The Python interface to RACF is great.

The Python package pysear to work with RACF is great. The source is on github, and the documentation starts here. It is well documented, and there are good examples.

I’ve managed to do a lot of processing with very little of my own code.

One project I’ve been meaning to do for a time is to extract the contents of a RACF database and compare them with a different database and show the differences. IBM provides a batch program, and a very large Rexx exec. This has some bugs and is not very nice to use. There is a Rexx interface, which worked, but I found I was writing a lot of code. Then I found the pysear code.

Background

The data returned for userids (and other types of data) have segments.
You can display the base segment for a user.

tso lu colin

To display the tso base segment

tso lu colin tso

Field names returned by pysear have the segment name as a prefix, for example base:max_incorrect_password_attempts.

My first query

What are the active classes in RACF?

See the example.

from sear import sear
import json
import sys
result = sear(
    {
        "operation": "extract",
        "admin_type": "racf-options"
    },
)
json_data = json.dumps(result.result   , indent=2)
print(json_data)

For error handling see error handling

This produces output like

{
  "profile": {
    "base": {
      "base:active_classes": [
        "DATASET",
        "USER",...
  ],
      "base:add_creator_to_access_list": true,
      ... 
      "base:max_incorrect_password_attempts": 3,
 
...
}

To process the active classes one at a time you need code like

for ac in result.result["profile"]["base"]["base:active_classes"]:
    print("Active class:",ac)

The returned attributes are called traits. See here for the traits for RACF options. The traits show

Traitbase:max_incorrect_password_attempts
RACF Keyrevoke
Data TypesString
Operators Allowed“set”,”delete”
Supported Operations“alter”,”extract”

For this attribute because it is a single valued object, you can set it or delete it.

You can use this attribute for example

result = sear(
    {
        "operation": "alter",
        "admin_type": "racf-options",
        "traits": {
            "base:max_incorrect_password_attempts": 5,
        },
    },
)

The trait “base:active_classes” is list of classes [“DATASET”, “USER”,…]

The trait is

Traitbase:active_classes
RACF Keyclassact
Data Typesstring
Operators Allowed"add", "remove"
Supported Operations"alter", "extract"

Because it is a list, you can add or remove an element, you do not use set or delete which would replace the whole list.

Some traits, such as use counts, have Operators Allowed of N/A. You can only extract and display the information.

My second query

What are the userids in RACF?

The traits are listed here, and code examples are here.

I used 

from sear import sear
import json

# get all userids begining with ZWE
users = sear(
    {
        "operation": "search",
        "admin_type": "user",
        "userid_filter": "ZWE",
    },
)
profiles  = users.result["profiles"]
# Now process each profile in turn.
# because this is for userid profiles we need admin_type=user and userid=....
for profile in profiles:
    user = sear(
       {
          "operation": "extract",
          "admin_type": "user",
          "userid": profile,
       }, 
    )
    segments = user.result["profile"]
    #print("segment",segments)
    for segment in segments:   # eg base or omvs
      for w1,v1 in segments[segment].items():
          #print(w1,v1)
          #for w2,v2 in v1.items():
          #  print(w1,w2,v2 )
          json_data = json.dumps(v1  , indent=2)
          print(w1,json_data)

This gave 

==PROFILE=== ZWESIUSR
base:auditor false
base:automatic_dataset_protection false
base:create_date "05/06/20"
base:default_group "ZWEADMIN"
base:group_connections [
  {
    ...
    "base:group_connection_group": "IZUADMIN",
    ...
    "base:group_connection_owner": "IBMUSER",
    ...
},
{
    ...
    "base:group_connection_group": "IZUUSER",
   ...
}
...
omvs:default_shell "/bin/sh"
omvs:home_directory "/apps/zowe/v10/home/zwesiusr"
omvs:uid 990017
===PROFILE=== ZWESVUSR
...

Notes on using search and extract

If you use “operation”: “search” you need a ….._filter. If you use extract you use the data type directly, such as “userid”:…

Processing resources

You can process RACF resources. For example a OPERCMDS provide for MVS.DISPLAY commands.

The sear command need a “class”:…. value, for example

result = sear(
    {
        "operation": "search",
        "admin_type": "resource",
        "class": "OPERCMDS",
        "resource_filter": "MVS.**",
    },
)
result = sear(
    {
        "operation": "extract",
        "admin_type": "resource",
        "resource": "MVS.DISPLAY",
        "class": "Opercmds",
    },
)

The value of the class is converted to upper case.

Changing a profile

If you change a profile, for example to issue the PERMIT command

from sear import sear
import json

result = sear(
    {   "operation": "alter",
        "admin_type": "permission",
        "resource": "MVS.DISPLAY.*",
        "userid": "ADCDG",
        "traits": {
          "base:access": "CONTROL"
        },
        "class": "OPERCMDS"

    },
)
json_data = json.dumps(result.result   , indent=2)
print(json_data)

The output was

{
  "commands": [
    {
      "command": "PERMIT MVS.DISPLAY.* CLASS(OPERCMDS)ACCESS (CONTROL) ID(ADCDG)",
      "messages": [
        "ICH06011I RACLISTED PROFILES FOR OPERCMDS WILL NOT REFLECT THE UPDATE(S) UNTIL A SETROPTS REFRESH IS ISSUED"
      ]
    }
  ],
  "return_codes": {
    "racf_reason_code": 0,
    "racf_return_code": 0,
    "saf_return_code": 0,
    "sear_return_code": 0
  }
}

Error handling

Return codes and errors messages

There are two layers of error handling.

  • Invalid requests – problems detected by pysear
  • Non zero return code from the underlying RACF code.

If pysear detects a problem it returns it in

result.result.get("errors")

For example you have specified an invalid parameter such as “userzzz“:”MINE”

If you do not have this field, then the request was passed to the RACF service. This returns multiple values. See IRRSMO00 return and reason codes. There will be values for

  • SAF return code
  • RACF return code
  • RACF reason code
  • sear return code.

If the RACF return code is zero then the request was successful.

To make error handling easier – and have one error handling for all requests I used 


try:
   result = try_sear(search)     
except Exception as ex:
   print("Exception-Colin Line112:",ex)
   quit()

Where try_sear was

def try_sear(data):
    # execute the request
    result = sear(data)
    if  result.result.get("errors") != None:
        print("Request:",result.request)
        print("Error with request:",result.result["errors"])
        raise ValueError("errors")
    elif (result.result["return_codes"]["racf_reason_code"] != 0):
        rcs = result.result["return_codes"]
        print("SAF Return code",rcs["saf_return_code"],
              "RACF Return code",  rcs["racf_return_code"],
              "RACF Reason code",["racf_reason_code"],
        )
        raise ValueError("return codes")
    return result

Overall

This interface is very easy to do.
I use it to extract definitions from one RACF database, save them as JSON files. Repeat with a different (historical) RACF database, then compare the two JSON files to see the differences.

