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DRAMSpec - A DRAM Current and Timing Generator

If you use DRAMSpec in your research, we would appreciate a citation to:

A High-Level DRAM Timing, Power and Area Exploration Tool, O. Naji, A. Hansson, C. Weis, M. Jung, N. Wehn., IEEE International Conference on Embedded Computer Systems Architectures Modeling and Simulation (SAMOS), July, 2015, Samos Island, Greece, DOI

BibTeX:

@INPROCEEDINGS{DRAMSpec,
author={O. Naji and C. Weis and M. Jung and N. Wehn and A. Hansson},
booktitle={2015 International Conference on Embedded Computer Systems: Architectures, Modeling, and Simulation (SAMOS)},
title={A high-level DRAM timing, power and area exploration tool},
year={2015},
pages={149-156},
keywords={DRAM chips;energy conservation;logic design;memory architecture;microprocessor chips;DDR3;DRAMSpec;energy saving;mobile devices;open source high-level DRAM bank modeling tool;processor designers;servers;Computational modeling;Computer architecture;Delays;Integrated circuit modeling;Performance evaluation;Random access memory},
doi={10.1109/SAMOS.2015.7363670},
month={July},}

For more information about our other tools please visit: http://www.uni-kl.de/3d-dram/tools/

LICENSE

Copyright (c) 2015-2017, University of Kaiserslautern All rights reserved.

Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:

  1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.

  2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution.

  3. Neither the name of the copyright holder nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission.

THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

Author: Omar Naji, Matthias Jung, Christian Weis, Kamal Haddad, Andre Lucas Chinazzo

Installing

DRAMSpec requires some libraries from boost. If you do not have it or the version you have is older than the 1.58, please follow the first four (4) steps from their getting started section. After updating your boost version, make sure to link it properly in the project file.

DRAMSpec is built as a Qt Creator project, therefore requiring the qmake tool. If you do not have Qt installed, you can find it here. The current version of DRAMSpec is properly built by QMake version 3.0 and Qt version 5.2.1 or newer. You can check your QMake and Qt version using the following command:

    qmake --version

Cloning from github (recursive to get submodules!)

    git clone --recursive <URL>

Building DRAMSpec

  1. To be sure DRAMSpec repository was properly cloned, build and run the program in test mode either by using the script below or compiling and running the debug version of the program manually. If chosen to do manually, make sure you run the executable directly from within the directory build/debug!
    ./runTests.sh
  1. After getting the "No errors detected" message, you are ready to build DRAMSpec itself. To do that, simply run the buildDRAMSpec.sh script:
    ./buildDRAMSpec.sh

The executable is now available under build/release/ by the name dramspec.

Running DRAMSpec

The program expect as parameters (at least) one technology and one achitecture description files. The flags -t and -p precede the technology and architecture description files, respectively.

The optional -term flag will include the IO termination currents for read and write operations of the DRAM.

For more detailed information on timings, it is possible to print out all internal timing variables using the flag -internaltimings.

    ./build/release/dramspec -t <path/to/technologyfilename> -p <path/to/parameterfilename> [-term] [-internaltimings]

Examples:

    ./build/release/dramspec -t technology_input/techddr3_5x.json -p architecture_input/parddr3.json

It is also possible to run multiple input files at once:

    ./build/release/dramspec -t <t1.json> <t2.json> -p <p1.json> <p2.json> [-term] [-internaltimings]

Note: the number of technology and architecture description files must be equal.

