AWK — a Blast from Wrangling Past.

AWK script to match attribute number with column header name.

dict.awk

gawk -F, ‘BEGIN{OFS=”,”} NR==1 {split($0,dict,”,”);for (d in dict) print d, dict[d]}’ psam_pusa.csv

Command line to run dict.awk (and some of the output).

./dict.awk 2>null | head

1,RT
2,SERIALNO
3,DIVISION
4,SPORDER
5,PUMA
6,REGION
7,ST
8,ADJINC
9,PWGTP
10,AGEP

Basic awk script to filter and project pertinent data from the four pums files.

pums.awk

gawk -F, ‘BEGIN{OFS=”,”} (NR==1 || FNR!=1) && ($10>=18 && $104>1000) \
{print $2,$3,$5,$6,$7,$8,$10,$39,$67,$69,$89,$104,$112}’ psam_pusa.csv psam_pusb.csv psam_pusc.csv psam_pusd.csv

Next, a python script that consumes/processes the data piped from awk. The script creates a dataframe from the input data and outputs a high-performance feather file that interoperates with R and Linux OS’s.

pums.py

import sys, pandas as pd, numpy as np, feather

import warnings
warnings.filterwarnings(‘ignore’)

functdir = “c:/steve/jupyter/notebooks/functions”
sys.path.append(functdir)

from newmyfuncs import *

fthname = “pumspy.feather”

pums = pd.read_csv(sys.stdin,header=0)
pums.columns = [c.lower() for c in pums.columns]

print(pums.shape,”\n”)
print(pums.columns,”\n”)
print(pums.dtypes,”\n”)

feather.write_dataframe(pums,fthname)

prarr(pums)

Command line to link the awk and python scripts. Output included. Almost 11M records with 13 attributes — in 70 seconds elapsed time.

time ./pums.awk 2>null | python pums.py

(10925570, 13)

Index([‘serialno’, ‘division’, ‘puma’, ‘region’, ‘st’, ‘adjinc’, ‘agep’, ‘mar’,
‘schl’, ‘sex’, ‘hisp’, ‘pincp’, ‘rac1p’],
dtype=’object’)

serialno int64
division int64
puma int64
region int64
st int64
adjinc int64
agep int64
mar int64
schl int64
sex int64
hisp int64
pincp int64
rac1p int64
dtype: object

    serialno  division  puma  region  st  ...  schl  sex  hisp  pincp  rac1p   

0 2013000000154 6 2500 3 1 … 20 2 1 52000 2
1 2013000000154 6 2500 3 1 … 16 1 1 99000 2
2 2013000000156 6 1700 3 1 … 21 2 1 39930 2
3 2013000000160 6 2200 3 1 … 14 2 1 10300 3
4 2013000000160 6 2200 3 1 … 16 1 1 1100 3

[5 rows x 13 columns]

           serialno  division  puma  region  ...  sex  hisp  pincp  rac1p   

10925565 2017001533765 8 300 4 … 1 1 29800 1
10925566 2017001534830 8 200 4 … 2 1 9000 1
10925567 2017001534957 8 300 4 … 1 24 4000 1
10925568 2017001535265 8 200 4 … 2 1 5000 9
10925569 2017001536156 8 400 4 … 1 1 2400 1

[5 rows x 13 columns]

real 1m9.569s
user 1m1.576s
sys 0m2.359s

Now a similar exercise with R. The same pums.awk feeds the R script.

pums.r

suppressMessages(library(readr))
suppressMessages(library(data.table))
suppressMessages(library(fst))
suppressMessages(library(feather))

wd <- “c:/bigdata/steve/awk”
setwd(wd)

fstnme <- “pumsfst.fst”
fthnme <- “pumsfth.feather”

f <- file(“stdin”)
open(f)
pums <- data.table(read_csv(readLines(f,n=-1)))

setnames(pums,tolower(names(pums)))

print(dim(pums))
print(str(pums))
head(pums)
tail(pums)

write_fst(pums,fstnme)
write_feather(pums, fthnme)

