9.2.0.6 Intersection Error

Similar Messages

• "Invalid cell intersection" error

  Hi,
  I'm a beginner in administering and using Hyperion Financial Management 11.1.1.3
  I'm trying to enter an Intercompany transaction in HFM on the workspace but, after I'd specified the transaction ID and picked the members, I pressed the save button and I got the following error: "Invalid cell intersection".
  I created the following rule file and loaded it but still the error arised:
  HS.Account.IsICP("ShortTermPay") = TRUE
  HS.Account.IsICP("ShortTermDebt") = TRUE
  HS.Entity.IsICP("Stamford") = TRUE
  HS.Entity.IsICP("Florida") = TRUE
  Sub Transaction()
  HS.SupportsTran "S#Actual.A#ShortTermPay"
  HS.SupportsTran "S#Actual.A#ShortTermDebt"
  End sub
  I want to define an account as IC account and also an entity as ICP. Do you know how?
  I loaded an ICTrans file which is a sample installed with Hyperion but the same error arised.
  I'd appreciate any help.
  Thank you and best regards,
  Ahmed.

  Hi JTF,
  Thank you sooooo much for your reply.
  Really, you solved my issue.
  I saved the two IC transactions I've created successfully but when I match them "Auto Match" by account, I faced the following error: "missing account and/or matching account"
  Do you know what to do?
  Thank you again.
  Ahmed

• Getting Invalid Intersection for Account with net 0 balance

  Hi FDM Gurus,
  We are getting an invalid intersection error for an account that nets to zero in the validate step, because the individual amounts that net to zero are coming in from the source system without an ICP member (hence mapping to ICP None).     The account in HFM is an "IsICP", so ICP None is invalid (is blocked for input by a rule).
  The individual amounts in the import section include 2 source accounts that are mapped to the same account, and also mapped to the exact same dimension members for that HFM account:
  E00210 B420199 [ICP NONE] NORF NOFUNC FDMLOAD NOC4 <ENTITY CURRENCY>    1000
  E00210 B420199 [ICP NONE] NORF NOFUNC FDMLOAD NOC4 <ENTITY CURRENCY>   -1000
  In the validate step, the data is condensed into 1 line, with a zero balance.
  E00210 B420199 [ICP NONE] NORF NOFUNC FDMLOAD NOC4 <ENTITY CURRENCY>   0
  Here is the invalid intersection report.   Interestingly, only 1 of the 2 offsetting accounts (one with the negative balance) shows up in the report:
  Detail Dimensions:
  FM Entity FM Account ICP NOE_RF Function DataType C4 Data Value Amount
  E00210 B420199 [ICP NONE] NORF NOFUNC FDMLOAD NOC4 <ENTITY CURRENCY>   -1000
  Does anyone know how to avoid this issue?   We tried to post a journal for each line item in which we tried to 'back out' the source system amount (offsetting entry) and  included another entry with a valid ICP member.   But we still get the invalid intersection error.
  Is there a way to fix this (short of doing something in the import script to prevent data from importing, which we prefer not to do)?
  Thanks,
  Mark

  Thanks for the reply.          Actually, in this situation, the source data is coming in with an ICP partner (999) that is mapped ato [ICP None].    It's an exceptional case where the source data in this account contained an ICP partner that we already have mapped to ICP None, and it was not possible to go back and change the source data. BUT the source account has to be mapped to an IsICP account in HFM (one-off situation).
  So we posted the journal to try to zero out the balance, and make additional entry in the journal to manually move the balance to an ICP partner.
  I would think if the balance is 0.00 in the account, it would not try to validate the intersection in HFM.   But it seems to be validating based on each individual source account, although they net out to zero in total for the HFM account.
  I'm not sure if there is much we can do here.  Just hoping maybe someone had run into the issue and could share how they resolved it...

• Pathfinder problems... CS4 (just upgraded)

  There seems to be some shift in the function of the pathfinders. It only seems to work for me about half the time, other times it wont do the simplest things and spits out the message "Could not complete operation. Pathfinder result describes empty region."
  Here's what it's doing at the moment:
  I have a circle with a rectangle overlapping part of it.
  Add: Error
  Subtract:
  works just fine
  Intersect: Error
  Exclude Overlap: Error
  Minus Back: Error
  The objects are on the same layer. The objects were created with the circle and box tools (so the shapes
  are closed. Both shapes have solid fills using the same color model.
  What gives? Is there a difference in the way it functions? Or has my software gone screwy?
  Thanks!
  -Ted

  I have had the problem a number of times, now I'll try to track some doc specs when it occurs. Though fwiw, I
  have been working in docs over 12 pages
  Copying the objects to a new doc did work, so that's a work around for the moment anyhow. Annoying...
  Now off to the photoshop forum and the disappearing tool shape/outline issue...
  :p
  -Ted
  Don't get me wrong though--CS4 has many nice new things that make it well worth the price of admission.

• Intersection Validation Report error

  After clicking the Validate step to get the intersection validation report (Enable Intersection Validation) is turned on, I get the following error in a new window
  "The XML page cannot be displayed Cannot view XML input using XSL style sheet. Please correct the error and then click the Refresh button, or try again later."
  Any help would be appreciated

  You can't open the XML directly from the outbox. The user ID that you are accessing the file with will likeyl not have access to the directory where the XSL file is stored. The XSL file is used to translate the XML file into a viewable format.
  You can copy the XSL file into a directory where you do have access and modify the XML to look to that directory.
  BTW, please open new threads for your questions.
  Edited by: TonyScalese on Apr 14, 2011 1:35 PM

• FDM: Error retrieving audit intersection cell information

  Hi,
  Could anyone please tell me how to resolve an error we've been having?
  When I right click in a cell in HFM with a view to using the Audit Intersection menu pick to review data uploaded using FDM, I see the error message "Error retrieving audit intersection cell information". Strangly, this works fine in our PPD environment, but we can't seem to get it working in Live even though the Drill-Back set up was copied across from PPD (with references to PPD changed to Live obviously)
  Thanks in advance
  Phil

  Which Version of HFM are you on? I know that in 9.3.1 Classic, you must update the metadata between migrations to the specific application name of FDM, if you have the same FDM app name, this would not apply, but if they change, you will need to change the metadata between them. The FDM app name is defined in the Application Settings dimension of metadata.
  JTF

• FDM 11.1.2.3  intersection validation error

  Hello All,
  we have migrated from EPM 11.1.1.3 to EPM 11.1.2.3.
  in EPM 11.1.2.3 FDM,  when we import any flat file delimited by comma and then tried to validate it we are getting Intersection validation error
  same flat file can be validated successfully in old system EPM 11.1.1.3.
  any ideas, where do i start to troubleshoot this issue ?
  regards,
  -Dattatray Mate

  Hi -Dattatray Mate
  I think you are loading data to HFM
  your data value is empty in FDM
  Select  < entity currency> in FDM
  In FDM locations-> General -> DataValue  there you can select  < entity currency>
  and in CUSTOM 3 you have not set custom top members in HFM  i guess (Valid member combination to load data )
  please check these things

• Runtime Error '1004':, Method 'Intersect' of object '_Global' failed

  Hello
  I am getting a runtime error 1004, can someone tell me why?  I am getting the runtime error on the first Application.Intercept statement.
  Thank you for your help!
  smsemail
  Private Sub Worksheet_Change(ByVal Target As Range)
  Application.ScreenUpdating = False
  Application.DisplayAlerts = False
  If Not Application.Intersect(Target, Me.Range("A:A")) Is Nothing Then
  lastRow = ActiveSheet.Range("A" & Rows.Count).End(xlUp).Row
  If lastRow < 17 Then
  Exit Sub
  End If
  If lastRow > 67 Then
  lastRow = 67
  End If
  Else
  Exit Sub
  End If
  If Not Application.Intersect(Target, Me.Range("A17:A" & lastRow)) Is Nothing Then
  Application.EnableEvents = False
  If Application.WorksheetFunction.CountA(Worksheets("RIPS").Range("A17:A67")) = 0 Then
  Exit Sub
  End If
  If Application.WorksheetFunction.CountA(Worksheets("RIPS").Range("B17:B67")) = 0 And _
  Application.WorksheetFunction.CountA(Worksheets("RIPS").Range("C17:C67")) = 0 And _
  Application.WorksheetFunction.CountA(Worksheets("RIPS").Range("D17:D67")) = 0 Then
  Exit Sub
  End If
  If CmdExecute = True Then
  Exit Sub
  End If
  If CmdClear = True Then
  Exit Sub
  End If
  Worksheets("RIPSSummary").Activate
  lastRow = ActiveSheet.Range("A" & Rows.Count).End(xlUp).Row
  Set SourceRange = Application.Intersect(Range("A2:A" & lastRow), ActiveSheet.UsedRange)
  MsgBox "Source Range: " & SourceRange
  Worksheets("RIPS").Activate
  lastRow = ActiveSheet.Range("A" & Rows.Count).End(xlUp).Row
  Set TargetRange = Application.Intersect(Range("A17:A" & lastRow), ActiveSheet.UsedRange)
  MsgBox "Target Range: " & TargetRange
  Exit Sub
  wsDeleted = False
  For Each acell In SourceRange.Cells
  RecordFound = True
  If Not IsEmpty(acell.Value) Then
  Set C = TargetRange.Find(acell.Value, LookIn:=x1values)
  If C Is Nothing Then
  RecordFound = False
  End If
  If RecordFound = False Then
  wsDeleted = True
  For Each Worksheet In Worksheets
  If Worksheet.Name = acell.Value Then
  Worksheet.Delete
  End If
  Next Worksheet
  End If
  End If
  Next acell
  If vbKeyDelete Or _
  vbKeyClear Then
  r = lastRow
  Do Until r < 17
  If Worksheets("RIPS").Range("A" & r).Value = "" Then
  Rows(r).Delete
  End If
  r = r - 1
  Loop
  End If
  Application.EnableEvents = True
  End If
  Application.ScreenUpdating = True
  Application.DisplayAlerts = True
  End Sub

  It should work but maybe there's something about your workbook we can't see.
  In passing generally best not to disable screenupdating, alerts or events unless need to do so. More importantly though you should ensure they always get reset. As written you have several Exit Sub's before any code that resets them. Also in case of an error
  consider resetting them in an error handler.

• Error with intersects function

  I've an error I don't understand the cause.(it worked before the SDK update)
  Here is my code :
       * Permet de vérifier que l'évênement passé en paramètre n'en chavauche aucun autre
      function detectCollision(guiEvent: DayEvent) {
          // On sélectionne tous les évênements affichés sauf celui pour lequel on test les limites
          for (e in app_events.displayedEvents.content[p | p.id != guiEvent.id]) {
              if (e.intersects(guiEvent.boundsInLocal.minX, guiEvent.boundsInLocal.minY+5, guiEvent.boundsInLocal.width, guiEvent.boundsInLocal.height-10) == true) {
                  guiEvent.guiEvent.stroke = Color.RED;
                  collisionsDetected = true;
                  break;
              } else {
                  guiEvent.guiEvent.stroke = Color.rgb(77,130,178);
                  collisionsDetected = false;
      }"DayEvent" is a Group...("e" too)
  The error is:
  "An internal error has occurred in the OpenJFX compiler."

