/* IconProcs README A BYOND library for manipulating icons and colors by Lummox JR version 1.0 The IconProcs library was made to make a lot of common icon operations much easier. BYOND's icon manipulation routines are very capable but some of the advanced capabilities like using alpha transparency can be unintuitive to beginners. CHANGING ICONS Several new procs have been added to the /icon datum to simplify working with icons. To use them, remember you first need to setup an /icon var like so: GLOBAL_DATUM_INIT(my_icon, /icon, new('iconfile.dmi')) icon/ChangeOpacity(amount = 1) A very common operation in DM is to try to make an icon more or less transparent. Making an icon more transparent is usually much easier than making it less so, however. This proc basically is a frontend for MapColors() which can change opacity any way you like, in much the same way that SetIntensity() can make an icon lighter or darker. If amount is 0.5, the opacity of the icon will be cut in half. If amount is 2, opacity is doubled and anything more than half-opaque will become fully opaque. icon/GrayScale() Converts the icon to grayscale instead of a fully colored icon. Alpha values are left intact. icon/ColorTone(tone) Similar to GrayScale(), this proc converts the icon to a range of black -> tone -> white, where tone is an RGB color (its alpha is ignored). This can be used to create a sepia tone or similar effect. See also the global ColorTone() proc. icon/MinColors(icon) The icon is blended with a second icon where the minimum of each RGB pixel is the result. Transparency may increase, as if the icons were blended with ICON_ADD. You may supply a color in place of an icon. icon/MaxColors(icon) The icon is blended with a second icon where the maximum of each RGB pixel is the result. Opacity may increase, as if the icons were blended with ICON_OR. You may supply a color in place of an icon. icon/Opaque(background = "#000000") All alpha values are set to 255 throughout the icon. Transparent pixels become black, or whatever background color you specify. icon/BecomeAlphaMask() You can convert a simple grayscale icon into an alpha mask to use with other icons very easily with this proc. The black parts become transparent, the white parts stay white, and anything in between becomes a translucent shade of white. icon/AddAlphaMask(mask) The alpha values of the mask icon will be blended with the current icon. Anywhere the mask is opaque, the current icon is untouched. Anywhere the mask is transparent, the current icon becomes transparent. Where the mask is translucent, the current icon becomes more transparent. icon/UseAlphaMask(mask, mode) Sometimes you may want to take the alpha values from one icon and use them on a different icon. This proc will do that. Just supply the icon whose alpha mask you want to use, and src will change so it has the same colors as before but uses the mask for opacity. COLOR MANAGEMENT AND HSV RGB isn't the only way to represent color. Sometimes it's more useful to work with a model called HSV, which stands for hue, saturation, and value. * The hue of a color describes where it is along the color wheel. It goes from red to yellow to green to cyan to blue to magenta and back to red. * The saturation of a color is how much color is in it. A color with low saturation will be more gray, and with no saturation at all it is a shade of gray. * The value of a color determines how bright it is. A high-value color is vivid, moderate value is dark, and no value