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/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/import/generic/memory/lib/utils/mss_rank.H $ */
/* */
/* OpenPOWER HostBoot Project */
/* */
/* Contributors Listed Below - COPYRIGHT 2019 */
/* [+] International Business Machines Corp. */
/* */
/* */
/* Licensed under the Apache License, Version 2.0 (the "License"); */
/* you may not use this file except in compliance with the License. */
/* You may obtain a copy of the License at */
/* */
/* http://www.apache.org/licenses/LICENSE-2.0 */
/* */
/* Unless required by applicable law or agreed to in writing, software */
/* distributed under the License is distributed on an "AS IS" BASIS, */
/* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or */
/* implied. See the License for the specific language governing */
/* permissions and limitations under the License. */
/* */
/* IBM_PROLOG_END_TAG */
///
/// @file mss_rank.H
/// @brief Tools to obtain rank info from DIMM or PORT target
///
// *HWP HWP Owner: Mark Pizzutillo <Mark.Pizzutillo@ibm.com>
// *HWP HWP Backup: Stephen Glancy <sglancy@us.ibm.com>
// *HWP Team: Memory
// *HWP Level: 2
// *HWP Consumed by: HB:FSP
#ifndef _MSS_GENERIC_RANK_H_
#define _MSS_GENERIC_RANK_H_
#include <fapi2.H>
#include <generic/memory/lib/utils/pos.H>
#include <generic/memory/lib/utils/find.H>
#include <generic/memory/lib/mss_generic_attribute_getters.H>
#include <generic/memory/lib/utils/shared/mss_generic_consts.H>
namespace mss
{
namespace rank
{
///
/// @brief Rank traits class for variations depending on MC
///
template <mss::mc_type MC = DEFAULT_MC_TYPE>
class rankTraits;
///
/// @brief Rank info class
///
template <mss::mc_type MC = DEFAULT_MC_TYPE, typename TT = rankTraits<MC>>
class info
{
public:
// Delete default constructor
info() = delete;
///
/// @brief Constructor for info object
/// @param[in] i_target DIMM target
/// @param[in] i_index dimm rank index 0-3
/// @param[out] o_rc return code, FAPI2_RC_SUCCESS if no error
///
info(const fapi2::Target<fapi2::TARGET_TYPE_DIMM>& i_dimm_target, const uint8_t i_index, fapi2::ReturnCode& o_rc)
{
o_rc = fapi2::FAPI2_RC_SUCCESS;
uint8_t l_master_ranks_per_dimm = 0;
FAPI_TRY(mss::attr::get_num_master_ranks_per_dimm(i_dimm_target, l_master_ranks_per_dimm));
FAPI_ASSERT((i_index < l_master_ranks_per_dimm),
fapi2::MSS_RANK_OUT_OF_RANGE()
.set_TARGET(i_dimm_target)
.set_RANK(i_index),
"Rank %u provided to info constructor for DIMM %s exceeded the number of master ranks per DIMM",
i_index, mss::c_str(i_dimm_target));
// Targets
iv_dimm_target = i_dimm_target;
iv_port_target = mss::find_target<DEFAULT_MEM_PORT_TARGET>(i_dimm_target);
// Ranks
iv_dimm_rank = i_index;
iv_port_rank = iv_dimm_rank + ((mss::relative_pos<DEFAULT_MEM_PORT_TARGET>(i_dimm_target) * TT::RANK_INDEX_STEP));
fapi_try_exit:
o_rc = fapi2::current_err;
}
///
/// @brief Constructor for info object
/// @param[in] i_target PORT target
/// @param[in] i_index port rank index 0-7
/// @param[out] o_rc return code, FAPI2_RC_SUCCESS if no error
///
info(const fapi2::Target<DEFAULT_MEM_PORT_TARGET>& i_port_target, const uint8_t i_index, fapi2::ReturnCode& o_rc)
{
o_rc = fapi2::FAPI2_RC_SUCCESS;
// Dimm Target
const uint8_t l_target_index = i_index / TT::RANK_INDEX_STEP;
const auto l_dimms = mss::find_targets<fapi2::TARGET_TYPE_DIMM>(i_port_target);
// This assumes that the mc_type max # of dimms per port is correct
FAPI_ASSERT( !l_dimms.empty(),
fapi2::MSS_EMPTY_VECTOR().
set_FUNCTION(INIT_RANK_INFO).
set_TARGET(i_port_target),
"Empty dimm vector received on port %s",
mss::spd::c_str(i_port_target));
{
// This will remain false in two cases:
// Either:
// 1. The corresponding DIMM index is out of range (caused by port index out of range)
// 2. The corresponding DIMMs master_ranks_per_dimm is less than the desired rank
bool l_valid_rank = false;
for (const auto& l_dimm : l_dimms)
{
// Since we can't guarantee the order of the returned dimms, we iterate through until we (might) find
// the right one. There's a chance it may not exist for example given info(port, rank13) would give us
// a dimm index above 2, which may be out of range, so we could never find a matching dimm, so we will
// throw that error.
