478 lines
19 KiB
Objective-C
Vendored
478 lines
19 KiB
Objective-C
Vendored
//
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// HFRepresenterTextViewCallout.m
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// HexFiend_2
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//
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// Copyright 2011 ridiculous_fish. All rights reserved.
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//
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#import "HFRepresenterTextViewCallout.h"
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#import "HFRepresenterTextView.h"
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static const CGFloat HFTeardropRadius = 12;
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static const CGFloat HFTeadropTipScale = 2.5;
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static const CGFloat HFShadowXOffset = -6;
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static const CGFloat HFShadowYOffset = 0;
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static const CGFloat HFShadowOffscreenHack = 3100;
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static NSPoint rotatePoint(NSPoint center, NSPoint point, CGFloat percent) {
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CGFloat radians = percent * M_PI * 2;
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CGFloat x = point.x - center.x;
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CGFloat y = point.y - center.y;
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CGFloat newX = x * cos(radians) + y * sin(radians);
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CGFloat newY = x * -sin(radians) + y * cos(radians);
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return NSMakePoint(center.x + newX, center.y + newY);
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}
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static NSPoint scalePoint(NSPoint center, NSPoint point, CGFloat percent) {
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CGFloat x = point.x - center.x;
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CGFloat y = point.y - center.y;
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CGFloat newX = x * percent;
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CGFloat newY = y * percent;
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return NSMakePoint(center.x + newX, center.y + newY);
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}
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static NSBezierPath *copyTeardropPath(void) {
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static NSBezierPath *sPath = nil;
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if (! sPath) {
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CGFloat radius = HFTeardropRadius;
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CGFloat rotation = 0;
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CGFloat droppiness = .15;
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CGFloat tipScale = HFTeadropTipScale;
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CGFloat tipLengthFromCenter = radius * tipScale;
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NSPoint bulbCenter = NSMakePoint(-tipLengthFromCenter, 0);
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NSPoint triangleCenter = rotatePoint(bulbCenter, NSMakePoint(bulbCenter.x + radius, bulbCenter.y), rotation);
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NSPoint dropCorner1 = rotatePoint(bulbCenter, triangleCenter, droppiness / 2);
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NSPoint dropCorner2 = rotatePoint(bulbCenter, triangleCenter, -droppiness / 2);
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NSPoint dropTip = scalePoint(bulbCenter, triangleCenter, tipScale);
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NSBezierPath *path = [[NSBezierPath alloc] init];
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[path appendBezierPathWithArcWithCenter:bulbCenter radius:radius startAngle:-rotation * 360 + droppiness * 180. endAngle:-rotation * 360 - droppiness * 180. clockwise:NO];
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[path moveToPoint:dropCorner1];
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[path lineToPoint:dropTip];
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[path lineToPoint:dropCorner2];
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[path closePath];
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sPath = path;
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}
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return [sPath retain];
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}
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@implementation HFRepresenterTextViewCallout
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/* A helpful struct for representing a wedge (portion of a circle). Wedges are counterclockwise. */
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typedef struct {
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double offset; // 0 <= offset < 1
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double length; // 0 <= length <= 1
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} Wedge_t;
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static inline double normalizeAngle(double x) {
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/* Convert an angle to the range [0, 1). We typically only generate angles that are off by a full rotation, so a loop isn't too bad. */
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while (x >= 1.) x -= 1.;
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while (x < 0.) x += 1.;
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return x;
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}
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static inline double distanceCCW(double a, double b) { return normalizeAngle(b-a); }
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static inline double wedgeMax(Wedge_t wedge) {
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return normalizeAngle(wedge.offset + wedge.length);
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}
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/* Computes the smallest wedge containing the two given wedges. Compute the wedge from the min of one to the furthest part of the other, and pick the smaller. */
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static Wedge_t wedgeUnion(Wedge_t wedge1, Wedge_t wedge2) {
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// empty wedges don't participate
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if (wedge1.length <= 0) return wedge2;
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if (wedge2.length <= 0) return wedge1;
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Wedge_t union1 = wedge1;
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union1.length = fmin(1., fmax(union1.length, distanceCCW(union1.offset, wedge2.offset) + wedge2.length));
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Wedge_t union2 = wedge2;
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union2.length = fmin(1., fmax(union2.length, distanceCCW(union2.offset, wedge1.offset) + wedge1.length));
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Wedge_t result = (union1.length <= union2.length ? union1 : union2);
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HFASSERT(result.length <= 1);
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return result;
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}
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- (instancetype)init {
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self = [super init];
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if (self) {
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// Initialization code here.