  This is helpful... :-)
  I can reproduce the error with the simple code:
  var app_events: Node[];
  var collisionsDetected: Boolean;
  function detectCollision(guiEvent: Group) {
    for (e in app_events[p | p.visible]) {
      if (e.intersects(guiEvent.boundsInLocal.minX, guiEvent.boundsInLocal.minY+5, guiEvent.boundsInLocal.width, guiEvent.boundsInLocal.height-10) == true) {
        collisionsDetected = true;
        break;
      } else {
        collisionsDetected = false;
  }I suggest you report the bug to Jira / Kenai with the above code. If you don't want or cannot, just tell, I will do.
  *[EDIT]* I went ahead, since I could reproduce it, and made the bug [http://javafx-jira.kenai.com/browse/JFXC-3283]
  As guessed from the cryptic error, the problem comes from the break instruction. So a workaround is not to use it! :-) Or to change the instructions. Maybe the compiler thinks that break is supposed to be a value (implicit return).
  A possible solution is:
  function detectCollision(guiEvent: Group) {
    for (e in app_events[p | p.visible]) {
      collisionsDetected = e.intersects(
          guiEvent.boundsInLocal.minX, guiEvent.boundsInLocal.minY+5,
          guiEvent.boundsInLocal.width, guiEvent.boundsInLocal.height-10);
      if (collisionsDetected) break;
  }Simple, elegant (in my eye!) and compiling...
  A less breaking solution (ie. with minimal change to your code) is to say your function returns nothing: function detectCollision(guiEvent: DayEvent): Void
  Another, perhaps better, is to return true or false instead of changing some global variable.
  The compiler tries hard to guess the types, but sometime it fails and behaves badly or even crashes...
  Edited by: PhiLho on Jun 18, 2009 3:45 PM

• BExAnalyzer: SAPBEXsetFilterValue and others: runtime error 1004, Intersect

  Hello there,
  any idea why e.g. SAPBexSetFilterValue does not work any more in BI7.0?
  We need to set serveral filter values by macro which worked like a charme in BW3.5.
  Now, all functions that have to to with filter values cause a runtime error 1004, saying that the intersect-property of the application object could not be assigned.
  Does anyone have the same problem or even a solution or just a snipplet of working code (set or get a filter value).
  As far as I've found out, the drill-down-functions may cause the same problem.
  Any hints are welcome. Thank you.

  Sure, here it is. Simple enough, but not working no matter what I try:
  Dim result As Long
      ' last parameter (atCell) left out. Cursor placed on filter cell for costcenter. If you have a look
      ' at the API, then the ActiveCell will be used in that case. This worked quite good in BW 3.5
      result = Run("SAPBEXSetFilterValue", "DE00DECCR10000", "0HIER")
      ' The statement above will call the following code inside the API:
      '    Public Function SAPBEXsetFilterValue(intValue As String, Optional hierValue As String, Optional atCell As Range) As Integer
      '      extErrorBegin ("3.x API SAPBEXsetFilterValue called")
      '      If atCell Is Nothing Then Set atCell = Application.ActiveCell
      '      SAPBEXsetFilterValue = paddin.SAPBEXsetFilterValue(ActiveWorkbook.Name, intValue, hierValue, atCell)
      '      extErrorEnd
      '    End Function
      ' No matter if I use my statement (Run(...)) or call the API statement directly, I always receive a runtime error '1004',
      ' saying that the intersect-property of application-object could not be assigned.
  SAPBEXSetFilterValue worked like a charme in BW3.5. We used it in several workbooks for automation and this becomes a really big problem now in BW7.0.
  Any help/idea welcome!

• FDM Intersection validation error

  Hi,
  When I try to load data to HFM thru FDM, I am getting 'MISSING VALUE' error during 'export' step. I have enabled selected 'Enable Intersection Validation' and this time I see error during 'validate' step.Intersection Validation report is generated during 'Validate' step and it shows dimension 'Data Value' and value as [MISSING _VALUE] for the same.
  I have given values for all the dimensions in HFM and all are coming perfectly.But I'm not able to figure out where the 'Data Value' is coming from.After 'Data Value', I see Amount which has the original data value specified in the data file.
  I have also checked 'FDM Web ServerName' which is set to 'local host'. Can any one suggest me if there is anything I'm missing.
  Thanks in advance

  hi what kind of MISSING VALUE error you guys got. can you please let me know in detail.
  as i am new to FDM. please help me in understanding. thanks for providing some knowledge on your valuable time.

• Intersection type confusion (or javac or JLS error?)

  I am confused about what methods are available for a type parameter with multiple bounds.
  Consider the slightly modified version of the jls [url http://java.sun.com/docs/books/jls/third_edition/html/typesValues.html#120149]discussion  on type variables:
  package TypeVarMembers;
  class C {
    void mCDefault() {}    
    public void mCPublic() {}      
    private void mCPrivate() {}
    protected void mCProtected() {}
  abstract class CT extends C implements I {}
  interface I {  
    void mI();
  class X
    <T extends C & I> void test(T t, CT ct) {   
      t.mI(); // OK
      t.mCDefault(); // OK
      t.mCPublic(); // OK
      t.mCPrivate(); // compile-time error
      t.mCProtected(); // OK
      ct.mCDefault();
  }The modification are declaring CT abstract, putting the method test inside the class X and adding parameter of type CT to test.
  When I try to compile this I get error
  $ javac -g Intersection.java
  Intersection.java:20: cannot find symbol
  symbol: method mCDefault()
      t.mCDefault(); // OKNote that I do not get the error for similar call to CT.
  Is this something I have misunderstood?
  Thanks in advance for your time and responses.

  I found [url http://bugs.sun.com/bugdatabase/view_bug.do?bug_id=5073060]bug 5073060, Package private members not found for intersection types which is the issue I was confused about.
  Thankfully, I seem to have understood the spec correctly. The fix won't be available till Jaguar but at least I found a work-around.
  Sorry to bother you all without looking first, but it was only because I felt it was probably my lack of understanding rather then compiler bug.

• Error 00936 -Missing expression for INTERSECT function

  My sql is simple one:
  I have 2 tables customer and user module. I want to get customer id and count of
  users for that customer which has both module id 9 and 13 assigned to him.
  I am using an intersect to remove duplicates.
  select c.cust_id as "Customer Id",
    select count(user_id) from
       (select um.user_id from user_mod um
           um.user_cust_id = c.cust_id
            and um.umod_id = 9
         INTERSECT
        select um.user_id from user_mod um
        um.user_cust_id = c.cust_id
        and um.umod_id = 13
      ) as "Both Modules"
  from
  customer c
  where c.not_del = 0However I am getting a ora00936 at "select count(user_id)". Anyobdy know why and how to overcome it?

  The scalar subquery in your SELECT needs to be enclosed in parens like this:
  SELECT c.cust_id as "Customer Id", 
         (SELECT COUNT(user_id)
         FROM (SELECT um.user_id
               FROM user_mod um
               WHERE um.user_cust_id = c.cust_id and
                     um.umod_id = 9
               INTERSECT
               SELECT um.user_id
               FROM user_mod um
               WHERE um.user_cust_id = c.cust_id and
                     um.umod_id = 13)) as "Both Modules"
  FROM customer c
  WHERE c.not_del = 0.
  However, that will still not work since Oracle will not recognize c.cust_id in the nested part of the query. I would tend to write your query as something like:
  SELECT c.cust_id as "Customer Id"
  FROM customer c,
       (SELECT user_cust_id, COUNT(*) cnt
        FROM (SELECT user_cust_id
              FROM user_mod
              WHERE umod_id = 9
              INTERSECT
              SELECT user_cust_id
              FROM user_mod
              WHERE umod_id = 13)
        GROUP BY user_cust_id) b
  WHERE c.cust_id = b.user_cust_id(+) and
        c.not_del = 0HTH
  John

• Audit Intersection - HFM to FDM drill back error: 2656

  Since we created a new HFM application and switched our existing FDM application to read off of the new one drill back no longer works. We get this error message . . .
  Error: An error occurred logging on to the system using single sign-on. Please contact your administrator:
  Error: 2656 - The single sign-on script is not enabled or does not exist. Please contact your administrator.

  Verify that the FDQM application name matches the name in the FDMAPPName field in the HFM application Settings.

• Bus error - Help!

