1oho.txt

sbc-bench v0.6.1 FriendlyElec NanoPi M4 (Thu, 04 Oct 2018 09:15:48 +0000)

Distributor ID:	Debian
Description:	Debian GNU/Linux 9.5 (stretch)
Release:	9.5
Codename:	stretch

Armbian release info:
BOARD=nanopim4
BOARD_NAME="Nanopi M4"
BOARDFAMILY=rk3399
VERSION=5.60
LINUXFAMILY=rk3399
BRANCH=default
ARCH=arm64
IMAGE_TYPE=stable
BOARD_TYPE=conf
INITRD_ARCH=arm64
KERNEL_IMAGE_TYPE=Image

/usr/bin/gcc (Debian 6.3.0-18+deb9u1) 6.3.0 20170516

Uptime: 09:15:48 up 4 min,  2 users,  load average: 0.99, 0.51, 0.21

Linux 4.4.156-rk3399 (nanopim4) 	10/04/18 	_aarch64_	(6 CPU)

avg-cpu:  %user   %nice %system %iowait  %steal   %idle
           6.08    0.00    1.50    0.46    0.00   91.95

Device:            tps    kB_read/s    kB_wrtn/s    kB_read    kB_wrtn
mmcblk0          21.73       883.46       558.90     261381     165356
zram0             2.84         2.49         8.87        736       2624
zram1             1.01         4.04         0.01       1196          4
zram2             1.01         4.04         0.01       1196          4
zram3             1.01         4.04         0.01       1196          4
zram4             1.01         4.04         0.01       1196          4

              total        used        free      shared  buff/cache   available
Mem:           919M         68M        467M        6.9M        384M        766M
Swap:          459M          0B        459M

Filename				Type		Size	Used	Priority
/dev/zram1                             	partition	117744	0	5
/dev/zram2                             	partition	117744	0	5
/dev/zram3                             	partition	117744	0	5
/dev/zram4                             	partition	117744	0	5

##########################################################################

Checking cpufreq OPP for cpu0-cpu3:

Cpufreq OPP: 1512    Measured: 1502.246/1503.383/1502.928
Cpufreq OPP: 1416    Measured: 1406.860/1406.967/1406.614
Cpufreq OPP: 1200    Measured: 1190.923/1191.225/1191.087
Cpufreq OPP: 1008    Measured: 998.820/999.291/999.026
Cpufreq OPP:  816    Measured: 806.878/806.987/807.036
Cpufreq OPP:  600    Measured: 591.280/590.983/590.838
Cpufreq OPP:  408    Measured: 399.537/399.448/399.660

Checking cpufreq OPP for cpu4-cpu5:

Cpufreq OPP: 1992    Measured: 1984.272/1985.468/1985.419
Cpufreq OPP: 1800    Measured: 1793.332/1793.511/1793.471
Cpufreq OPP: 1608    Measured: 1601.317/1601.535/1601.575
Cpufreq OPP: 1416    Measured: 1409.332/1409.624/1409.639
Cpufreq OPP: 1200    Measured: 1193.385/1193.702/1193.592
Cpufreq OPP: 1008    Measured: 1001.435/1001.702/1001.326
Cpufreq OPP:  816    Measured: 809.635/809.685/809.348
Cpufreq OPP:  600    Measured: 592.393/592.652/592.778
Cpufreq OPP:  408    Measured: 400.967/400.919/401.104

##########################################################################

Executing tinymembench on a little core:

tinymembench v0.4.9 (simple benchmark for memory throughput and latency)

==========================================================================
== Memory bandwidth tests                                               ==
==                                                                      ==
== Note 1: 1MB = 1000000 bytes                                          ==
== Note 2: Results for 'copy' tests show how many bytes can be          ==
==         copied per second (adding together read and writen           ==
==         bytes would have provided twice higher numbers)              ==
== Note 3: 2-pass copy means that we are using a small temporary buffer ==
==         to first fetch data into it, and only then write it to the   ==
==         destination (source -> L1 cache, L1 cache -> destination)    ==
== Note 4: If sample standard deviation exceeds 0.1%, it is shown in    ==
==         brackets                                                     ==
==========================================================================

 C copy backwards                                     :   1293.8 MB/s (0.5%)
 C copy backwards (32 byte blocks)                    :   1305.8 MB/s (0.4%)
 C copy backwards (64 byte blocks)                    :   1296.7 MB/s (0.4%)
 C copy                                               :   1296.2 MB/s (0.4%)
 C copy prefetched (32 bytes step)                    :   1007.2 MB/s
 C copy prefetched (64 bytes step)                    :   1151.3 MB/s
 C 2-pass copy                                        :   1175.6 MB/s (0.2%)
 C 2-pass copy prefetched (32 bytes step)             :    842.6 MB/s
 C 2-pass copy prefetched (64 bytes step)             :    658.2 MB/s (0.1%)
 C fill                                               :   4636.0 MB/s
 C fill (shuffle within 16 byte blocks)               :   4635.6 MB/s (0.3%)
 C fill (shuffle within 32 byte blocks)               :   4634.0 MB/s
 C fill (shuffle within 64 byte blocks)               :   4636.5 MB/s
 ---
 standard memcpy                                      :   1342.6 MB/s
 standard memset                                      :   4634.5 MB/s
 ---
 NEON LDP/STP copy                                    :   1346.7 MB/s
 NEON LDP/STP copy pldl2strm (32 bytes step)          :    940.3 MB/s (0.7%)
 NEON LDP/STP copy pldl2strm (64 bytes step)          :   1144.1 MB/s
 NEON LDP/STP copy pldl1keep (32 bytes step)          :   1514.0 MB/s
 NEON LDP/STP copy pldl1keep (64 bytes step)          :   1515.6 MB/s
 NEON LD1/ST1 copy                                    :   1339.3 MB/s (0.2%)
 NEON STP fill                                        :   4638.6 MB/s
 NEON STNP fill                                       :   1487.1 MB/s (2.2%)
 ARM LDP/STP copy                                     :   1347.4 MB/s
 ARM STP fill                                         :   4637.8 MB/s
 ARM STNP fill                                        :   1485.9 MB/s (1.8%)

