What you provide to `random_seed( put=... )`

is used to determine the starting state of the generator, which (as janneb states) should have as much entropy as reasonably possible. You could construct some relatively sophisticated method of generating this entropy - grabbing from the system somehow is a good choice for this. The code janneb links is a good example.

However, I typically like to be able to reproduce a single run from a given seed if necessary. This is useful for debugging and regression testing. Then, for production runs, the code can pull a single seed 'randomly' somehow. Therefore, I want to get good RNG from a single 'seed'. In my experience, this is easily achieved by providing this single seed then letting the generator add entropy by generating numbers. Consider the following example:

```
program main
implicit none
integer, parameter :: wp = selected_real_kind(15,307)
integer, parameter :: n_discard = 100
integer :: state_size, i
integer, allocatable, dimension(:) :: state
real(wp) :: ran, oldran
call random_seed( size=state_size )
write(*,*) '-- state size is: ', state_size
allocate(state(state_size))
! -- Simple method of initializing seed from single scalar
state = 20180815
call random_seed( put=state )
! -- 'Prime' the generator by pulling the first few numbers
! -- In reality, these would be discarded but I will print them for demonstration
ran = 0.5_wp
do i=1,n_discard
oldran = ran
call random_number(ran)
write(*,'(a,i3,2es26.18)') 'iter, ran, diff: ', i, ran, ran-oldran
enddo
! Now the RNG is 'ready'
end program main
```

