### Table of Contents

- Usage
- General Comments
- GDXRANK Example
- RANK Example
- Example 1: Rank a vector, and display the data in sorted order
- Example 2: Generate percentiles for a random vector
- Example 3: Use GDXRANK to report multisectoral Monte Carlo results
- Example 4: Repeated computation of percentiles within a loop
- Example 5: Use GDXRANK generating percentiles for heterogenous households.

This utility consists of an executable file, `gdxrank.exe`

, and a GAMS libinclude file, `rank.gms`

. The former resides in the GAMS system directory, and the latter resides in the inclib/ subdirectory of GAMS system.

- Date
- July, 2003

**Source of this document**: http://www.mpsge.org/gdxrank/index.html

# Usage

## Usage for GDXRANK

GDXRANK reads one or more one dimensional parameters from a GDX file, sorts each parameter and writes the sorted indices as a one dimensional parameters to the output GDX file.

**Usage**:

gdxrank inputfile outputfile

Each one dimensional parameter is read from the input file, sorted and the corresponding integer permutation index written to the output file using the same name for the symbol. GAMS special values such as `Eps`

, `+Inf`

and `-Inf`

are recognized.

## Usage for RANK

$LIBINCLUDE rank v s r [p]

The first three arguments are required. The last is optional. These are defined as following:

Type | Argument | Description |
---|---|---|

Input: | v(s) | Array of values to be ranked. |

s | A one-dimensional set, the domain of array v. | |

Output: | r(s) | Rank order of element v(s), an integer between 1 and card(s), ranking from smallest to largest. |

Optional: (input and output) | p(*) | On input this vector specifies percentile levels to be computed. On output, it returns the linearly interpolated percentiles. |

# General Comments

- RANK only works for numeric data. You cannot sort sets.
- The first invocation must be outside of a loop or if block. This routine may be used within a
`loop`

or`if`

block only if it is first initialized with blank invocations (`"$LIBINCLUDE rank"`

in a context where set and parameter declarations are permitted (See Example 3). - The following names are used within these routines and may not be used in the calling program:
rank_tmp rank_u rank_p

- This routine returns rank values and does not return
`sorted vectors`

, however rank values are easily used to produce a sorted array. This can be done using computed "leads" and "lags" in GAMS' ordered set syntax, as illustrated in examples 1 and 3 below.

# GDXRANK Example

In this example we sort a parameter, create a sorted version and verify that the sort worked correctly:

set I /i1 * i6/; parameter A(I) /i1=+Inf, i2=-Inf, i3=Eps, i4= 10, i5=30, i6=20/; display A; * write symbol A to gdx file execute_unload "rank_in.gdx", A; * sort symbol; permutation index will be named A also execute 'gdxrank rank_in.gdx rank_out.gdx'; * load the permutation index parameter AIndex(i); execute_load "rank_out.gdx", AIndex=A; display AIndex; * create a sorted version parameter ASorted(i); ASorted(i + (AIndex(i)- Ord(i))) = A(i); display ASorted; * check that the result is sorted set C(i); C(i)=Yes$(Ord(i) < Card(i)) and (ASorted(i) > ASorted(i+1)); display C; Abort$(Card(C) <> 0) 'sort failed';

# RANK Example

## Example 1: Rank a vector, and display the data in sorted order

set i Set on which random data are defined /a,b,d,c,e,f /, k Ordered set for displaying sorted data/1*6/; parameter x(i) Random data to be sorted, r(i) Rank values, s(k,i) Sorted data; x(i) = uniform(0,1); $libinclude rank x i r display x; * Generate a sorted list using the ordered set k. * This assignment statement illustrates how the rank orders * can be used to sort output for display in proper order. This * statement uses GAMS support for computed "leads" and "lags" * on the ordered set k. The loop is used to improve execution * speed for larger dimensional sets: loop(k$sameas(k,"1"), s(k+(r(i)-1),i) = x(i); ); option s:3:0:1; display s;

Example1 writes the following lines to ex1.lst:

---- 11 PARAMETER x Random data to be sorted a 0.172, b 0.843, d 0.550, c 0.301, e 0.292, f 0.224 ---- 75 PARAMETER s Sorted data 1.a 0.172 2.f 0.224 3.e 0.292 4.c 0.301 5.d 0.550 6.b 0.843

Example1 writes the following lines to ex1.lst:

---- 11 PARAMETER x Random data to be sorted a 0.172, b 0.843, d 0.550, c 0.301, e 0.292, f 0.224 ---- 75 PARAMETER s Sorted data 1.a 0.172 2.f 0.224 3.e 0.292 4.c 0.301 5.d 0.550 6.b 0.843