==========================================================================
== Framebuffer read tests.                                              ==
==                                                                      ==
== Many ARM devices use a part of the system memory as the framebuffer, ==
== typically mapped as uncached but with write-combining enabled.       ==
== Writes to such framebuffers are quite fast, but reads are much       ==
== slower and very sensitive to the alignment and the selection of      ==
== CPU instructions which are used for accessing memory.                ==
==                                                                      ==
== Many x86 systems allocate the framebuffer in the GPU memory,         ==
== accessible for the CPU via a relatively slow PCI-E bus. Moreover,    ==
== PCI-E is asymmetric and handles reads a lot worse than writes.       ==
==                                                                      ==
== If uncached framebuffer reads are reasonably fast (at least 100 MB/s ==
== or preferably >300 MB/s), then using the shadow framebuffer layer    ==
== is not necessary in Xorg DDX drivers, resulting in a nice overall    ==
== performance improvement. For example, the xf86-video-fbturbo DDX     ==
== uses this trick.                                                     ==
==========================================================================

 NEON LDP/STP copy (from framebuffer)                 :    202.2 MB/s
 NEON LDP/STP 2-pass copy (from framebuffer)          :    184.1 MB/s
 NEON LD1/ST1 copy (from framebuffer)                 :     49.9 MB/s
 NEON LD1/ST1 2-pass copy (from framebuffer)          :     48.2 MB/s
 ARM LDP/STP copy (from framebuffer)                  :     99.6 MB/s
 ARM LDP/STP 2-pass copy (from framebuffer)           :     95.4 MB/s

==========================================================================
== Memory latency test                                                  ==
==                                                                      ==
== Average time is measured for random memory accesses in the buffers   ==
== of different sizes. The larger is the buffer, the more significant   ==
== are relative contributions of TLB, L1/L2 cache misses and SDRAM      ==
== accesses. For extremely large buffer sizes we are expecting to see   ==
== page table walk with several requests to SDRAM for almost every      ==
== memory access (though 64MiB is not nearly large enough to experience ==
== this effect to its fullest).                                         ==
==                                                                      ==
== Note 1: All the numbers are representing extra time, which needs to  ==
==         be added to L1 cache latency. The cycle timings for L1 cache ==
==         latency can be usually found in the processor documentation. ==
== Note 2: Dual random read means that we are simultaneously performing ==
==         two independent memory accesses at a time. In the case if    ==
==         the memory subsystem can't handle multiple outstanding       ==
==         requests, dual random read has the same timings as two       ==
==         single reads performed one after another.                    ==
==========================================================================

block size : single random read / dual random read, [MADV_NOHUGEPAGE]
      1024 :    0.0 ns          /     0.0 ns 
      2048 :    0.0 ns          /     0.0 ns 
      4096 :    0.0 ns          /     0.0 ns 
      8192 :    0.0 ns          /     0.0 ns 
     16384 :    0.0 ns          /     0.0 ns 
     32768 :    0.1 ns          /     0.1 ns 
     65536 :    4.6 ns          /     7.7 ns 
    131072 :    7.0 ns          /    10.7 ns 
    262144 :    8.3 ns          /    11.9 ns 
    524288 :   15.0 ns          /    21.1 ns 
   1048576 :  102.6 ns          /   155.5 ns 
   2097152 :  147.0 ns          /   192.7 ns 
   4194304 :  172.7 ns          /   210.0 ns 
   8388608 :  186.0 ns          /   218.4 ns 
  16777216 :  194.8 ns          /   224.4 ns 
  33554432 :  199.0 ns          /   228.8 ns 
  67108864 :  201.8 ns          /   233.3 ns 

block size : single random read / dual random read, [MADV_HUGEPAGE]
      1024 :    0.0 ns          /     0.0 ns 
      2048 :    0.0 ns          /     0.0 ns 
      4096 :    0.0 ns          /     0.0 ns 
      8192 :    0.0 ns          /     0.0 ns 
     16384 :    0.0 ns          /     0.0 ns 
     32768 :    0.1 ns          /     0.1 ns 
     65536 :    4.6 ns          /     7.7 ns 
    131072 :    7.0 ns          /    10.7 ns 
    262144 :    8.3 ns          /    12.0 ns 
    524288 :   14.9 ns          /    21.3 ns 
   1048576 :  102.6 ns          /   155.4 ns 
   2097152 :  145.9 ns          /   191.6 ns 
   4194304 :  167.3 ns          /   202.8 ns 
   8388608 :  178.6 ns          /   206.7 ns 
  16777216 :  184.3 ns          /   208.2 ns 
  33554432 :  187.1 ns          /   208.8 ns 
  67108864 :  188.5 ns          /   209.1 ns 

Executing tinymembench on a big core:

tinymembench v0.4.9 (simple benchmark for memory throughput and latency)

==========================================================================
== Memory bandwidth tests                                               ==
==                                                                      ==
== Note 1: 1MB = 1000000 bytes                                          ==
== Note 2: Results for 'copy' tests show how many bytes can be          ==
==         copied per second (adding together read and writen           ==
==         bytes would have provided twice higher numbers)              ==
== Note 3: 2-pass copy means that we are using a small temporary buffer ==
==         to first fetch data into it, and only then write it to the   ==
==         destination (source -> L1 cache, L1 cache -> destination)    ==
== Note 4: If sample standard deviation exceeds 0.1%, it is shown in    ==
==         brackets                                                     ==
==========================================================================

 C copy backwards                                     :   2227.1 MB/s
 C copy backwards (32 byte blocks)                    :   2226.4 MB/s
 C copy backwards (64 byte blocks)                    :   2207.0 MB/s
 C copy                                               :   2241.7 MB/s
 C copy prefetched (32 bytes step)                    :   2223.8 MB/s
 C copy prefetched (64 bytes step)                    :   2221.9 MB/s
 C 2-pass copy                                        :   2045.3 MB/s
 C 2-pass copy prefetched (32 bytes step)             :   2059.3 MB/s
 C 2-pass copy prefetched (64 bytes step)             :   2056.9 MB/s
 C fill                                               :   4766.9 MB/s (0.3%)
 C fill (shuffle within 16 byte blocks)               :   4767.3 MB/s
 C fill (shuffle within 32 byte blocks)               :   4765.3 MB/s
 C fill (shuffle within 64 byte blocks)               :   4765.5 MB/s
 ---
 standard memcpy                                      :   2255.1 MB/s
 standard memset                                      :   4768.0 MB/s (0.3%)
 ---
 NEON LDP/STP copy                                    :   2261.1 MB/s
 NEON LDP/STP copy pldl2strm (32 bytes step)          :   2256.4 MB/s (0.5%)
 NEON LDP/STP copy pldl2strm (64 bytes step)          :   2255.7 MB/s
 NEON LDP/STP copy pldl1keep (32 bytes step)          :   2223.0 MB/s
 NEON LDP/STP copy pldl1keep (64 bytes step)          :   2222.3 MB/s
 NEON LD1/ST1 copy                                    :   2259.8 MB/s
 NEON STP fill                                        :   4766.1 MB/s (0.3%)
 NEON STNP fill                                       :   4738.0 MB/s (0.1%)
 ARM LDP/STP copy                                     :   2261.1 MB/s
 ARM STP fill                                         :   4766.4 MB/s (0.3%)
 ARM STNP fill                                        :   4738.0 MB/s