Input Data

DRAM Technology related inputs

Parameter Description Unit
TechnologyNode Technology node (not used in any calculation). um
Vdd Main power supply voltage. V
Vpp Wordlines HIGH level voltage. V
WireResistance Wire resistance per length unit (Sheet resistance). Ohm/mm
WireCapacitance Wire capacitance per length unit (Sheet capacitance). fF/mm
CellCapacitance Total capacitance of a single cell. fF
CellResistance Total resistance of a single cell. KOhm
CellWidth Length in row direction of a single cell. um
CellHeight Length in column direction of a single cell. um
BitlineCapacitancePerCell Capacitance due to each cell connected to the local bitline. aF
BitlineResistancePerCell Resistance due to each cell connected to the local bitline. Ohm
WordlineCapacitancePerCell Capacitance due to each cell connected to the local wordline. aF
WordlineResistancePerCell Resistance due to each cell connected to the local wordline. Ohm
PrimarySenseAmpHeight Lenght in column direction of the primary sense amplifier. um
LocalWordlineDriverWitdh Lenght in row direction of the local wordline driver. um
LocalWordlineDriverResistance Output resistance of the local wordline driver. Ohm
RowDecoderWidth Length in row direction of the row address decoder. um
GlobalWordlineDriverResistance Output resistance of the global wordline driver. Ohm
SecondarySenseAmpCurrent Current sinked by the secondary sense amplifier. uA
WriteDriverResistance Output resistance of the write driver. Ohm
ColumnDecoderHeight Lenght in column direction of the column address decoder. um
CSLDriverResistance Output resistance of the column select line driver. Ohm
CSLLoadCapacitance Column select line capacitive load (LBL to GBL transistors gates). fF
GlobalDataLineDriverResistance Output resistance of the global dataline driver. Ohm
DQDriverHeight Length in column direction of the DQ driver. um
DQtoTSVWireLength Length of the wire from DQ main line to TSV connection. um
DQDriverResistance Output resistance of the DQ driver. Ohm
IDD2NFreqSlope Slope in relation to operating frequency of the precharge background current. mA/MHz
IDD2NTempAlpha Alpha coeff. (alpha * (exp(beta * (T - TRef)) - 1)) in relation to operating temperature of the precharge background current. mA
IDD2NTempBeta Beta coeff. (alpha * (exp(beta * (T - TRef)) - 1)) in relation to operating temperature of the precharge background current. C^-1
IDD2NRefTemp Ref. temperature (alpha * (exp(beta * (T - TRef)) - 1)) in relation to operating temperature of the precharge background current. C
IDD2NOffset Constant term of precharge background current. It is IDD2n at 0 MHz and TRef. mA
OCDCurrentSlope Slope of current sinked by the off-chip driver in relation to operating frequency. uA/MHz
FullySharedResourcesCurrent Current drawn by resources shared by all banks. For example, O/I interface, supply voltage generators and common control logic [5]. mA
SemiSharedResourcesCurrent Current drawn by resources shared by some* banks. For example, O/I interface, supply voltage generators and common control logic [5]. mA
nBanksPerSemiSharedResource *Number of banks that share each semi global resource. mA
TSVHeight Length in column direction of TSV area. um
AdditionalTRLLatency Added latency (tAL [2]) to tCAS resulting in tRL. cc
DriverEnableDelay Time interval between driving signal to active driver. ns
InOutSSADelay Signal delay from input to output of the secondary sense amplifier. ns
CommandDecoderDelay Clock wave pipeline delay for decode and fetch command in the same cycle it is registered. ns
IODelay I/O interface delay. ns
SSAPrechargeDelay Secondary sense amplifier precharge delay. ns
tWRMargin Security margin for Write Recovery. ns
EqualizerDelay Equalizer circuit enabling delay. ns
VppPumpsEfficiency (Optional) Efficiency of voltage pumps for Vpp, when existing. -

DRAM Architecture related inputs

Parameter Description Unit
DRAMType DRAM type. Currently only differenciates between DDR or SDR. -
3D Flag for 3D designs. ON means it is a 3D design. -
DLL Flag for the usage of Dealy-Locked Loop. ON means the DRAM uses DLL. -
ExternalVPP (Optional) Flag for the existance of external Vpp voltage source. YES/NO. -
ChannelSize Data storage capacity of a single channel. Gbit
NumberOfBanksPerChannel Total number of banks in a single channel. dimensionless
NumberOfHorizontalBanksPerChannel Number of banks in row direction. (Optional) dimensionless
NumberOfVerticalBanksPerChannel Number of banks in a column direction. (Optional) dimensionless
CellsPerSubarrayRow Number of cells in row direction in a subarray, including redundace. dimensionless
RedundantCellsPerSubarrayRow Number of redundant cells in row direction in a subarray. dimensionless
CellsPerSubarrayColumn Number of cells in column direction in a subarray, including redundance. dimensionless
RedundantCellsPerSubarrayColumn Number of redundant cells in column direction in a subarray. dimensionless
Interface Number of datalines of the IO bus. This number is the length of a single data word. bit
Prefetch Number of prefetched data words for a single read command (RD). dimensionless
Frequency Nominal Synchronous DRAM clock frequency. MHz
CoreFrequency DRAM Core clock frequency. Set to 0 (zero) for automatic calculation. MHz
TilesPerBank Number of tiles (subsections) of a single bank. dimensionless
PageSize Amount of data sensed after an bank activate command (ACT). KByte
PageSpanningFactor Percetange of page size sensed on a single bank tile. dimensionless
SubarrayToPageFactor Ratio between number of cells in a physical row and the page size. dimensionless
BitlineArchitecture Chosen architecture of bitlines. Can be either OPEN bitlines, or FOLDED bitlines. -
RetentionTime Minimum amout of time each and every cell must keep its information before being refreshed. ms
tREFI(base) Base average interval between two AREF commands (1X refresh mode, normal temperature). Please see [4] for reference. us
RefreshMode Base tREFI divider for effective tREFI [4]. Please use 1, 2, etc, for X1, X2, ect, refresh modes. dimensionless
Temperature Operating temperature of the device. C

Output Data

Timings [2]

