25%
31.07.2013
_record;
14 int counter_limit;
15
16 counter_limit = 100;
17
18 for ( counter=1; counter <= counter_limit; counter++)
19 {
20 my_record.x = counter;
21 my_record.y = counter + 1
25%
18.07.2013
?
The hdparm [3] tool exposes all the disk's details to the administrator's prying eye. From the output presented in Listing 1, you can determine that this is indeed a solid state device (line 25), supporting
25%
17.02.2015
:
Tegra X1:
25.6GBps memory bandwidth
HDMI 2.0 and HDCP 2.2
10W power
Peak performance: 1,024GFLOPS with FP16; 512GFLOPS with FP32
ARM Cortex CPUs:
Quad-core 64-bit ARM Cortex-A57 ... 25
25%
05.02.2019
drwxr-xr-x - bradmatic 8 Jan 23:52 .
drwxr-xr-x - bradmatic 8 Jan 23:52 |---- bin
.rw-r--r-- 194 bradmatic 8 Jan 23:52 | |---- hello-cdk.ts
.rw-r--r-- 37 bradmatic 8 Jan 23:52 |---- cdk
25%
05.12.2014
Yes
Filesystems (Internal HDs)
ext4
ext4
ext3/ext4/XFS
Btrfs
USB 3.0
2x
2x
1x
2x
USB 2.0
2x
1x
4x
25%
17.05.2017
, 5 ) / ( 8, 5 ) }
DATA {
(0,0): 0, 1, 2, 3, 4,
(1,0): 5, 6, 7, 8, 9,
(2,0): 10, 11, 12, 13, 14,
(3,0): 15, 16, 17, 18, 19,
(4,0): 20, 21, 22, 23, 24,
(5,0): 25, 26, 27, 28, 29,
(6
25%
05.12.2014
(data$IPAddress)
14 srt <- ct[order(ct$freq, decreasing = TRUE), ]
15 top10 <- head(srt,10)
16
17 ggplot(data=top10, aes(x=x, y=freq, fill=x))
+ geom_histogram(stat="identity", colour="black", show
25%
30.11.2025
with the /accepteula option, which can be useful in scripting. Unfortunately, this option does not work for all of the Sysinternal tools.
The programs only run on a Windows system as of Windows 2000 Server
25%
02.08.2021
%util
sda 10.91 6.97 768.20 584.64 4.87 18.20 30.85 72.31 13.16 20.40 0.26 70.44 83.89 1.97 3.52
nvme0n1 58.80 12.22 17720.47 48.71 230
25%
21.01.2021
This first article of a series looks at the forces that have driven desktop supercomputing, beginning with the history of PC and supercomputing processors through the 1990s into the early 2000s.
... 1992
i486DX2
2:1 clock multiplier, 40/20, 50/25, 66/33 speeds; L2 on MB
Mar 1994
i486DX4
3:1 clock multiplier, 75/25, 100/33 speeds; 16KB L1 cache on-die, L2 ...
This first article of a series looks at the forces that have driven desktop supercomputing, beginning with the history of PC and supercomputing processors through the 1990s into the early 2000s.
