; docformat = 'rst' ; ; NAME: ; cgLayout ; ; PURPOSE: ; The purpose of this program is to return the normalized position coordinates for ; a line plot, contour plot, or image plot with a specific "layout" in the current ; graphics window. A "layout" has a specified grid of columns and rows organized ; inside a graphics display window. This is similar to the positions calculated by ; !P.Multi, although a great deal more flexible. ; ;******************************************************************************************; ; ; ; Copyright (c) 2012, by Fanning Software Consulting, Inc. All rights reserved. ; ; ; ; Redistribution and use in source and binary forms, with or without ; ; modification, are permitted provided that the following conditions are met: ; ; ; ; * Redistributions of source code must retain the above copyright ; ; notice, this list of conditions and the following disclaimer. ; ; * Redistributions in binary form must reproduce the above copyright ; ; notice, this list of conditions and the following disclaimer in the ; ; documentation and/or other materials provided with the distribution. ; ; * Neither the name of Fanning Software Consulting, Inc. nor the names of its ; ; contributors may be used to endorse or promote products derived from this ; ; software without specific prior written permission. ; ; ; ; THIS SOFTWARE IS PROVIDED BY FANNING SOFTWARE CONSULTING, INC. ''AS IS'' AND ANY ; ; EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES ; ; OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT ; ; SHALL FANNING SOFTWARE CONSULTING, INC. BE LIABLE FOR ANY DIRECT, INDIRECT, ; ; INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED ; ; TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; ; ; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ; ; ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ; ; (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS ; ; SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ; ;******************************************************************************************; ; ;+ ; The purpose of this program is to return the normalized position coordinates for ; a line plot, contour plot, or image plot with a specific "layout" in the current ; graphics window. A "layout" has a specified grid of columns and rows organized ; inside a graphics display window. This is similar to the positions calculated by ; !P.Multi, although a great deal more flexible. Of course, with additional flexibility ; and power comes more responsibility. You will be required to use the NoErase keyword ; correctly and you will be responsible for setting the character size on your plots. ; These jobs are normally handled by !P.Multi. Some users will find this liberating, some ; will find it a pain in the keister. There is always !P.Multi to go back to. ; ; A grid position is a combination of the number of columns and rows desired, plus ; the application of inside and outside margins, as well as a desired aspect ratio. ; Margins are specified in units of one-third the !D.X_PX_CM value to be device independent. ; The outside margins locate the grid inside the graphics display window. ; (These are equivalent to !X.OMargin and !Y.OMargin system variable when displaying ; a grid with !P.Multi, for example.) Inside margins use the same units, but are ; used to modify the initial grid positions in the window. (These are equivalent ; to using the XMargin and YMargin keywords on a plot command.) For example, inside margins ; might be used to leave room inside a larger position for color bars or other annotations ; you wish to put on a graphics display. The aspect ratio modifies the grid position ; after the outside and inside margins have been applied to create the final grid position, ; which will be centered in its initial grid position. ; ; :Categories: ; Graphics, Utilities ; ; :Returns: ; This function returns the normalized position coordinates for a particular ; location in a grid of locations (if the layout parameter is a three-element array), ; or a 4-by-(ncols*nrows) array of grid positions with one position for each location ; in the ncols by nrows grid of locations (if the layout parameter is a two-element array). ; The return variable is suitable for passing to the POSITION keyword of an IDL graphics ; command (e.g., cgPlot, cgContour, cgImage, etc.). The grid positions are organized in ; row