## Example 2: Generate percentiles for a random vector

set i Set on which random data are defined /a,b,d,c,e /, p Percentiles (all of them) /0*100/; parameter x(i) Random data to be sorted; * Generate the random data on set i: x(i) = uniform(0,1); display x; parameter r(i) Rank values, pct(*) Percentiles to be computed /20 20.0, median 50.0, 75 75.0/; * Generate ranks and compute the specified percedntiles (Note that * the rank array, r, is required, even if the values are not used.) $libinclude rank x i r pct * Display three percentiles: display pct;

The random data are displayed as follows in the listing file:

---- 11 PARAMETER x Random data to be sorted a 0.172, b 0.843, d 0.550, c 0.301, e 0.292

The interpolated percentiles are computed as follows:

---- 103 PARAMETER pct Percentiles 20 0.268, 75 0.550, median 0.301

The following code evaluates a full set of percentiles, from 1 to 100. The GAMS special value of EPS is used to represent zero in the percentile calculation. (Percentiles between zero and one are not permitted to avoid misunderstandings about how percentiles are scaled.)

pct(p) = (ord(p) - 1) + eps; pct("median") = 0; display pct; $libinclude rank x i r pct display pct; * Plot the results using GNUPLOT: set pl(p) /20,40,60,80,100/; $setglobal domain p $setglobal labels pl $libinclude plot pct

## Example 3: Use GDXRANK to report multisectoral Monte Carlo results

One of the most perplexing challenges in economic modeling with GAMS is to present multisectoral results in an easily interpreted format. One simple idea is to present sectoral results in a sorted sequence to make it easier to identify the most seriously affectd sectors. The presentation of results in a multisectoral model is made even more challenging when model results are generated for a randomized set of scenarios. A summary of Monte Carlo results involves reporting both mean results and their sensitivity. One means of characterizing the sensitivity of model results is to report functions of the sample distribution such as the upper and lower quartiles.

In this example, I illustrate how gdxrank can be used to help report results from the Monte Carlo analysis of a multisectoral model.

SET run Samples (potentially not all solved) /1*1000/, i Sectors for which results are to be compared / ELE,OLE,OLP,GAS,COA,OFU,FME,NFM,CHM,MWO,TPP, CNM,CLO,FOO,OTH,CON,AGF,RLW,TRK,PIP,MAR,AIR, TRO,TMS,PST,TRD,CAT,OIN,PSM,SSM,ECM,SCS,GEO,FIN,ADM /; parameter v(run,i) Monte-Carlo results for all sectors; * Load the sectoral results from the sensitivity analysis from * a GDX file: $gdxin 'ex3.gdx' $load v set s(run) Solved cases, k Count used for quartiles /1*1000/, ki Count used for sectors /1*100/ qtl Quartiles (set) /q25,q50,q75/, imap(ki,i) Mapping from ordered list to sector labels; parameter qvalue(i,*) Quartile values mean(i) Mean impact on sector i, meanrank(i) Mean rank of sector i, x(run) Vector used for sorting, r(run) Rank values returned, qv(qtl) Quartiles (values) /q25 25, q50 50, q75 75/ quartile(qtl) Quartiles (evaluated); * Identify which scenarios have been solved (some of the runs * may have failed): s(run) = yes$(smax(i,abs(v(run,i))) ne 0); * Evaluate means and support for results: qvalue(i,"mean") = sum(s, v(s,i)) / card(s); qvalue(i,"min") = smin(s, v(s,i)); qvalue(i,"max") = smax(s, v(s,i)); display qvalue; * Determine ranking of sectors by mean impact: mean(i) = qvalue(i,"mean"); $libinclude rank mean i meanrank * The following statement creates a tuple matching the ordered * set, ki, to the set of sectors, i. In this tuple, the sequence of * assignments corresponds to increasing mean impacts: imap(ki+(meanrank(i)-ord(ki)),i) = yes; * Evaluate quartiles of sectoral impacts for each sector: loop(i, x(s) = v(s,i); * Load quartile with the perctiles to be * evaluated (25th, 50th and 75th): quartile(qtl) = qv(qtl); $libinclude rank x s r quartile * Save the quartile values: qvalue(i,qtl) = quartile(qtl); ); display qvalue; parameter results(ki,i,*) Summary of impacts (sorted); results(ki,i,"mean")$imap(ki,i) = mean(i); results(ki,i,qtl)$imap(ki,i) = qvalue(i,qtl); display results;