  Hi,
  I've been asked to see if I can fix a C program so that it will run on a mac. It currently compiles and runs perfectly on a linux machine, but as soon as you run it on a mac, it will compile, but quit with a bus error very early on. The full code is here:
  // Program for the construction of cartograms (density-equalizing map
  // projections) using the Gastner-Newman technique. The program needs polygon
  // coordinates and a count of cases in each region as input, calculates the new
  // coordinates, and writes these to a file. Postscript images of the original
  // map and the cartogram are created.
  // WRITTEN BY MICHAEL GASTNER, September 20, 2004.
  // If you use output created by this program please acknowledge the use of this
  // code and its first publication in:
  // "Generating population density-equalizing maps", Michael T. Gastner and
  // M. E. J. Newman, Proceedings of the National Academy of Sciences of the
  // United States of America, vol. 101, pp. 7499-7504, 2004.
  // The input coordinates in MAPGENFILE must be in ArcInfo "generate" format of
  // the type:
  // 1
  // 0.3248690E+06 0.8558454E+06
  // 0.3248376E+06 0.8557575E+06
  // 0.3248171E+06 0.8556783E+06
  // 0.3247582E+06 0.8556348E+06
  // 0.3246944E+06 0.8555792E+06
  // 0.3246167E+06 0.8555253E+06
  // 0.3250221E+06 0.8557324E+06
  // 0.3249436E+06 0.8557322E+06
  // 0.3248690E+06 0.8558454E+06
  // END
  // 1
  // 0.3248690E+06 0.8558454E+06
  // 0.3249651E+06 0.8558901E+06
  // 0.3250519E+06 0.8559769E+06
  // 0.3250691E+06 0.8561246E+06
  // 0.3249678E+06 0.8560541E+06
  // 0.3249003E+06 0.8560088E+06
  // 0.3076424E+06 0.8477603E+06
  // 0.3075691E+06 0.8477461E+06
  // 0.3075595E+06 0.8476719E+06
  // END
  // 2
  // 0.6233591E+06 0.6056502E+06
  // 0.6235193E+06 0.6056467E+06
  // 0.6235054E+06 0.6055372E+06
  // 0.7384296E+06 0.2334260E+06
  // 0.7383532E+06 0.2345770E+06
  // END
  // END
  // The number of cases in CENSUSFILE must be given in the form
  // region #cases (optional comment), e. g:
  // 43 0.9 Alabama
  // 51 0.3 Alaska
  // 37 0.8 Arizona
  // 47 0.6 Arkansas
  // 25 5.4 California
  // 32 0.8 Colorado
  // 19 0.8 Connecticut
  // 29 0.3 Delaware
  // 28 0.3 District of Columbia
  // 49 2.5 Florida
  // 45 1.3 Georgia
  // 1 0.4 Hawaii
  // The output coordinates are written to CARTGENFILE in ArcInfo "generate"
  // format. A postscript image of the original input is prepared as MAP2PS,
  // an image of the cartogram as CART2PS.
  // Modified on Oct 29, 2004. The number of divisions in each dimension lx, ly
  // will now be determined from the input map. Also fixed array bound
  // violations in intpol and newt2, and centered the ps-files.
  // Modified on Dec 3, 2004. Introduced pointers bbmaxx,bbmaxy,bbminx,bbminy -
  // the bounding box coordinates for each polygon - to reduce calculations in
  // crnmbr. Thanks to Chris Brunsdon for the suggestion.
  // Program now terminates with error message if there is no density specified
  // in CENSUSFILE for a region on the map.
  // "Donut" polygons are now handled properly. Polygons oriented clockwise will
  // be considered exterior boundaries. If they are oriented anti-clockwise they
  // are holes inside an enclosing polygon. (Unconventional for mathematicians,
  // but this is ArcGIS standard.) The identifier is either that of the enclosing
  // polygon, or -99999 in which case it is a hole in the preceding polygon.
  // The population can now be a floating-point number.
  // If a region contains exactly zero population, it will be replaced by
  // MINPOPFAC times the smallest positive population in any region.
  // Obviously, MINPOPFAC should be <1, I will set it to 0.1 by default. This
  // should reduce the value of sigma necessary for the integrator to finish
  // properly.
  // Modified on March 31, 2005. Initialized maxchange in nonlinvoltra() as
  // INFTY. Replaced crnmbr() by a similar, but faster routine interior().
  // Many thanks to Stuart Anderson for pointing out this shortcut.
  // TO DO LIST:
  // - Do Gaussian blur within nonlinvoltra as a simple call to calcv and
  // eliminate gaussianblur().
  // - Modify the NR code for the FFTs to deal more naturally with the fencepost
  // issue. No more copying of arrays in sinft and cosft.
  // - Write truly two-dimensional versions of coscosft, cossinft, and sincosft.
  // See Chan and Ho: A new two-dimensional fast cosine transform algorithm,
  // IEEE Transactions on Signal Processing, 39, 481ff. (1991).
  // - Read polygon data directly from shapefile instead of generate file.
  // - Reorganize data structures. It is currently quite a mess to read.
  // Inclusions
  #include <math.h>
  #include <stdio.h>
  #include <stdlib.h>
  // Definitions
  #define CART2PS "./cart.ps","w" // Cartogram image.
  #define CARTGENFILE "./cartogram.gen" // Cartogram generate file.
  #define CENSUSFILE "./census.dat","r" // Input.
  #define CONVERGENCE 1e-100 // Convergence criterion for integrator.
  // #define DISPLFILE "./displ.dat","w"
  #define FALSE 0
  #define HINITIAL 1e-4 // Initial time step size in nonlinvoltra.
  #define IMAX 50 // Maximum number of iterations in Newton-Raphson routine.
  #define INFTY 1e100
  #define LINELENGTH 1000
  #define MAP2PS "map.ps","w" // Map image.
  #define MAPGENFILE "./map.gen","r" // Input coordinates.
  #define MAX(a,b) ((b>a)?(b):(a))
  #define MAXINTSTEPS 3000 // Maximum number of time steps in nonlinvoltra.
  #define MAXNSQLOG 18 // The number of sample points for rho_0 is <~2^MAXNSQLOG.
  #define MIN(a,b) ((b<a)?(b):(a))
  #define MINH 1e-5 // Smallest permitted time step in the integrator.
  #define MINPOPFAC 0.1 // Replace 0 population by a fraction of the minimum.
  #define NR_END 1
  #define NSUBDIV 1 // Number of linear subdivisions for digitizing the density.
  #define PADDING 1.5 // Determines space between map and boundary.
  #define PI 3.141592653589793
  #define SIGMA 0.1 // Initial width of Gaussian blur.
  #define SIGMAFAC 1.2 // Increase sigma by this factor. Must be > 1.
  #define SWAP(a,b) tempr=(a);(a)=(b);(b)=tempr;
  #define TIMELIMIT 1e8 // Maximum time allowed in integrator.
  #define TOLF 1e-3 // Sensitivity w. r. t. function value in newt2.
  #define TOLINT 1e-3 // Sensitivity of the integrator.
  #define TOLX 1e-3 // Sensitivity w. r. t. independent variables in newt2.
  #define TRUE !FALSE
  // Types
  typedef int BOOLEAN;
  typedef struct
  float x;
  float y;
  } POINT;
  // Globals
  float bbmaxx,*bbmaxy,*bbminx,*bbminy,**gridvx,*gridvy,maxx,maxy,minpop,
  minx,miny,polymaxx,polymaxy,polyminx,polyminy,*rho,**rho_0,**vx,**vy,*x,
  *xappr,xstepsize,**y,*yappr,ystepsize;
  int lx,ly,maxid,nblurs=0,npoly,npolycorn,*npolyinreg,nregcorn,nregion,
  polygonid,**polyinreg,*regionid,*regionidinv,*within;
  POINT *polycorn,*regcorn;
  // Function prototypes
  int readline(char line[],FILE *infile);
  void countpoly(FILE *infile);
  void countcorn(FILE *infile);
  void readcorn(FILE *infile);
  void makeregion(void);
  void pspicture(FILE *outfile);
  void bboxes(void);
  void interior(void);
  double regionarea(int ncrns,POINT *polygon);
  void digdens(void);
  void four1(float data[],unsigned long nn,int isign);
  void realft(float data[],unsigned long n,int isign);
  void cosft(float z[],unsigned long n,int isign);
  void sinft(float z[],unsigned long n,int isign);
  void coscosft(float **y,int isign1,int isign2);
  void cossinft(float **y,int isign1,int isign2);
  void sincosft(float **y,int isign1,int isign2);
  float **dmatrix(long nrl,long nrh,long ncl,long nch);
  float *d3tensor(long nrl, long nrh, long ncl, long nch, long ndl, long ndh);
  void free_matrix(float **m,long nrl,long nrh,long ncl,long nch);
  void free_f3tensor(float *t,long nrl,long nrh,long ncl,long nch,long ndl,
  long ndh);
  void fourn(float data[],unsigned long nn[],int ndim,int isign);
  void rlft3(float *data,float **speq,unsigned long nn1,unsigned long nn2,
  unsigned long nn3,int isign);
  void gaussianblur(void);
  void initcond(void);
  void calcv(float t);
  float intpol(float **arr,float x,float y);
  BOOLEAN newt2(float h,float *xappr,float xguess,float *yappr,float yguess,
  int j,int k);
  BOOLEAN nonlinvoltra(void);
  POINT transf(POINT p);
  void cartogram(void);
  // Function to read one line.
  int readline(char line[],FILE *infile)
  if (fgets(line,LINELENGTH,infile)==NULL) return 1;
  return 0;
  // Function to count the number of polygons.
  void countpoly(FILE *infile)
  char line[LINELENGTH];
  npoly = 0;
  while (!readline(line,infile)) if (line[0] == 'E') npoly++;
  npoly--; // The .gen file ends with two consecutive "END"s.
  // Function to count polygon corners. Also determines minimum/maximum x-/y-
  // coordinate.
  void countcorn(FILE *infile)
  BOOLEAN bnd_ok = FALSE;
  char line[LINELENGTH];
  float x,y;
  int polyctr=0,ratiolog;
  npolycorn = (int*)calloc(npoly,sizeof(int));
  polycorn = (POINT*)malloc(npoly*sizeof(POINT));
  readline(line,infile); // Skip first line.
  readline(line,infile);
  sscanf(line,"%f %f",&x,&y);
  polyminx = x; polymaxx = x; polyminy = y; polymaxy = y;
  npolycorn[0] = 1;
  while (!readline(line,infile))
  if (line[0] != 'E')
  sscanf(line,"%f %f",&x,&y);
  if (x < polyminx) polyminx = x;
  if (x > polymaxx) polymaxx = x;
  if (y < polyminy) polyminy = y;
  if (y > polymaxy) polymaxy = y;
  npolycorn[polyctr]++;
  else
  readline(line,infile);
  polycorn[polyctr] = (POINT)malloc(npolycorn[polyctr]sizeof(POINT));