Here, I give a single seed, and then generate a random number 100 times. Typically, I would discard these initial, potentially corrupted, numbers. In this example, I'm printing them to see whether they look non-random. Running with PGI 15.10:

```
enet-mach5% pgfortran --version
pgfortran 15.10-0 64-bit target on x86-64 Linux -tp sandybridge
The Portland Group - PGI Compilers and Tools
Copyright (c) 2015, NVIDIA CORPORATION. All rights reserved.
enet-mach5% pgfortran main.f90 && ./a.out
-- state size is: 34
iter, ran, diff: 1 8.114813341476008191E-01 3.114813341476008191E-01
iter, ran, diff: 2 8.114813341476008191E-01 0.000000000000000000E+00
iter, ran, diff: 3 8.114813341476008191E-01 0.000000000000000000E+00
iter, ran, diff: 4 8.114813341476008191E-01 0.000000000000000000E+00
iter, ran, diff: 5 8.114813341476008191E-01 0.000000000000000000E+00
iter, ran, diff: 6 2.172220012214012286E-01 -5.942593329261995905E-01
iter, ran, diff: 7 2.172220012214012286E-01 0.000000000000000000E+00
iter, ran, diff: 8 2.172220012214012286E-01 0.000000000000000000E+00
iter, ran, diff: 9 2.172220012214012286E-01 0.000000000000000000E+00
iter, ran, diff: 10 2.172220012214012286E-01 0.000000000000000000E+00
iter, ran, diff: 11 6.229626682952016381E-01 4.057406670738004095E-01
iter, ran, diff: 12 6.229626682952016381E-01 0.000000000000000000E+00
iter, ran, diff: 13 6.229626682952016381E-01 0.000000000000000000E+00
iter, ran, diff: 14 6.229626682952016381E-01 0.000000000000000000E+00
iter, ran, diff: 15 6.229626682952016381E-01 0.000000000000000000E+00
iter, ran, diff: 16 2.870333536900204763E-02 -5.942593329261995905E-01
iter, ran, diff: 17 2.870333536900204763E-02 0.000000000000000000E+00
iter, ran, diff: 18 4.344440024428024572E-01 4.057406670738004095E-01
iter, ran, diff: 19 4.344440024428024572E-01 0.000000000000000000E+00
iter, ran, diff: 20 4.344440024428024572E-01 0.000000000000000000E+00
iter, ran, diff: 21 8.401846695166028667E-01 4.057406670738004095E-01
iter, ran, diff: 22 8.401846695166028667E-01 0.000000000000000000E+00
iter, ran, diff: 23 6.516660036642036857E-01 -1.885186658523991809E-01
iter, ran, diff: 24 6.516660036642036857E-01 0.000000000000000000E+00
iter, ran, diff: 25 6.516660036642036857E-01 0.000000000000000000E+00
iter, ran, diff: 26 5.740667073800409526E-02 -5.942593329261995905E-01
iter, ran, diff: 27 5.740667073800409526E-02 0.000000000000000000E+00
iter, ran, diff: 28 2.746286719594053238E-01 2.172220012214012286E-01
iter, ran, diff: 29 2.746286719594053238E-01 0.000000000000000000E+00
iter, ran, diff: 30 2.746286719594053238E-01 0.000000000000000000E+00
iter, ran, diff: 31 6.803693390332057334E-01 4.057406670738004095E-01
iter, ran, diff: 32 6.803693390332057334E-01 0.000000000000000000E+00
iter, ran, diff: 33 3.033320073284073715E-01 -3.770373317047983619E-01
iter, ran, diff: 34 3.033320073284073715E-01 0.000000000000000000E+00
iter, ran, diff: 35 7.090726744022077810E-01 4.057406670738004095E-01
iter, ran, diff: 36 1.148133414760081905E-01 -5.942593329261995905E-01
iter, ran, diff: 37 1.148133414760081905E-01 0.000000000000000000E+00
iter, ran, diff: 38 1.435166768450102381E-01 2.870333536900204763E-02
iter, ran, diff: 39 1.435166768450102381E-01 0.000000000000000000E+00
iter, ran, diff: 40 3.607386780664114667E-01 2.172220012214012286E-01
iter, ran, diff: 41 7.664793451402118762E-01 4.057406670738004095E-01
iter, ran, diff: 42 7.664793451402118762E-01 0.000000000000000000E+00
iter, ran, diff: 43 2.009233475830143334E-01 -5.655559975571975428E-01
iter, ran, diff: 44 2.009233475830143334E-01 0.000000000000000000E+00
iter, ran, diff: 45 6.353673500258167905E-01 4.344440024428024572E-01
iter, ran, diff: 46 4.110801709961720007E-02 -5.942593329261995905E-01
iter, ran, diff: 47 4.110801709961720007E-02 0.000000000000000000E+00
iter, ran, diff: 48 8.812926866162200668E-01 8.401846695166028667E-01
iter, ran, diff: 49 8.812926866162200668E-01 0.000000000000000000E+00
iter, ran, diff: 50 9.386993573542241620E-01 5.740667073800409526E-02
iter, ran, diff: 51 3.444400244280245715E-01 -5.942593329261995905E-01
iter, ran, diff: 52 7.501806915018249811E-01 4.057406670738004095E-01
iter, ran, diff: 53 9.961060280922282573E-01 2.459253365904032762E-01
iter, ran, diff: 54 9.961060280922282573E-01 0.000000000000000000E+00