at all is black. Just as BYOND uses "#rrggbb" to represent RGB values, a similar format is used for HSV: "#hhhssvv". The hue is three hex digits because it ranges from 0 to 0x5FF. * 0 to 0xFF - red to yellow * 0x100 to 0x1FF - yellow to green * 0x200 to 0x2FF - green to cyan * 0x300 to 0x3FF - cyan to blue * 0x400 to 0x4FF - blue to magenta * 0x500 to 0x5FF - magenta to red Knowing this, you can figure out that red is "#000ffff" in HSV format, which is hue 0 (red), saturation 255 (as colorful as possible), value 255 (as bright as possible). Green is "#200ffff" and blue is "#400ffff". More than one HSV color can match the same RGB color. Here are some procs you can use for color management: ReadRGB(rgb) Takes an RGB string like "#ffaa55" and converts it to a list such as list(255,170,85). If an RGBA format is used that includes alpha, the list will have a fourth item for the alpha value. hsv(hue, sat, val, apha) Counterpart to rgb(), this takes the values you input and converts them to a string in "#hhhssvv" or "#hhhssvvaa" format. Alpha is not included in the result if null. ReadHSV(rgb) Takes an HSV string like "#100FF80" and converts it to a list such as list(256,255,128). If an HSVA format is used that includes alpha, the list will have a fourth item for the alpha value. RGBtoHSV(rgb) Takes an RGB or RGBA string like "#ffaa55" and converts it into an HSV or HSVA color such as "#080aaff". HSVtoRGB(hsv) Takes an HSV or HSVA string like "#080aaff" and converts it into an RGB or RGBA color such as "#ff55aa". BlendRGB(rgb1, rgb2, amount) Blends between two RGB or RGBA colors using regular RGB blending. If amount is 0, the first color is the result; if 1, the second color is the result. 0.5 produces an average of the two. Values outside the 0 to 1 range are allowed as well. The returned value is an RGB or RGBA color. BlendHSV(hsv1, hsv2, amount) Blends between two HSV or HSVA colors using HSV blending, which tends to produce nicer results than regular RGB blending because the brightness of the color is left intact. If amount is 0, the first color is the result; if 1, the second color is the result. 0.5 produces an average of the two. Values outside the 0 to 1 range are allowed as well. The returned value is an HSV or HSVA color. BlendRGBasHSV(rgb1, rgb2, amount) Like BlendHSV(), but the colors used and the return value are RGB or RGBA colors. The blending is done in HSV form. HueToAngle(hue) Converts a hue to an angle range of 0 to 360. Angle 0 is red, 120 is green, and 240 is blue. AngleToHue(hue) Converts an angle to a hue in the valid range. RotateHue(hsv, angle) Takes an HSV or HSVA value and rotates the hue forward through red, green, and blue by an angle from 0 to 360. (Rotating red by 60° produces yellow.) The result is another HSV or HSVA color with the same saturation and value as the original, but a different hue. GrayScale(rgb) Takes an RGB or RGBA color and converts it to grayscale. Returns an RGB or RGBA string. ColorTone(rgb, tone) Similar to GrayScale(), this proc converts an RGB or RGBA color to a range of black -> tone -> white instead of using strict shades of gray. The tone value is an RGB color; any alpha value is ignored. */ /* Get Flat Icon DEMO by DarkCampainger This is a test for the get flat icon proc, modified approprietly for icons and their states. Probably not a good idea to run this unless you want to see how the proc works in detail. mob icon = 'old_or_unused.dmi' icon_state = "green" Login() // Testing image underlays