndex);
else
sprintf(debugStr, "port %d", portp->PortNum);
}
DBGPRINT("Sending PM Set(PortStatus %s, Sel=0x%04x) to LID 0x%04x Node 0x%016"PRIx64"\n",
debugStr, p->CounterSelectMask.AsReg32, portp->pathp->DLID,
portp->nodep->NodeInfo.NodeGUID);
DBGPRINT(" Name: %.*s\n",
NODE_DESCRIPTION_ARRAY_SIZE,
(char*)portp->nodep->NodeDesc.NodeString);
BSWAP_STL_CLEAR_PORT_STATUS_REQ(p);
fstatus = stl_pm_send_recv(port, portp, MMTHD_SET, STL_PM_ATTRIB_ID_CLEAR_PORT_STATUS,
1<<24, &req, &resp);
if (FSUCCESS != fstatus) {
//DBGPRINT("stl_pm_send_recv fstatus=%s\n", iba_fstatus_msg(fstatus));
goto fail;
}
fail:
return fstatus;
}
#if !defined(VXWORKS) || defined(BUILD_DMC)
static FSTATUS dm_send_recv(struct omgt_port *port,
IB_PATH_RECORD *pathp,
uint32 attr,
uint32 modifier,
DM_MAD *mad)
{
FSTATUS fstatus;
struct omgt_mad_addr addr;
size_t recv_size;
memset(&addr, 0, sizeof(addr));
addr.lid = pathp->DLID;
if (pathp->u1.s.HopLimit == 1) {
if ((pathp->DGID.Type.Global.InterfaceID >> 40) == OUI_TRUESCALE)
addr.lid = pathp->DGID.Type.Global.InterfaceID & 0xFFFFFFFF;
}
addr.qpn = 1;
addr.qkey = QP1_WELL_KNOWN_Q_KEY;
addr.pkey = pathp->P_Key;
mad->common.BaseVersion = IB_BASE_VERSION;
mad->common.MgmtClass = MCLASS_DEV_MGT;
mad->common.ClassVersion = IB_DEV_MGT_CLASS_VERSION;
mad->common.mr.AsReg8 = 0;
mad->common.mr.s.Method = MMTHD_GET;
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
mad->common.TransactionID = (++g_transId) << 24;
#else
mad->common.TransactionID = (++g_transId) & 0xffffffff;
#endif
mad->common.AttributeID = attr;
mad->common.AttributeModifier = modifier;
// rest of fields should be ignored for a Get, zero'ed above
BSWAP_MAD_HEADER((MAD*)mad);
ASSERT(addr.lid);
recv_size = sizeof(*mad);
fstatus = omgt_send_recv_mad_no_alloc(port,
(uint8_t *)mad, sizeof(*mad),
&addr,
(uint8_t *)mad, &recv_size,
RESP_WAIT_TIME,
g_smaRetries-1);
BSWAP_MAD_HEADER((MAD*)mad);
if (FSUCCESS == fstatus && mad->common.u.NS.Status.AsReg16 != MAD_STATUS_SUCCESS) {
DBGPRINT("DMA response with bad status: 0x%x\n", mad->common.u.NS.Status.AsReg16);
fstatus = FERROR;
}
return fstatus;
}
FSTATUS DmGetIouInfo(struct omgt_port *port, IB_PATH_RECORD *pathp, IOUnitInfo *pIouInfo)
{
DM_MAD mad;
FSTATUS fstatus;
MemoryClear(&mad, sizeof(mad));
DBGPRINT("Sending DM Get(IouInfo) to LID 0x%04x\n", pathp->DLID);
fstatus = dm_send_recv(port, pathp, DM_ATTRIB_ID_IOUNIT_INFO, 0, &mad);
if (FSUCCESS != fstatus)
goto fail;
*pIouInfo = *(IOUnitInfo*)mad.DMData;
BSWAP_DM_IOUNIT_INFO(pIouInfo);
fail:
return fstatus;
}
FSTATUS DmGetIocProfile(struct omgt_port *port,
IB_PATH_RECORD *pathp,
uint8 slot,
IOC_PROFILE *pIocProfile)
{
DM_MAD mad;
FSTATUS fstatus;
MemoryClear(&mad, sizeof(mad));
DBGPRINT("Sending DM Get(IocProfile, %u) to LID 0x%04x\n", slot, pathp->DLID);
fstatus = dm_send_recv(port, pathp, DM_ATTRIB_ID_IOCONTROLLER_PROFILE, slot, &mad);
if (FSUCCESS != fstatus)
goto fail;
*pIocProfile = *(IOC_PROFILE*)mad.DMData;
BSWAP_DM_IOC_PROFILE(pIocProfile);
fail:
return fstatus;
}
/* last - first must be <= 3 */
FSTATUS DmGetServiceEntries(struct omgt_port *port,
IB_PATH_RECORD *pathp,
uint8 slot,
uint8 first,
uint8 last,
IOC_SERVICE *pIocServices)
{
DM_MAD mad;
FSTATUS fstatus;
IOC_SERVICE *p;
MemoryClear(&mad, sizeof(mad));
DBGPRINT("Sending DM Get(ServiceEntries, %u, %u-%u) to LID 0x%04x\n",
slot, first, last, pathp->DLID);
fstatus = dm_send_recv(port, pathp, DM_ATTRIB_ID_SERVICE_ENTRIES,
DM_ATTRIB_MODIFIER_SERVICE_ENTRIES(slot, first, last), &mad);
if (FSUCCESS != fstatus)
goto fail;
p = (IOC_SERVICE*)mad.DMData;
for (; first <= last; first++, pIocServices++,p++) {
*pIocServices = *p;
BSWAP_DM_IOC_SERVICE(pIocServices);
}
fail:
return fstatus;
}
#endif
FSTATUS InitSmaMkey(uint64 mkey)
{
g_mkey = mkey;
return FSUCCESS;
}
FSTATUS InitMad(EUI64 portguid, FILE *verbose_file)
{
g_verbose_file = verbose_file;
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
return registerUmadt(portguid, &g_umadtHandle);
#else
return FSUCCESS;
#endif
}
void DestroyMad(void)
{
#if defined(IB_STACK_IBACCESS) || defined(CAL_IBACCESS)
if (g_umadtHandle) {
flush_rcv(g_umadtHandle, FLUSH_WAIT_TIME);
(void)iba_umadt_deregister(g_umadtHandle);
}
#endif
}