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/* IBM_PROLOG_BEGIN_TAG */
/* This is an automatically generated prolog. */
/* */
/* $Source: src/import/generic/memory/lib/utils/mcbist/gen_mss_mcbist_address.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 gen_mss_mcbist_address.H
/// @brief Class for mcbist related addresses (addresses below the hash translation)
///
// *HWP HWP Owner: Stephen Glancy <sglancy@us.ibm.com>
// *HWP HWP Backup: Andre Marin <aamarin@us.ibm.com>
// *HWP Team: Memory
// *HWP Level: 3
// *HWP Consumed by: HB:FSP
#ifndef _GEN_MSS_MCBIST_ADDRESS_H_
#define _GEN_MSS_MCBIST_ADDRESS_H_
#include <fapi2.H>
#include <utility>
#include <generic/memory/lib/ecc/ecc_traits.H>
namespace mss
{
namespace mcbist
{
///
/// @class address
/// @brief Represents a physical address in memory
/// @note
/// 0:1 port select
/// 2 dimm select
/// 3:4 mrank(0 to 1)
/// 5:7 srank(0 to 2)
/// 8:25 row(0 to 17)
/// 26:32 col(3 to 9)
/// 33:35 bank(0 to 2)
/// 36:37 bank_group(0 to 1)
///
class address
{
public:
// How far over we shift to align the address in either the register or a buffer
static constexpr uint64_t MAGIC_PAD = 26;
// first is the start bit of the field, second is the length
using field = std::pair<uint64_t, uint64_t>;
constexpr static field PORT = {0, 2};
constexpr static field DIMM = {2, 1};
constexpr static field MRANK = {3, 2};
constexpr static field SRANK = {5, 3};
constexpr static field ROW = {8, 18};
constexpr static field COL = {26, 7};
constexpr static field BANK = {33, 3};
constexpr static field BANK_GROUP = {36, 2};
constexpr static field LAST_VALID = BANK_GROUP;
///
/// @brief default ctor
///
address() = default;
// Used when accessing an integral value containing a port and DIMM combination
static constexpr uint64_t DIMM_BIT = 63;
static constexpr uint64_t PORT_START = 61;
static constexpr uint64_t PORT_LEN = 2;
///
/// @brief Construct an address from a uint64_t
/// @param[in] i_value representing an address
///
address( const uint64_t i_value ):
iv_address(i_value << MAGIC_PAD)
{
}
///
/// @brief Conversion operator to uint64_t
/// @warn Right-aligns the address
///
inline operator uint64_t() const
{
return iv_address >> MAGIC_PAD;
}
///
/// @brief Set a field for an address
/// @tparam F the field to set
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
template< const field& F >
inline address& set_field( const uint64_t i_value )
{
iv_address.insertFromRight<F.first, F.second>(i_value);
return *this;
}
///
/// @brief Get a field from an address
/// @tparam F the field to get
/// @return right-aligned uint64_t representing the value
///
template< const field& F >
inline uint64_t get_field() const
{
uint64_t l_value = 0;
iv_address.extractToRight<F.first, F.second>(l_value);
return l_value;
}
///
/// @brief Get a range of addresses.
/// @tparam[in] F the left-most valid field. So, if the address was for master rank,
/// the left-most valid field would be MRANK
/// @param[out] o_end representing an address to end at
/// @note this pointer is the start address
///
template< const field& F >
inline void get_range( address& o_end ) const
{
constexpr uint64_t START = F.first + F.second;
constexpr uint64_t LEN = (LAST_VALID.first + LAST_VALID.second) - START;
// All we need to do is fill in the bits to the right of the last valid field
o_end.iv_address = iv_address;
o_end.iv_address.setBit<START, LEN>();
}
///
/// @brief Get an end address for sim mode
/// @param[out] o_end representing an address to end at
/// @note this pointer is the start address
///
inline void get_sim_end_address( address& o_end ) const
{
// This magic number represents a range of addresses which cover all
// cache lines the training algorithms touch. By effecting 0 - this end
// address you'll effect everything which has bad ECC in the sim.
// TODO: this will have to change for explorer. it's algorithm dependent.