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}
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return self;
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}
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- (void)dealloc {
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[_representedObject release];
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[_color release];
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[_label release];
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[super dealloc];
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}
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- (NSComparisonResult)compare:(HFRepresenterTextViewCallout *)callout {
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return [_representedObject compare:callout.representedObject];
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}
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static Wedge_t computeForbiddenAngle(double distanceFromEdge, double angleToEdge) {
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Wedge_t newForbiddenAngle;
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/* This is how far it is to the center of our teardrop */
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const double teardropLength = HFTeardropRadius * HFTeadropTipScale;
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if (distanceFromEdge <= 0) {
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/* We're above or below. */
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if (-distanceFromEdge >= (teardropLength + HFTeardropRadius)) {
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/* We're so far above or below we won't be visible at all. No hope. */
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newForbiddenAngle = (Wedge_t){.offset = 0, .length = 1};
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} else {
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/* We're either above or below the bounds, but there's a hope we can be visible */
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double invertedAngleToEdge = normalizeAngle(angleToEdge + .5);
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double requiredAngle;
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if (-distanceFromEdge >= teardropLength) {
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// We're too far north or south that all we can do is point in the right direction
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requiredAngle = 0;
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} else {
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// By confining ourselves to required angles, we can make ourselves visible
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requiredAngle = acos(-distanceFromEdge / teardropLength) / (2 * M_PI);
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}
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// Require at least a small spread
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requiredAngle = fmax(requiredAngle, .04);
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double requiredMin = invertedAngleToEdge - requiredAngle;
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double requiredMax = invertedAngleToEdge + requiredAngle;
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newForbiddenAngle = (Wedge_t){.offset = requiredMax, .length = distanceCCW(requiredMax, requiredMin) };
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}
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} else if (distanceFromEdge < teardropLength) {
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// We're onscreen, but some angle will be forbidden
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double forbiddenAngle = acos(distanceFromEdge / teardropLength) / (2 * M_PI);
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// This is a wedge out of the top (or bottom)
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newForbiddenAngle = (Wedge_t){.offset = angleToEdge - forbiddenAngle, .length = 2 * forbiddenAngle};
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} else {
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/* Nothing prohibited at all */
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newForbiddenAngle = (Wedge_t){0, 0};
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}
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return newForbiddenAngle;
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}
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static double distanceMod1(double a, double b) {
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/* Assuming 0 <= a, b < 1, returns the distance between a and b, mod 1 */
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if (a > b) {
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return fmin(a-b, b-a+1);
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} else {
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return fmin(b-a, a-b+1);
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}
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}
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+ (void)layoutCallouts:(NSArray *)callouts inView:(HFRepresenterTextView *)textView {
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// Keep track of how many drops are at a given location
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NSCountedSet *dropsPerByteLoc = [[NSCountedSet alloc] init];
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const CGFloat lineHeight = [textView lineHeight];
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const NSRect bounds = [textView bounds];
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NSMutableArray *remainingCallouts = [[callouts mutableCopy] autorelease];
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[remainingCallouts sortUsingSelector:@selector(compare:)];
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while ([remainingCallouts count] > 0) {
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/* Get the next callout to lay out */
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const NSInteger byteLoc = [remainingCallouts[0] byteOffset];
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/* Get all the callouts that share that byteLoc */
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NSMutableArray *sharedCallouts = [NSMutableArray array];
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FOREACH(HFRepresenterTextViewCallout *, testCallout, remainingCallouts) {
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if ([testCallout byteOffset] == byteLoc) {