iter, ran, diff: 55 8.221603419923440015E-02 -9.138899938929938571E-01
iter, ran, diff: 56 4.879567012730348097E-01 4.057406670738004095E-01
iter, ran, diff: 57 1.109193695682364478E-01 -3.770373317047983619E-01
iter, ran, diff: 58 7.625853732324401335E-01 6.516660036642036857E-01
iter, ran, diff: 59 7.625853732324401335E-01 0.000000000000000000E+00
iter, ran, diff: 60 2.831393817822487335E-01 -4.794459914501914000E-01
iter, ran, diff: 61 6.888800488560491431E-01 4.057406670738004095E-01
iter, ran, diff: 62 7.462867195940532383E-01 5.740667073800409526E-02
iter, ran, diff: 63 8.036933903320573336E-01 5.740667073800409526E-02
iter, ran, diff: 64 8.036933903320573336E-01 0.000000000000000000E+00
iter, ran, diff: 65 1.644320683984688003E-01 -6.392613219335885333E-01
iter, ran, diff: 66 5.701727354722692098E-01 4.057406670738004095E-01
iter, ran, diff: 67 6.849860769482774003E-01 1.148133414760081905E-01
iter, ran, diff: 68 1.481334147600819051E-01 -5.368526621881954952E-01
iter, ran, diff: 69 5.538740818338823146E-01 4.057406670738004095E-01
iter, ran, diff: 70 1.605380964906970576E-01 -3.933359853431852571E-01
iter, ran, diff: 71 5.662787635644974671E-01 4.057406670738004095E-01
iter, ran, diff: 72 7.672021111475118005E-01 2.009233475830143334E-01
iter, ran, diff: 73 6.360901160331167148E-01 -1.311119951143950857E-01
iter, ran, diff: 74 6.647934514021187624E-01 2.870333536900204763E-02
iter, ran, diff: 75 9.231234697231371911E-01 2.583300183210184287E-01
iter, ran, diff: 76 3.288641367969376006E-01 -5.942593329261995905E-01
iter, ran, diff: 77 5.034149292976053403E-02 -2.785226438671770666E-01
iter, ran, diff: 78 3.249701648891658579E-01 2.746286719594053238E-01
iter, ran, diff: 79 4.110801709961720007E-01 8.611000610700614288E-02
iter, ran, diff: 80 7.268168600551945246E-01 3.157366890590225239E-01
iter, ran, diff: 81 1.325575271289949342E-01 -5.942593329261995905E-01
iter, ran, diff: 82 2.147735613282293343E-01 8.221603419923440015E-02
iter, ran, diff: 83 8.951429003614350677E-01 6.803693390332057334E-01
iter, ran, diff: 84 9.606624794444940107E-02 -7.990766524169856666E-01
iter, ran, diff: 85 8.749502748152764298E-01 7.788840268708270287E-01
iter, ran, diff: 86 6.864316089628772488E-01 -1.885186658523991809E-01
iter, ran, diff: 87 3.753116578189263919E-01 -3.111199511439508569E-01
iter, ran, diff: 88 4.614216639259325348E-01 8.611000610700614288E-02
iter, ran, diff: 89 8.632683590919612016E-01 4.018466951660286668E-01
iter, ran, diff: 90 5.110403908483931446E-01 -3.522279682435680570E-01
iter, ran, diff: 91 3.512250603649960112E-01 -1.598153304833971333E-01
iter, ran, diff: 92 2.984351275420635830E-01 -5.278993282293242828E-02
iter, ran, diff: 93 7.902858007228701354E-01 4.918506731808065524E-01
iter, ran, diff: 94 9.136098520217217356E-01 1.233240512988516002E-01
iter, ran, diff: 95 8.360105557375590024E-01 -7.759929628416273317E-02
iter, ran, diff: 96 7.623052313611680120E-01 -7.370532437639099044E-02
iter, ran, diff: 97 2.525198759725810760E-02 -7.370532437639099044E-01
iter, ran, diff: 98 9.228433278518650695E-01 8.975913402546069619E-01
iter, ran, diff: 99 1.283834133499510699E-01 -7.944599145019139996E-01
iter, ran, diff: 100 7.311534560989940701E-01 6.027700427490430002E-01
```

8 of the first 10 numbers generated are the repeated! This is a good illustration of why some generators require a high-entropy state in the first place. However, after 'some' time, the numbers start to look reasonable.

For my applications, 100 or so random numbers is a very small cost, so whenever I seed a generator, I prime them in this manner. I didn't observe this obviously bad behavior on ifort 16.0, gfortran 4.8, or gfortran 8.1. Non-repeating numbers is a pretty low bar, though. So I would prime for all compilers, not just ones I have observed bad behavior for.

From the comments, some compilers attempt to eliminate bad behavior by processing the input state in some way to yield the actual internal state. Gfortran uses an "xor cipher". The operation is reversed on a `get`

.

can someone make an "ifort" tag synonym for intel-fortran?No. This was discussed a while ago, see meta.stackoverflow.com/questions/284685/…. – High Performance Mark Aug 17 '18 at 11:17