  polyctr++;
  if (ceil(log((polymaxx-polyminx)/(polymaxy-polyminy))/log(2))+
  floor(log((polymaxx-polyminx)/(polymaxy-polyminy))/log(2))>
  2*log((polymaxx-polyminx)/(polymaxy-polyminy))/log(2))
  ratiolog = (int)floor(log((polymaxx-polyminx)/(polymaxy-polyminy))/log(2));
  else
  ratiolog = (int)ceil(log((polymaxx-polyminx)/(polymaxy-polyminy))/log(2));
  lx = (int)pow(2,(int)(0.5*(ratiolog+MAXNSQLOG)));
  ly = (int)pow(2,(int)(0.5*(MAXNSQLOG-ratiolog)));
  if ((polymaxx-polyminx)/lx > (polymaxy-polyminy)/ly)
  maxx = 0.5((1PADDING)*polymaxx(1-PADDING)polyminx);
  minx = 0.5((1-PADDING)*polymaxx(1PADDING)polyminx);
  maxy = 0.5(polymaxypolyminy(maxx-minx)ly/lx);
  miny = 0.5(polymaxy+polyminy-(maxx-minx)ly/lx);
  else
  maxy = 0.5((1PADDING)*polymaxy(1-PADDING)polyminy);
  miny = 0.5((1-PADDING)*polymaxy(1PADDING)polyminy);
  maxx = 0.5(polymaxxpolyminx(maxy-miny)lx/ly);
  minx = 0.5(polymaxx+polyminx-(maxy-miny)lx/ly);
  // Uncomment the next lines for interactive choice of boundary conditions.
  /* printf("For the %i polygon(s) under consideration:\n",npoly);
  printf("minimum x = %f\tmaximum x = %f\n",polyminx,polymaxx);
  printf("minimum y = %f\tmaximum y = %f\n",polyminy,polymaxy);
  while (!bnd_ok)
  printf("Type in your choice of boundaries.\nminx = ");
  scanf("%f",&minx);
  printf("maxx = ");
  scanf("%f",&maxx);
  printf("miny = ");
  scanf("%f",&miny);
  printf("maxy = ");
  scanf("%f",&maxy);
  if (minx>polyminx || maxx<polymaxx || miny>polyminy || maxy<polymaxy)
  printf("Invalid choice, does not enclose the polygon(s).\n");
  else bnd_ok = TRUE;
  // Function to read polygon corners. The first and last vertex of each polygon
  // must be identical.
  void readcorn(FILE *infile)
  char line[LINELENGTH];
  float xcoord,ycoord;
  int i,id,polyctr=0;
  polygonid = (int)malloc(npolysizeof(int));
  xstepsize = (maxx-minx)/lx;
  ystepsize = (maxy-miny)/ly;
  if (fabs((xstepsize/ystepsize)-1)>1e-3)
  fprintf(stderr,"WARNING: Area elements are not square: %f : %f\n",
  xstepsize,ystepsize);
  readline(line,infile);
  sscanf(line,"%i",&id);
  polygonid[polyctr] = id;
  i = 0;
  while (!readline(line,infile))
  if (line[0] != 'E')
  sscanf(line,"%f %f",&xcoord,&ycoord);
  polycorn[polyctr].x = (xcoord-minx)/xstepsize;
  polycorn[polyctr][i++].y = (ycoord-miny)/ystepsize;
  else
  // Is first and last vertex the same?
  if (fabs(polycorn[polyctr][0].x-
  polycorn[polyctr][npolycorn[polyctr]-1].x)+
  fabs(polycorn[polyctr][0].y-
  polycorn[polyctr][npolycorn[polyctr]-1].y)>1e-12)
  fprintf(stderr,
  "ERROR: %i-th polygon does not close upon itself.\n",
  polyctr+1);
  fprintf(stderr,"Identifier %i, first point %f %f.\n",
  polygonid[polyctr],polycorn[polyctr][0].x*xstepsize+minx,
  polycorn[polyctr][0].y*ystepsize+miny);
  exit(1);
  readline(line,infile);
  sscanf(line,"%i",&id);
  i = 0;
  polyctr++;
  if (polyctr<npoly) polygonid[polyctr] = id;
  polyminx = (polyminx-minx)/xstepsize;
  polyminy = (polyminy-miny)/ystepsize;
  polymaxx = (polymaxx-minx)/xstepsize;
  polymaxy = (polymaxy-miny)/ystepsize;
  // Function to make regions from polygons.
  void makeregion(void)
  BOOLEAN repeat;
  int i,lastid,minid,polyctr,ptctr,regctr;
  // Count the number of regions.
  nregion = 0;
  maxid = minid = polygonid[0];
  for (polyctr=0; polyctr<npoly; polyctr++)
  if (polygonid[polyctr] == -99999) continue;
  if (polygonid[polyctr]>maxid || polygonid[polyctr]<minid) nregion++;
  else
  repeat = FALSE;
  for (i=0; i<polyctr; i++)
  if (polygonid[polyctr]==polygonid)
  repeat = TRUE;
  break;
  if (!repeat) nregion++;
  if (polygonid[polyctr]>maxid) maxid = polygonid[polyctr];
  if (polygonid[polyctr]<minid) minid = polygonid[polyctr];
  if (minid < 0)
  fprintf(stderr,
  "ERROR: Negative region identifier %i.\n",minid);
  exit(1);
  // Match region identifiers.
  regionid = (int)malloc(nregionsizeof(int));
  nregion = 0;
  maxid = minid = polygonid[0];
  for (polyctr=0; polyctr<npoly; polyctr++)
  if (polygonid[polyctr] == -99999) continue;
  if (polygonid[polyctr]>maxid || polygonid[polyctr]<minid)
  regionid[nregion++] = polygonid[polyctr];
  else
  repeat = FALSE;
  for (i=0; i<polyctr; i++)
  if (polygonid[polyctr]==polygonid)
  repeat = TRUE;
  break;
  if (!repeat) regionid[nregion++] = polygonid[polyctr];
  if (polygonid[polyctr]>maxid) maxid = polygonid[polyctr];
  if (polygonid[polyctr]<minid) minid = polygonid[polyctr];
  regionidinv = (int)malloc((maxid+1)sizeof(int));
  // Negative number for unused identifiers.
  for (i=0; i<=maxid; i++) regionidinv = -1;
  for (regctr=0; regctr<nregion; regctr++)
  regionidinv[regionid[regctr]] = regctr;
  // Which polygons contribute to which regions?
  npolyinreg = (int*)calloc(nregion,sizeof(int));
  polyinreg = (int*)malloc(nregion*sizeof(int));
  lastid = polygonid[0];
  for (polyctr=0; polyctr<npoly; polyctr++)
  if (polygonid[polyctr] != -99999)
  npolyinreg[regionidinv[polygonid[polyctr]]]++;
  lastid = polygonid[polyctr];
  else npolyinreg[regionidinv[lastid]]++;
  for (regctr=0; regctr<nregion; regctr++)
  polyinreg[regctr] = (int)malloc(npolyinreg[regctr]sizeof(int));
  for (regctr=0; regctr<nregion; regctr++) npolyinreg[regctr] = 0;
  lastid = polygonid[0];
  for (polyctr=0; polyctr<npoly; polyctr++)
  if (polygonid[polyctr] != -99999)
  polyinreg[regionidinv[polygonid[polyctr]]]
  [npolyinreg[regionidinv[polygonid[polyctr]]]++] = polyctr;
  lastid = polygonid[polyctr];
  else polyinreg[regionidinv[lastid]][npolyinreg[regionidinv[lastid]]++]
  = polyctr;
  // Make regions from polygons. Start and end each polygon at (0,0).
  nregcorn = (int*)calloc(nregion,sizeof(int));
  regcorn = (POINT*)malloc(nregion*sizeof(POINT));
  for (regctr=0; regctr<nregion; regctr++)
  for (i=0; i<npolyinreg[regctr]; i++)
  nregcorn[regctr] += npolycorn[polyinreg[regctr]]+1;
  nregcorn[regctr]++;
  for (regctr=0; regctr<nregion; regctr++)
  regcorn[regctr] = (POINT)malloc(nregcorn[regctr]sizeof(POINT));
  ptctr = 0;
  regcorn[regctr][ptctr].x = regcorn[regctr][ptctr++].y = 0.0;
  for (polyctr=0; polyctr<npolyinreg[regctr]; polyctr++)
  for (i=0; i<npolycorn[polyinreg[regctr][polyctr]]; i++)
  regcorn[regctr][ptctr++] = polycorn[polyinreg[regctr][polyctr]];
  regcorn[regctr][ptctr].x = regcorn[regctr][ptctr++].y = 0.0;
  // Function to prepare a map in postscript standard letter format.
  void pspicture(FILE *outfile)
  char line[LINELENGTH];
  float addx,addy,b,conv,g,r;
  int ptctr,regctr;
  if (11*lx > 8.5*ly)
  conv = (float)8.5*72/lx;
  addx = 0;
  addy = 1136-8.5*36ly/lx;
  else
  conv = (float)11*72/ly;
  addx = 8.536-11*36lx/ly;
  addy = 0;
  fprintf(outfile,"0.5 setlinewidth\n");
  for (regctr=0; regctr<nregion; regctr++)
  fprintf(outfile,"newpath\n");
  fprintf(outfile,"%f %f moveto\n",
  regcorn[regctr][1].x*conv+addx,
  regcorn[regctr][1].y*conv+addy);
  for (ptctr=2; ptctr<nregcorn[regctr]; ptctr++)
  if (fabs(regcorn[regctr][ptctr].x)+
  fabs(regcorn[regctr][ptctr].y)>1e-12)
  fprintf(outfile,"%f %f lineto\n",
  regcorn[regctr][ptctr].x*conv+addx,
  regcorn[regctr][ptctr].y*conv+addy);
  else
  fprintf(outfile,"closepath\n");
  if (ptctr<nregcorn[regctr]-1)
  ptctr++;
  fprintf(outfile,"%f %f moveto\n",
  regcorn[regctr][ptctr].x*conv+addx,
  regcorn[regctr][ptctr].y*conv+addy);
  // Determine colors for map (without better knowledge I will do it
  // arbitrarily).
  if (regctr%3 == 0)
  r = (float)regctr/nregion;
  g = 1-(float)regctr/nregion;
  b = fabs(1-2*(float)regctr/nregion);
  else if (regctr%3 == 1)
  b = (float)regctr/nregion;
  r = 1-(float)regctr/nregion;
  g = fabs(1-2*(float)regctr/nregion);
  else
  g = (float)regctr/nregion;
  b = 1-(float)regctr/nregion;
  r = fabs(1-2*(float)regctr/nregion);
  fprintf(outfile,"%f %f %f setrgbcolor\ngsave\nfill\n",r,g,b);
  fprintf(outfile,"grestore\n0 setgray stroke\n");
  fprintf(outfile,"showpage\n");
  // Function to find the bounding box for each polygon.
  void bboxes(void)
  int i,j;
  float maxx, minx, maxy, miny;
  bbmaxx = (float)malloc(npolysizeof(float));
  bbmaxy = (float)malloc(npolysizeof(float));
  bbminx = (float)malloc(npolysizeof(float));
  bbminy = (float)malloc(npolysizeof(float));
  for (i = 0; i < npoly; i++)
  maxx = polycorn[0].x;
  maxy = polycorn[0].y;
  minx = maxx;
  miny = maxy;
  for (j = 0; j < npolycorn; j++)
  if (polycorn[j].x > maxx) maxx = polycorn[j].x;
  if (polycorn[j].x < minx) minx = polycorn[j].x;
  if (polycorn[j].y < miny) miny = polycorn[j].y;
  if (polycorn[j].y > maxy) maxy = polycorn[j].y;
  bbmaxx=maxx;
  bbmaxy=maxy;
  bbminx=minx;
  bbminy=miny;
  void interior(void)
  int i,inhowmanyregions,inregion[2],j,k,l,m,n,regctr;
  // Initialize within[][]. -1 means outside all regions.
  for (i=0; i<=lx; i++) for (j=0; j<=ly; j++) within[j] = -1;
  // Fill within[][].
  for (i=0; i<nregion; i++) for (j=0; j<npolyinreg; j++)
  for (k=0, n=npolycorn[polyinreg[j]]-1;
  k<npolycorn[polyinreg[j]]; n=k++)
  for (l=(int)ceil(MIN(polycorn[polyinreg[j]][k-1].y,
  polycorn[polyinreg[j]][k].y));
  l<MAX(polycorn[polyinreg[j]][k-1].y,
  polycorn[polyinreg[j]][k].y); l++)
  for (m=(int)floor(bbminx[polyinreg[j]]);
  m<(polycorn[polyinreg[j]][n].x-
  polycorn[polyinreg[j]][k].x)*
  (l-polycorn[polyinreg[j]][k].y)/
  (polycorn[polyinreg[j]][n].y-
  polycorn[polyinreg[j]][k].y)+
  polycorn[polyinreg[j]][k].x;
  m++)
  within[m][l] = i-within[m][l]-1;
  // Function to determine polygon area. This is needed to determine the average
  // population.
  // The problem in short is to find the area of a polygon whose vertices are