Command line to run pums.awk and pipe output to pums.r. Output included. 125 seconds that includes writing feather and fst files. Note that the R readr loader makes different data type choices than pandas.

time ./pums.awk 2>null | rscript pums.r

[1] 10925570 13 Classes ‘data.table’ and ‘data.frame’: 10925570 obs. of 13 variables:
serialno:num2.01e+122.01e+122.01e+122.01e+122.01e+12… division: num 6 6 6 6 6 6 6 6 6 6 …
puma:chr”02500″”02500″”01700″”02200″… region : num 3 3 3 3 3 3 3 3 3 3 …
st:chr”01″”01″”01″”01″… adjinc : num 1061971 1061971 1061971 1061971 1061971 …
agep:num55566361207881595670… mar : num 1 1 3 4 5 2 2 1 1 1 …
schl:chr”20″”16″”21″”14″… sex : num 2 1 2 2 1 2 2 1 2 1 …
hisp:chr”01″”01″”01″”01″… pincp : chr “000052000” “000099000” “000039930” “000010300” …
$ rac1p : num 2 2 2 3 3 2 1 1 1 1 …

• attr(*, “.internal.selfref”)=
  serialno division puma region st adjinc agep mar schl sex hisp pincp
  1: 2.013e+12 6 02500 3 01 1061971 55 1 20 2 01 000052000
  2: 2.013e+12 6 02500 3 01 1061971 56 1 16 1 01 000099000
  3: 2.013e+12 6 01700 3 01 1061971 63 3 21 2 01 000039930
  4: 2.013e+12 6 02200 3 01 1061971 61 4 14 2 01 000010300
  5: 2.013e+12 6 02200 3 01 1061971 20 5 16 1 01 000001100
  6: 2.013e+12 6 02400 3 01 1061971 78 2 01 2 01 000003900
  rac1p 1: 2
  2: 2
  3: 2
  4: 3
  5: 3
  6: 2

  serialno division  puma region st  adjinc agep mar schl sex hisp 

  1: 2.017002e+12 8 00500 4 56 1011189 51 3 20 1 01
  2: 2.017002e+12 8 00300 4 56 1011189 19 5 18 1 01
  3: 2.017002e+12 8 00200 4 56 1011189 20 5 19 2 01
  4: 2.017002e+12 8 00300 4 56 1011189 18 5 16 1 24
  5: 2.017002e+12 8 00200 4 56 1011189 31 5 18 2 01
  6: 2.017002e+12 8 00400 4 56 1011189 60 3 19 1 01

  pincp rac1p 

  1: 000035300 1
  2: 000029800 1
  3: 000009000 1
  4: 000004000 1
  5: 000005000 9
  6: 000002400 1

real 1m53.440s
user 1m0.655s
sys 0m2.779s

Finally, a more sophisticated pums.awk that uses associative arrays. This works for command lines using both pums.py and pums.r as above.

pums.awk

gawk -F, ‘BEGIN{OFS=”,”} NR==1 {split($0,dict,”,”);for (d in dict) newdict[dict[d]] = d}\ (NR==1 || FNR!=1) && ($newdict[“AGEP”]>=18 && $newdict[“PINCP”]>1000)\ $newdict[“SERIALNO”],$newdict[“DIVISION”],$newdict[“REGION”],$newdict[“ST”],$newdict[“PUMA”],$newdict[“AGEP”],$newdict[“HICOV”],\ $newdict[“MAR”],$newdict[“RAC1P”],$newdict[“HISP”],$newdict[“SEX”],$newdict[“SCHL”],$newdict[“PINCP”],$newdict[“ADJINC”]}’ psam_pusa.csv psam_pusb.csv psam_pusc.csv psam_pusd.csv

Fun. My take is that dusty AWK can indeed serve an important role in 2019 data pipelines — provided that it’s used simply and to its projecting/filtering strengths. That’s it for now. Off to Octoberfest. Happy wrangling!¶