Note: The sear command only works with the active database, so I had to make the historical database active, run the commands, and switch back to the current data base.

Using ISPF edit macros to displaying the junk in a catalog

You can use IDCAMS DCOLLECT to collect SMS information about data sets on your z/OS system. This gives lots of information about a dataset, size, creation date, SMS attributes etc.

With processing you can get reports on dataset, volumes, and what is using all the space. This allows you to delete dataset which are no longer needed.

This does not help when you are trying to clean out your catalogs, and removing stuff which should not be in that catalog. For example there are usually entries in a catalog which should really be in user catalogs.

I could not find tools to help me with this. I fell back to using and ISPF edit macro to process a LISTCAT listing and extracting relevant data. It is not difficult (once you know) and it is quick and easy.

This blog post gives some examples of how you can use ISPF edit macros to process data in data sets or spool.

The output from the short Rexx exec is

TCPIP.ETC.SERVICES             1998.284 B3SYS1
SYS1.RACFDS                    1999.288 B3CFG1
SYS1.IPLPARM                   1999.288 B3SYS1
...
LOG.MISC                       2025.107 USER04 
IBMUSER.S0W1.SPFTEMP3.CNTL     2026.002 USER07
IBMUSER.S0W1.SPFLOG1.LIST      2026.013 USER04
IBMUSER.SMF                    2026.013 USER07

With this I asked What is LOG.MISC 2025.107 doing in the catalog? It is there because I did not have the controls in place to stop people putting datasets into the catalog.

Instead of just displaying the information, I could have had the exec create IDCAMS statements, for example to get it recataloged, or deleted; based on creating date or other information.

Get your LISTCAT listing

I used

//IBMLISC JOB 1,MSGCLASS=H 
// EXPORT SYMLIST=(*) 
// SET CAT=&SYSVER. 
//S1  EXEC PGM=IDCAMS 
//SYSPRINT DD SYSOUT=* 
//SYSIN DD *,SYMBOLS=JCLONLY 
 LISTCAT NONVSAM CATALOG(CATALOG.&CAT..MASTER) ALL 
/*
  • The // SET CAT=&SYSVER. gets a local copy of the system symbol &SYSVER. You can use the operator command D SYMBOLS to list all the system symbols defined. On my system &SYSVER is Z31B
  • In //SYSIN DD *,SYMBOLS=JCLONLY the SYMBOLS=JCLONLY says substitute variables in the following SYSIN data, and substitute from the JCL symbols. &CAT is Z31B, and so the catalog name becomes CATALOG.Z31B.MASTER. You cannot use &SYMVER directly in the SYSIN data.

Edit the listing

I used SDSF and the SE line command on the output of the LISTCAT. You get an ISPF edit session with the spool data.

Run the exec

I have a Rexx exec called LISTCATN in USER.Z31B.CLIST. I’ll describe it in sections below

Standard Rexx starting code

/* REXX */ 
/* 
exec to Nonvsam records from a catalog listing 
*/ 
ADDRESS ISPEXEC 
'ISREDIT MACRO (parms) '

Use MACRO(parms) to get the parameters passed to the macro

Define parsing arguments

I define search arguments in a variable stem. This separates the data from the logic, and makes it easy to change or extend.

  data.1 = "NONVSAM 2 10" 
  fcol.1 = 18 
  flen.1 = 48 

  data.2 = "CREATION 38 48 " 
  fcol.2 = 54 
  flen.2 = 8 

  data.3 = "VOLSER 8 15  " 
  fcol.3 = 27 
  flen.3 = 8 

  data.0 = 3 
  sortcols  = "50 60"

Later there is code

  • do I = 1 to data.0 this processes each section in the stems
  • There a find data.1 which substitutes to “find NONVSAM 2 10”. This says Find the string NONVSAM in columns 2 to 10
  • If the find locates the string, the code retrieves the line. The code does a substring from fcol.1 for length flen.1 and saves the value
  • data.0 = 3 says there are three data sections.
  • sortcols = “50 60” is used at the end sort the file by the date column.

Remove uninteresting records

  "ISREDIT autosave off     " 
  "ISREDIT exclude all" 
  "ISREDIT find NONVSAM   2 10 ALL       " 
  "ISREDIT find CREATION ALL         " 
  "ISREDIT find VOLSER   ALL         " 
   if rc != 0 then data.0 = 2 /* ignore the volser */ 
  "ISREDIT delete all  x             "
  • “ISREDIT autosave off ” I have this as standard in ISPF edit macros, basically it says do not save the data if I press PF3.
  • “ISREDIT exclude all” –
  • “ISREDIT find NONVSAM 2 10 ALL ” find these lines
  • “ISREDIT find CREATION ALL ”
  • “ISREDIT find VOLSER ALL ”
  • If volser was not found, then listcat wasn’t specified with the right statement, so do not try to process any VOLSER records
    • if rc != 0 then data.0 = 2 /* ignore the volser */
  • “ISREDIT delete all x ” delete all the records which are still excluded leaving only the records I searched for.

Process the records

do j = 1  by 1 
  string = "" 
  do i = 1 to data.0 
    "ISREDIT find "data.i 
    if rc <> 0 then leave 
    "ISREDIT  (f) = LINENUM .ZCSR " 
    "ISREDIT  (d)  = LINE   " f 
     name = substr(d,fcol.i,flen.i) /* from col and length */ 
     string = string || " " || name 
  end 

  if rc <> 0 then leave 
  out.j = string 
end

This code uses the data in the variable stems defined higher up. It keeps the logic separate from the search data.

  • do j = 1 by 1 iterate through the whole file until the end of file
  • string = “” preset the output string
  • do i = 1 to data.0 for the records we specified
  • “ISREDIT find “data.i find it
  • if rc <> 0 then leave if not found then leave
  • “ISREDIT (f) = LINENUM .ZCSR ” Get the line number where the find found the data.
  • “ISREDIT ( d ) = LINE ” f get the line contents – getting the line number found in the previous step
  • name = substr(d,fcol.i,flen.i) /* from col and length */ extract the field of interest from the line
  • string = string || ” ” || name build up a string of the values found
  • end
  • if rc <> 0 then leave we got a not found, so end of file,
  • out.j = string save the data in a stem for processing below
  • end

Do something with the records

You can do processing on the data, for example create JCL to delete the dataset.

In this example I delete all records from the file, and insert the saved records

  "ISREDIT exclude all" 
  "ISREDIT delete all  x             " 
  do  i = 1 to j -1 
   v = out.i 
    "ISREDIT  LINE_after .zcsr  =   (v)" 
  end 
 "ISREDIT sort     " sortcols 
exit
  • “ISREDIT delete all “ delete all processed the lines in the file
  • do i = 1 to j -1 we have a stem of the records we processed iterate over them
  • v = out.i make a copy of the data, make it easy for ISPF. ISPF only does simple substitutions
  • “ISREDIT LINE_after .zcsr = (v)” insert after the current (last) line the value from v, which is the saved string.
  • end
  • “ISREDIT sort ” sortcols sort on the creation date
  • exit

The output

The output from this is the dataset name, the create date, and the volume it is on. 