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[sharedCallouts addObject:testCallout];
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}
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}
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/* We expect to get at least one */
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const NSUInteger calloutCount = [sharedCallouts count];
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HFASSERT(calloutCount > 0);
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/* Get the character origin */
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const NSPoint characterOrigin = [textView originForCharacterAtByteIndex:byteLoc];
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Wedge_t forbiddenAngle = {0, 0};
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// Compute how far we are from the top (or bottom)
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BOOL isNearerTop = (characterOrigin.y < NSMidY(bounds));
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double verticalDistance = (isNearerTop ? characterOrigin.y - NSMinY(bounds) : NSMaxY(bounds) - characterOrigin.y);
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forbiddenAngle = wedgeUnion(forbiddenAngle, computeForbiddenAngle(verticalDistance, (isNearerTop ? .25 : .75)));
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// Compute how far we are from the left (or right)
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BOOL isNearerLeft = (characterOrigin.x < NSMidX(bounds));
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double horizontalDistance = (isNearerLeft ? characterOrigin.x - NSMinX(bounds) : NSMaxX(bounds) - characterOrigin.x);
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forbiddenAngle = wedgeUnion(forbiddenAngle, computeForbiddenAngle(horizontalDistance, (isNearerLeft ? .5 : 0.)));
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/* How much will each callout rotate? No more than 1/8th. */
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HFASSERT(forbiddenAngle.length <= 1);
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double changeInRotationPerCallout = fmin(.125, (1. - forbiddenAngle.length) / calloutCount);
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double totalConsumedAmount = changeInRotationPerCallout * calloutCount;
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/* We would like to center around .375. */
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const double goalCenter = .375;
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/* We're going to pretend to work on a line segment that extends from the max prohibited angle all the way back to min */
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double segmentLength = 1. - forbiddenAngle.length;
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double goalSegmentCenter = normalizeAngle(goalCenter - wedgeMax(forbiddenAngle)); //may exceed segmentLength!
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/* Now center us on the goal, or as close as we can get. */
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double consumedSegmentCenter;
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/* We only need to worry about wrapping around if we have some prohibited angle */
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if (forbiddenAngle.length <= 0) { //never expect < 0, but be paranoid
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consumedSegmentCenter = goalSegmentCenter;
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} else {
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/* The consumed segment center is confined to the segment range [amount/2, length - amount/2] */
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double consumedSegmentCenterMin = totalConsumedAmount/2;
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double consumedSegmentCenterMax = segmentLength - totalConsumedAmount/2;
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if (goalSegmentCenter >= consumedSegmentCenterMin && goalSegmentCenter < consumedSegmentCenterMax) {
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/* We can hit our goal */
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consumedSegmentCenter = goalSegmentCenter;
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} else {
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/* Pick either the min or max location, depending on which one gets us closer to the goal segment center mod 1. */
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if (distanceMod1(goalSegmentCenter, consumedSegmentCenterMin) <= distanceMod1(goalSegmentCenter, consumedSegmentCenterMax)) {
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consumedSegmentCenter = consumedSegmentCenterMin;
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} else {
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consumedSegmentCenter = consumedSegmentCenterMax;
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}
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}
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}
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/* Now convert this back to an angle */
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double consumedAngleCenter = normalizeAngle(wedgeMax(forbiddenAngle) + consumedSegmentCenter);
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// move us slightly towards the character
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NSPoint teardropTipOrigin = NSMakePoint(characterOrigin.x + 1, characterOrigin.y + floor(lineHeight / 8.));
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// make the pin
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NSPoint pinStart, pinEnd;
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pinStart = NSMakePoint(characterOrigin.x + .25, characterOrigin.y);
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pinEnd = NSMakePoint(pinStart.x, pinStart.y + lineHeight);
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// store it all, invalidating as necessary
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NSInteger i = 0;
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FOREACH(HFRepresenterTextViewCallout *, callout, sharedCallouts) {
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/* Compute the rotation */
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double seq = (i+1)/2; //0, 1, -1, 2, -2...
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if ((i & 1) == 0) seq = -seq;
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//if we've got an even number of callouts, we want -.5, .5, -1.5, 1.5...