underlays += image(icon='old_or_unused.dmi',icon_state="red") underlays += image(icon='old_or_unused.dmi',icon_state="red", pixel_x = 32) underlays += image(icon='old_or_unused.dmi',icon_state="red", pixel_x = -32) // Testing image overlays add_overlay(image(icon='old_or_unused.dmi',icon_state="green", pixel_x = 32, pixel_y = -32)) add_overlay(image(icon='old_or_unused.dmi',icon_state="green", pixel_x = 32, pixel_y = 32)) add_overlay(image(icon='old_or_unused.dmi',icon_state="green", pixel_x = -32, pixel_y = -32)) // Testing icon file overlays (defaults to mob's state) add_overlay('_flat_demoIcons2.dmi') // Testing icon_state overlays (defaults to mob's icon) add_overlay("white") // Testing dynamic icon overlays var/icon/I = icon('old_or_unused.dmi', icon_state="aqua") I.Shift(NORTH,16,1) add_overlay(I) // Testing dynamic image overlays I=image(icon=I,pixel_x = -32, pixel_y = 32) add_overlay(I) // Testing object types (and layers) add_overlay(/obj/effect/overlayTest) loc = locate (10,10,1) verb Browse_Icon() set name = "1. Browse Icon" // Give it a name for the cache var/iconName = "[ckey(src.name)]_flattened.dmi" // Send the icon to src's local cache src<

") Output_Icon() set name = "2. Output Icon" to_chat(src, "Icon is: [icon2base64html(get_flat_icon(src))]") Label_Icon() set name = "3. Label Icon" // Give it a name for the cache var/iconName = "[ckey(src.name)]_flattened.dmi" // Copy the file to the rsc manually var/icon/I = fcopy_rsc(get_flat_icon(src)) // Send the icon to src's local cache src< 57 && ch < 65) || (ch > 70 && ch < 97) || ch > 102) break ++digits if(digits == 8) break var/single = digits < 6 if(digits != 3 && digits != 4 && digits != 6 && digits != 8) return if(digits == 4 || digits == 8) usealpha = 1 for(i=start, digits>0, ++i) ch = text2ascii(rgb, i) if(ch >= 48 && ch <= 57) ch -= 48 else if(ch >= 65 && ch <= 70) ch -= 55 else if(ch >= 97 && ch <= 102) ch -= 87 else break --digits switch(which) if(0) r = (r << 4) | ch if(single) r |= r << 4 ++which else if(!(digits & 1)) ++which if(1) g = (g << 4) | ch if(single) g |= g << 4 ++which else if(!(digits & 1)) ++which if(2) b = (b << 4) | ch if(single) b |= b << 4 ++which else if(!(digits & 1)) ++which if(3) alpha = (alpha << 4) | ch if(single) alpha |= alpha << 4 . = list(r, g, b) if(usealpha) . += alpha /proc/ReadHSV(hsv) if(!hsv) return // interpret the HSV or HSVA value var/i=1,start=1 if(text2ascii(hsv) == 35) ++start // skip opening # var/ch,which=0,hue=0,sat=0,val=0,alpha=0,usealpha var/digits=0 for(i=start, i<=length(hsv), ++i) ch = text2ascii(hsv, i) if(ch < 48 || (ch > 57 && ch < 65) || (ch > 70 && ch < 97) || ch > 102) break ++digits if(digits == 9) break if(digits > 7) usealpha = 1 if(digits <= 4) ++which if(digits <= 2) ++which for(i=start, digits>0, ++i) ch = text2ascii(hsv, i) if(ch >= 48 && ch <= 57) ch -= 48 else if(ch >= 65 && ch <= 70) ch -= 55 else if(ch >= 97 && ch <= 102) ch -= 87 else break --digits switch(which) if(0) hue = (hue << 4) | ch if(digits == (usealpha ? 6 : 4)) ++which if(1) sat = (sat << 4) | ch if(digits == (usealpha ? 4 : 2)) ++which if(2) val = (val << 4) | ch if(digits == (usealpha ? 