  // given. Recall Stokes' theorem in 3d for a vector field v:
  // integral[around closed curve dA]v(x,y,z).ds =
  // integral[over area A]curl(v).dA.
  // Now let v(x,y,z) = (0,Q(x,y),0) and dA = (0,0,dx*dy). Then
  // integral[around closed curve dA]Q(x,y)dy = integral[over area A]dQ/dxdxdy.
  // If Q = x:
  // A = integral[over area A]dx*dy = integral[around closed curve dA]x dy.
  // For every edge from (x,y) to (x[i1],y[i1]) there is a
  // parametrization
  // (x(t),y(t)) = ((1-t)xtx[i+1],(1-t)y+ty[i1]), 0<t<1
  // so that the path integral along this edge is
  // int[from 0 to 1]{(1-t)xt*x[i+1]}(y[i1]-y)dt =
  // 0.5(y[i1]-y)(x+x[i1]).
  // Summing over all edges yields:
  // Area = 0.5*[(x[0]+x[1])(y[1]-y[0]) + (x[1]+x[2])(y[2]-y[1]) + ...
  // ...(x[n-1]+x[n])(y[n]-y[n-1])+(x[n]x[0])(y[0]-y[n])]
  // ArcGIS treats a clockwise direction as positive, so there is a minus sign.
  double regionarea(int ncrns,POINT *polygon)
  double area=0;
  int i;
  for (i=0; i<ncrns-1; i++)
  area -=
  0.5(polygon.xpolygon[i+1].x)(polygon[i1].y-polygon.y);
  return area -= 0.5(polygon[ncrns-1].x+polygon[0].x)
  (polygon[0].y-polygon[ncrns-1].y);
  // Function to digitize density.
  void digdens(void)
  char line[LINELENGTH];
  double area,avgdens,*cases,dens,minpop=INFTY,ncases,totarea=0.0,totpop=0.0;
  FILE* infile;
  int i,id,ii,inhowmanyregions,inregion[2],j,jj,regctr;
  if ((infile=fopen(CENSUSFILE))==NULL)
  fprintf(stderr,"ERROR: Cannot find CENSUSFILE.\n");
  exit(1);
  // Find the minimum positive number of cases.
  while (!readline(line,infile))
  sscanf(line,"%i %lf",&id,&ncases);
  if (ncases<minpop && ncases>1e-12) minpop = ncases;
  fclose(infile);
  // Store the number of cases in an array.
  cases = (double)malloc(nregionsizeof(double));
  for (i=0; i<nregion; i++) cases = -1.0;
  infile = fopen(CENSUSFILE);
  while (!readline(line,infile))
  sscanf(line,"%i %lf",&id,&ncases);
  if (id>maxid || regionidinv[id]<0)
  fprintf(stderr,"ERROR: Identifier %i in CENSUSFILE does not\n",id);
  fprintf(stderr,"match any identifier in generate file.\n");
  exit(1);
  if (ncases>1e-12) totpop += (cases[regionidinv[id]] = ncases);
  else totpop += (cases[regionidinv[id]] = MINPOPFAC*minpop);
  for (regctr=0; regctr<nregion; regctr++) if (cases[regctr] < 0.0)
  fprintf(stderr,"ERROR: No density for region %i?\n",regionid[regctr]);
  fprintf(stderr,"cases = %f\n",cases[regctr]);
  exit(1);
  fclose(infile);
  // Calculate regions' areas, total area to be mapped, regional and average
  // densities.
  area = (double)malloc(nregionsizeof(double));
  for (regctr=0; regctr<nregion; regctr++)
  totarea += (area[regctr] = regionarea(nregcorn[regctr],regcorn[regctr]));
  dens = (double)malloc(nregionsizeof(double));
  for (regctr=0; regctr<nregion; regctr++)
  dens[regctr] = cases[regctr]/area[regctr];
  avgdens = totpop/totarea;
  // Digitize density.
  for (i=0; i<=lx; i++) for (j=0; j<=ly; j++) rho_0[j] = 0; // Initialize.
  printf("digitizing density ...\n");
  for (i=0; i<lx; i++) for (j=0; j<ly; j++)
  if (within[j]==-1) rho_0[j] = avgdens;
  else rho_0[j] = dens[within[j]];
  // Fill the edges correctly.
  rho_0[0][0] += rho_0[0][ly] + rho_0[lx][0] + rho_0[lx][ly];
  for (i=1; i<lx; i++) rho_0[0] += rho_0[ly];
  for (j=1; j<ly; j++) rho_0[0][j] += rho_0[lx][j];
  for (i=0; i<lx; i++) rho_0[ly] = rho_0[0];
  for (j=0; j<=ly; j++) rho_0[lx][j] = rho_0[0][j];
  // Replace rho_0 by Fourier transform
  coscosft(rho_0,1,1);
  free(area);
  free(cases);
  for (i=0; i<npoly; i++) free(polycorn);
  free(polycorn);
  for (i=0; i<nregion; i++) free(regcorn);
  free(regcorn);
  free(dens);
  free(npolycorn);
  free(nregcorn);
  free(polygonid);
  free(regionid);
  free(regionidinv);
  free(bbmaxx);
  free(bbmaxy);
  free(bbminx);
  free(bbminy);
  for (i=0; i<nregion; i++) free(polyinreg);
  free(polyinreg);
  free(npolyinreg);
  // Function to replace data[1...2*nn] by its discrete Fourier transform, if
  // isign is input as 1; or replaces data[1...2*nn] by nn times its inverse
  // discrete Fourier transform, if isign is input as -1. data is a complex array
  // of length nn or, equivalently, a real array of length 2*nn. nn MUST be an
  // integer power of 2 (this is not checked for!).
  // From "Numerical Recipes in C".
  void four1(float data[],unsigned long nn,int isign)
  double theta,wi,wpi,wpr,wr,wtemp;
  float tempi,tempr;
  unsigned long i,istep,j,m,mmax,n;
  n=nn<<1;
  j=1;
  for (i=1; i<n; i+=2)
  if (j>i)
  // This is the bit-reversal section of the routine.
  SWAP(data[j],data);
  SWAP(data[j1],data[i1]); // Exchange the two complex numbers.
  m=n>>1;
  while (m>=2 && j>m)
  j -= m;
  m>>=1;
  j += m;
  // Here begins the Danielson-Lanczos section of the routine.
  mmax=2;
  while (n>mmax) // Outer loop executed log_2 nn times.
  istep = mmax<<1;
  // Initialize the trigonometric recurrence.
  theta = isign*(6.28318530717959/mmax);
  wtemp = sin(0.5*theta);
  wpr = -2.0wtempwtemp;
  wpi = sin(theta);
  wr = 1.0;
  wi = 0.0;
  for (m=1; m<mmax; m+=2) // Here are the two nested inner loops.
  for (i=m; i<=n; i+=istep)
  j=i+mmax; // This is the Danielson-Lanczos formula
  tempr=wrdata[j]-widata[j+1];
  tempi=wrdata[j1]widata[j];
  data[j]=data-tempr;
  data[j1]=data[i1]-tempi;
  data += tempr;
  data[i+1] += tempi;
  wr = (wtemp=wr)wpr-wiwpi+wr; // Trigonometric recurrence.
  wi = wiwprwtempwpiwi;
  mmax=istep;
  // Function to calculate the Fourier Transform of a set of n real-valued data
  // points. It replaces this data (which is stored in array data[1...n]) by the
  // positive frequency half of its complex Fourier Transform. The real-valued
  // first and last components of the complex transform are returned as elements
  // data[1] and data[2] respectively. n must be a power of 2. This routine also
  // calculates the inverse transform of a complex data array if it is the
  // transform of real data. (Result in this case must be multiplied by 2/n).
  // From "Numerical Recipes in C".
  void realft(float data[],unsigned long n,int isign)
  double theta,wi,wpi,wpr,wr,wtemp;
  float c1=0.5,c2,h1i,h1r,h2i,h2r;
  unsigned long i,i1,i2,i3,i4,np3;
  theta = 3.141592653589793/(double) (n>>1); // Initialize the recurrence
  if (isign == 1)
  c2 = -0.5;
  four1(data,n>>1,1); // The forward transform is here.
  else // Otherwise set up for an inverse transform.
  c2 = 0.5;
  theta = -theta;
  wtemp = sin(0.5*theta);
  wpr = -2.0wtempwtemp;
  wpi = sin(theta);
  wr = 1.0+wpr;
  wi = wpi;
  np3 = n+3;
  for (i=2; i<=(n>>2); i++) // Case i=1 done separately below.
  i4 = 1(i3=np3-(i2=1+(i1=ii-1)));
  // The two separate transforms are separated out of data.
  h1r = c1*(data[i1]+data[i3]);
  h1i = c1*(data[i2]-data[i4]);
  h2r = -c2*(data[i2]+data[i4]);
  h2i = c2*(data[i1]-data[i3]);
  // Here they are recombined to form the true transform of the original
  // data.
  data[i1] = h1r+wrh2r-wih2i;
  data[i2] = h1iwrh2iwih2r;
  data[i3] = h1r-wrh2r+wih2i;
  data[i4] = -h1iwrh2iwih2r;
  wr = (wtemp=wr)wpr-wiwpi+wr; // The recurrence.
  wi = wiwprwtempwpiwi;
  if (isign == 1)
  data[1] = (h1r=data[1])+data[2]; // Squeeze the first and last data
  // together to get them all within the original array.
  data[2] = h1r-data[2];
  else
  data[1] = c1*((h1r=data[1])+data[2]);
  data[2] = c1*(h1r-data[2]);
  // This is the inverse transform for the case isign = -1.
  four1(data,n>>1,-1);
  // Function to calculate the cosine transform of a set z[0...n] of real-valued
  // data points. The transformed data replace the original data in array z. n
  // must be a power of 2. For forward transform set isign=1, for back transform
  // isign = -1. (Note: The factor 2/n has been taken care of.)
  // From "Numerical Recipes in C".
  void cosft(float z[],unsigned long n,int isign)
  double theta,wi=0.0,wpi,wpr,wr=1.0,wtemp;
  float *a,sum,y1,y2;
  int j,n2;
  // Numerical Recipes starts counting at 1 which is rather confusing. I will
  // count from 0.
  a = (float)malloc((n+2)sizeof(float));
  for (j=1; j<=n+1; j++) a[j] = z[j-1];
  // Here is the Numerical Recipes code.
  theta=PI/n; //Initialize the recurrence.
  wtemp = sin(0.5*theta);
  wpr = -2.0wtempwtemp;
  wpi = sin(theta);
  sum = 0.5*(a[1]-a[n+1]);
  a[1] = 0.5*(a[1]a[n1]);
  n2 = n+2;
  for (j=2; j<=(n>>1); j++)
  wr = (wtemp=wr)wpr-wiwpi+wr;
  wi = wiwprwtempwpiwi;
  y1 = 0.5*(a[j]+a[n2-j]);
  y2 = (a[j]-a[n2-j]);
  a[j] = y1-wi*y2;
  a[n2-j] = y1+wi*y2;
  sum += wr*y2;
  realft(a,n,1);
  a[n+1] = a[2];
  a[2] = sum;
  for (j=4; j<=n; j+=2)
  sum += a[j];
  a[j] = sum;
  // Finally I revert to my counting method.
  if (isign == 1) for (j=1; j<=n+1; j++) z[j-1] = a[j];
  else if (isign == -1) for (j=1; j<=n+1; j++) z[j-1] = 2.0*a[j]/n;
  free(a);
  // Function to calculate the sine transform of a set of n real-valued data
  // points stored in array z[0..n]. The number n must be a power of 2. On exit
  // z is replaced by its transform. For forward transform set isign=1, for back
  // transform isign = -1.
  void sinft(float z[],unsigned long n,int isign)
  double theta,wi=0.0,wpi,wpr,wr=1.0,wtemp;
  float *a,sum,y1,y2;
  int j;
  unsigned long n2=n+2;
  // See my comment about Numerical Recipe's counting above. Note that the last
  // component plays a completely passive role and does not need to be stored.
  a = (float*) malloc((n+1)*sizeof(float));
  for (j=1; j<=n; j++) a[j] = z[j-1];
  // Here is the Numerical Recipes code.
  theta = PI/(double)n; // Initialize the recurrence.