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if (! (calloutCount & 1)) seq -= .5;
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// compute the angle of rotation
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double angle = consumedAngleCenter + seq * changeInRotationPerCallout;
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// our notion of rotation has 0 meaning pointing right and going counterclockwise, but callouts with 0 pointing left and going clockwise, so convert
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angle = normalizeAngle(.5 - angle);
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NSRect beforeRect = [callout rect];
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callout->rotation = angle;
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callout->tipOrigin = teardropTipOrigin;
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callout->pinStart = pinStart;
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callout->pinEnd = pinEnd;
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// Only the first gets a pin
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pinStart = pinEnd = NSZeroPoint;
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NSRect afterRect = [callout rect];
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if (! NSEqualRects(beforeRect, afterRect)) {
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[textView setNeedsDisplayInRect:beforeRect];
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[textView setNeedsDisplayInRect:afterRect];
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}
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i++;
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}
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/* We're done laying out these callouts */
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[remainingCallouts removeObjectsInArray:sharedCallouts];
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}
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[dropsPerByteLoc release];
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}
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- (CGAffineTransform)teardropTransform {
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CGAffineTransform trans = CGAffineTransformMakeTranslation(tipOrigin.x, tipOrigin.y);
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trans = CGAffineTransformRotate(trans, rotation * M_PI * 2);
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return trans;
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}
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- (NSRect)teardropBaseRect {
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NSSize teardropSize = NSMakeSize(HFTeardropRadius * (1 + HFTeadropTipScale), HFTeardropRadius*2);
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NSRect result = NSMakeRect(-teardropSize.width, -teardropSize.height/2, teardropSize.width, teardropSize.height);
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return result;
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}
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- (CGAffineTransform)shadowTransform {
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CGFloat shadowXOffset = HFShadowXOffset;
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CGFloat shadowYOffset = HFShadowYOffset;
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CGFloat offscreenOffset = HFShadowOffscreenHack;
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// Figure out how much movement the shadow offset produces
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CGFloat shadowTranslationDistance = hypot(shadowXOffset, shadowYOffset);
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CGAffineTransform transform = CGAffineTransformIdentity;
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transform = CGAffineTransformTranslate(transform, tipOrigin.x + offscreenOffset - shadowXOffset, tipOrigin.y - shadowYOffset);
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transform = CGAffineTransformRotate(transform, rotation * M_PI * 2 - atan2(shadowTranslationDistance, 2*HFTeardropRadius /* bulbHeight */));
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return transform;
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}
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- (void)drawShadowWithClip:(NSRect)clip {
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USE(clip);
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CGContextRef ctx = [[NSGraphicsContext currentContext] graphicsPort];
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// Set the shadow. Note that these shadows are pretty unphysical for high rotations.
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NSShadow *shadow = [[NSShadow alloc] init];
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[shadow setShadowBlurRadius:5.];
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[shadow setShadowOffset:NSMakeSize(HFShadowXOffset - HFShadowOffscreenHack, HFShadowYOffset)];
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[shadow setShadowColor:[NSColor colorWithDeviceWhite:0. alpha:.5]];
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[shadow set];
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[shadow release];
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// Draw the shadow first and separately
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CGAffineTransform transform = [self shadowTransform];
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CGContextConcatCTM(ctx, transform);
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NSBezierPath *teardrop = copyTeardropPath();
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[teardrop fill];
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[teardrop release];
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// Clear the shadow
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CGContextSetShadowWithColor(ctx, CGSizeZero, 0, NULL);
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// Undo the transform
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CGContextConcatCTM(ctx, CGAffineTransformInvert(transform));
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}
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- (void)drawWithClip:(NSRect)clip {
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USE(clip);
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CGContextRef ctx = [[NSGraphicsContext currentContext] graphicsPort];
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// Here's the font we'll use
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CTFontRef ctfont = CTFontCreateWithName(CFSTR("Helvetica-Bold"), 1., NULL);
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if (ctfont) {
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// Set the font
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[(NSFont *)ctfont set];
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// Get characters
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NSUInteger labelLength = MIN([_label length], kHFRepresenterTextViewCalloutMaxGlyphCount);
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UniChar calloutUniLabel[kHFRepresenterTextViewCalloutMaxGlyphCount];
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[_label getCharacters:calloutUniLabel range:NSMakeRange(0, labelLength)];
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// Get our glyphs and advances
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CGGlyph glyphs[kHFRepresenterTextViewCalloutMaxGlyphCount];
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CGSize advances[kHFRepresenterTextViewCalloutMaxGlyphCount];
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CTFontGetGlyphsForCharacters(ctfont, calloutUniLabel, glyphs, labelLength);
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CTFontGetAdvancesForGlyphs(ctfont, kCTFontHorizontalOrientation, glyphs, advances, labelLength);
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// Count our glyphs. Note: this won't work with any label containing spaces, etc.