TCPIP.ETC.SERVICES             1998.284 B3SYS1
SYS1.RACFDS                    1999.288 B3CFG1
SYS1.IPLPARM                   1999.288 B3SYS1
...
IBMUSER.S0W1.SPFTEMP3.CNTL     2026.002 USER07
IBMUSER.S0W1.SPFLOG1.LIST      2026.013 USER04
IBMUSER.SMF                    2026.013 USER07

From the data information I can see which entries were due to me – because they were all after the Jan 2025.

Different ways of processing records

Not every dataset has the same information. For example, deleting uninteresting rows

NONVSAM ------- ADCD.DYNISPF.ISPPLIB 
       DATASET-OWNER-----(NULL)     CREATION--------2016.236 
       VOLSER------------B3SYS1     DEVTYPE------X'3010200F' FSEQN------------------0 
NONVSAM ------- ADCD.WLM 
       DATASET-OWNER-----(NULL)     CREATION--------2023.010 
       STORAGECLASS -----SCBASE     MANAGEMENTCLASS---(NULL) 
       DATACLASS --------(NULL)     LBACKUP ---0000.000.0000 
       VOLSER------------B3USR1     DEVTYPE------X'3010200F' FSEQN------------------0

The second dataset ADCD.WLM has SMS information, Storage Class, Management Class, and Data Class, which are not present with the first dataset ADCD.DYNISPF.ISPPLIB.

You could process this sequentially and have logic like…

If the row starts with

  • NONVSAM – then write out the previous information, get the dataset name, and start again
  • VOLSER – then parse the volser value
  • DATASET – then parse the creation date
  • STORAGECLASS – then parse the SC and MC values
  • DATACLASS – then parse the DC value

For example 

"ISREDIT     (last)  = LINENUM .ZLAST" 
do j = 1  by 1  to last 
  "ISREDIT      ( d )  = LINE   " j 
  if substr(d,2,7) = "NONVSAM" then 
  do 
      count = count + 1 
      string =  dsn cd vol sc mc dc 
      sc = "        " 
      mc = "        " 
      dc = "        " 
      vol= "      " 
      dsn= "      " 
      cd = "      " 
      out.count = string 
      say string 
      /* do the next */ 
      dsn = substr(d,18,48) 
  end 
  else 
  if substr(d,9,7) = "DATASET" then cd = substr(d,54,8) 
  else 
  if substr(d,9,6) = "VOLSER" then vol = substr(d,27,6) 
  else 
  if substr(d,9,6) = "STORAG" then 
  do 
     sc = substr(d,27,8) 
     mc = substr(d,56,8) 
  end 
  else 
  if substr(d,9,6) = "DATACL" then vol = substr(d,27,8) 
end

This gives output like

NFS.CNTL                       2000.336 B3SYS1 
SYS1.RACFDS.BACKUP             2001.164 B3CFG1 
SYS1.UADS                      2003.137 B3CFG1 
NETVIEW.ADCD.NTVTABS           2009.027 B3USR1 SCBASE   (NULL) 
SYT1.ZOS.CNTL                  2012.013 B3USR1 SCBASE   (NULL) 
TCPIP.PROFILE.TCPIP            2016.236 B3SYS1

So not difficult at all.

What’s going on in my program in Unix Services?

On Linux, starting a Python program is subsecond. On z/OS, running on zD&T (so emulated hardware) it takes about 2 seconds. I wondered if what was causing this – is my ZFS file system slow?

I used the Unix command

bpxtrace -o /tmp/trace -f format -c  python ac.py

to capture a trace.

This produced output like

       PID ASID TCB    Local time      System call           Additional trace
-  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  -  - 
     65589 0049 8FB2F8 08:27:13.722080 Call open             parms: 0000004D 
     65589 0049 8FB2F8 08:27:13.722714 Exit open             rv=00000004 
     65589 0049 8FB2F8 08:27:13.722741 Call fstat            parms: 00000004 
     65589 0049 8FB2F8 08:27:13.722785 Exit fstat            rv=00000000 
     65589 0049 8FB2F8 08:27:13.722817 Call lseek            parms: 00000004 
     65589 0049 8FB2F8 08:27:13.722824 Exit lseek            rv=00000000 
     65589 0049 8FB2F8 08:27:13.722836 Call lseek            parms: 00000004 
     65589 0049 8FB2F8 08:27:13.722883 Exit lseek            rv=00000000 
     65589 0049 8FB2F8 08:27:13.722896 Call lseek            parms: 00000004 
     65589 0049 8FB2F8 08:27:13.722901 Exit lseek            rv=00000000

This is ok, but I want to know how long the calls took.

I wrote an ISPF Rexx script

/* REXX */ 
/* 
exec to extract the alias records from a catalog listing 
*/ 
ADDRESS ISPEXEC 
'ISREDIT MACRO (lines) ' 
"ISREDIT         (f) = LINENUM .ZLAST" 
sum = 0
do j = 3  by 2 to f 
   k = j + 1 
   "ISREDIT      ( bef) = LINE   " j 
   "ISREDIT      ( aft) = LINE   " k 
   parse var bef . 27 mm 29 . 30 ss 39 . 40 what 
   parse var aft . 27 am 29 . 30 as 39 
   before = 60 * mm    + ss 
   after  = 60 * am    + as 
   sum = sum + (after - before) 
   delta = format(after - before,1,6) 
   string = "== "delta what 
   "ISREDIT  LINE  (k) =  (string)" 
    
end 
say sum
exit

running the Rexx script produced output in the file like

     65589 0049 8FB2F8 08:27:13.722080 Call open      
== 0.000630 Call open 
     65589 0049 8FB2F8 08:27:13.722741 Call fstat     
== 0.000050 Call fstat 
     65589 0049 8FB2F8 08:27:13.722817 Call lseek     
== 0.000000 Call lseek

Using the ISPF commands

  • X all
  • f “==” all
  • del all x
  • sort 1 11

This gave

== 0.000000 Call lseek 
== 0.000000 Call lseek 
...
0.000820 Call close            parms: 00000005 00000000 00000000 05FC0119 
0.001450 Call cond_timed_wait  parms: 00000000 000F4240 00000001 00000000 20861040
0.002450 Call loadhfs          parms: 00000048 /u/tmp/zowet/colin/envz/lib/python3...
0.004200 Call loadhfs          parms: 00000008 CELQDCPP 00000000 0000010C 61E9F3F1
0.004310 Call loadhfs          parms: 00000007 CXXRT64 00000000 0000010C 61E9F3F1 
0.034780 Call mvsprocclp       parms: 00000100 00000000 00000000 00000000 
0.042970 Call mvsprocclp       parms: 00000100 2081D1D8 2086CC75 00000000

There were nearly 500 lines in the output file. 400 entries were 100 microseconds or less. There were 6 entries taking longer than 1 millisecond.
My trace file was of duration 1.1 seconds. Adding up the individual times took 0.13 seconds, so it looks like the delays are not caused by the file system, and I need to look else where.

