// Plot uses HTML5/SVG to create a graph which you can view in your browser func Plot(location string, r reg.New, yx, xy bool) { if location == "stdin" { // We don't have a filename or location. Using the current // UNIX timestamp in nanoseconds instead. File is created // in the working directory. cwd, _ := os.Getwd() name := fmt.Sprintf("/plot-%d.html", time.Now().UnixNano()) absPath := cwd + name loc, err = os.Create(absPath) if err != nil { fault.Trap(err, "errFsperm") } defer loc.Close() } else { // We have both the filename and the location // where to create it. Proceed normally. cwd := filepath.Dir(location) name := fmt.Sprintf("/plot-for-%s.html", filepath.Base(location)) absPath := cwd + name loc, err = os.Create(absPath) if err != nil { fault.Trap(err, "errFsperm") } defer loc.Close() } // Draw the data points // Initialize the graph object with 33x22 grids gp := r.GraphInit(xgcount, ygcount) fmt.Fprintf(loc, "<!DOCTYPE html>\n\n") fmt.Fprintf(loc, "<!-- ratChart -->\n") fmt.Fprintf(loc, "<!-- This plot was generated by %s-->\n\n", doc.MiniVer()) fmt.Fprintf(loc, "<!-- This file is best rendered in modern versions of -->\n") fmt.Fprintf(loc, "<!-- Mozilla Firefox/Google Chrome. To render the plot, -->\n") fmt.Fprintf(loc, "<!-- open this file with your browser. -->\n\n") fmt.Fprintf(loc, "<head>\n") fmt.Fprintf(loc, "\t<meta charset=\"%s\">\n", charset) fmt.Fprintf(loc, "\t<title>ratchart</title>\n") fmt.Fprintf(loc, "\t<style type=\"text/css\">\n") fmt.Fprintf(loc, "\t\tbody {background-color: %s; background-attachment: fixed; font-family: \"%s\"}\n", bgcolor, bodyfnt) fmt.Fprintf(loc, "\t\t.headerbar {background-color: #116A95; color: %s; font-family: \"%s\";\n\t\t font-size: 20px;font-weight: bold; padding: 2px; text-align: center;}\n", bgcolor, plotfnt) fmt.Fprintf(loc, "\t\t.plotarea {background-color: %s; font-family: \"%s\"; font-size: 12px; float: left;}\n", bgcolor, plotfnt) fmt.Fprintf(loc, "\t\t.legend {background-color: %s; float: right; color: %s; padding: 15px;}\n", legendcl, bgcolor) fmt.Fprintf(loc, "\t</style>\n") fmt.Fprintf(loc, "</head>\n") fmt.Fprintf(loc, "<body>\n") fmt.Fprintf(loc, "\t<div class=\"headerbar\">\n") fmt.Fprintf(loc, "\t\t<p>\n") if yx && xy || !yx && !xy { fmt.Fprintf(loc, "\t\t\tPlot for: %s and %s\n", r.Equation("YonX"), r.Equation("XonY")) } if yx && !xy { fmt.Fprintf(loc, "\t\t\tPlot for: %s\n", r.Equation("YonX")) } if !yx && xy { fmt.Fprintf(loc, "\t\t\tPlot for: %s\n", r.Equation("XonY")) } fmt.Fprintf(loc, "\t\t</p>\n") fmt.Fprintf(loc, "\t</div>\n") fmt.Fprintf(loc, "\t<div class=\"plotarea\">\n") fmt.Fprintf(loc, "\t\t<svg width=\"1000\" height=\"600\">\n") // Tag to show which line is which if yx && xy || !yx && !xy { fmt.Fprintf(loc, "\t\t\t<line x1=\"40\" y1=\"0\" x2=\"40\" y2=\"50\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") fmt.Fprintf(loc, "\t\t\t<line x1=\"190\" y1=\"0\" x2=\"190\" y2=\"50\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") fmt.Fprintf(loc, "\t\t\t<line x1=\"40\" y1=\"50\" x2=\"190\" y2=\"50\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") fmt.Fprintf(loc, "\t\t\t<text x=\"50\" y =\"20\" fill=\"black\"> Y on X </text>\n") fmt.Fprintf(loc, "\t\t\t<text x=\"50\" y =\"40\" fill=\"black\"> X on Y </text>\n") fmt.Fprintf(loc, "\t\t\t<line x1=\"100\" y1=\"16\" x2=\"180\" y2=\"16\" style=\"stroke:rgb(248,32,32);stroke-width:3\"/>\n") fmt.Fprintf(loc, "\t\t\t<line x1=\"100\" y1=\"36\" x2=\"180\" y2=\"36\" style=\"stroke:rgb(11,92,20);stroke-width:3\"/>\n") } // Line definition // fmt.Fprintf(loc, "\t\t\t<line x1=\"%.2f\" y1=\"%.2f\" x2=\"%.2f\" y2=\"%.2f\" style=\"stroke:rgb(32,42,198);stroke-width:3\"/>\n", 40,20,40,10) // Origin tag // On the graph, (0,0) starts from (310,500) fmt.Fprintf(loc, "\t\t\t<text x=\"260\" y =\"520\" fill=\"black\"> (0,0) </text>\n") // // X