  wtemp = sin(0.5*theta);
  wpr = -2.0wtempwtemp;
  wpi = sin(theta);
  a[1] = 0.0;
  for (j=2; j<=(n>>1)+1; j++)
  // Calculate the sine for the auxiliary array.
  wr = (wtemp=wr)wpr-wiwpi+wr;
  // The cosine is needed to continue the recurrence.
  wi = wiwprwtempwpiwi;
  // Construct the auxiliary array.
  y1 = wi*(a[j]+a[n2-j]);
  y2 = 0.5*(a[j]-a[n2-j]);
  // Terms j and N-j are related.
  a[j] = y1+y2;
  a[n2-j] = y1-y2;
  // Transform the auxiliary array.
  realft(a,n,1);
  // Initialize the sum used for odd terms below.
  a[1] *= 0.5;
  sum = a[2] = 0.0;
  // Even terms determined directly. Odd terms determined by running sum.
  for (j=1; j<=n-1; j+=2)
  sum += a[j];
  a[j] = a[j+1];
  a[j+1] = sum;
  // Change the indices.
  if (isign == 1) for (j=1; j<=n; j++) z[j-1] = a[j];
  else if (isign == -1) for (j=1; j<=n; j++) z[j-1] = 2.0*a[j]/n;
  z[n] = 0.0;
  free(a);
  // Function to calculate a two-dimensional cosine Fourier transform. Forward/
  // backward transform in x: isign1 = +/-1, in y: isign2 = +/-1.
  void coscosft(float **y,int isign1,int isign2)
  float temp[lx+1];
  unsigned long i,j;
  for (i=0; i<=lx; i++)
  cosft(y,ly,isign2);
  for (j=0; j<=ly; j++)
  for (i=0; i<=lx; i++) temp=y[j];
  cosft(temp,lx,isign1);
  for (i=0; i<=lx; i++) y[j]=temp;
  // Function to calculate a cosine Fourier transform in x and a sine transform
  // in y. Forward/backward transform in x: isign1 = +/-1, in y: isign2 = +/-1.
  void cossinft(float **y,int isign1,int isign2)
  float temp[lx+1];
  unsigned long i,j;
  for (i=0; i<=lx; i++)
  sinft(y,ly,isign2);
  for (j=0; j<=ly; j++)
  for (i=0; i<=lx; i++) temp=y[j];
  cosft(temp,lx,isign1);
  for (i=0; i<=lx; i++) y[j]=temp;
  // Function to calculate a sine Fourier transform in x and a cosine transform
  // in y. Forward/backward transform in x: isign1 = +/-1, in y: isign2 = +/-1.
  void sincosft(float **y,int isign1,int isign2)
  float temp[lx+1];
  unsigned long i,j;
  for (i=0; i<=lx; i++)
  cosft(y,ly,isign2);
  for (j=0; j<=ly; j++)
  for (i=0; i<=lx; i++) temp=y[j];
  sinft(temp,lx,isign1);
  for (i=0; i<=lx; i++) y[j]=temp;
  // Function to allocate a float matrix with subscript range
  // m[nrl..nrh][ncl..nch]. From "Numerical Recipes in C".
  float **dmatrix(long nrl,long nrh,long ncl,long nch)
  long i, nrow=nrh-nrl1,ncol=nch-ncl1;
  float **m;
  /* allocate pointers to rows */
  m=(float **) malloc((unsigned int)((nrow+NR_END)sizeof(float)));
  if (!m)
  fprintf(stderr,"allocation failure 1 in matrix()\n");
  exit(1);
  m += NR_END;
  m -= nrl;
  /* allocate rows and set pointers to them */
  m[nrl]=(float *) malloc((unsigned int)((nrowncol+NR_END)sizeof(float)));
  if (!m[nrl])
  fprintf(stderr,"allocation failure 2 in matrix()\n");
  exit(1);
  m[nrl] += NR_END;
  m[nrl] -= ncl;
  for(i=nrl1;i<=nrh;i+) m=m[i-1]+ncol;
  /* return pointer to array of pointers to rows */
  return m;
  // Function to allocate a float 3tensor with range
  // t[nrl..nrh][ncl..nch][ndl..ndh]. From "Numerical Recipes in C".
  float *d3tensor(long nrl, long nrh, long ncl, long nch, long ndl, long ndh)
  long i,j,nrow=nrh-nrl1,ncol=nch-ncl+1,ndep=ndh-ndl1;
  float *t;
  /* allocate pointers to pointers to rows */
  t=(float *) malloc((sizet)((nrow+NREND)sizeof(float*)));
  if (!t)
  fprintf(stderr,"allocation failure 1 in f3tensor()\n");
  exit(1);
  t += NR_END;
  t -= nrl;
  /* allocate pointers to rows and set pointers to them */
  t[nrl]=(float **) malloc((sizet)((nrowncol+NREND)*sizeof(float)));
  if (!t[nrl])
  fprintf(stderr,"allocation failure 2 in f3tensor()\n");
  exit(1);
  t[nrl] += NR_END;
  t[nrl] -= ncl;
  /* allocate rows and set pointers to them */
  t[nrl][ncl]=(float *) malloc((sizet)((nrowncol*ndep+NREND)sizeof(float)));
  if (!t[nrl][ncl])
  fprintf(stderr,"allocation failure 3 in f3tensor()\n");
  exit(1);
  t[nrl][ncl] += NR_END;
  t[nrl][ncl] -= ndl;
  for(j=ncl1;j<=nch;j+) t[nrl][j]=t[nrl][j-1]+ndep;
  for(i=nrl1;i<=nrh;i+) {
  t=t[i-1]+ncol;
  t[ncl]=t[i-1][ncl]+ncol*ndep;
  for(j=ncl1;j<=nch;j+) t[j]=t[j-1]+ndep;
  /* return pointer to array of pointers to rows */
  return t;
  void free_matrix(float **m,long nrl,long nrh,long ncl,long nch)
  free((char*) (m[nrl]+ncl-1));
  free((char*) (m+nrl-1));
  void free_f3tensor(float *t,long nrl,long nrh,long ncl,long nch,long ndl,
  long ndh)
  free((char*) (t[nrl][ncl]+ndl-1));
  free((char*) (t[nrl]+ncl-1));
  free((char*) (t+nrl-1));
  // Function to replace data by its ndim-dimensional discrete Fourier transform,
  // if isign is input as 1. nn[1..ndim] is an integer array containing the
  // lengths of each dimension (number of complex values), which MUST be all
  // powers of 2. data is a real array of length twice the product of these
  // lengths, in which the data are stored as in a multidimensional complex
  // array: real and imaginary parts of each element are in consecutive
  // locations, and the rightmost index of the array increases most rapidly as
  // one proceeds along data. For a two-dimensional array, this is equivalent to
  // storing the arrays by rows. If isign is input as -1, data is replaced by its
  // inverse transform times the product of the lengths of all dimensions.
  void fourn(float data[],unsigned long nn[],int ndim,int isign)
  int idim;
  unsigned long i1,i2,i3,i2rev,i3rev,ip1,ip2,ip3,ifp1,ifp2;
  unsigned long ibit,k1,k2,n,nprev,nrem,ntot;
  double tempi,tempr;
  float theta,wi,wpi,wpr,wr,wtemp;
  for (ntot=1, idim=1; idim<=ndim; idim++)
  ntot *= nn[idim];
  nprev = 1;
  for (idim=ndim; idim>=1; idim--)
  n = nn[idim];
  nrem = ntot/(n*nprev);
  ip1=nprev << 1;
  ip2 = ip1*n;
  ip3 = ip2*nrem;
  i2rev = 1;
  for (i2=1; i2<=ip2; i2+=ip1)
  if (i2 < i2rev)
  for (i1=i2; i1<=i2+ip1-2; i1+=2)
  for (i3=i1; i3<=ip3; i3+=ip2)
  i3rev = i2rev+i3-i2;
  SWAP(data[i3],data[i3rev]);
  SWAP(data[i31],data[i3rev1]);
  ibit = ip2>>1;
  while (ibit>=ip1 && i2rev>ibit)
  i2rev -= ibit;
  ibit >>= 1;
  i2rev += ibit;
  ifp1 = ip1;
  while (ifp1 < ip2)
  ifp2 = ifp1 << 1;
  theta = 2isignPI/(ifp2/ip1);
  wtemp = sin(0.5*theta);
  wpr = -2.0wtempwtemp;
  wpi = sin(theta);
  wr = 1.0;
  wi = 0.0;
  for (i3=1; i3<=ifp1; i3+=ip1)
  for (i1=i3; i1<=i3+ip1-2; i1+=2)
  for (i2=i1; i2<=ip3; i2+=ifp2)
  k1 = i2;
  k2 = k1+ifp1;
  tempr = (float)wrdata[k2]-(float)widata[k2+1];
  tempi = (float)wrdata[k21](float)widata[k2];
  data[k2] = data[k1]-tempr;
  data[k2+1] = data[k1+1]-tempi;
  data[k1] += tempr;
  data[k1+1] += tempi;
  wr = (wtemp=wr)wpr-wiwpi+wr;
  wi = wiwprwtempwpiwi;
  ifp1 = ifp2;
  nprev *= n;
  // Function to calculate a three-dimensional Fourier transform of
  // data[1..nn1][1..nn2][1..nn3] (where nn1=1 for the case of a logically two-
  // dimensional array). This routine returns (for isign=1) the complex fast
  // Fourier transform as two complex arrays: On output, data contains the zero
  // and positive frequency values of the third frequency component, while
  // speq[1..nn1][1..2*nn2] contains the Nyquist critical frequency values of the
  // third frequency component. First (and second) frequency components are
  // stored for zero, positive, and negative frequencies, in standard wrap-around
  // order. See Numerical Recipes for description of how complex values are
  // arranged. For isign=-1, the inverse transform (times nn1nn2nn3/2 as a
  // constant multiplicative factor) is performed, with output data (viewed as
  // real array) deriving from input data (viewed as complex) and speq. For
  // inverse transforms on data not generated first by a forward transform, make
  // sure the complex input data array satisfies property 12.5.2 from NR. The
  // dimensions nn1, nn2, nn3 must always be integer powers of 2.
  void rlft3(float *data,float **speq,unsigned long nn1,unsigned long nn2,
  unsigned long nn3,int isign)
  double theta,wi,wpi,wpr,wr,wtemp;
  float c1,c2,h1r,h1i,h2r,h2i;
  unsigned long i1,i2,i3,j1,j2,j3,nn[4],ii3;
  if (1+&data[nn1][nn2][nn3]-&data[1][1][1] != nn1nn2nn3)
  fprintf(stderr,
  "rlft3: problem with dimensions or contiguity of data array\n");
  exit(1);
  c1 = 0.5;
  c2 = -0.5*isign;
  theta = 2isign(PI/nn3);
  wtemp = sin(0.5*theta);
  wpr = -2.0wtempwtemp;
  wpi = sin(theta);
  nn[1] = nn1;
  nn[2] = nn2;
  nn[3] = nn3 >> 1;
  // Case of forward transform. Here is where most all of the compute time is
  // spent. Extend data periodically into speq.
  if (isign == 1)
  fourn(&data[1][1][1]-1,nn,3,isign);
  for (i1=1; i1<=nn1; i1++)
  for (i2=1, j2=0; i2<=nn2; i2++)
  speq[i1][++j2] = data[i1][i2][1];
  speq[i1][++j2] = data[i1][i2][2];
  for (i1=1; i1<=nn1; i1++)
  // Zero frequency is its own reflection; otherwise locate corresponding
  // negative frequency in wrap-around order.
  j1 = (i1 != 1 ? nn1-i1+2 : 1);
  // Initialize trigonometric recurrence.
  wr = 1.0;
  wi = 0.0;
  for (ii3=1, i3=1; i3<=(nn3>>2)+1; i3+,ii3=2)
  for (i2=1; i2<=nn2; i2++)
  if (i3 == 1)
  j2 = (i2 != 1 ? ((nn2-i2)<<1)+3 : 1);
  h1r = c1*(data[i1][i2][1]+speq[j1][j2]);
  h1i = c1*(data[i1][i2][2]-speq[j1][j2+1]);
  h2i = c2*(data[i1][i2][1]-speq[j1][j2]);
  h2r = -c2*(data[i1][i2][2]speq[j1][j21]);
  data[i1][i2][1] = h1r+h2r;
  data[i1][i2][2] = h1i+h2i;
  speq[j1][j2] = h1r-h2r;
  speq[j1][j2+1] = h2i-h1i;
  else
  j2 = (i2 != 1 ? nn2-i2+2 : 1);
  j3 = nn3+3-(i3<<1);
  h1r = c1*(data[i1][i2][ii3]+data[j1][j2][j3]);
  h1i = c1*(data[i1][i2][ii31]-data[j1][j2][j31]);
  h2i = c2*(data[i1][i2][ii3]-data[j1][j2][j3]);
  h2r = -c2*(data[i1][i2][ii31]+data[j1][j2][j31]);