// If we do find the right dimm, we need to then make sure that the master_ranks_per_dimm attribute
// is greater than the expected dimm rank.
if (mss::relative_pos<DEFAULT_MEM_PORT_TARGET>(l_dimm) == l_target_index)
{
uint8_t l_master_ranks_per_dimm = 0;
FAPI_TRY(mss::attr::get_num_master_ranks_per_dimm(l_dimm, l_master_ranks_per_dimm));
// The rank passed in matches one of a valid DIMM
l_valid_rank = (i_index % TT::RANK_INDEX_STEP) < l_master_ranks_per_dimm;
iv_dimm_target = l_dimm;
}
}
FAPI_ASSERT(l_valid_rank,
fapi2::MSS_RANK_OUT_OF_RANGE()
.set_TARGET(i_port_target)
.set_RANK(i_index),
"Rank %u provided to rank_info constructor for PORT %s was out of range",
i_index, mss::c_str(i_port_target));
// Port Target
iv_port_target = i_port_target;
// Ranks
iv_dimm_rank = i_index % TT::RANK_INDEX_STEP;
iv_port_rank = i_index;
}
fapi_try_exit:
o_rc = fapi2::current_err;
}
///
/// @brief Accessor for port rank
/// @return the number (0-7) of the rank within its port
///
inline const uint8_t get_port_rank() const
{
return iv_port_rank;
}
///
/// @brief Accessor for rank number of DIMM
/// @return the number (0-3) of the DIMM
///
inline const uint8_t get_dimm_rank() const
{
return iv_dimm_rank;
}
///
/// @brief Accessor for DIMM target
/// @return the dimm target associated with the rank
///
inline const fapi2::Target<fapi2::TARGET_TYPE_DIMM> get_dimm_target() const
{
return iv_dimm_target;
}
///
/// @brief Accessor for PORT target
/// @return the port target associated with the rank
///
inline const fapi2::Target<DEFAULT_MEM_PORT_TARGET> get_port_target() const
{
return iv_port_target;
}
private:
fapi2::Target<fapi2::TARGET_TYPE_DIMM> iv_dimm_target;
fapi2::Target<DEFAULT_MEM_PORT_TARGET> iv_port_target;
uint8_t iv_dimm_rank;
uint8_t iv_port_rank;
};
///
/// @brief Obtains all DIMM ranks on a given port target
/// @param[in] i_port_target port target
/// @param[out] o_vect vector of ranks
/// @return FAPI2_RC_SUCCESS iff success
///
template <mss::mc_type MC = DEFAULT_MC_TYPE, typename TT = rankTraits<MC>>
fapi2::ReturnCode ranks_on_port(const fapi2::Target<DEFAULT_MEM_PORT_TARGET>& i_port_target,
std::vector<info<MC>>& o_vect)
{
o_vect.clear();
uint8_t l_master_ranks_per_dimm[TT::MAX_DIMMS_PER_PORT] = {0};
FAPI_TRY(mss::attr::get_num_master_ranks_per_dimm(i_port_target, l_master_ranks_per_dimm));
FAPI_ASSERT(((l_master_ranks_per_dimm[0] <= TT::MAX_RANKS_PER_DIMM) &&
(l_master_ranks_per_dimm[1] <= TT::MAX_RANKS_PER_DIMM)),
fapi2::MSS_TOO_MANY_PRIMARY_RANKS_ON_PORT()
.set_PORT_TARGET(i_port_target),
"Primary ranks on PORT %s exceeded %u",
mss::c_str(i_port_target),
TT::MAX_RANKS_PER_DIMM);
for (const auto& l_dimm : mss::find_targets<fapi2::TARGET_TYPE_DIMM>(i_port_target))
{
const uint8_t l_dimm_pos = mss::relative_pos<DEFAULT_MEM_PORT_TARGET>(l_dimm);
const uint8_t l_port_index_start = l_dimm_pos * TT::RANK_INDEX_STEP;
fapi2::ReturnCode l_rc = fapi2::FAPI2_RC_SUCCESS;
// For each rank index of the dimm from the port's perspective
for (uint8_t l_index = l_port_index_start; l_index < (l_port_index_start + l_master_ranks_per_dimm[l_dimm_pos]);
++l_index)
{
o_vect.push_back(mss::rank::info<>(i_port_target, l_index, l_rc));
FAPI_TRY(l_rc);
}
}
fapi_try_exit:
return fapi2::current_err;
}
///
/// @brief Obtains all ranks on a given DIMM target
/// @param[in] i_target DIMM target
/// @param[out] o_vect vector of ranks
/// @return FAPI2_RC_SUCCESS iff success
///
template <mss::mc_type MC = DEFAULT_MC_TYPE, typename TT = rankTraits<MC>>
fapi2::ReturnCode ranks_on_dimm(const fapi2::Target<fapi2::TARGET_TYPE_DIMM>& i_dimm_target,
std::vector<info<MC>>& o_vect)
{
o_vect.clear();
uint8_t l_master_ranks_per_dimm = 0;
FAPI_TRY(mss::attr::get_num_master_ranks_per_dimm(i_dimm_target, l_master_ranks_per_dimm));
FAPI_ASSERT(l_master_ranks_per_dimm <= TT::MAX_RANKS_PER_DIMM,
fapi2::MSS_TOO_MANY_PRIMARY_RANKS_ON_DIMM()
.set_RANK_COUNT(l_master_ranks_per_dimm)
.set_DIMM_TARGET(i_dimm_target),
"Seeing %d primary ranks on DIMM %s",
l_master_ranks_per_dimm,
mss::c_str(i_dimm_target));
{
// Return code for constructor call
fapi2::ReturnCode l_rc = fapi2::FAPI2_RC_SUCCESS;
// For each rank index from the dimm's perspective
for (uint8_t l_index = 0; l_index < l_master_ranks_per_dimm; l_index++)
{
o_vect.push_back(mss::rank::info<>(i_dimm_target, l_index, l_rc));
FAPI_TRY(l_rc, "ranks_on_dimm(): Error in rank::info constructor call for DIMM %s and rank %u",
mss::c_str(i_dimm_target), l_index);
}
}
return fapi2::FAPI2_RC_SUCCESS;
fapi_try_exit:
return fapi2::current_err;
}
} // rank
} // mss
#endif
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