From data to reports missing the potholes

I’ve been doing work with datasets on z/OS to produce reports. These range from SMF data to DCOLLECT data on datasets and SMS data.

It took a while to “get it right”, because I made some poor decisions as to how to process the data, and some of my processing was much more complex than it needed to be. It was easiest to start again!

I’ve been working with Python and Python tools, and other tools available on the platforms. See Pandas 102, notes on using pandas.

My current environment is to use some Python code to read a record, parse the record into a dictionary(dict), then add the dict to a list of records. Then either pass the list of dicts to Pandas to display, or to externalise the data, and have a second Python program to read the externalised data, and do the Pandas processing.

Reading the data

The data is usually in data sets rather than files in Unix Services. You can copy a dataset to a file, but it is easier to use the python package pyzfile to read datasets directly.

from pyzfile import * 

try:
  with ZFile("//'COLIN.DCOLLECT.OUT'", "rb,type=record,noseek") as file: 
     for rec in file: 
        #l = len(rec) 
        yield  rec 
    except ZFileError as e: 
        print(e,file=sys.stderr)

Often a data source will contain a mixture of record types, for example a dump of SMF datasets, may contain many different record types and subtypes.

You need to consider if you want to process all record types in one pass, or process one record type in one run, and a different record type in a different run.

Processing the data

You will normally have a mapping of the layout of the data in a record. Often there are a mix of records types, you need to decide which record types you process and which you ignore.

Field names

Some of the field names in a record are cryptic, they were created when field names could only be 8 characters or less. For example DCDDSNAM. This stands for DCollect records record type D, field name DS NAMe. You need to decide what you name the field. Do you name it DCDDSNAM, and tell the reader to go and look in the documentation to understand the field names in the report, or do you try to add value and just call it DSN, or DataSetName. You cannot guess some fields, such as DCDVSAMI. This is VSAM Inconsistency.

You also need to consider the printed report. If you have a one character field in the record, and a field name which is 20 characters long – by the default the printed field will be 20 characters long, and so waste space in the report. If the field is rarely used you could call it BF1 for Boring Field 1.

Character strings

Python works in ASCII, and strings need to be in ASCII to be printable. You will need to convert character data from EBCIDC to ASCII.

You can use substring to extract data from a record for example. So to extract a string, and convert it…

DSN =  record[20:63].decode('cp500').strip())

Integers

Integers – you will need to covert this to internal format. I found using the Python Struct very good to use. You give a string of conversion characters (integer, integer, …) and it returns an array of the data. If you are processing the data on a different platform, you may need to worry about big end and little end conversion of numbers.

Strange integers

Some records have units like hundredths of a second. You may want to convert these to float

float_value = float(input_value)/100

Packed numbers

Packed numbers are a representation of a date in “decimal” format. For example a yyyyddd for year 2025, day 5 is 0X2025005F” where the F is a sign digit. You cannot just print it (it comes out as 539295839).

Bit masks

Bit masks are very common, for example there is a 1 byte field DCVFLAG1 with values:

  • DCVUSPVT 0x20 Private
  • DCVUSPUB 0x10 Public
  • DCVUSSTG 0x08 Storage
  • DCVSHRDS 0X04 Device is sharable

If the value of the field is 0x14 – what do you return? I would create a field Flag1 with value of a list[“Public”,”Shareable”]. If all the bits were off, this would return an empty list []. It would be easy to create [“DCVUSPUB”,”DCVSHRDS”] or just display the hex value 14 (or 0x14) – but this makes it hard to interpret the data for the people reading the reports.

Triplets

SMF records contain triplets. These are defined by [offset to start, length of data, count of data] within the record.

For example in the SMF30 record there are many triplet sections. There is one for “usage data” involved in usage based pricing. There can be zero or more sections like

  • Product owner
  • Product name
  • TCB time used in hundredths of a second

How are you going to process this?
The SMF record has 3 fields for usage

  • SMF30UDO Offset to Usage Data section in SMF 30 record
  • SMF30UDL Length of each Usage Data section in SMF 30 record
  • SMF30UDN Number of Usage Data section in SMF 30 record

I would create a variable UsageData = [{“ProdOwner”: …,”ProdName”: …, “TCBTime”: …},{“ProdOwner”: …,”ProdName”: …, “TCBTime”: …},]

and convert TCBTime from an integer representing a hundreds of a second, to a floating point number.

Having these triplets make a challenge when printing the record. You could decide to

  • omit this data
  • summarise the data – and provide only a sum of the TCBTime value
  • give the data as a list of dicts, then have a Pandas step to copy only the fields you need for your reports.

For this usage data, I may want a report showing which jobs used which product, and how my much CPU the job used in that product. Although I may capture the data as a list of products, i could extract the data, and create another data record with

  • jobname1, product1, … CPU used1
  • jobname1, product2, … CPU used2
  • jobname2, product1, … CPU used1
  • jobname2, product3, … CPU used3

and remove the product data from the original data record.

Do you want all of the fields?

You may want to ignore fields, such as reserved values, length of record values, record_ type, and any fields you are not interested in. Record length tends to be the first field, and this is usually not interesting when generating default reports.

How to handle a different length record?

The format of many records change with new releases, typically adding new fields.

You need to be able to handle records from the previous release, where the record is shorter. For example do not add these fields to your dict, or give add them with a “None” value.

Now I’ve got a record – now what?

Once you have got your record, and created a dict from the contents {fieldname1=value, fieldname2=value2…} , you could just add it to the list to be passed to Pandas. It is not always that simple.

I found that some records need post processing before saving.

Calculations

For a DCOLLECT record, there is a field which says

DCVFRESP: Free Space on Volume (in KB when DCVCYLMG is set to 0 or in MB when DCVCLYMG is set to 1)

You need to check bit DCVCYLMG and have logic like

if DCVCYLMG  == 1:
	  data["FreeSpVolKB"] = data["FreeSpVolKB"] * 1024

Adding or deleting fields

For some fields I did some calculations to simplify the processing. For example I wanted average time when I had total_time, and count.

I created average_time = total_time / count, added this field, and deleted total_time and count fields.

Error handling

I found some records have an error flag, for example “Error calculating volume capacity”. You need to decide what to do.

  • Do you include them, and have the risk, that the calculations/display of volume capacity might be wrong?
  • Do you report record during the collection stage, and not include them in the overall data?