  data[i1][i2][ii3] = h1r+wrh2r-wih2i;
  data[i1][i2][ii3+1] = h1iwrh2iwih2r;
  data[j1][j2][j3] = h1r-wrh2r+wih2i;
  data[j1][j2][j3+1] = -h1iwrh2iwih2r;
  // Do the recurrence.
  wr = (wtemp=wr)wpr-wiwpi+wr;
  wi = wiwprwtempwpiwi;
  // Case of reverse transform.
  if (isign == -1)
  fourn(&data[1][1][1]-1,nn,3,isign);
  // Function to perform Gaussian blur.
  void gaussianblur(void)
  float **blur,***conv,***pop,**speqblur,**speqconv,*speqpop;
  int i,j,p,q;
  blur = d3tensor(1,1,1,lx,1,ly);
  conv = d3tensor(1,1,1,lx,1,ly);
  pop = d3tensor(1,1,1,lx,1,ly);
  speqblur = dmatrix(1,1,1,2*lx);
  speqconv = dmatrix(1,1,1,2*lx);
  speqpop = dmatrix(1,1,1,2*lx);
  // Fill population and convolution matrix.
  for (i=1; i<=lx; i++) for (j=1; j<=ly; j++)
  if (i > lx/2) p = i-1-lx;
  else p = i-1;
  if (j > ly/2) q = j-1-ly;
  else q = j-1;
  pop[1][j] = rho_0[i-1][j-1];
  conv[1][j] = 0.5*
  (erf((p+0.5)/(sqrt(2.0)(SIGMApow(SIGMAFAC,nblurs))))-
  erf((p-0.5)/(sqrt(2.0)(SIGMA*pow(SIGMAFAC,nblurs)))))
  (erf((q+0.5)/(sqrt(2.0)(SIGMApow(SIGMAFAC,nblurs))))-
  erf((q-0.5)/(sqrt(2.0)(SIGMA*pow(SIGMAFAC,nblurs)))))/(lxly);
  // Fourier transform.
  rlft3(pop,speqpop,1,lx,ly,1);
  rlft3(conv,speqconv,1,lx,ly,1);
  // Multiply pointwise.
  for (i=1; i<=lx; i++)
  for (j=1; j<=ly/2; j++)
  blur[1][2*j-1] =
  pop[1][2j-1]*conv[1][2j-1]-
  pop[1][2j]*conv[1][2j];
  blur[1][2*j] =
  pop[1][2j]*conv[1][2j-1]+
  pop[1][2j-1]*conv[1][2j];
  for (i=1; i<=lx; i++)
  speqblur[1][2*i-1] =
  speqpop[1][2i-1]*speqconv[1][2i-1]-
  speqpop[1][2i]*speqconv[1][2i];
  speqblur[1][2*i] =
  speqpop[1][2i]*speqconv[1][2i-1]+
  speqpop[1][2i-1]*speqconv[1][2i];
  // Backtransform.
  rlft3(blur,speqblur,1,lx,ly,-1);
  // Write to rho_0.
  for (i=1; i<=lx; i++) for (j=1; j<=ly; j++) rho_0[i-1][j-1] = blur[1][j];
  free_f3tensor(blur,1,1,1,lx,1,ly);
  free_f3tensor(conv,1,1,1,lx,1,ly);
  free_f3tensor(pop,1,1,1,lx,1,ly);
  free_matrix(speqblur,1,1,1,2*lx);
  free_matrix(speqconv,1,1,1,2*lx);
  free_matrix(speqpop,1,1,1,2*lx);
  // Function to initialize rho_0. The original density is blurred with width
  // SIGMA*pow(SIGMAFAC,nblurs).
  void initcond(void)
  float maxpop;
  int i,j;
  // Reconstruct population density.
  coscosft(rho_0,-1,-1);
  // There must not be negative densities.
  for (i=0; i<lx; i++) for (j=0; j<ly; j++) if (rho_0[j]<-1e10)
  fprintf(stderr,"ERROR: Negative density in DENSITYFILE.\n");
  exit(1);
  // Perform Gaussian blur.
  printf("Gaussian blur ...\n");
  gaussianblur();
  // Find the mimimum density. If it is very small suggest an increase in
  // SIGMA.
  minpop = rho_0[0][0];
  maxpop = rho_0[0][0];
  for (i=0; i<lx; i++) for (j=0; j<ly; j++) if (rho_0[j]<minpop)
  minpop = rho_0[j];
  for (i=0; i<lx; i++) for (j=0; j<ly; j++) if (rho_0[j]>maxpop)
  maxpop = rho_0[j];
  if (0<minpop && minpop<1e-8*maxpop)
  fprintf(stderr,"Minimimum population very small (%f). Integrator\n",
  minpop);
  fprintf(stderr,
  "will probably converge very slowly. You can speed up the\n");
  fprintf(stderr,"process by increasing SIGMA to a value > %f.\n",
  SIGMA*pow(SIGMAFAC,nblurs));
  // Replace rho_0 by cosine Fourier transform in both variables.
  coscosft(rho_0,1,1);
  // Function to calculate the velocity field
  void calcv(float t)
  int j,k;
  // Fill rho with Fourier coefficients.
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  rho[j][k] = exp(-((PIj/lx)*(PI*j/lx)+(PI*k/ly)*(PI*k/ly))*t)rho_0[j][k];
  // Calculate the Fourier coefficients for the partial derivative of rho.
  // Store temporary results in arrays gridvx, gridvy.
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  gridvx[j][k] = -(PIj/lx)rho[j][k];
  gridvy[j][k] = -(PIk/ly)rho[j][k];
  // Replace rho by cosine Fourier backtransform in both variables.
  coscosft(rho,-1,-1);
  // Replace vx by sine Fourier backtransform in the first and cosine Fourier
  // backtransform in the second variable.
  sincosft(gridvx,-1,-1);
  // Replace vy by cosine Fourier backtransform in the first and sine Fourier
  // backtransform in the second variable.
  cossinft(gridvy,-1,-1);
  // Calculate the velocity field.
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  gridvx[j][k] = -gridvx[j][k]/rho[j][k];
  gridvy[j][k] = -gridvy[j][k]/rho[j][k];
  // Function to bilinearly interpolate a two-dimensional array. For higher
  // accuracy one could consider higher order interpolation schemes.
  float intpol(float **arr,float x,float y)
  int gaussx,gaussy;
  float deltax,deltay;
  // Decompose x and y into an integer part and a decimal.
  gaussx = (int)x;
  gaussy = (int)y;
  deltax = x-gaussx;
  deltay = y-gaussy;
  // Interpolate.
  if (gaussx==lx && gaussy==ly)
  return arr[gaussx][gaussy];
  if (gaussx==lx)
  return (1-deltay)arr[gaussx][gaussy]deltayarr[gaussx][gaussy1];
  if (gaussy==ly)
  return (1-deltax)arr[gaussx][gaussy]deltaxarr[gaussx1][gaussy];
  return (1-deltax)(1-deltay)arr[gaussx][gaussy]+
  (1-deltax)deltayarr[gaussx][gaussy1]
  deltax(1-deltay)arr[gaussx1][gaussy]
  deltaxdeltayarr[gaussx1][gaussy1];
  // Function to find the root of the system of equations
  // xappr-0.5h*v_x(t+h,xappr,yappr)-x[j][k]-0.5*hvx[j][k]=0,
  // yappr-0.5h*v_y(t+h,xappr,yappr)-y[j][k]-0.5*hvy[j][k]=0
  // with Newton-Raphson. Returns TRUE after sufficient convergence.
  BOOLEAN newt2(float h,float *xappr,float xguess,float *yappr,float yguess,
  int j,int k)
  float deltax,deltay,dfxdx,dfxdy,dfydx,dfydy,fx,fy;
  int gaussx,gaussxplus,gaussy,gaussyplus,i;
  // Initial guess.
  *xappr = xguess;
  *yappr = yguess;
  for (i=1; i<=IMAX; i++)
  // fx, fy are the left-hand sides of the two equations. Find
  // v_x(t+h,xappr,yappr), v_y(t+h,xappr,yappr) by interpolation.
  fx = xappr-0.5*h*intpol(gridvx,*xappr,*yappr)-x[j][k]-0.5*hvx[j][k];
  fy = yappr-0.5*h*intpol(gridvy,*xappr,*yappr)-y[j][k]-0.5*hvy[j][k];
  // Linearly approximate the partial derivatives of fx, fy with a finite
  // difference method. More elaborate techniques are possible, but this
  // quick and dirty method appears to work reasonably for our purpose.
  gaussx = (int)(*xappr);
  gaussy = (int)(*yappr);
  if (gaussx == lx) gaussxplus = 0;
  else gaussxplus = gaussx+1;
  if (gaussy == ly) gaussyplus = 0;
  else gaussyplus = gaussy+1;
  deltax = x[j][k] - gaussx;
  deltay = y[j][k] - gaussy;
  dfxdx = 1 - 0.5h
  ((1-deltay)*(gridvx[gaussxplus][gaussy]-gridvx[gaussx][gaussy])+
  deltay*(gridvx[gaussxplus][gaussyplus]-gridvx[gaussx][gaussyplus]));
  dfxdy = -0.5h
  ((1-deltax)*(gridvx[gaussx][gaussyplus]-gridvx[gaussx][gaussy])+
  deltax*(gridvx[gaussxplus][gaussyplus]-gridvx[gaussxplus][gaussy]));
  dfydx = -0.5h
  ((1-deltay)*(gridvy[gaussxplus][gaussy]-gridvy[gaussx][gaussy])+
  deltay*(gridvy[gaussxplus][gaussyplus]-gridvy[gaussx][gaussyplus]));
  dfydy = 1 - 0.5h
  ((1-deltax)*(gridvy[gaussx][gaussyplus]-gridvy[gaussx][gaussy])+
  deltax*(gridvy[gaussxplus][gaussyplus]-gridvy[gaussxplus][gaussy]));
  // If the current approximation is (xappr,yappr) for the zero of
  // (fx(x,y),fy(x,y)) and J is the Jacobian, then we can approximate (in
  // vector notation) for |delta|<<1:
  // f((xappr,yappr)+delta) = f(xappr,yappr)+J*delta.
  // Setting f((xappr,yappr)+delta)=0 we obtain a set of linear equations
  // for the correction delta which moves f closer to zero, namely
  // J*delta = -f.
  // The improved approximation is then x = xappr+delta.
  // The process will be iterated until convergence is reached.
  if ((fx*fx + fy*fy) < TOLF) return TRUE;
  deltax = (fy*dfxdy - fxdfydy)/(dfxdxdfydy - dfxdy*dfydx);
  deltay = (fx*dfydx - fydfxdx)/(dfxdxdfydy - dfxdy*dfydx);
  if ((deltax*deltax + deltay*deltay) < TOLX) return TRUE;
  *xappr += deltax;
  *yappr += deltay;
  //printf("deltax %f, deltay %f\n",deltax,deltay);
  fprintf(stderr,"newt2 failed, increasing sigma to %f.\n",
  SIGMA*pow(SIGMAFAC,nblurs));
  return FALSE;
  // Function to integrate the nonlinear Volterra equation. Returns TRUE after
  // the displacement field converged, after MAXINTSTEPS integration steps, or
  // if the time exceeds TIMELIMIT.
  BOOLEAN nonlinvoltra(void)
  BOOLEAN stepsize_ok;
  #ifdef DISPLFILE
  FILE *displfile = fopen(DISPLFILE);
  #endif
  float h,maxchange=INFTY,t,vxplus,vyplus,xguess,yguess;
  int i,j,k;
  do
  initcond();
  nblurs++;
  if (minpop<0.0)
  fprintf(stderr,
  "Minimum population negative, will increase sigma to %f\n",
  SIGMA*pow(SIGMAFAC,nblurs));
  while (minpop<0.0);
  h = HINITIAL;
  t = 0; // Start at time t=0.
  // (x[j][k],y[j][k]) is the position for the element that was at position
  // (j,k) at time t=0.
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  x[j][k] = j;
  y[j][k] = k;
  calcv(0.0);
  // (gridvx[j][k],gridvy[j][k]) is the velocity at position (j,k).
  // (vx[j][k],vy[j][k]) is the velocity at position (x[j][k],y[j][k]).
  // At t=0 they are of course identical.
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  vx[j][k] = gridvx[j][k];
  vy[j][k] = gridvy[j][k];
  i = 1; // i counts the integration steps.
  // Here is the integrator.
  do
  stepsize_ok = TRUE;
  calcv(t+h);
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  // First take a naive integration step. The velocity at time t+h for
  // the element [j][k] is approximately
  // v(th,x[j][k]+hvx[j][k],y[j][k]hvy[j][k]).
  // The components, call them vxplus and vyplus, are interpolated from
  // gridvx and gridvy.
  vxplus = intpol(gridvx,x[j][k]hvx[j][k],y[j][k]hvy[j][k]);
  vyplus = intpol(gridvy,x[j][k]hvx[j][k],y[j][k]hvy[j][k]);