order, starting with the grid location in the upper-left of the graphihcs display window. ; ; :Params: ; ; layout: in, required, type=integer ; This parameter sets up the grid layout for the current graphics window. A grid ; is organized by columns and rows, with the first grid position located in the upper-left ; corner of the current graphics display window and proceeding in row order. This parameter ; is either a two-element vector, giving the number of columns and number of rows, ; respectively (e.g., [ncols,nrows]), or it is a three-element vector, giving, in addition, the ; specific grid location for which a position is required (e.g, [ncols, nrows, gridPosition]). ; Grid positions start at 1 with the first grid in the upper left corner of the graphics display ; window and proceed in row order, sequentually, until the last grid position, which is equal ; to the number of columns times the number of rows. ; ; :Keywords: ; ; aspect: in, optional, type=float ; This kewyord allows you to specify a specific aspect ratio for the return ; positions. The aspect ratio is calculated as YDimension/XDimension. So, for ; example, if you wish the positions to be twice as wide as they are high, you ; would set the Aspect keyword to 1.0/2.0 or 0.5. If you wish your positions to ; have a square aspect ratio, you would set the Aspect keyword to 1.0. ; ; ixmargin: in, optional, type=integer ; This keyword is a two-element vector that sets the right and left, respectively, inside ; X margin for the grid position. Units are multiples of !D.X_CH_SIZE. Default = [0,0]. ; ; iymargin: in, optional, type=integer ; This keyword is a two-element vector that sets the bottom and top, respectively, inside ; Y margin for the grid position. Units are multiples of !D.Y_CH_SIZE. Default = [0,0]. ; ; oxmargin: in, optional, type=integer ; This keyword is a two-element vector that sets the right and left, respectively, inside ; X margin for the grid position. The default OXMargins are suitable for displaying line ; plots. If you are displaying image plots, you may wish to make the OXMargins the same on ; both sides of the graphics display window (e.g, OXMargin=[5,5]). Units are multiples of ; !D.X_CH_SIZE. Default = [10,4]. ; ; oymargin: in, optional, type=integer ; This keyword is a two-element vector that sets the bottom and top, respectively, inside ; Y margin for the grid position. The default OYMargins are suitable for displaying line ; plots. There is a little additional room at the top of the plot in the defaults for adding ; a title to a multiple plot set-up. Units are multiples of !D.Y_CH_SIZE. Default = [6,8]. ; ; xgap: in, optional, type=integer, default=14 ; This keywords sets the distance between plots in the X dimension. Units are multiples ; of !D.X_CH_SIZE. ; ; ygap: in, optional, type=integer, default=8 ; This keywords sets the distance between plots in the Y dimension. Units are multiples ; of !D.Y_CH_SIZE. ; ; :Examples: ; Here is how to use this program to display line plots:: ; ; cgDisplay, WID=0 ; pos = cgLayout([2,2]) ; FOR j=0,3 DO BEGIN ; cgPlot, cgDemoData(17), NoErase=j NE 0, Position=pos[*,j], Title='Plot ' + StrTrim(j+1,2) ; ENDFOR ; cgText, 0.5, 0.925, /Normal, 'Example Plot Layout', Alignment=0.5, Charsize=cgDefCharsize()*1.25 ; ; Here is how to use this program to display contour plots or images with colorbars:: ; ; cgDisplay, WID=1 ; cgLoadCT, 22, /Brewer, /Reverse ; pos = cgLayout([2,2], OXMargin=[5,5], OYMargin=[5,12], XGap=3, YGap=10) ; FOR j=0,3 DO BEGIN ; p = pos[*,j] ; cgImage, cgDemoData(18), NoErase=j NE 0, Position=p ; cgColorBar, position=[p[0], p[3]+0.05, p[2], p[3]+0.1] ; ENDFOR ; cgText, 0.5, 0.925, /Normal, 'Example Image Layout', Alignment=0.5, Charsize=cgDefCharsize()*1.25 ; ; .. image:: cglayout.png ; ; Here is how to display square plots in a PostScript file:: ; ; cgPS_Open, 'cglayout_example.ps' ; cgDisplay ; pos = cgLayout([2,2], Aspect=1.0) ; FOR j=0,3 DO BEGIN ; cgPlot, cgDemoData(17), NoErase=j NE 0, Position=pos[*,j], Title='Plot ' + StrTrim(j+1,2) ; ENDFOR ; cgText, 0.5, 0.925, /Normal, 'Example Plot Layout', Alignment=0.5, Charsize=cgDefCharsize()*1.25 ; cgPS_Close ; ; Here is how to draw the third plot in a 3 column by 2 row layout:: ; ; cgDisplay, 800, 600, WID=3 ; cgPlot, cgDemoData(17), Position=cgLayout([3,2,3]) ; ; :Author: ; FANNING SOFTWARE CONSULTING:: ; David W. Fanning ; 1645 Sheely Drive ; Fort