// we'll need to talk to the microchip about this
constexpr uint64_t l_magic_sim_number = 0b1000000;
get_range<COL>(o_end);
o_end.set_column(l_magic_sim_number);
return;
}
///
/// @brief Get a range of addresses given a master rank
/// @param[in] i_start representing an address to start from
/// @param[out] o_end representing an address to end at
///
inline static void get_mrank_range( const address& i_start, address& o_end )
{
i_start.get_range<MRANK>(o_end);
}
///
/// @brief Get a range of addresses given a master rank
/// @param[in] i_port representing the port for the starting address
/// @param[in] i_dimm representing the dimm for the starting address
/// @param[in] i_mrank representing the master rank for the starting address
/// @param[out] o_start representing an address to start from
/// @param[out] o_end representing an address to end at
///
inline static void get_mrank_range( const uint64_t i_port,
const uint64_t i_dimm,
const uint64_t i_mrank,
address& o_start,
address& o_end )
{
o_start.set_port(i_port).set_dimm(i_dimm).set_master_rank(i_mrank);
get_mrank_range(o_start, o_end);
}
///
/// @brief Get a range of addresses given a slave rank
/// @param[in] i_start representing an address to start from
/// @param[out] o_end representing an address to end at
///
inline static void get_srank_range( const address& i_start, address& o_end )
{
i_start.get_range<SRANK>(o_end);
}
///
/// @brief Get a range of addresses given a slave rank
/// @param[in] i_port representing the port for the starting address
/// @param[in] i_dimm representing the dimm for the starting address
/// @param[in] i_mrank representing the master rank for the starting address
/// @param[in] i_srank representing the slave rank for the starting address
/// @param[out] o_start representing an address to start from
/// @param[out] o_end representing an address to end at
///
inline static void get_srank_range( const uint64_t i_port, const uint64_t i_dimm,
const uint64_t i_mrank, const uint64_t i_srank,
address& o_start,
address& o_end )
{
o_start.set_port(i_port).set_dimm(i_dimm).set_master_rank(i_mrank).set_slave_rank(i_srank);
get_srank_range(o_start, o_end);
}
///
/// @brief Set the port value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
inline address& set_port( const uint64_t i_value )
{
return set_field<PORT>(i_value);
}
///
/// @brief Get the port value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_port() const
{
return get_field<PORT>();
}
///
/// @brief Set the DIMM value for an address
/// @param[in] i_value the value to set
/// @note 0 is the DIMM[0] != 0 is DIMM[1]
/// @return address& for method chaining
///
inline address& set_dimm( const uint64_t i_value )
{
return set_field<DIMM>(i_value);
}
///
/// @brief Get the DIMM value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_dimm() const
{
return get_field<DIMM>();
}
///
/// @brief Set the port and DIMM value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
/// @note Useful for indexing all ports/DIMM on a controller
///
inline address& set_port_dimm( const fapi2::buffer<uint64_t> i_value )
{
uint64_t l_read_port = 0;
i_value.extractToRight<PORT_START, PORT_LEN>(l_read_port);
return set_dimm(i_value.getBit<DIMM_BIT>()).set_port(l_read_port);
}
///
/// @brief Get the port and DIMM value for an address
/// @return right-aligned uint64_t representing the value
/// @note Useful for indexing all ports/DIMM on a controller
///
inline uint64_t get_port_dimm() const
{
fapi2::buffer<uint64_t> l_value;
l_value.insertFromRight<PORT_START, PORT_LEN>(get_port());
l_value.writeBit<DIMM_BIT>(get_dimm());
return l_value;
}
///
/// @brief Set the master rank value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
inline address& set_master_rank( const uint64_t i_value )
{
return set_field<MRANK>(i_value);
}
///
/// @brief Get the master rank value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_master_rank() const
{
return get_field<MRANK>();
}
///
/// @brief Set the slave rank value for an address
/// @param[in] i_value the value to set
///
inline void set_slave_rank( const uint64_t i_value )
{
set_field<SRANK>(i_value);
}
///
/// @brief Get the slave rank value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_slave_rank() const
{
return get_field<SRANK>();
}
///
/// @brief Set the row value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
inline address& set_row( const uint64_t i_value )
{
return set_field<ROW>(i_value);
}
///
/// @brief Get the row value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_row() const
{
return get_field<ROW>();
}
///
/// @brief Set the column value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
inline address& set_column( const uint64_t i_value )
{
return set_field<COL>(i_value);
}
///
/// @brief Get the column value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_column() const
{
return get_field<COL>();
}
///
/// @brief Set the bank value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
inline address& set_bank( const uint64_t i_value )
{
return set_field<BANK>(i_value);
}
///
/// @brief Get the bank value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_bank() const
{
return get_field<BANK>();
}
///
/// @brief Set the bank group value for an address
/// @param[in] i_value the value to set
/// @return address& for method chaining
///
inline address& set_bank_group( const uint64_t i_value )
{
return set_field<BANK_GROUP>(i_value);
}
///
/// @brief Get the bank group value for an address
/// @return right-aligned uint64_t representing the value
///
inline uint64_t get_bank_group() const
{
return get_field<BANK_GROUP>();
}
private:
// We use a fapi2 buffer as it has static compile-time support
fapi2::buffer<uint64_t> iv_address;
};
} // close namespace mcbist
} // close namespace mss
#endif
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