How you accumulate the data, dicts or lists?

When using Pandas you can build each record as a dict of values {“kw1″:”v1″,”kw2″:”v2”}, then build a list of dicts [{}, {}…]

or have “column” have a list of values {“Jobname”: [“job1″,”job2″…],”CPUUsed”:[99,101…] … }. As you process each field you append it to the appropriate “column” field.

# a dict of lists
datad = {"dsn":["ABC","DEF"],
         "volser":["SYSRES","USER02"]}
datad["dsn"].append("GHI")
datad["volser"].append("OLDRES")

pdd =  pd.DataFrame(datal) 
 

# a list of dicts
dictl = [
    {"dsn":"ABC","volser":"SYSRES"},
    {"dsn":"DEF","volser":"USER02S"}]
newdict = {"dsn":"GHI","volser":"OLDRES"}

dictl.append(newdict)

pdl = pd.DataFrame.from_records(datal)

I think it is better to capture your data in a dict, then add the dict to the list of records.

For example with

DCVFRESP: Free Space on Volume (in KB when DCVCYLMG is set to 0 or in MB when DCVCLYMG is set to 1)

If you use a dict to collect the data, you can then easily massage the values, before adding the dict to the list.

if DCVCYLMG  == 1:
  data["FreeSpVolKB"] = data["FreeSpVolKB"] * 1024

grand_data.append[data]

If you try to do this using “column” values it gets really messy trying to do a similar calculation.

Using the data

It took a long time to process the dataset and create the Python data. I found it quicker overall to process the dataset once, and externalise the data using Pickle, or JSON. Then have different Python programs which read the data in and processed it. For example

  • Creating a new data structure using just the columns I was interested in.
  • Filtering which rows I wanted.
  • Save it

Pandas 102, notes on using pandas

Pandas is a great tool for displaying data from Python. You give it arrays of data, and it can display, summarise, group, print and plot. It is used for the simplest data, up to data analysts processing megabytes of data.

There is a lot of good information about getting started with Pandas, and how you can do advanced things with Pandas. I did the Pandas 101 level of reading, I struggled with the next step, so my notes for the 102 level of reading are below. Knowing that something can be done means you can go and look for it. If you look but cannot find, it may be that you are using the wrong search arguments, or there is no information on it.

Working with data

I’ve been working with “flat files” on z/OS. For example the output of DCOLLECT which is information about dataset etc from SMS.

One lesson I learned was you should isolate the extraction from the processing (except for trivial amounts of data). Extracting data from flat files can be expensive, and take a long time, for example it may include conversion from EBCDIC to ASCII. It is better to capture the data from the flat file in python variables, then write the data to disk using JSON, or pickle (Python object serialisation). As a separate step read the data into memory from your saved file, then do your data processing work, with pandas, or other tools.

Feeding data into Pandas

The work I’ve done has been two dimensional, rows and columns; you can have multi dimensional.

You can use a list of dictionaries(dicts), or dict of list:

# a dict of lists
datad = {"dsn":["ABC","DEF"],
         "volser":["SYSRES","USER02"]}
pdd =  pd.DataFrame(datal)  

# a list of dicts
datal = [{"dsn":"ABC","volser":"SYSRES"},
         {"dsn":"DEF","volser":"USER02S"},
        ]   

pdl = pd.DataFrame.from_records(datal)

Processing data like pdd = pd.DataFrame(datal) creates a pandas data frame. You take actions on this data frame. You can create other data frames from an original data fram, for example with a subset of the rows and columns.

I was processing a large dataset of data, and found it easiest to create a dict for each row of data, and then accumulate each row as a list. Before I used Pandas, I had just printed out each row. I do not know which performs better. Someone else used a dict of lists, and appended each row’s data to the “dsn” or “volser” list.

What can you do with it?

The first thing is to print it. Once the data is in Pandas you can use either of pdd or pdl above.

print(pdd)

gave

   dsn   volser
0  ABC   SYSRES
1  DEF  USER02S

Where the 0, 1 are the row numbers of the data.

With my real data I got

                                             DSN  ... AllocSpace
0   SYS1.VVDS.VA4RES1                             ...       1660
1   SYS1.VTOCIX.A4RES1                            ...        830
2   CBC.SCCNCMP                                   ...     241043
3   CBC.SCLBDLL                                   ...        885
4   CBC.SCLBDLL2                                  ...        996
..                                           ...  ...        ...
93  SYS1.SERBLPA                                  ...        498
94  SYS1.SERBMENU                                 ...        277
95  SYS1.SERBPENU                                 ...      17652
96  SYS1.SERBT                                    ...        885
97  SYS1.SERBTENU                                 ...        332

[98 rows x 7 columns]

The data was formatted to match my window size. With a larger window I got more columns.

You can change this by using

pd.set_option('display.max_rows', 500)
pd.set_option('display.max_columns', 500)
pd.set_option('display.width', 1000)

Which columns are displayed ?

Rather than all of the columns being displayed you can select which columns are displayed.

You can tell from the data you passed to pandas, or use the command

print(list(opd.columns.values))

This displays the values of the column names, as a list.

To display the columns you specify use

print(opd[["DSN","VOLSER","ExpDate","CrDate","LastRef","63bit alloc space KB", "AllocSpace"]])

You can say display all but the specified columns

print(opd.loc[:, ~opd.columns.isin(["ExpDate","CrDate","LastRef"])])

Select which rows you want displayed

print(opd.loc[opd["VOLSER"].str.startswith("A4"),["DSN","VOLSER",]])

or

print(opd.loc[opd["DSN"].str.startswith("SYS1."),["DSN","VOLSER",]])

gave

                                             DSN  VOLSER  
0   SYS1.VVDS.VA4RES1                             A4RES1  
1   SYS1.VTOCIX.A4RES1                            A4RES1  
12  SYS1.ADFMAC1                                  A4RES1  
13  SYS1.CBRDBRM                                  A4RES1  
14  SYS1.CMDLIB                                   A4RES1  
..                                           ...     ...  
93  SYS1.SERBLPA                                  A4RES1  
94  SYS1.SERBMENU                                 A4RES1  
95  SYS1.SERBPENU                                 A4RES1  
96  SYS1.SERBT                                    A4RES1  
97  SYS1.SERBTENU                                 A4RES1  

[88 rows x 2 columns]

From this we can see 88 (out of 97) rows were displayed. Row 0, 1 , 12, 13, but not rows 2, 3, …

What does .loc do?

My interpretation of this (which I haven’t seen documented)

If there is one parameter, this is a list of the columns you want.

If there are two parameters, the second is the list of the columns you want displayed. The first column is conceptually a list of True or False, with one value per row, saying if the row should be selected or not. So for

print(opd.loc[opd["VOLSER"].str.startswith("A4"),["DSN","VOLSER",]])

opd[“VOLSER”].str.startswith(“A4”)

says take the column called VOLSER, convert it to a string. If it starts with the string “A4” then return True, else return False. This returns a list of one entry per row.
The opd.loc[opd[“VOLSER”].str.startswith(“A4”),…) then selects the rows.