coordinate tag // xtag := fmt.Fprintf("\t\t\t<text x=\"910\" y =\"530\" fill=\"black\"> (%0.f,0) </text>\n", gp.Xgrids[len(gp.Xgrids)-1]) // // Y coordinate tag // ytag := fmt.Fprintf("\t\t\t<text x=\"260\" y =\"25\" fill=\"black\"> (0,%0.f) </text>\n", gp.Ygrids[len(gp.Ygrids)-1]) // Y- axis fmt.Fprintf(loc, "\t\t\t<line x1=\"305\" y1=\"35\" x2=\"305\" y2=\"505\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") // Y -axis label fmt.Fprintf(loc, "\t\t\t<text x=\"200\" y=\"285\" fill=\"black\"> (Y) </text>\n") // Mirror X fmt.Fprintf(loc, "\t\t\t<line x1=\"305\" y1=\"35\" x2=\"995\" y2=\"35\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") // X axis fmt.Fprintf(loc, "\t\t\t<line x1=\"305\" y1=\"505\" x2=\"995\" y2=\"505\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") // X axis label fmt.Fprintf(loc, "\t\t\t<text x=\"620\" y=\"580\" fill=\"black\"> (X) </text>\n") // Mirror Y fmt.Fprintf(loc, "\t\t\t<line x1=\"995\" y1=\"35\" x2=\"995\" y2=\"505\" style=\"stroke:rgb(15,25,32);stroke-width:3\"/>\n") // Draw framework // Draw grids // Vertical grids, 33 of them, spacing 20 for I := 0; ; I++ { J := 20.0 * float64(I) X, _, term := reg.Translate(J, 0) if term { break } fmt.Fprintf(loc, "%s%.2f%s%s%.2f%s%s", x1var, X, y1const, x2var, X, y2const, grstyle) if I > 0 && I < (len(gp.Xgrids)-1) { fmt.Fprintf(loc, "\t\t\t<text x=\"%.0f\" y=\"520\" fill=\"black\" transform=\"rotate(60 %.0f,520)\">%.2f</text>\n", gp.Xcoord[I], gp.Xcoord[I], gp.Xgrids[I]) } } // Horizontal grids, 22 of them, spacing 20 for I := 0; ; I++ { J := 20.0 * float64(I) _, Y, term := reg.Translate(0, J) if term { break } fmt.Fprintf(loc, "%s%s%.2f%s%s%.2f%s", x1const, y1var, Y, x2const, y2var, Y, grstyle) if I > 0 && I < (len(gp.Ygrids)-1) { fmt.Fprintf(loc, "\t\t\t<text x=\"240\" y=\"%.0f\" fill=\"black\" transform=\"rotate(0 260,%.0f)\">%.2f</text>\n", gp.Ycoord[I], gp.Ycoord[I], gp.Ygrids[I]) } } // Initialize plotter pl := gp.PlotInit(r) for index, element := range pl.X { fmt.Fprintf(loc, "%s%f%s%f%s\n", circstr, element, circmid, pl.Y[index], circsty) } // Draw regression lines rg := r.ReglineInit(gp) xxy1, xxy2 := rg.XonXY[0], rg.XonXY[1] // X on Y yxy1, yxy2 := rg.YonXY[0], rg.YonXY[1] xyx1, xyx2 := rg.XonYX[0], rg.XonYX[1] // Y on X yyx1, yyx2 := rg.YonYX[0], rg.YonYX[1] if !yx && xy || !yx && !xy { // XonY fmt.Fprintf(loc, "\t\t\t<line x1=\"%.2f\" y1=\"%.2f\" x2=\"%.2f\" y2=\"%.2f\" style=\"stroke:rgb(11,92,20);stroke-width:3\"/>\n", xxy1, yxy1, xxy2, yxy2) } if yx && !xy || !yx && !xy { // YonX fmt.Fprintf(loc, "\t\t\t<line x1=\"%.2f\" y1=\"%.2f\" x2=\"%.2f\" y2=\"%.2f\" style=\"stroke:rgb(248,32,32);stroke-width:3\"/>\n", xyx1, yyx1, xyx2, yyx2) } fmt.Fprintf(loc, "\t\t</svg>\n") fmt.Fprintf(loc, "\t</div>\n") fmt.Fprintf(loc, "\t<div class=\"legend\">\n") fmt.Fprintf(loc, "\t\t<p> <u> AXIS SCALE: </u> </p>\n") fmt.Fprintf(loc, "\t\t<p> * X-axis: %.3f units </p>\n", r.GridScale("X", xgcount)) fmt.Fprintf(loc, "\t\t<p> * Y-axis: %.3f units </p>\n", r.GridScale("Y", ygcount)) fmt.Fprintf(loc, "\t\t<p> <u> AXIS LABLE: </u> </p>\n") fmt.Fprintf(loc, "\t\t<p> * X-axis: %s </p>\n", r.Xlabel) fmt.Fprintf(loc, "\t\t<p> * Y-axis: %s </P>\n", r.Ylabel) fmt.Fprintf(loc, "\t\t<p> <u> STATS: </u> </p>\n") fmt.Fprintf(loc, "\t\t<p> * R value: %.2f </p>\n", r.Rval()) fmt.Fprintf(loc, "\t\t<p> * RegCoeff (Y on X): %.2f </p>\n", r.Byx()) fmt.Fprintf(loc, "\t\t<p> * RegCoeff (X on Y): %.2f </p>\n", r.Bxy()) fmt.Fprintf(loc, "\t\t<p> * Confidence: %.2f%% </p>\n", r.Conf()) fmt.Fprintf(loc, "\t\t<p> * Covariance: %.2f </p>\n", r.Covariance()) fmt.Fprintf(loc, "\t\t<p> * StdDev (X): %.1f </p>\n", r.SdX()) fmt.Fprintf(loc, "\t\t<p> * StdDev (Y): %.1f </p>\n", r.SdY()) fmt.Fprintf(loc, "\t</div>\n") fmt.Fprintf(loc, "</body>\n") fmt.Fprintf(loc, "</html>") }