Collins, CO 80526 USA ; Phone: 970-221-0438 ; E-mail: david@idlcoyote.com ; Coyote's Guide to IDL Programming: http://www.idlcoyote.com ; ; :History: ; Change History:: ; Written, 19 December 2012 by David W. Fanning, from suggestions from Matthew Argall. ; Changed the notion of one "unit" from the values of !D.X_CH_SIZE and !D.Y_CH_SIZE to ; 1/3 of the value of !D.X_PX_CM. This gives me more consistent measurements on the ; display and in a PostScript file. 12 Feb 2013. DWF. ; ; :Copyright: ; Copyright (c) 2012, Fanning Software Consulting, Inc. ;- FUNCTION cgLayout, layout, $ ASPECT=aspect, $ IXMARGIN=ixMargin, $ IYMARGIN=iyMargin, $ OXMARGIN=oxMargin, $ OYMARGIN=oyMargin, $ XGAP=xgap, $ YGAP=ygap Compile_Opt idl2 Catch, theError IF theError NE 0 THEN BEGIN Catch, /CANCEL void = cgErrorMsg() RETURN, -1 ENDIF ; Check parameters. IF N_Elements(layout) EQ 0 THEN BEGIN Print, 'Syntax: pos = cgLocator([2,3,1])' RETURN, -1 ENDIF IF N_Elements(layout) EQ 3 THEN layoutIndex = layout[2]-1 ; Check keywords. area = Keyword_Set(area) IF N_Elements(ixmargin) EQ 0 THEN ixmargin = [0,0] IF N_Elements(iymargin) EQ 0 THEN iymargin = [0,0] IF N_Elements(oxmargin) EQ 0 THEN oxmargin = [10,4] IF N_Elements(oymargin) EQ 0 THEN oymargin = [6,8] IF N_Elements(xgap) EQ 0 THEN xgap = 14 IF N_Elements(ygap) EQ 0 THEN ygap = 8 ; Get the size of the window. If the current device supports windows, ; a window has to be open. IF ((!D.FLAGS AND 256) NE 0) AND !D.Window LT 0 THEN BEGIN createdWindow = 1 Window, /Pixmap ENDIF ELSE createdWindow = 0 xsize = Double(!D.X_Size) ysize = Double(!D.Y_Size) IF createdWindow THEN WDelete, !D.Window ; Number of columns and rows. IF N_Elements(layout) LT 2 THEN Message, 'Layout parameter must be a 2- or 3-element vector.' ncols = layout[0] nrows = layout[1] ; Set up the inside and outside margins and the gaps between positions. unit = !D.X_PX_CM / 3 xomargin = oxmargin * unit yomargin = oymargin * unit ximargin = ixmargin * unit / xsize yimargin = iymargin * unit / ysize gapx = xgap * unit gapy = ygap * unit ; Calculate the window or drawing area inside the graphics window. winarea = [ xomargin[0], yomargin[0], xsize - xomargin[1], ysize - yomargin[1] ] ; Calculate the plot width and height. plot_width = (winarea[2] - winarea[0] - gapx*(ncols-1)) / ncols plot_height = (winarea[3] - winarea[1] - gapy*(nrows-1)) / nrows ; Calculate the plot areas inside the drawing area. plot_areas = FltArr(4, ncols, nrows) FOR j=0,nrows-1 DO BEGIN FOR k=0,ncols-1 DO BEGIN plot_areas[0,k,j] = winarea[0] + (plot_width + gapx) * k ; x0 plot_areas[2,k,j] = plot_areas[0,k,j] + plot_width ; x1 plot_areas[1,k,j] = winarea[3] - (plot_height + gapy) * j ; y0 plot_areas[3,k,j] = plot_areas[1,k,j] - plot_height ; y1 ENDFOR ENDFOR ; Normalize the plot areas. plot_areas[[0,2],*,*] = plot_areas[[0,2],*,*] / xsize plot_areas[[1,3],*,*] = plot_areas[[1,3],*,*] / ysize ; Calculate the plot positions. These are the plot areas with the ; inside margins subtracted. positions = FltArr(4, ncols, nrows) positions[0,*,*] = plot_areas[0,*,*] + ximargin[0] positions[2,*,*] = plot_areas[2,*,*] - ximargin[1] positions[3,*,*] = plot_areas[1,*,*] + yimargin[0] positions[1,*,*] = plot_areas[3,*,*] - yimargin[1] ; Reform the positions into a 4 by ncols*rows array. positions = Reform(positions, 4, ncols*nrows) ; Did the user ask for an aspect ratio? IF N_Elements(aspect) NE 0 THEN BEGIN ; Make sure aspect is not 0. IF aspect[0] EQ 0 THEN Message, 'The aspect ratio cannot be zero.' ; Calculate the same aspect ratio for each of the positions. FOR j=0,ncols*nrows-1 DO BEGIN p = positions[*,j] xpixSize = (p[2] - p[0]) * xsize ypixSize = (p[3] - p[1]) * ysize ratio = aspect[0] ; Try to fit the width. If you can't maintain ; the aspect ratio, fit the height. trialX = xpixSize trialY = trialX * ratio IF trialY GT ypixSize THEN BEGIN trialY = ypixSize trialX = trialY / ratio ENDIF ; Recalculate the position of the plot in the window. p[0] = (((xpixSize - trialX) / 2.0) / xsize) + p[0] p[2] = p[0] + (trialX/Float(xsize)) p[1] = (((ypixSize - trialY) / 2.0) / ysize) + p[1] p[3] = p[1] + (trialY/Float(ysize)) positions[*,j] = p ENDFOR ENDIF ; If you have a layout index use that to return a specific ; position. Otherwise, return all the positions calculated ; for the window. IF N_Elements(layoutIndex) EQ 0 THEN BEGIN RETURN, positions ENDIF ELSE BEGIN RETURN, positions[*,layoutIndex] ENDELSE END