You can select rows and columns

print(opd.loc[opd["VOLSER"].str.startswith("A4"),["DSN","VOLSER","63bit alloc space KB",]])

You can process the data, such as sort

The following statements extracts columns from the original data, sorts the data, and creates a new data frame. The new data frame is printed. 

sdata= opd[["DSN","VOLSER","63bit alloc space KB",]].sort_values(by=["63bit alloc space KB","DSN"], ascending=False)
print(sdata)

This gave

                                             DSN  VOLSER  63bit alloc space KB
2   CBC.SCCNCMP                                   A4RES1                241043
35  SYS1.MACLIB                                   A4RES1                210664
36  SYS1.LINKLIB                                  A4RES1                166008
90  SYS1.SEEQINST                                 A4RES1                103534
42  SYS1.SAMPLIB                                  A4RES1                 82617
..                                           ...     ...                   ...
62  SYS1.SBPXTENU                                 A4RES1                    55
51  SYS1.SBDTMSG                                  A4RES1                    55
45  SYS1.SBDTCMD                                  A4RES1                    55
12  SYS1.ADFMAC1                                  A4RES1                    55
6   FFST.SEPWMOD3                                 A4RES1                    55

[98 rows x 3 columns]

Showing that all the rows, and all the (three) columns which had been copied to the sdata data frame.

Saving data

Reading an external file and processing the data into Python arrarys took an order of magnitude longer than processing it Pandas.

You should consider a two step approach to looking at data

  • Extract the data and exported it in an access format, such as Pickle or JSON. While getting this part working, use only a few rows of data. Once it works, you can process all of the data.
  • Do the analysis using the exported data.

Export the data

You should consider externalising the data in JSON or pickles format for example

# write out the data to a file
fPickle = open('pickledata', 'wb')    
    # source, destination
pickle.dump(opd, fPickle)                    
fPickle.close()

Import and do the analysis


# and read it in
fPickle = open('pickledata', 'rb')    
opd = pickle.load(fPickle)
fPickle.close()
print(odp)

Processing multiple data sources as one

If you have multiple sets of data, for example for Monday, Tuesday, Wednesday, etc you can use

week =  pd.concat(monday,tuesday,wednesday,thursday,friday)

Processing data within fields

Within my data, I have a field with information like

                   DSN  VOLSER           FormatType
0    SYS1.VVDS.VC4RES1  C4RES1                   []
1   SYS1.VTOCIX.C4RES1  C4RES1              [Fixed]
2          CBC.SCCNCMP  C4RES1    [Fixed, Variable]
3          CBC.SCLBDLL  C4RES1    [Fixed, Variable]
4         CBC.SCLBDLL2  C4RES1    [Fixed, Variable]

Where the data under FormatType is a list. You can reference elements in a list.

For example 

x =  data.FormatType.apply(lambda x: 'Variable' in x)
print(x)

gives

0     False
1     False
2      True
3      True
4      True

The command 

print(data.loc[ data.FormatType.apply(lambda x: 'Blocked' in x)])

gives

              DSN  VOLSER           FormatType
2     CBC.SCCNCMP  C4RES1    [Fixed, Variable]
3     CBC.SCLBDLL  C4RES1    [Fixed, Variable]
4    CBC.SCLBDLL2  C4RES1    [Fixed, Variable]

Basic operations on columns

You can do basic operations on columns such as

print(dataset[["CountIO","CacheHits"]].sum())

The sum() (and count() etc) functions add up the specified columns.

This gave

[361 rows x 10 columns]
CountIO      74667.0
CacheHits     1731.0
dtype: float64

An operation like

print(dataset.sum())

Would have totalled all the columns, including some which are meaningless, for example, maximum value found.

Doing aggregation, count, sum, maximum, minimum etc.

Simple aggregation

You can aggregate data

# Extract just the fields of interest
d = dataset[["DSN","CountIO","CacheHits"]]
print(d.groupby("DSN").sum())

Gave

                                        CountIO  CacheHits
DSN                                                       
ADCD.Z31B.PARMLIB                          68.0       60.0
ADCD.Z31B.PROCLIB                          66.0       66.0
ADCD.Z31B.VTAMLST                         141.0      141.0
COLIN.TCPPARMS                              4.0        4.0
FEU.Z31B.PARMLIB                            4.0        0.0
IXGLOGR.ATR.S0W1.RM.DATA.A0000000.DATA      4.0        0.0
SYS1.DAE                                    0.0        0.0
SYS1.DBBLIB                               974.0      932.0

More complex aggregation

The .agg() gives you much more control as to what, and how you want to process data.

print(d.groupby("DSN").agg({'DSN' : ['count'], 'CountIO' : ['sum','max'],"CacheHits": ["sum"]}))

gave

                                         DSN  CountIO          CacheHits
                                       count      sum      max       sum
DSN                                                                     
ADCD.Z31B.PARMLIB                         19     68.0      7.0      60.0
ADCD.Z31B.PROCLIB                         30     66.0      3.0      66.0
ADCD.Z31B.VTAMLST                          6    141.0     41.0     141.0
COLIN.TCPPARMS                             2      4.0      3.0       4.0
FEU.Z31B.PARMLIB                           1      4.0      4.0       0.0
IXGLOGR.ATR.S0W1.RM.DATA.A0000000.DATA     4      4.0      1.0       0.0
SYS1.DAE                                   1      0.0      NaN       0.0
SYS1.DBBLIB                                2    974.0    932.0     932.0

Notes:

  • The columns are not in the order I specified. It is hard to see which field Max applies to
  • There is a Not a Number (Nan) in one of the value. You need to allow for this.
  • In the simple case using .sum() by default it tries to sum all of the columns. Using .agg you can specify which columns you want to process

Processing a dataset is easy in Python.

I’ve been doing more with Python on z/OS, and have spent time using datasets. With the pyzfile package this is very easy! (Before this you had to copy a data set to a file in Unix Services).

You can do all the things you normally expect to do: open, close, read, write, locate, info etc.

from pyzfile import * 
def readfile(): 
   try: 
        with ZFile("//'COLIN.DCOLLECT.OUT'", "rb,type=record,noseek") as file: 
            for kw,value in file.info().items():            
               print(kw,":",value)
            for rec in file: 
               yield  rec 
    except ZFileError as e: 
        print(e,file=sys.stderr) 
                                                                                           
def reader(nrecords): 
    nth = 0                                                                            
    for line in readfile(): 
        nth += 1 
        if  nth > nrecords: 
            break 
        if nth % 100 == 99:
            print("Progress:",nth+1,file=sys.stderr)
        ## Do something..