==========================================================================
== Framebuffer read tests.                                              ==
==                                                                      ==
== Many ARM devices use a part of the system memory as the framebuffer, ==
== typically mapped as uncached but with write-combining enabled.       ==
== Writes to such framebuffers are quite fast, but reads are much       ==
== slower and very sensitive to the alignment and the selection of      ==
== CPU instructions which are used for accessing memory.                ==
==                                                                      ==
== Many x86 systems allocate the framebuffer in the GPU memory,         ==
== accessible for the CPU via a relatively slow PCI-E bus. Moreover,    ==
== PCI-E is asymmetric and handles reads a lot worse than writes.       ==
==                                                                      ==
== If uncached framebuffer reads are reasonably fast (at least 100 MB/s ==
== or preferably >300 MB/s), then using the shadow framebuffer layer    ==
== is not necessary in Xorg DDX drivers, resulting in a nice overall    ==
== performance improvement. For example, the xf86-video-fbturbo DDX     ==
== uses this trick.                                                     ==
==========================================================================

 NEON LDP/STP copy (from framebuffer)                 :    651.7 MB/s (0.2%)
 NEON LDP/STP 2-pass copy (from framebuffer)          :    564.8 MB/s (0.8%)
 NEON LD1/ST1 copy (from framebuffer)                 :    710.1 MB/s
 NEON LD1/ST1 2-pass copy (from framebuffer)          :    614.3 MB/s
 ARM LDP/STP copy (from framebuffer)                  :    464.3 MB/s
 ARM LDP/STP 2-pass copy (from framebuffer)           :    459.7 MB/s

==========================================================================
== Memory latency test                                                  ==
==                                                                      ==
== Average time is measured for random memory accesses in the buffers   ==
== of different sizes. The larger is the buffer, the more significant   ==
== are relative contributions of TLB, L1/L2 cache misses and SDRAM      ==
== accesses. For extremely large buffer sizes we are expecting to see   ==
== page table walk with several requests to SDRAM for almost every      ==
== memory access (though 64MiB is not nearly large enough to experience ==
== this effect to its fullest).                                         ==
==                                                                      ==
== Note 1: All the numbers are representing extra time, which needs to  ==
==         be added to L1 cache latency. The cycle timings for L1 cache ==
==         latency can be usually found in the processor documentation. ==
== Note 2: Dual random read means that we are simultaneously performing ==
==         two independent memory accesses at a time. In the case if    ==
==         the memory subsystem can't handle multiple outstanding       ==
==         requests, dual random read has the same timings as two       ==
==         single reads performed one after another.                    ==
==========================================================================

block size : single random read / dual random read, [MADV_NOHUGEPAGE]
      1024 :    0.0 ns          /     0.0 ns 
      2048 :    0.0 ns          /     0.0 ns 
      4096 :    0.0 ns          /     0.0 ns 
      8192 :    0.0 ns          /     0.0 ns 
     16384 :    0.0 ns          /     0.0 ns 
     32768 :    0.0 ns          /     0.0 ns 
     65536 :    4.1 ns          /     6.5 ns 
    131072 :    6.2 ns          /     8.7 ns 
    262144 :    8.9 ns          /    11.6 ns 
    524288 :   10.3 ns          /    13.3 ns 
   1048576 :   14.7 ns          /    20.3 ns 
   2097152 :  106.6 ns          /   161.8 ns 
   4194304 :  151.5 ns          /   203.0 ns 
   8388608 :  178.7 ns          /   224.7 ns 
  16777216 :  192.2 ns          /   233.4 ns 
  33554432 :  199.1 ns          /   238.9 ns 
  67108864 :  210.0 ns          /   252.7 ns 

block size : single random read / dual random read, [MADV_HUGEPAGE]
      1024 :    0.0 ns          /     0.0 ns 
      2048 :    0.0 ns          /     0.0 ns 
      4096 :    0.0 ns          /     0.0 ns 
      8192 :    0.0 ns          /     0.0 ns 
     16384 :    0.0 ns          /     0.0 ns 
     32768 :    0.0 ns          /     0.0 ns 
     65536 :    4.1 ns          /     6.5 ns 
    131072 :    6.1 ns          /     8.7 ns 
    262144 :    7.2 ns          /     9.5 ns 
    524288 :    7.7 ns          /     9.9 ns 
   1048576 :   11.4 ns          /    15.8 ns 
   2097152 :  105.0 ns          /   158.9 ns 
   4194304 :  149.6 ns          /   198.6 ns 
   8388608 :  171.2 ns          /   211.1 ns 
  16777216 :  181.5 ns          /   215.0 ns 
  33554432 :  187.1 ns          /   217.1 ns 
  67108864 :  189.9 ns          /   218.4 ns 

##########################################################################

OpenSSL 1.1.0f, built on 25 May 2017
type             16 bytes     64 bytes    256 bytes   1024 bytes   8192 bytes  16384 bytes
aes-128-cbc     103440.87k   326336.34k   684406.61k   980143.45k  1119739.90k  1129392.81k
aes-128-cbc     320614.86k   813931.41k  1240112.47k  1393840.47k  1487680.85k  1493325.14k
aes-192-cbc      98814.58k   293838.83k   566120.53k   760456.19k   844024.49k   850673.66k
aes-192-cbc     311353.10k   779927.19k  1046739.97k  1241559.38k  1309461.16k  1305335.13k
aes-256-cbc      96426.95k   273432.85k   496017.83k   639114.24k   697297.58k   701573.80k
aes-256-cbc     300919.42k   720214.61k   992523.43k  1073237.67k  1123595.61k  1128863.06k