  // Based on (vx[j][k],vy[j][k]) and (vxplus,vyplus) we expect the
  // new position at time t+h to be:
  xguess = x[j][k] + 0.5h(vx[j][k]+vxplus);
  yguess = y[j][k] + 0.5h(vy[j][k]+vyplus);
  // Then we make a better approximation by solving the two nonlinear
  // equations:
  // xappr[j][k]-0.5hv_x(t+h,xappr[j][k],yappr[j][k])-
  // x[j][k]-0.5hvx[j][k]=0,
  // yappr[j][k]-0.5hv_y(t+h,xappr[j][k],yappr[j][k])-
  // y[j][k]-0.5hvy[j][k]=0
  // with Newton-Raphson and (xguess,yguess) as initial guess.
  // If newt2 fails to converge, exit nonlinvoltra.
  if (!newt2(h,&xappr[j][k],xguess,&yappr[j][k],yguess,j,k))
  return FALSE;
  // If the integration step was too large reduce the step size.
  if ((xguess-xappr[j][k])*(xguess-xappr[j][k])+
  (yguess-yappr[j][k])*(yguess-yappr[j][k]) > TOLINT)
  if (h<MINH)
  fprintf(stderr,
  "Time step below %f, increasing SIGMA to %f\n",
  h,SIGMA*pow(SIGMAFAC,nblurs));
  nblurs++;
  return FALSE;
  h /= 10;
  stepsize_ok = FALSE;
  break;
  if (!stepsize_ok) continue;
  else
  t += h;
  maxchange = 0.0; // Monitor the maximum change in positions.
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  if ((x[j][k]-xappr[j][k])*(x[j][k]-xappr[j][k])+
  (y[j][k]-yappr[j][k])*(y[j][k]-yappr[j][k]) > maxchange)
  maxchange =
  (x[j][k]-xappr[j][k])*(x[j][k]-xappr[j][k])+
  (y[j][k]-yappr[j][k])*(y[j][k]-yappr[j][k]);
  x[j][k] = xappr[j][k];
  y[j][k] = yappr[j][k];
  vx[j][k] = intpol(gridvx,xappr[j][k],yappr[j][k]);
  vy[j][k] = intpol(gridvy,xappr[j][k],yappr[j][k]);
  h *= 1.2; // Make the next integration step larger.
  if (i%10==0) printf("time %f\n",t);
  i++;
  } while (i<MAXINTSTEPS && t<TIMELIMIT && maxchange>CONVERGENCE);
  if (maxchange>CONVERGENCE)
  fprintf(stderr,
  "WARNING: Insufficient convergence within %i steps, time %f.\n",
  MAXINTSTEPS,TIMELIMIT);
  #ifdef DISPLFILE
  // Write displacement field to file.
  fprintf(displfile,"time %f\nminx %f\nmaxx %f\nminy %f\nmaxy %f\n",
  t,minx,maxx,miny,maxy);
  fprintf(displfile,"sigma %f\n",SIGMA*pow(SIGMAFAC,nblurs-1));
  fprintf(displfile,"background %f\nlx\nly\n\n",0,lx,ly);
  for (j=0; j<=lx; j++) for (k=0; k<=ly; k++)
  fprintf(displfile,"j %i, k %i, x %f, y %f\n",j,k,x[j][k],y[j][k]);
  fclose(displfile);
  #endif
  return TRUE;
  // Function to transform points according to displacement field.
  POINT transf(POINT p)
  float deltax,deltay,den,t,u;
  int gaussx,gaussy;
  POINT a,b,c,d,ptr;
  p.x = (p.x-minx)*lx/(maxx-minx);
  p.y = (p.y-miny)*ly/(maxy-miny);
  gaussx = (int)p.x;
  gaussy = (int)p.y;
  if (gaussx<0 || gaussx>lx || gaussy<0 || gaussy>ly)
  fprintf(stderr,"ERROR: Coordinate limits exceeded in transf.\n");
  exit(1);
  deltax = p.x - gaussx;
  deltay = p.y - gaussy;
  // The transformed point is the intersection of the lines:
  // (I) connecting
  // (1-deltax)(x,y[gaussx][gaussy])deltax(x,y[gaussx1][gaussy])
  // and
  // (1-deltax)(x,y[gaussx][gaussy1])+deltax(x,y[gaussx+1][gaussy1])
  // (II) connecting
  // (1-deltay)(x,y[gaussx][gaussy])deltay(x,y[gaussx][gaussy1])
  // and
  // (1-deltay)(x,y[gaussx1][gaussy])+deltay(x,y[gaussx+1][gaussy1]).
  // Call these four points a, b, c and d.
  a.x = (1-deltax)*x[gaussx][gaussy] + deltax*x[gaussx+1][gaussy];
  a.y = (1-deltax)*y[gaussx][gaussy] + deltax*y[gaussx+1][gaussy];
  b.x = (1-deltax)*x[gaussx][gaussy+1] + deltax*x[gaussx1][gaussy1];
  b.y = (1-deltax)*y[gaussx][gaussy+1] + deltax*y[gaussx1][gaussy1];
  c.x = (1-deltay)*x[gaussx][gaussy] + deltay*x[gaussx][gaussy+1];
  c.y = (1-deltay)*y[gaussx][gaussy] + deltay*y[gaussx][gaussy+1];
  d.x = (1-deltay)*x[gaussx+1][gaussy] + deltay*x[gaussx1][gaussy1];
  d.y = (1-deltay)*y[gaussx+1][gaussy] + deltay*y[gaussx1][gaussy1];
  // Solve the vector equation a+t(b-a) = c+u(d-c) for the scalars t, u.
  if (fabs(den=(b.x-a.x)(c.y-d.y)+(a.y-b.y)(c.x-d.x))<1e-12)
  fprintf(stderr,"ERROR: Transformed area element has parallel edges.\n");
  exit(1);
  t = ((c.x-a.x)(c.y-d.y)+(a.y-c.y)(c.x-d.x))/den;
  u = ((b.x-a.x)(c.y-a.y)+(a.y-b.y)(c.x-a.x))/den;
  if (t<-1e-3|| t>1+1e-3 || u<-1e-3 || u>1+1e-3)
  fprintf(stderr,"WARNING: Transformed area element non-convex.\n");
  ptr.x = (1-(a.x+t(b.x-a.x))/lx)minx + ((a.x+t(b.x-a.x))/lx)maxx;
  ptr.y = (1-(a.y+t(b.y-a.y))/ly)miny + ((a.y+t(b.y-a.y))/ly)maxy;
  return ptr;
  // Function to read spatial features from user-specified file and map to
  // cartogram.
  void cartogram(void)
  char id[LINELENGTH],line[LINELENGTH];
  FILE infile,outfile;
  float xcoord,ycoord;
  POINT p;
  infile = fopen(MAPGENFILE);
  outfile = fopen(CARTGENFILE,"w");
  while (!readline(line,infile))
  if (sscanf(line,"%s %f %f",&id,&xcoord,&ycoord)==3)
  p.x = xcoord;
  p.y = ycoord;
  p = transf(p);
  fprintf(outfile,"%s %f %f\n",id,p.x,p.y);
  else if (sscanf(line,"%f %f",&xcoord,&ycoord)==2)
  p.x = xcoord;
  p.y = ycoord;
  p = transf(p);
  fprintf(outfile,"%f %f\n",p.x,p.y);
  else
  sscanf(line,"%s",&id);
  fprintf(outfile,"%s\n",id);
  fclose(infile);
  fclose(outfile);
  main(void)
  BOOLEAN n;
  char c;
  FILE genfile,psfile = fopen(MAP2PS);
  float oldlx,oldly,oldmaxx,oldmaxy,oldminx,oldminy,totarea;
  int i,polyctr,regctr;
  // Read the polygon coordinates.
  if ((genfile = fopen(MAPGENFILE)) == NULL)
  fprintf(stderr,"ERROR: Cannot find MAPGENFILE\n");
  exit(1);
  countpoly(genfile);
  fclose(genfile);
  genfile = fopen(MAPGENFILE);
  countcorn(genfile);
  fclose(genfile);
  genfile = fopen(MAPGENFILE);
  readcorn(genfile);
  fclose(genfile);
  makeregion();
  printf("%i polygon(s), %i region(s)\n",npoly,nregion);
  printf("lx=%i, ly=%i\n",lx,ly);
  // Calculate total area.
  //totarea = 0.0;
  //for (regctr=0; regctr<nregion; regctr++)
  // printf("region %i has area %f, contains %i polygons\n",regionid[regctr],
  // regionarea(nregcorn[regctr],regcorn[regctr]),npolyinreg[regctr]);
  // totarea += regionarea(nregcorn[regctr],regcorn[regctr]);
  //printf("totarea = %f\n",totarea);
  // Make map.
  pspicture(psfile);
  fclose(psfile);
  // Allocate memory for arrays.
  gridvx = (float*)malloc((lx+1)*sizeof(float));
  gridvy = (float*)malloc((lx+1)*sizeof(float));
  rho = (float*)malloc((lx+1)*sizeof(float));
  rho_0 = (float*)malloc((lx+1)*sizeof(float));
  vx = (float*)malloc((lx+1)*sizeof(float));
  vy = (float*)malloc((lx+1)*sizeof(float));
  x = (float*)malloc((lx+1)*sizeof(float));
  xappr = (float*)malloc((lx+1)*sizeof(float));
  y = (float*)malloc((lx+1)*sizeof(float));
  yappr = (float*)malloc((lx+1)*sizeof(float));
  within = (int*)malloc((lx+1)*sizeof(int));
  for (i=0; i<=lx; i++)
  gridvx = (float)malloc((ly+1)sizeof(float));
  gridvy = (float)malloc((ly+1)sizeof(float));
  rho = (float)malloc((ly+1)sizeof(float));
  rho_0 = (float)malloc((ly+1)sizeof(float));
  vx = (float)malloc((ly+1)sizeof(float));
  vy = (float)malloc((ly+1)sizeof(float));
  x = (float)malloc((ly+1)sizeof(float));
  xappr = (float)malloc((ly+1)sizeof(float));
  y = (float)malloc((ly+1)sizeof(float));
  yappr = (float)malloc((ly+1)sizeof(float));
  within = (int)malloc((ly+1)sizeof(int));
  // Digitize the density.
  bboxes();
  interior();
  digdens();
  // Solve the diffusion equation.
  do n = nonlinvoltra(); while (!n);
  // Print cartogram generate file.
  cartogram();
  // Read the transformed polygon coordinates.
  oldlx = lx;
  oldly = ly;
  oldmaxx = maxx;
  oldmaxy = maxy;
  oldminx = minx;
  oldminy = miny;
  genfile = fopen(CARTGENFILE,"r");
  countpoly(genfile);
  fclose(genfile);
  genfile = fopen(CARTGENFILE,"r");
  countcorn(genfile);
  fclose(genfile);
  lx = oldlx;
  ly = oldly;
  maxx = oldmaxx;
  maxy = oldmaxy;
  minx = oldminx;
  miny = oldminy;
  genfile = fopen(CARTGENFILE,"r");
  readcorn(genfile);
  fclose(genfile);
  makeregion();
  // Make cartogram
  psfile = fopen(CART2PS);
  pspicture(psfile);
  fclose(psfile);
  The part of the code where the bus error occurs is this:
  void interior(void)
  int i,inhowmanyregions,inregion[2],j,k,l,m,n,regctr;
  // Initialize within[][]. -1 means outside all regions.
  for (i=0; i<=lx; i++) for (j=0; j<=ly; j++) within[j] = -1;
  // Fill within[][].
  for (i=0; i<nregion; i++) for (j=0; j<npolyinreg; j++)
  for (k=0, n=npolycorn[polyinreg[j]]-1;
  k<npolycorn[polyinreg[j]]; n=k++)
  for (l=(int)ceil(MIN(polycorn[polyinreg[j]][k-1].y,
  polycorn[polyinreg[j]][k].y));
  l<MAX(polycorn[polyinreg[j]][k-1].y,
  polycorn[polyinreg[j]][k].y); l++)
  for (m=(int)floor(bbminx[polyinreg[j]]);
  m<(polycorn[polyinreg[j]][n].x-
  polycorn[polyinreg[j]][k].x)*
  (l-polycorn[polyinreg[j]][k].y)/
  (polycorn[polyinreg[j]][n].y-
  polycorn[polyinreg[j]][k].y)+
  polycorn[polyinreg[j]][k].x;
  m++)
  within[m][l] = i-within[m][l]-1;
  I really have no idea what is going on. Can anyone help?
  Thanks,
  mooseguy

  orangekay wrote:
  That is absolutely unreadable.
  I agree completely. How about also providing a link to a set of input files so that we could actually run the code ourselves? Otherwise, there is no chance to debug the source code, it is just a mess.
  You might have better luck with an older version of the file. To quote the comments:
  // Modified on March 31, 2005. Initialized maxchange in nonlinvoltra() as
  // INFTY. Replaced crnmbr() by a similar, but faster routine interior().
  // Many thanks to Stuart Anderson for pointing out this shortcut.
  I suspect that the "interior" function is just plain incorrect. It doesn't matter if it runs on some other OS. Something about it is wrong and the code is so cryptic that it can't be deciphered.