2 : 0)) ++which if(3) alpha = (alpha << 4) | ch . = list(hue, sat, val) if(usealpha) . += alpha /proc/HSVtoRGB(hsv) if(!hsv) return "#000000" var/list/HSV = ReadHSV(hsv) if(!HSV) return "#000000" var/hue = HSV[1] var/sat = HSV[2] var/val = HSV[3] // Compress hue into easier-to-manage range hue -= hue >> 8 if(hue >= 0x5fa) hue -= 0x5fa var/hi,mid,lo,r,g,b hi = val lo = round((255 - sat) * val / 255, 1) mid = lo + round(abs(round(hue, 510) - hue) * (hi - lo) / 255, 1) if(hue >= 765) if(hue >= 1275) {r=hi; g=lo; b=mid} else if(hue >= 1020) {r=mid; g=lo; b=hi } else {r=lo; g=mid; b=hi } else if(hue >= 510) {r=lo; g=hi; b=mid} else if(hue >= 255) {r=mid; g=hi; b=lo } else {r=hi; g=mid; b=lo } return (HSV.len > 3) ? rgb(r,g,b,HSV[4]) : rgb(r,g,b) /proc/RGBtoHSV(rgb) if(!rgb) return "#0000000" var/list/RGB = ReadRGB(rgb) if(!RGB) return "#0000000" var/r = RGB[1] var/g = RGB[2] var/b = RGB[3] var/hi = max(r,g,b) var/lo = min(r,g,b) var/val = hi var/sat = hi ? round((hi-lo) * 255 / hi, 1) : 0 var/hue = 0 if(sat) var/dir var/mid if(hi == r) if(lo == b) {hue=0; dir=1; mid=g} else {hue=1535; dir=-1; mid=b} else if(hi == g) if(lo == r) {hue=512; dir=1; mid=b} else {hue=511; dir=-1; mid=r} else if(hi == b) if(lo == g) {hue=1024; dir=1; mid=r} else {hue=1023; dir=-1; mid=g} hue += dir * round((mid-lo) * 255 / (hi-lo), 1) return hsv(hue, sat, val, (RGB.len>3 ? RGB[4] : null)) /proc/hsv(hue, sat, val, alpha) if(hue < 0 || hue >= 1536) hue %= 1536 if(hue < 0) hue += 1536 if((hue & 0xFF) == 0xFF) ++hue if(hue >= 1536) hue = 0 if(sat < 0) sat = 0 if(sat > 255) sat = 255 if(val < 0) val = 0 if(val > 255) val = 255 . = "#" . += TO_HEX_DIGIT(hue >> 8) . += TO_HEX_DIGIT(hue >> 4) . += TO_HEX_DIGIT(hue) . += TO_HEX_DIGIT(sat >> 4) . += TO_HEX_DIGIT(sat) . += TO_HEX_DIGIT(val >> 4) . += TO_HEX_DIGIT(val) if(!isnull(alpha)) if(alpha < 0) alpha = 0 if(alpha > 255) alpha = 255 . += TO_HEX_DIGIT(alpha >> 4) . += TO_HEX_DIGIT(alpha) /* Smooth blend between HSV colors amount=0 is the first color amount=1 is the second color amount=0.5 is directly between the two colors amount<0 or amount>1 are allowed */ /proc/BlendHSV(hsv1, hsv2, amount) var/list/HSV1 = ReadHSV(hsv1) var/list/HSV2 = ReadHSV(hsv2) // add missing alpha if needed if(HSV1.len < HSV2.len) HSV1 += 255 else if(HSV2.len < HSV1.len) HSV2 += 255 var/usealpha = HSV1.len > 3 // normalize hsv values in case anything is screwy if(HSV1[1] > 1536) HSV1[1] %= 1536 if(HSV2[1] > 1536) HSV2[1] %= 1536 if(HSV1[1] < 0) HSV1[1] += 1536 if(HSV2[1] < 0) HSV2[1] += 1536 if(!HSV1[3]) {HSV1[1] = 0; HSV1[2] = 0} if(!HSV2[3]) {HSV2[1] = 0; HSV2[2] = 0} // no value for one color means don't change saturation if(!HSV1[3]) HSV1[2] = HSV2[2] if(!HSV2[3]) HSV2[2] = HSV1[2] // no saturation for one color means don't change hues if(!HSV1[2]) HSV1[1] = HSV2[1] if(!HSV2[2]) HSV2[1] = HSV1[1] // Compress hues into easier-to-manage range HSV1[1] -= HSV1[1] >> 8 HSV2[1] -= HSV2[1] >> 8 var/hue_diff = HSV2[1] - HSV1[1] if(hue_diff > 765) hue_diff -= 1530 else if(hue_diff <= -765) hue_diff += 1530 var/hue = round(HSV1[1] + hue_diff * amount, 1) var/sat = round(HSV1[2] + (HSV2[2] - HSV1[2]) * amount, 1) var/val = round(HSV1[3] + (HSV2[3] - HSV1[3]) * amount, 1) var/alpha = usealpha ? round(HSV1[4] + (HSV2[4] - HSV1[4]) * amount, 1) : null // normalize hue if(hue < 0 || hue >= 1530) hue %= 1530 if(hue < 0) hue += 1530 // decompress hue hue += round(hue / 255) return hsv(hue, sat, val, alpha) /proc/BlendRGBasHSV(rgb1, rgb2, amount) return HSVtoRGB(RGBtoHSV(rgb1), RGBtoHSV(rgb2), amount) /proc/HueToAngle(hue) // normalize hsv in case anything is screwy if(hue < 0 || hue >= 1536) hue %= 1536 if(hue < 0) hue += 1536 // Compress hue into easier-to-manage range hue -= hue >> 8 return hue / (1530/360) /proc/AngleToHue(angle) // normalize hsv in case anything is screwy if(angle < 0 || angle >= 360) angle -= 360 * round(angle / 360) var/hue = angle * (1530/360) // Decompress hue hue += round(hue / 255) return hue // positive angle rotates forward through red->green->blue /proc/RotateHue(hsv, angle) var/list/HSV = ReadHSV(hsv) // normalize hsv in case anything is screwy if(HSV[1] >= 1536) HSV[1] %= 1536 if(HSV[1] < 0) HSV[1] += 1536 // Compress hue into easier-to-manage range HSV[1] -= HSV[1] >> 8 if(angle < 0 || angle >= 360) angle -= 360 * round(angle / 360) HSV[1] = round(HSV[1] + angle * (1530/360), 1) // normalize hue if(HSV[1] < 0 || HSV[1] >= 1530) HSV[1] %= 1530 if(HSV[1] < 0) HSV[1] += 1530 // decompress hue HSV[1] += round(HSV[1] / 255) return hsv(HSV[1], HSV[2], HSV[3], (HSV.len > 3 ? HSV[4] : null)) // Convert an rgb color to grayscale /proc/GrayScale(rgb) var/list/RGB = ReadRGB(rgb) var/gray = RGB[1]*0.3 + RGB[2]*0.59 + RGB[3]*0.11 return (RGB.len > 3) ? rgb(gray, gray, gray, RGB[4]) : rgb(gray, gray, gray) // Change grayscale color to black->tone->white range /proc/ColorTone(rgb, tone) var/list/RGB = ReadRGB(rgb) var/list/TONE = ReadRGB(tone) var/gray = RGB[1]*0.3 + RGB[2]*0.59 + RGB[3]*0.11 var/tone_gray = TONE[1]*0.3 + TONE[2]*0.59 + TONE[3]*0.11 if(gray <= tone_gray) return BlendRGB("#000000", tone, gray/(tone_gray || 1)) else return BlendRGB(tone, "#ffffff", (gray-tone_gray)/((255-tone_gray) || 1)) //Used in the OLD chem colour mixing algorithm /proc/GetColors(hex) hex = uppertext(hex) // No alpha set? Default to full alpha. if(length(hex) == 7) hex += "FF" var/hi1 = text2ascii(hex, 2) // R var/lo1 = text2ascii(hex, 3) // R var/hi2 = text2ascii(hex, 4) // G var/lo2 = text2ascii(hex, 5) // G var/hi3 = text2ascii(hex, 6) // B var/lo3 = text2ascii(hex, 7) // B var/hi4 = text2ascii(hex, 8) // A var/lo4 = text2ascii(hex, 9) // A return list(((hi1>= 65 ? hi1-55 : hi1-48)<<4) | (lo1 >= 65 ? lo1-55 : lo1-48), ((hi2 >= 65 ? hi2-55 : hi2-48)<<4) | (lo2 >= 65 ? lo2-55 : lo2-48), ((hi3 >= 65 ? hi3-55 : hi3-48)<<4) | (lo3 >= 65 ? lo3-55 : lo3-48), ((hi4 >= 65 ? hi4-55 : hi4-48)<<4) | (lo4 >= 65 ? lo4-55 : lo4-48)) //Interface for using DrawBox() to draw 1 pixel on a coordinate. //Returns the same icon specifed in the argument, but with the pixel drawn /proc/DrawPixel(icon/I,colour,drawX,drawY) if(!I) return 0 var/Iwidth = I.Width() var/Iheight = I.Height() if(drawX > Iwidth || drawX <= 0) return 0 if(drawY > Iheight || drawY <= 0) return 0 I.DrawBox(colour,drawX, drawY) return I //Interface for easy drawing of one pixel on an atom. /atom/proc/DrawPixelOn(colour, drawX, drawY) var/icon/I = new(icon) var/icon/J = DrawPixel(I, colour, drawX, drawY) if(J) //Only set the icon if it succeeded, the icon without the pixel is 1000x better than a black square. icon = J return J return 0 //Hook, override to run code on- wait this is images //Images have dir without being an atom, so they get their own definition. //Lame. /image/proc/setDir(newdir) dir = newdir /* Gives the result RGB of a RGB string after a matrix transformation. No alpha. * Input: rr, rg, rb, gr, gg, gb, br, bg, bb, cr, cg, cb * Output: RGB string */ /proc/RGBMatrixTransform(list/color, list/cm) ASSERT(cm.len >= 9) if(cm.len < 12) // fill in the rest for(var/i in 1 to (12 - cm.len)) cm += 0 if(!islist(color)) color = ReadRGB(color) color[1] = color[1] * cm[1] + color[2] * cm[2] + color[3] * cm[3] + cm[10] * 255 color[2] = color[1] * cm[4] + color[2] * cm[5] + color[3] * cm[6] + cm[11] * 255 color[3] = color[1] * cm[7] + color[2] * cm[8] + color[3] * cm[9] + cm[12] * 255 return rgb(color[1], color[2], color[3])