The program produces the following display output:

q25 q50 q75 mean 1 .FOO -13.767 -12.110 -10.671 -12.259 2 .MWO -13.496 -11.982 -10.512 -12.035 3 .SCS -12.244 -10.418 -8.738 -10.588 4 .CLO -8.763 -7.407 -6.158 -7.480 5 .ADM -7.865 -5.601 -3.470 -5.812 6 .CNM -6.437 -5.320 -4.404 -5.461 7 .OTH -5.732 -4.781 -4.012 -4.892 8 .PIP -3.142 -1.930 -0.836 -2.145 9 .OIN -2.124 -1.339 -0.563 -1.358 10.TPP -2.527 -0.988 0.521 -1.041 11.GEO -1.542 -0.826 -0.196 -0.883 12.AGF -1.178 -0.624 -0.072 -0.625 13.ECM 0.137 0.466 0.796 0.441 14.SSM 0.303 0.711 1.079 0.684 15.CON 0.604 1.071 1.479 1.041 16.PST 0.814 1.924 2.966 1.858 17.RLW 1.885 2.787 3.632 2.738 18.OFU 2.789 3.300 3.829 3.330 19.OLE 3.155 3.553 3.964 3.554 20.ELE 3.480 3.896 4.318 3.892 21.PSM 3.733 4.134 4.591 4.168 22.CAT 3.216 4.417 5.461 4.369 23.TRO 3.953 5.123 6.549 5.282 24.OLP 4.614 5.262 5.909 5.295 25.TRD 5.694 6.454 7.250 6.476 26.AIR 5.227 7.182 9.276 7.320 27.FIN 4.919 7.301 10.175 7.640 28.COA 6.581 7.818 9.125 7.878 29.TMS 5.668 8.530 11.086 8.591 30.CHM 8.071 9.299 10.534 9.319 31.TRK 7.031 9.367 11.851 9.577 32.MAR 9.485 13.072 16.424 13.049 33.GAS 4.437 13.183 22.311 13.462 34.FME 14.794 16.617 18.382 16.642 35.NFM 23.299 26.398 29.281 26.263

The tabular report is helpful, but it does not convey the results as immediately as a picture. GNUPLOT's errorbar plot format is a convenient graphical format for portraying this information. The libinclude interface to GNUPLOT does not support this type of plot, so the continuation of the program produces the GNUPLOT command and data files before invoking the GNUPLOT program:

* Write out a GNUPLOT file to generate a chart of the results: file kplt /ex3.gnu/; put kplt; kplt.lw=0; put "reset"/; put 'set title "Sectoral Impacts with Quartiles"'/; put "set linestyle 1 lt 8 lw 1 pt 8 ps 0.5"/; put "set grid"/; put 'set ylabel "% change"'/; put "set xzeroaxis"/; put "set bmargin 4"/; put "set xlabel 'sector'"/; put 'set xrange [1:',card(i),']'/; put 'set xtics rotate ('; loop(ki, loop(i$imap(ki,i), put '\'/' "',i.tl,'" ',ord(ki):0,',';)); put @(file.cc-1) ')'/; put "plot 'ex3.dat' notitle with errorbars ls 1"/; putclose; file kpltdata /ex3.dat/; put kpltdata; kpltdata.nr=2; kpltdata.nw=14; kpltdata.nd=6; loop(ki, loop(i$imap(ki,i), put ord(ki):0,qvalue(i,"mean"), qvalue(i,"q25"), qvalue(i,"q75")/;)); putclose; execute 'wgnupl32 ex3.gnu -';