##########################################################################

7-Zip (a) [64] 16.02 : Copyright (c) 1999-2016 Igor Pavlov : 2016-05-21
p7zip Version 16.02 (locale=en_US.UTF-8,Utf16=on,HugeFiles=on,64 bits,6 CPUs LE)

LE
CPU Freq:  1499  1501  1498  1503  1503  1503  1503  1503  1503

RAM size:     919 MB,  # CPU hardware threads:   6
RAM usage:    675 MB,  # Benchmark threads:      6

                       Compressing  |                  Decompressing
Dict     Speed Usage    R/U Rating  |      Speed Usage    R/U Rating
         KiB/s     %   MIPS   MIPS  |      KiB/s     %   MIPS   MIPS

22:        730   100    711    711  |      16190   100   1381   1381
23:        704   100    718    718  |      15822   100   1369   1369
24:        676   100    727    727  |      15435   100   1355   1355
----------------------------------  | ------------------------------
Avr:             100    719    719  |              100   1368   1368
Tot:             100   1044   1043

7-Zip (a) [64] 16.02 : Copyright (c) 1999-2016 Igor Pavlov : 2016-05-21
p7zip Version 16.02 (locale=en_US.UTF-8,Utf16=on,HugeFiles=on,64 bits,6 CPUs LE)

LE
CPU Freq:  1983  1985  1985  1985  1985  1985  1985  1985  1985

RAM size:     919 MB,  # CPU hardware threads:   6
RAM usage:    675 MB,  # Benchmark threads:      6

                       Compressing  |                  Decompressing
Dict     Speed Usage    R/U Rating  |      Speed Usage    R/U Rating
         KiB/s     %   MIPS   MIPS  |      KiB/s     %   MIPS   MIPS

22:       1452   100   1414   1413  |      23559   100   2009   2009
23:       1385   100   1412   1412  |      23026   100   1993   1992
24:       1319   100   1419   1418  |      22486   100   1974   1974
----------------------------------  | ------------------------------
Avr:             100   1415   1415  |              100   1992   1992
Tot:             100   1703   1703

##########################################################################

7-Zip (a) [64] 16.02 : Copyright (c) 1999-2016 Igor Pavlov : 2016-05-21
p7zip Version 16.02 (locale=en_US.UTF-8,Utf16=on,HugeFiles=on,64 bits,6 CPUs LE)

LE
CPU Freq:  1443  1973  1980  1985  1985  1985  1985  1985  1985

RAM size:     919 MB,  # CPU hardware threads:   6
RAM usage:    675 MB,  # Benchmark threads:      6

                       Compressing  |                  Decompressing
Dict     Speed Usage    R/U Rating  |      Speed Usage    R/U Rating
         KiB/s     %   MIPS   MIPS  |      KiB/s     %   MIPS   MIPS

22:       4657   509    891   4531  |     101406   525   1646   8648
23:       4401   519    864   4485  |      98712   524   1629   8542
24:       4274   532    864   4596  |      95885   523   1608   8416
----------------------------------  | ------------------------------
Avr:             520    873   4537  |              524   1628   8535
Tot:             522   1250   6536

7-Zip (a) [64] 16.02 : Copyright (c) 1999-2016 Igor Pavlov : 2016-05-21
p7zip Version 16.02 (locale=en_US.UTF-8,Utf16=on,HugeFiles=on,64 bits,6 CPUs LE)

LE
CPU Freq:  1984  1985  1985  1985  1985  1985  1985  1985  1985

RAM size:     919 MB,  # CPU hardware threads:   6
RAM usage:    675 MB,  # Benchmark threads:      6

                       Compressing  |                  Decompressing
Dict     Speed Usage    R/U Rating  |      Speed Usage    R/U Rating
         KiB/s     %   MIPS   MIPS  |      KiB/s     %   MIPS   MIPS

22:       4639   507    889   4513  |     101094   522   1650   8621
23:       4387   517    864   4470  |      98571   523   1631   8529
24:       4016   492    878   4319  |      96203   524   1611   8444
----------------------------------  | ------------------------------
Avr:             506    877   4434  |              523   1631   8532
Tot:             514   1254   6483

7-Zip (a) [64] 16.02 : Copyright (c) 1999-2016 Igor Pavlov : 2016-05-21
p7zip Version 16.02 (locale=en_US.UTF-8,Utf16=on,HugeFiles=on,64 bits,6 CPUs LE)

LE
CPU Freq:  1983  1985  1984  1985  1985  1985  1985  1985  1985

RAM size:     919 MB,  # CPU hardware threads:   6
RAM usage:    675 MB,  # Benchmark threads:      6

                       Compressing  |                  Decompressing
Dict     Speed Usage    R/U Rating  |      Speed Usage    R/U Rating
         KiB/s     %   MIPS   MIPS  |      KiB/s     %   MIPS   MIPS

22:       4603   509    880   4478  |     101212   525   1645   8631
23:       4346   512    864   4428  |      98590   525   1624   8531
24:       4252   531    860   4572  |      96147   527   1601   8439
----------------------------------  | ------------------------------
Avr:             518    868   4493  |              526   1623   8534
Tot:             522   1246   6513