It gave

access_method : QSAM
blksize : 27998
device : DISK
dsname : COLIN.DCOLLECT.OUT
dsorgConcat : False
dsorgHFS : False
dsorgHiper : False
dsorgMem : False
dsorgPDE : False
dsorgPDSdir : False
dsorgPDSmem : False
dsorgPO : False
dsorgPS : True
dsorgTemp : False
dsorgVSAM : False
maxreclen : 1020
mode : {'append': False, 'read': True, 'update': False, 'write': False}
noseek_to_seek : NOSWITCH
openmode : RECORD
recfmASA : False
recfmB : True
recfmBlk : True
recfmF : False
recfmM : False
recfmS : False
recfmU : False
recfmV : True
vsamRKP : 0
vsamRLS : NORLS
vsamkeylen : 0
vsamtype : NOTVSAM
Progress: 100
...

Where the fields are taken from fldata().

Great stuff!

Of course once you’ve got a record, doing something with it may be harder, because , for example Python is ASCII, and you’ll need to convert any character strings from EBCDIC to ASCII.

What is using all the space on this file system?

Help ! My ZFS has filled up shows how to use the du command to list entries under specified directory, and display the files using the most space. This may not be what you want, because you could have a second file system mounted over a sub-directory, and you do not want to include this in the output.

To display the size of files on the device, and not all sub-directories, use the command

find /u -xdev -size +2048 -exec ls -o {} \;|awk '{print  $4, $8 }' |sort -n -r |head -n 20

This command does

  • find
  • /u this directory
  • -xdev only files on this same file system – do not (x) go to a different device
  • -size +2048 where the size is greater(+) than 2048 of 512 byte blocks (1MiB)
  • -exec ls -o {} \; execute the command -ls -o on the name of the file
  • awk ‘{print $4, $8 }’ extract the 4th and 8th fields from the data – the size and file name
  • sort -n -r sort the data, treating the data as numbers(-n) in reverse order (-r). It defaults to the first column
  • head -n 20 and display only the first 20 lines of output.

I used this, and found I had many large files I didn’t want. I removed them, and got a lot of disk space back!

0/10 for JCL 101 homework

When I worked with customers, you could often tell people who were not experienced, and setting up subsystems and applications

“My first JCL”

//STEPLIB   DD DSN=ABC120.EG1.SABCAUTH,DISP=SHR   /* USER LIB  */ 
//          DD DSN=ABC120.SABCANLE,DISP=SHR 
//          DD DSN=ABC120.SABCAUTH,DISP=SHR 
//          DD DSN=CEE.SCEERUN,DISP=SHR 
...
//FILE1     DD DSN=ABC120.EG1.FILE01,DISP=SHR 
//FILE2     DD DSN=ABC120.EG1.FILE02,DISP=SHR

Where the FILE datasets contain user data.

All the ABC120.* datasets were shipped on a volume ABCV12. When the system was updated to a newer service level, the volume ABCV12 was refreshed and put on all systems.

What could go wrong?

The first problem – whoops

With the volume ABCV12 being replaced, all the user data is replaced – Whoops.

Solution: You need to keep your libraries and user data separate. Product libraries on ABCV12, and user data on USRxxx. You might want to make the volume for the product libraries (ABCV12) read only.

The second problem – what is this?

Once you have fixed the problem and separated the data onto different volumes you upgrade to the next version ABCV13.

Now your JCL is

//STEPLIB   DD DSN=ABC130.EG1.SABCAUTH,DISP=SHR   /* USER LIB  */ 
//          DD DSN=ABC130.SABCANLE,DISP=SHR 
//          DD DSN=ABC130.SABCAUTH,DISP=SHR 
//          DD DSN=CEE.SCEERUN,DISP=SHR 
...
//FILE1     DD DSN=ABC120.EG1.FILE01,DISP=SHR 
//FILE2     DD DSN=ABC120.EG1.FILE02,DISP=SHR

People looking at this will be confused and will ask what release are we running, it looks like 1.3, but the data sets say 1.2

Solution: Use a name like ABCUSER.EG1.FILE01 instead of ABC120.EG1.FILE01. These names never change when you migrate to a newer release.

You can enforce which HLQ’s can use which volumes using HSM rules.

You want to do a test upgrade to the next release: – how much work is it!!

Over this weekend, you want to test out the next release and go from release 1.3 to 1.4. You look at all your JCL, use SRCHFOR ABC130. and find all the places where you have ABC130 (wow, lots of places). You will have to change the JCL to run the subsystem at the start of the test, run your test, and change it all back ready for production next week. With all the changes you need to be careful not to make a mistake. (And of course all the change request paper work needs to be approved)

A better way is to use dataset aliases.

DEFINE ALIAS(NAME(ABC.SABCAUTH) RELATE(ABC120.SABCAUTH))
DEFINE ALIAS(NAME(ABC.SABCANLE) RELATE(ABC120.SABCANLE)) 
etc

So when you use ABC.SABCAUTH under the covers it uses ABC920.SABCAUTH

Your JCL now looks like

//STEPLIB   DD DSN=ABCUSR.EG1.SABCAUTH,DISP=SHR   /* USER LIB  */ 
//          DD DSN=ABC.SABCANLE,DISP=SHR 
//          DD DSN=ABC.SABCAUTH,DISP=SHR 
//          DD DSN=CEE.SCEERUN,DISP=SHR 
...
//FILE1     DD DSN=ABCUSER.EG1.FILE01,DISP=SHR 
//FILE2     DD DSN=ABCUSER.EG1.FILE02,DISP=SHR

You do not need to worry about APF authorising the CSQ.SCSQAUTH. The dataset which is checked is the dataset the alias points to.

To test the next release this weekend, you delete the aliases and define the new ones. You do not need to change your JCL libraries. You run your tests and at the end delete the new aliases and redefine the old one. The JCL will fit on one screen is much easier than changing all your JCL libraries, and less error prone. (And someone else can review the JCL before you make the changes)

An alternative way

You could use system symbolics EGHLQ = ABC120, and refer to it as in //STEPLIB DSN=&EGHLQ..SABCAUTH

Hands up…

If you are guilty of the problems raised in the blog post, you can get round them.

You can implement the alias for the product libraries, and gradually change all references to use the aliases.

Where you have

//FILE1     DD DSN=ABC120.EG1.FILE01,DISP=SHR 
//FILE2     DD DSN=ABC120.EG1.FILE02,DISP=SHR

You can define an alias for these and use DSN=ABCUSER.EG1.FILE01. Once you’ve made the change your friends will appreciate the clarity, and the only people who know about the mess you made are the storage administrators.

In the long term you may be able to fix it by copying the datasets to new ones with the proper name, and deleting the old ones.