## Example 4: Repeated computation of percentiles within a loop

$title GAMS Program Illustrates Repeated Computation of Percentiles $ontext Dear Prof Rutherford, I am sorry to bother you again. If you recall I was having difficulty with the ‘rank’ function. I wasn’t able to run it in loop and use the 95th percentile value as a constraint in the next run of the loop, while also retaining a value of the 95th percentile for every iteration of the loop. [model below]. In the loop $libinclude rank call I ask GAMS to place the ranked values in pct, it only runs for 1 iteration before the ‘user error’ in rank. Whereas if I ask gams to put the ranked values in pct2, it runs for 2 iterations before saying ‘user error’. This must mean that the rank function only allows pct to be over-written once, after which it ‘fills up’ and generates a user error? How can I over come this? In your last email you though the problem was that the original values are being over written. So I introduced xparam95(iter). I think rank does not allow them to be overwritten. I am only a novice and have been stuck on this for sometime, your help will be invaluable. Kind regards, Ashar $offtext set iter Iterations /iter1*iter10/, week Weeks in the year /1*52/, percentile Percentiles (all of them) /1*100/, pctl(percentile) Percentiles to be computed /50, 75, 80, 95/; parameter z(week) Values to be sorted, rnk(week) Rank values, pct(*) Percentiles to be computed (input) and those values (output), pct0(*) Percentiles to be computed, pctval(iter,*) Percentile values in successive iterations; * Generate a "permanent copy" of the percentiles to be computed. * This will be used to initialize pct before each call to rank; pct0(percentile)$pctl(percentile) = ord(percentile); * Assume that a model solution delivers the values; z(week) = uniform(0,1); * Assign the percentile values to be computed here: pct(pctl) = pct0(pctl); display "Here are the INPUT values of PCT0 and PCT prior to the call to rank:", pct0, pct; $libinclude rank z week rnk pct display "Here are the values of PCT0 and PCT after the call to rank:", pct0, "Note that rank has changed the OUTPUT value of pct", pct; * Do several iterations, computing percentiles in each step: loop(iter, * Substitute a call to the NLP solver by a call to the random * number generator. In many applications, this substitution * produces profoundly more sensible results. * * solve catchment using nlp maximizing max; z(week) = uniform(0,1); * If you want to retrieve percentile values, you need to reassign * the percentiles that you wish to retrieve at this point in the * program. If pct() were not reassigned at this point, the INPUT * values would correspond to the OUTPUTs from the previous call. pct(pctl) = pct0(pctl); $libinclude rank z week rnk pct pctval(iter,pctl) = pct(pctl); ); display pctval; Output: ---- 58 Here are the INPUT values of PCT0 and PCT prior to the call to rank: ---- 58 PARAMETER pct0 Percentiles to be computed 50 50.000, 75 75.000, 80 80.000, 95 95.000 ---- 58 PARAMETER pct Percentiles to be computed (input) and those values (output) 50 50.000, 75 75.000, 80 80.000, 95 95.000 ---- 153 Here are the values of PCT0 and PCT after the call to rank: ---- 153 PARAMETER pct0 Percentiles to be computed 50 50.000, 75 75.000, 80 80.000, 95 95.000 ---- 153 Note that rank has changed the OUTPUT value of pct ---- 153 PARAMETER pct Percentiles to be computed (input) and those values (output) 50 0.424, 75 0.662, 80 0.712, 95 0.864 ---- 273 PARAMETER pctval Percentile values in successive iterations 50 75 80 95 iter1 0.345 0.594 0.638 0.922 iter2 0.385 0.633 0.672 0.941 iter3 0.474 0.705 0.766 0.962 iter4 0.627 0.796 0.823 0.978 iter5 0.428 0.682 0.793 0.904 iter6 0.422 0.690 0.729 0.958 iter7 0.558 0.716 0.756 0.902 iter8 0.451 0.638 0.726 0.942 iter9 0.464 0.704 0.755 0.916 iter10 0.564 0.805 0.831 0.974

## Example 5: Use GDXRANK generating percentiles for heterogenous households.

$title Percentile ranking of household expenditure data with heterogenous household size set h /0*100/; parameter y(h) Aggregate expenditure associated with household type h, n(h) Number of persons associated with household type h, ypc(h) Per-capita expenditure of household type h rank(h) Rank of household in per-capita expenditure; * Assigne some random values: y(h) = uniform(0.2,1.2); n(h) = uniform(1,6); ypc(h) = y(h) / n(h); * Assign ranks to household based on per-capita expenditures: $libinclude rank ypc h rank * Now determine percentile ranking of the households taking into account * differences in numbers of members and household representation: set r Temporary set used for ranking /r0*r100/; parameter pcttmp(r) Temporary array for computing percentiles, pct(h) Percentile rankings for households; set r0(r) /r0/; * First, create an array with households assigned * loop((r0(r),h), pcttmp(r+(rank(h)-1)) = n(h);); loop(r, pcttmp(r) = pcttmp(r) + pcttmp(r-1);); pcttmp(r) = pcttmp(r) / sum(h, n(h)); loop((r0(r),h), pct(h) = pcttmp(r+(rank(h)-1));); parameter ranking Ranking of households and expenditures; loop((r0(r),h), ranking(r+(rank(h)-1),h,"n") = n(h); ranking(r+(rank(h)-1),h,"ypc") = ypc(h); ranking(r+(rank(h)-1),h,"pct") = pct(h); ); display ranking; Output: n ypc pct r0 .43 5.662 0.044 0.018 r1 .8 5.682 0.047 0.036 r2 .58 4.477 0.052 0.050 r3 .14 5.742 0.058 0.068 r4 .55 4.815 0.063 0.083 r5 .65 3.702 0.063 0.094 r6 .61 5.880 0.064 0.113 r7 .54 4.463 0.064 0.127 .... r98 .62 1.134 0.640 0.991 r99 .10 1.673 0.716 0.997 r100.73 1.053 1.076 1.000