Compression: 4537,4434,4493
Decompression: 8535,8532,8534
Total: 6536,6483,6513

##########################################################################

** cpuminer-multi 1.3.3 by tpruvot@github **
BTC donation address: 1FhDPLPpw18X4srecguG3MxJYe4a1JsZnd (tpruvot)

[2018-10-04 09:39:47] 6 miner threads started, using 'scrypt' algorithm.
[2018-10-04 09:39:47] CPU #4: 2.07 kH/s
[2018-10-04 09:39:47] CPU #5: 2.07 kH/s
[2018-10-04 09:39:47] CPU #1: 1.14 kH/s
[2018-10-04 09:39:47] CPU #2: 1.14 kH/s
[2018-10-04 09:39:47] CPU #0: 1.14 kH/s
[2018-10-04 09:39:47] CPU #3: 1.12 kH/s
[2018-10-04 09:39:52] Total: 8.69 kH/s
[2018-10-04 09:39:57] CPU #4: 2.07 kH/s
[2018-10-04 09:39:57] CPU #5: 2.07 kH/s
[2018-10-04 09:39:57] Total: 8.71 kH/s
[2018-10-04 09:39:57] CPU #0: 1.14 kH/s
[2018-10-04 09:39:57] CPU #1: 1.15 kH/s
[2018-10-04 09:39:57] CPU #2: 1.15 kH/s
[2018-10-04 09:39:57] CPU #3: 1.13 kH/s
[2018-10-04 09:40:02] Total: 8.71 kH/s
[2018-10-04 09:40:07] CPU #4: 2.07 kH/s
[2018-10-04 09:40:07] CPU #5: 2.07 kH/s
[2018-10-04 09:40:07] Total: 8.71 kH/s
[2018-10-04 09:40:07] CPU #0: 1.14 kH/s
[2018-10-04 09:40:07] CPU #1: 1.15 kH/s
[2018-10-04 09:40:07] CPU #2: 1.15 kH/s
[2018-10-04 09:40:07] CPU #3: 1.13 kH/s
[2018-10-04 09:40:12] Total: 8.69 kH/s
[2018-10-04 09:40:17] CPU #4: 2.07 kH/s
[2018-10-04 09:40:17] CPU #5: 2.07 kH/s
[2018-10-04 09:40:17] Total: 8.71 kH/s
[2018-10-04 09:40:17] CPU #0: 1.14 kH/s
[2018-10-04 09:40:17] CPU #1: 1.15 kH/s
[2018-10-04 09:40:17] CPU #2: 1.15 kH/s
[2018-10-04 09:40:17] CPU #3: 1.13 kH/s
[2018-10-04 09:40:22] Total: 8.71 kH/s
[2018-10-04 09:40:27] CPU #4: 2.07 kH/s
[2018-10-04 09:40:27] CPU #5: 2.07 kH/s
[2018-10-04 09:40:27] Total: 8.71 kH/s
[2018-10-04 09:40:27] CPU #0: 1.14 kH/s
[2018-10-04 09:40:27] CPU #1: 1.15 kH/s
[2018-10-04 09:40:27] CPU #2: 1.15 kH/s
[2018-10-04 09:40:27] CPU #3: 1.13 kH/s
[2018-10-04 09:40:32] Total: 8.69 kH/s
[2018-10-04 09:40:37] CPU #4: 2.07 kH/s
[2018-10-04 09:40:37] CPU #5: 2.07 kH/s
[2018-10-04 09:40:37] Total: 8.71 kH/s
[2018-10-04 09:40:37] CPU #0: 1.14 kH/s
[2018-10-04 09:40:37] CPU #1: 1.15 kH/s
[2018-10-04 09:40:37] CPU #2: 1.15 kH/s
[2018-10-04 09:40:37] CPU #3: 1.13 kH/s
[2018-10-04 09:40:42] Total: 8.71 kH/s
[2018-10-04 09:40:47] CPU #4: 2.07 kH/s
[2018-10-04 09:40:47] CPU #5: 2.07 kH/s
[2018-10-04 09:40:47] Total: 8.71 kH/s
[2018-10-04 09:40:47] CPU #0: 1.14 kH/s
[2018-10-04 09:40:47] CPU #2: 1.15 kH/s
[2018-10-04 09:40:47] CPU #1: 1.15 kH/s
[2018-10-04 09:40:47] CPU #3: 1.13 kH/s
[2018-10-04 09:40:52] Total: 8.70 kH/s
[2018-10-04 09:40:57] CPU #4: 2.05 kH/s
[2018-10-04 09:40:57] CPU #5: 2.05 kH/s
[2018-10-04 09:40:57] Total: 8.68 kH/s
[2018-10-04 09:40:57] CPU #0: 1.14 kH/s
[2018-10-04 09:40:57] CPU #2: 1.15 kH/s
[2018-10-04 09:40:57] CPU #1: 1.15 kH/s
[2018-10-04 09:40:57] CPU #3: 1.13 kH/s
[2018-10-04 09:41:02] Total: 8.64 kH/s
[2018-10-04 09:41:07] CPU #4: 2.02 kH/s
[2018-10-04 09:41:07] CPU #0: 1.14 kH/s
[2018-10-04 09:41:07] CPU #5: 2.01 kH/s
[2018-10-04 09:41:07] Total: 8.60 kH/s
[2018-10-04 09:41:07] CPU #1: 1.15 kH/s
[2018-10-04 09:41:07] CPU #2: 1.15 kH/s
[2018-10-04 09:41:07] CPU #3: 1.13 kH/s
[2018-10-04 09:41:12] Total: 8.57 kH/s
[2018-10-04 09:41:17] CPU #0: 1.14 kH/s
[2018-10-04 09:41:17] CPU #1: 1.15 kH/s
[2018-10-04 09:41:17] CPU #2: 1.14 kH/s
[2018-10-04 09:41:17] CPU #3: 1.13 kH/s
[2018-10-04 09:41:17] CPU #4: 1.97 kH/s
[2018-10-04 09:41:17] CPU #5: 1.97 kH/s
[2018-10-04 09:41:17] Total: 8.51 kH/s
[2018-10-04 09:41:22] Total: 8.50 kH/s
[2018-10-04 09:41:27] CPU #0: 1.14 kH/s
[2018-10-04 09:41:27] CPU #1: 1.15 kH/s
[2018-10-04 09:41:27] CPU #2: 1.15 kH/s
[2018-10-04 09:41:27] CPU #3: 1.13 kH/s
[2018-10-04 09:41:27] CPU #4: 1.96 kH/s
[2018-10-04 09:41:27] CPU #5: 1.95 kH/s
[2018-10-04 09:41:27] Total: 8.48 kH/s
[2018-10-04 09:41:32] Total: 8.45 kH/s
[2018-10-04 09:41:37] CPU #0: 1.14 kH/s
[2018-10-04 09:41:37] CPU #2: 1.14 kH/s
[2018-10-04 09:41:37] CPU #1: 1.15 kH/s
[2018-10-04 09:41:37] CPU #3: 1.13 kH/s
[2018-10-04 09:41:37] CPU #4: 1.93 kH/s
[2018-10-04 09:41:37] CPU #5: 1.92 kH/s
[2018-10-04 09:41:37] Total: 8.41 kH/s
[2018-10-04 09:41:42] Total: 8.40 kH/s
[2018-10-04 09:41:47] CPU #0: 1.14 kH/s
[2018-10-04 09:41:47] CPU #2: 1.15 kH/s
[2018-10-04 09:41:47] CPU #1: 1.15 kH/s
[2018-10-04 09:41:47] CPU #3: 1.13 kH/s
[2018-10-04 09:41:47] CPU #4: 1.92 kH/s
[2018-10-04 09:41:47] CPU #5: 1.90 kH/s
[2018-10-04 09:41:47] Total: 8.38 kH/s
[2018-10-04 09:41:52] Total: 8.37 kH/s
[2018-10-04 09:41:57] CPU #0: 1.14 kH/s
[2018-10-04 09:41:57] CPU #2: 1.15 kH/s
[2018-10-04 09:41:57] CPU #1: 1.15 kH/s
[2018-10-04 09:41:57] CPU #3: 1.13 kH/s
[2018-10-04 09:41:57] CPU #4: 1.90 kH/s
[2018-10-04 09:41:57] CPU #5: 1.88 kH/s
[2018-10-04 09:41:57] Total: 8.34 kH/s
[2018-10-04 09:42:02] Total: 8.31 kH/s
[2018-10-04 09:42:07] CPU #0: 1.14 kH/s
[2018-10-04 09:42:07] CPU #2: 1.15 kH/s
[2018-10-04 09:42:07] CPU #1: 1.15 kH/s
[2018-10-04 09:42:07] CPU #3: 1.13 kH/s
[2018-10-04 09:42:07] CPU #4: 1.88 kH/s