Abbreviation Description Unit
Frequency Nominal Synchronous DRAM clock frequency. MHz
Core Frequency DRAM core clock frequency. MHz
Max Core Frequency Maximun DRAM core clock frequency. MHz
ESTIMATED ANALOG DELAYS
tRCD Row to Column command Delay. The time interval between row access and data ready at sense amplifiers. ns
tCL or tCAS Column Access Strobe delay. The time interval between column access command and the start of data return by the DRAM device(s). ns
tRAS Row Access Strobe delay. The time interval between a row access command and data restoration in a DRAM array. ns
tRP Row Precharge delay. The time interval that it takes for a DRAM array to be precharged for another row access. ns
tRC Row Cycle delay. The time interval between accesses to different rows in a bank. tRC = tRAS + tRP. ns
tRL Read Latency delay. tRL = tCL + tAL, where tAL is the Added Latency to column accesses. ns
tRTP Read to Precharge delay. The time interval between a read and a precharge command. ns
tCCD Column-to-Column Delay. The minimum intra-device column-to-column command timing, determined by internal prefetch length. ns
tWR Write Recovery delay. The minimum time interval between the end of write data burst and the start of a precharge command. ns
tRFC Refresh Cycle delay. The time interval between Refresh and Activation commands. ns
tREFI Refresh Interval. Average time interval in between Refresh commands. ns
ESTIMATED LATENCIES
(in minimum number of clock cycles)
tRCD Row to Column command Delay latency. The time interval between row access and data ready at sense amplifiers. cc
tCL or tCAS Column Access Strobe latency. The time interval between column access command and the start of data return by the DRAM device(s). cc
Core tCL or tCAS Column Access Strobe latency. The time interval between column access command and the start of data return by the DRAM device(s). Given in minimum number of clock cycles of the DRAM core. cc
tRAS Row Access Strobe latency. The time interval between a row access command and data restoration in a DRAM array. cc
tRP Row Precharge latency. The time interval that it takes for a DRAM array to be precharged for another row access. cc
tRC Row Cycle latency. The time interval between accesses to different rows in a bank. tRC = tRAS + tRP. cc
tRL Read Latency latency. tRL = tCL + tAL, where tAL is the Added Latency to column accesses. cc
Core tRL Read Latency latency. tRL = tCL + tAL, where tAL is the Added Latency to column accesses. Given in minimum number of clock cycles of the DRAM core. cc
tRTP Read to Precharge latency. The time interval between a read and a precharge command. cc
tCCD Column-to-Column Delay latency. The minimum intra-device column-to-column command timing, determined by internal prefetch length. cc
Core tCCD Column-to-Column Delay latency. The minimum intra-device column-to-column command timing, determined by internal prefetch length. Given in minimum number of clock cycles of the DRAM core. cc
tWR Write Recovery latency. The minimum time interval between the end of write data burst and the start of a precharge command. cc
tRFC Refresh Cycle latency. The time interval between Refresh and Activation commands. cc
tREFI Refresh Interval latency. Average time interval in between Refresh commands. cc

Currents [3, 4, 5]

Abbreviation Description Unit
IDD0 Operating One Bank Active-Precharge Current. mA
IDD1 Operating One Bank Active-Read-Precharge Current. mA
IDD2N Precharge Standby Current mA
IDD3N Active Standby Current mA
Rho [5] Ratio of (IDD3N - IDD2N) which is independent on number of active banks -
IDD4R Operating Burst Read Current mA
IDD4W Operating Burst Write Current mA
IDD5B Burst Refresh Current mA

Physical sizings

Parameter Description Unit
Subarray height Height (column direction) of one subarray including sense amplifier. um
Subarray width Width (row direction) of one subarray including local wordline driver. um
Tile height Height (column direction) of one tile (bank subsection) including column address decoder. um
Tile width Width (row direction) of one tile (bank subsection) including row address decoder. um
Bank height Height (column direction) of one bank including DQ driver. um
Bank width Width (row direction) of one bank. um
Channel height Height (column direction) of one channel including TSV if 3D design. um
Channel width Width (row direction) of one channel. um
Channel area Area of one channel. (mm)^2

Reference

[1] A High-Level DRAM Timing, Power and Area Exploration Tool, O. Naji, A. Hansson, C. Weis, M. Jung, N. Wehn, IEEE International Conference on Embedded Computer Systems Architectures Modeling and Simulation (SAMOS), July, 2015, Samos Island, Greece, DOI

[2] Memory Systems: Cache, DRAM, Disk, B. Jacob, S. Ng and D. Wang, Morgan Kaufmann, 2007

[3] DDR3 SDRAM standard (revision F), JEDEC, July 2012.

[4] DDR4 SDRAM standard (revision B), JEDEC, June 2017.

[5] A New Bank Sensitive DRAMPower Model for Efficient Design Space Exploration, M. Jung, D. Mathew, É. Zulian, C. Weis, N. Wehn, IEEE International Workshop on Power and Timing Modeling, Optimization and Simulation (PATMOS), Sept., 2016, Bremen, Germany.

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