Defining dataset aliases is good, but take care

I can define a dataset alias CSQ.SCSQAUTH which points to dataset CSQ920.SCSQAUTH, and use CSQ,SCSQAUTH in my JCL. When I want to change to the next level of code, I just change CSQ.SCSQAUTH to point to CSQ940.SCSQAUTH, and my JCL just works unchanged! Every one should do this.

Background

As part of z/OS catalogs, you can define aliases to keep user information out of the master catalog. For example point a high level qualifier to a catalog

DEFINE ALIAS (NAME(CSQ920) RELATE('USERCAT.Z31B.PRODS')
DEFINE ALIAS (NAME(CSQ) RELATE('USERCAT.Z31B.PRODS')

If I now define a dataset CSQ.COLIN, the information about this data set will be store in the catalog USERCAT.Z31B.PRODS. When the dataset is used, the name is looked up in the master catalog, which says go and use catalog USERCAT.Z31B.PRODS.

Dataset level aliases

I can also define an alias at the data set level. For example CSQ.SCSQAUTH is an alias of CSQ920.SCSQAUTH. I can then use CSQ.SCSQAUTH in my JCL instead of CSQ920.SCSQAUTH

When the next version of code is available, I can change the alias of CSQ.SCSQAUTH to point to CSQ940.SCSQAUTH and my JCL will work as before. I do not need to go through my JCL libraries and replacing the old with new. This is great – every one should use it.

Create the alias using

DEFINE ALIAS(NAME(CSQ.SCSQAUTH) RELATE(CSQ920.CSQ9.SCSQAUTH))

For this to work the data set alias CSQ.SCSQAUTH must be in the same catalog as the data set it references, so both name and target need to be in USERCAT.Z31B.PRODS.

If I use ISPF 3.4 with CSQ.SCSQAUTH it gives volume of *ALIAS. If I browse the dataset it shows data set CSQ920.CSQ9.SCSQAUTH.

You do not need to worry about APF authorisation because controls are on the target data set CSQ920.CSQ9.SCSQAUTH.

What problems did I have?

I had a frustrating hour or so until I got it to work.

I had a different user catalog for the CSQ HLQ.

DEFINE ALIAS (NAME(CSQ920) RELATE('USERCAT.Z31B.PRODS')
DEFINE ALIAS (NAME(CSQ) RELATE('USERCAT.COLINS')
DEFINE ALIAS(NAME(CSQ.SCSQAUTH) RELATE(CSQ920.CSQ9.SCSQAUTH))

The above statements worked successfully, but ISPF 3.4 did not show CSQ.SCSQAUTH.

The commands

LISTCAT CATALOG('CATALOG.Z31B.MASTER') ALIAS
LISTCAT CATALOG('USERCAT.COLINS') ALIAS

did not show any entries for CSQ.SCSQAUTH.
If I tried to redefine the data set alias, it said DUPLICATE entry.

I had to use

LISTCAT CATALOG('USERCAT.Z31B.PRODS') ALIAS

and there was my CSQ.SCSQAUTH.

The documentation says

If the entryname in the RELATE parameter is non-VSAM, choose an aliasname in the NAME parameter that resolves to the same catalog as the entryname.

which I missed the first time round.

I had to delete the dataset alias from the catalog for the target dataset

DELETE CSQ.SCSQAUTH  CATALOG('USERCAT.Z31B.PRODS')

I then deleted the alias for CSQ, redefined it to point to the correct user catalog, redefined the data set alias and it worked.

DELETE    CSQ          ALIAS 
DEFINE ALIAS (NAME(CSQ) RELATE('USERCAT.Z31B.PRODS')
DEFINE ALIAS(NAME(CSQ.SCSQAUTH) RELATE(CSQ920.CSQ9.SCSQAUTH))

Getting sshfs to work to z/OS

You can “mount” a remote file system as a local directory over sshfs. (ssh file system).

Getting this working was a challenge. I do not know if it is an FTP problem, or a z/OS problem

The command, from Linux, is

sshfs colin@10.1.1.2: ~/mountpoint

where mountpoint is a local directory, and my z/OS system is on 10.1.1.2

This flows into the SSH daemon (SSHD) on z/OS which handles the handshake and encryption.

For the IBM provided SSHD, the /etc/ssh/sshd_config config file has

Subsystem sftp /usr/lib/ssh/sftp-server

Where /usr/lib/ssh/sftp-server is the executable to do the work. The IBM supplied object is a load module. You could replace this with a script or other module.

Once the session has been established you can access the files, as if they were on the local system.

What is running on z/OS?

If you use the ps -ef command it displays

     UID        PID       PPID  CMD                                               
OMVSKERN   50397264   67174474  /usr/sbin/sshd -f /etc/ssh/sshd_config -R                                          
   COLIN   67174482   50397264  /usr/sbin/sshd -f /etc/ssh/sshd_config -R         
   COLIN   50397267   67174482  sh -c /usr/lib/ssh/sftp-server
   COLIN   83951719   50397267  /usr/lib/ssh/sftp-server

This shows the calling chain – the first (SSHD) is at the top, and the last, /usr/lib/ssh/sftp-server, is doing the work to process the files

The shell used depends on the OMVS(PROGRAM()) defined for the userid.

When did sshfs work?

If I had OMVS(PROGRAM(‘/bin/sh’)) then the sshfs worked ok, I could used the files as expected.

If the program was for bash or for zhs, then the data as seen from Linux was in EBCDIC and so was not usable.

So how do I use zsh or bash?

I got round this problem…

I specified the userid as having OMVS(PROGRAM(‘/bin/sh’)), and changed to use the bash shell in the logon script

If I logon with ssh colin@10.1.1.2 then there are environment variables in /etc/profile and ~/.profile. 

SSH_CLIENT="10.1.0.2 44898 22"
SSH_CONNECTION="10.1.0.2 44898 10.1.1.2 22"
SSH_TTY="/dev/ttyp0000"

In my ~/.profile I’ve put (thanks to Kirk Wolf for suggesting the better if interactive shell sta

tement)

# for all interactive sessions use the following if
#if [[ $- = *i* ]];
# for sessions only with ssh use the following ig statement
if [[ ! -z "$ SSH_CONNECTION"  ]] 
    # ssh: switch to bash....
     #set -x 
     #     bash="/usr/lpp/Rocket/rsusr/ported/bin/bash" 
      bash="/u/zopen/usr/local/bin/bash" 
      echo "shell was  $SHELL bash $bash"
      if [[ $SHELL != $bash ]] 
        then 
          echo "using the bash shell" $bashs
          export SHELL="$bash" 
          exec "$bash" # replace the current script with bash
         # any code after the exec is not executed  
      fi 
 fi

which says. If the $SSH_CONNECTION variable is not the empty string, (the session came in over an ssh connection) then invoke $bash, and it replaces the current environment with the /u/zopen/usr/local/bin/bash.

With this I could use both sshfs for remote file access, and ssh for terminal access.

If there are better ways of doing this, please let me know