[2018-10-04 09:42:07] CPU #5: 1.86 kH/s
[2018-10-04 09:42:07] Total: 8.31 kH/s
[2018-10-04 09:42:12] Total: 8.29 kH/s
[2018-10-04 09:42:17] CPU #0: 1.14 kH/s
[2018-10-04 09:42:17] CPU #2: 1.15 kH/s
[2018-10-04 09:42:17] CPU #1: 1.15 kH/s
[2018-10-04 09:42:17] CPU #3: 1.13 kH/s
[2018-10-04 09:42:17] CPU #4: 1.86 kH/s
[2018-10-04 09:42:17] CPU #5: 1.84 kH/s
[2018-10-04 09:42:17] Total: 8.27 kH/s
[2018-10-04 09:42:22] Total: 8.27 kH/s
[2018-10-04 09:42:27] CPU #0: 1.14 kH/s
[2018-10-04 09:42:27] CPU #2: 1.15 kH/s
[2018-10-04 09:42:27] CPU #1: 1.15 kH/s
[2018-10-04 09:42:27] CPU #3: 1.13 kH/s
[2018-10-04 09:42:27] CPU #5: 1.85 kH/s
[2018-10-04 09:42:27] Total: 8.25 kH/s
[2018-10-04 09:42:27] CPU #4: 1.82 kH/s
[2018-10-04 09:42:32] Total: 8.23 kH/s
[2018-10-04 09:42:37] CPU #0: 1.14 kH/s
[2018-10-04 09:42:37] CPU #1: 1.15 kH/s
[2018-10-04 09:42:37] CPU #2: 1.15 kH/s
[2018-10-04 09:42:37] CPU #3: 1.13 kH/s
[2018-10-04 09:42:37] CPU #5: 1.83 kH/s
[2018-10-04 09:42:37] Total: 8.22 kH/s
[2018-10-04 09:42:37] CPU #4: 1.81 kH/s
[2018-10-04 09:42:42] Total: 8.20 kH/s
[2018-10-04 09:42:43] CPU #4: 1.80 kH/s
[2018-10-04 09:42:47] CPU #1: 1.15 kH/s
[2018-10-04 09:42:47] CPU #0: 1.14 kH/s
[2018-10-04 09:42:47] CPU #2: 1.14 kH/s
[2018-10-04 09:42:47] CPU #3: 1.13 kH/s
[2018-10-04 09:42:47] CPU #5: 1.81 kH/s
[2018-10-04 09:42:47] Total: 8.15 kH/s
[2018-10-04 09:42:52] CPU #4: 1.79 kH/s
[2018-10-04 09:42:52] Total: 8.17 kH/s
[2018-10-04 09:42:57] CPU #1: 1.15 kH/s
[2018-10-04 09:42:57] CPU #0: 1.14 kH/s
[2018-10-04 09:42:57] CPU #2: 1.15 kH/s
[2018-10-04 09:42:57] CPU #3: 1.13 kH/s
[2018-10-04 09:42:57] CPU #5: 1.81 kH/s
[2018-10-04 09:42:57] Total: 8.15 kH/s
[2018-10-04 09:43:02] CPU #4: 1.78 kH/s
[2018-10-04 09:43:03] CPU #5: 1.80 kH/s
[2018-10-04 09:43:03] Total: 8.14 kH/s
[2018-10-04 09:43:07] Total: 8.14 kH/s
[2018-10-04 09:43:07] CPU #1: 1.15 kH/s
[2018-10-04 09:43:07] CPU #0: 1.14 kH/s
[2018-10-04 09:43:07] CPU #2: 1.14 kH/s
[2018-10-04 09:43:07] CPU #3: 1.13 kH/s
[2018-10-04 09:43:12] CPU #5: 1.78 kH/s
[2018-10-04 09:43:12] Total: 8.11 kH/s
[2018-10-04 09:43:12] CPU #4: 1.75 kH/s
[2018-10-04 09:43:17] Total: 8.10 kH/s
[2018-10-04 09:43:17] CPU #1: 1.15 kH/s
[2018-10-04 09:43:17] CPU #0: 1.14 kH/s
[2018-10-04 09:43:17] CPU #2: 1.14 kH/s
[2018-10-04 09:43:17] CPU #3: 1.13 kH/s
[2018-10-04 09:43:22] CPU #5: 1.78 kH/s
[2018-10-04 09:43:22] Total: 8.10 kH/s
[2018-10-04 09:43:22] CPU #4: 1.75 kH/s
[2018-10-04 09:43:27] Total: 8.09 kH/s
[2018-10-04 09:43:27] CPU #1: 1.15 kH/s
[2018-10-04 09:43:27] CPU #0: 1.14 kH/s
[2018-10-04 09:43:27] CPU #2: 1.15 kH/s
[2018-10-04 09:43:27] CPU #3: 1.13 kH/s
[2018-10-04 09:43:32] CPU #5: 1.75 kH/s
[2018-10-04 09:43:32] Total: 8.06 kH/s
[2018-10-04 09:43:32] CPU #4: 1.73 kH/s
[2018-10-04 09:43:37] Total: 8.06 kH/s
[2018-10-04 09:43:37] CPU #1: 1.15 kH/s
[2018-10-04 09:43:37] CPU #0: 1.14 kH/s
[2018-10-04 09:43:37] CPU #2: 1.15 kH/s
[2018-10-04 09:43:37] CPU #3: 1.13 kH/s
[2018-10-04 09:43:42] CPU #5: 1.76 kH/s
[2018-10-04 09:43:42] Total: 8.06 kH/s
[2018-10-04 09:43:42] CPU #4: 1.73 kH/s
[2018-10-04 09:43:47] Total: 8.04 kH/s
[2018-10-04 09:43:47] CPU #1: 1.15 kH/s
[2018-10-04 09:43:47] CPU #0: 1.14 kH/s
[2018-10-04 09:43:47] CPU #2: 1.14 kH/s
[2018-10-04 09:43:47] CPU #3: 1.13 kH/s
[2018-10-04 09:43:52] CPU #5: 1.75 kH/s
[2018-10-04 09:43:52] Total: 8.03 kH/s
[2018-10-04 09:43:52] CPU #4: 1.71 kH/s
[2018-10-04 09:43:57] Total: 8.02 kH/s
[2018-10-04 09:43:57] CPU #1: 1.15 kH/s
[2018-10-04 09:43:57] CPU #0: 1.14 kH/s
[2018-10-04 09:43:57] CPU #2: 1.14 kH/s
[2018-10-04 09:43:57] CPU #3: 1.13 kH/s
[2018-10-04 09:44:02] CPU #5: 1.74 kH/s
[2018-10-04 09:44:02] Total: 7.99 kH/s
[2018-10-04 09:44:02] CPU #4: 1.70 kH/s
[2018-10-04 09:44:07] Total: 7.99 kH/s
[2018-10-04 09:44:07] CPU #1: 1.15 kH/s
[2018-10-04 09:44:07] CPU #0: 1.14 kH/s
[2018-10-04 09:44:07] CPU #2: 1.14 kH/s
[2018-10-04 09:44:07] CPU #3: 1.13 kH/s
[2018-10-04 09:44:12] CPU #5: 1.73 kH/s
[2018-10-04 09:44:12] Total: 7.99 kH/s
[2018-10-04 09:44:12] CPU #4: 1.69 kH/s
[2018-10-04 09:44:17] Total: 7.98 kH/s
[2018-10-04 09:44:17] CPU #1: 1.15 kH/s
[2018-10-04 09:44:17] CPU #0: 1.14 kH/s
[2018-10-04 09:44:17] CPU #3: 1.13 kH/s
[2018-10-04 09:44:17] CPU #2: 1.14 kH/s
[2018-10-04 09:44:22] CPU #5: 1.72 kH/s
[2018-10-04 09:44:22] Total: 7.96 kH/s
[2018-10-04 09:44:22] CPU #4: 1.68 kH/s
[2018-10-04 09:44:27] Total: 7.96 kH/s
[2018-10-04 09:44:27] CPU #1: 1.15 kH/s
[2018-10-04 09:44:27] CPU #0: 1.14 kH/s
[2018-10-04 09:44:27] CPU #2: 1.14 kH/s
[2018-10-04 09:44:27] CPU #3: 1.13 kH/s
[2018-10-04 09:44:32] CPU #5: 1.71 kH/s
[2018-10-04 09:44:32] Total: 7.96 kH/s
[2018-10-04 09:44:32] CPU #4: 1.68 kH/s
[2018-10-04 09:44:37] Total: 7.95 kH/s
[2018-10-04 09:44:37] CPU #1: 1.15 kH/s
[2018-10-04 09:44:37] CPU #2: 1.14 kH/s
[2018-10-04 09:44:37] CPU #0: 1.14 kH/s
[2018-10-04 09:44:37] CPU #3: 1.13 kH/s
[2018-10-04 09:44:42] CPU #5: 1.70 kH/s
[2018-10-04 09:44:42] Total: 7.94 kH/s
[2018-10-04 09:44:42] CPU #4: 1.66 kH/s

Total Scores: 8.71,8.70,8.69,8.68,8.64,8.60,8.57,8.51,8.50,8.48,8.45,8.41,8.40,8.38,8.37,8.34,8.31,8.29,8.27,8.25,8.23,8.22,8.20,8.17,8.15,8.14,8.11,8.10,8.09,8.06,8.04,8.03,8.02,7.99,7.98,7.96,7.95,7.94

##########################################################################

Testing clockspeeds again. System health now:

Time       big.LITTLE   load %cpu %sys %usr %nice %io %irq   Temp
09:44:40: 1992/1512MHz  6.23 100%   0%  99%   0%   0%   0%  85.6°C

Checking cpufreq OPP for cpu0-cpu3:

Cpufreq OPP: 1512    Measured: 1503.243/1503.506/1503.366
Cpufreq OPP: 1416    Measured: 1407.089/1407.151/1407.273
Cpufreq OPP: 1200    Measured: 1190.703/1191.170/1191.376
Cpufreq OPP: 1008    Measured: 998.736/999.110/998.060
Cpufreq OPP:  816    Measured: 807.134/807.095/807.223
Cpufreq OPP:  600    Measured: 591.168/591.300/590.996
Cpufreq OPP:  408    Measured: 399.410/398.822/399.481

Checking cpufreq OPP for cpu4-cpu5:

Cpufreq OPP: 1992    Measured: 1985.614/1985.150/1985.614
Cpufreq OPP: 1800    Measured: 1793.411/1793.391/1793.391
Cpufreq OPP: 1608    Measured: 1601.019/1601.794/1601.734
Cpufreq OPP: 1416    Measured: 1409.439/1409.516/1408.870
Cpufreq OPP: 1200    Measured: 1193.537/1193.509/1193.537
Cpufreq OPP: 1008    Measured: 1001.811/1001.799/1001.568
Cpufreq OPP:  816    Measured: 809.754/808.882/809.764
Cpufreq OPP:  600    Measured: 593.297/593.317/593.283
Cpufreq OPP:  408    Measured: 401.328/401.290/401.399

##########################################################################

System health while running tinymembench:

Time       big.LITTLE   load %cpu %sys %usr %nice %io %irq   Temp
09:16:00: 1992/1512MHz  1.00   8%   1%   6%   0%   0%   0%  36.2°C
09:18:00: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  36.2°C
09:20:00: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  36.2°C
09:22:00: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  37.5°C
09:24:00: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  37.5°C
09:26:00: 1992/1512MHz  1.25  17%   0%  16%   0%   0%   0%  45.0°C
09:28:00: 1992/1512MHz  1.03  16%   0%  16%   0%   0%   0%  45.0°C
09:30:00: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  45.6°C

System health while running OpenSSL benchmark:

Time       big.LITTLE   load %cpu %sys %usr %nice %io %irq   Temp
09:30:19: 1992/1512MHz  1.00  14%   0%  13%   0%   0%   0%  46.9°C
09:30:29: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  43.9°C
09:30:39: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  48.8°C
09:30:49: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  50.0°C
09:30:59: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  46.2°C
09:31:09: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  45.6°C
09:31:19: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  50.6°C
09:31:30: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  51.7°C
09:31:40: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  46.2°C
09:31:50: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  48.8°C
09:32:00: 1992/1512MHz  1.00  16%   0%  16%   0%   0%   0%  51.7°C

System health while running 7-zip single core benchmark:

Time       big.LITTLE   load %cpu %sys %usr %nice %io %irq   Temp
09:32:07: 1992/1512MHz  1.00  14%   0%  14%   0%   0%   0%  53.3°C
09:33:07: 1992/1512MHz  3.35  16%   0%  16%   0%   0%   0%  45.0°C
09:34:07: 1992/1512MHz  3.86  16%   0%  16%   0%   0%   0%  45.6°C
09:35:07: 1992/1512MHz  3.99  16%   0%  16%   0%   0%   0%  45.0°C
09:36:08: 1992/1512MHz  4.79  16%   0%  16%   0%   0%   0%  51.1°C
09:37:08: 1992/1512MHz  4.61  16%   0%  16%   0%   0%   0%  51.1°C

System health while running 7-zip multi core benchmark:

Time       big.LITTLE   load %cpu %sys %usr %nice %io %irq   Temp
09:37:48: 1992/1512MHz  4.83  15%   0%  14%   0%   0%   0%  52.2°C
09:38:08: 1992/1512MHz  4.84  80%   0%  79%   0%   0%   0%  65.6°C
09:38:28: 1992/1512MHz  4.64  79%   1%  78%   0%   0%   0%  57.2°C
09:38:48: 1992/1512MHz  4.45  83%   0%  82%   0%   0%   0%  68.3°C
09:39:09: 1992/1512MHz  4.56  75%   1%  74%   0%   0%   0%  61.9°C
09:39:29: 1992/1512MHz  4.25  83%   0%  82%   0%   0%   0%  70.6°C

System health while running cpuminer:

Time       big.LITTLE   load %cpu %sys %usr %nice %io %irq   Temp
09:39:47: 1992/1512MHz  4.85  19%   0%  19%   0%   0%   0%  66.1°C
09:40:08: 1992/1512MHz  5.18  99%   0%  99%   0%   0%   0%  80.0°C
09:40:30: 1992/1512MHz  5.52 100%   0%  99%   0%   0%   0%  82.2°C
09:40:53: 1992/1512MHz  5.66 100%   0%  99%   0%   0%   0%  83.9°C
09:41:15: 1992/1512MHz  5.83 100%   0%  99%   0%   0%   0%  84.4°C
09:41:37: 1992/1512MHz  5.88 100%   0%  99%   0%   0%   0%  83.9°C
09:42:00: 1992/1512MHz  6.08 100%   0%  99%   0%   0%   0%  85.0°C
09:42:23: 1992/1512MHz  6.06 100%   0%  99%   0%   0%   0%  82.2°C
09:42:45: 1992/1512MHz  6.15 100%   0%  99%   0%   0%   0%  83.3°C
09:43:08: 1416/1512MHz  6.11 100%   0%  99%   0%   0%   0%  85.0°C
09:43:31: 1416/1512MHz  6.13 100%   0%  99%   0%   0%   0%  85.0°C
09:43:54: 1992/1512MHz  6.09 100%   0%  99%   0%   0%   0%  83.3°C
09:44:17: 1416/1512MHz  6.12 100%   0%  99%   0%   0%   0%  83.3°C
09:44:40: 1992/1512MHz  6.23 100%   0%  99%   0%   0%   0%  85.6°C

Throttling statistics (time spent on each cpufreq OPP) for CPUs 4-5:

1992 MHz: 1640.67 sec
1800 MHz:       0 sec
1608 MHz:       0 sec
1416 MHz:   86.17 sec
1200 MHz:       0 sec
1008 MHz:       0 sec
 816 MHz:       0 sec
 600 MHz:       0 sec
 408 MHz:       0 sec

##########################################################################

Linux 4.4.156-rk3399 (nanopim4) 	10/04/18 	_aarch64_	(6 CPU)

avg-cpu:  %user   %nice %system %iowait  %steal   %idle
          30.96    0.00    0.42    0.07    0.00   68.55

Device:            tps    kB_read/s    kB_wrtn/s    kB_read    kB_wrtn
mmcblk0           3.29       131.05        81.46     268121     166664
zram0             0.42         0.36         1.33        744       2728
zram1             0.23         0.59         0.35       1200        720
zram2             0.24         0.60         0.35       1232        720
zram3             0.24         0.60         0.35       1224        720
zram4             0.24         0.59         0.35       1212        720

              total        used        free      shared  buff/cache   available
Mem:           919M         68M        695M        4.4M        155M        770M
Swap:          459M        2.8M        457M

Filename				Type		Size	Used	Priority
/dev/zram1                             	partition	117744	712	5
/dev/zram2                             	partition	117744	712	5
/dev/zram3                             	partition	117744	712	5
/dev/zram4                             	partition	117744	712	5

Architecture:          aarch64
Byte Order:            Little Endian
CPU(s):                6
On-line CPU(s) list:   0-5
Thread(s) per core:    1
Core(s) per socket:    3
Socket(s):             2
Model:                 4
CPU max MHz:           1512.0000
CPU min MHz:           408.0000
BogoMIPS:              48.00
Flags:                 fp asimd evtstrm aes pmull sha1 sha2 crc32