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NSUInteger glyphCount;
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for (glyphCount = 0; glyphCount < labelLength; glyphCount++) {
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if (glyphs[glyphCount] == 0) break;
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}
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// Set our color.
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[_color set];
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// Draw the pin first
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if (! NSEqualPoints(pinStart, pinEnd)) {
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[NSBezierPath setDefaultLineWidth:1.25];
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[NSBezierPath strokeLineFromPoint:pinStart toPoint:pinEnd];
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}
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CGContextSaveGState(ctx);
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CGContextBeginTransparencyLayerWithRect(ctx, NSRectToCGRect([self rect]), NULL);
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// Rotate and translate in preparation for drawing the teardrop
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CGContextConcatCTM(ctx, [self teardropTransform]);
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// Draw the teardrop
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NSBezierPath *teardrop = copyTeardropPath();
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[teardrop fill];
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[teardrop release];
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// Draw the text with white and alpha. Use blend mode copy so that we clip out the shadow, and when the transparency layer is ended we'll composite over the text.
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CGFloat textScale = (glyphCount == 1 ? 24 : 20);
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// we are flipped by default, so invert the rotation's sign to get the text direction. Use a little slop so we don't get jitter.
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const CGFloat textDirection = (rotation <= .27 || rotation >= .73) ? -1 : 1;
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CGPoint positions[kHFRepresenterTextViewCalloutMaxGlyphCount];
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CGFloat totalAdvance = 0;
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for (NSUInteger i=0; i < glyphCount; i++) {
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// make sure to provide negative advances if necessary
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positions[i].x = copysign(totalAdvance, -textDirection);
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positions[i].y = 0;
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CGFloat advance = advances[i].width;
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// Workaround 5834794
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advance *= textScale;
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// Tighten up the advances a little
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advance *= .85;
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totalAdvance += advance;
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}
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// Compute the vertical offset
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CGFloat textYOffset = (glyphCount == 1 ? 4 : 5);
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// LOL
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if ([_label isEqualToString:@"6"] || [_label isEqualToString:@"7"] == 7) textYOffset -= 1;
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// Apply this text matrix
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NSRect bulbRect = [self teardropBaseRect];
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CGAffineTransform textMatrix = CGAffineTransformMakeScale(-copysign(textScale, textDirection), copysign(textScale, textDirection)); //roughly the font size we want
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textMatrix.tx = NSMinX(bulbRect) + HFTeardropRadius + copysign(totalAdvance/2, textDirection);
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if (textDirection < 0) {
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textMatrix.ty = NSMaxY(bulbRect) - textYOffset;
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} else {
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textMatrix.ty = NSMinY(bulbRect) + textYOffset;
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}
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// Draw
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CGContextSetTextMatrix(ctx, textMatrix);
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CGContextSetTextDrawingMode(ctx, kCGTextClip);
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CGContextShowGlyphsAtPositions(ctx, glyphs, positions, glyphCount);
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CGContextSetBlendMode(ctx, kCGBlendModeCopy);
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CGContextSetGrayFillColor(ctx, 1., .66); //faint white fill
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CGContextFillRect(ctx, NSRectToCGRect(NSInsetRect(bulbRect, -20, -20)));
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// Done drawing, so composite
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CGContextEndTransparencyLayer(ctx);
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CGContextRestoreGState(ctx); // this also restores the clip, which is important
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// Done with the font
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CFRelease(ctfont);
|
|
}
|
|
}
|
|
|
|
- (NSRect)rect {
|
|
// get the transformed teardrop rect
|
|
NSRect result = NSRectFromCGRect(CGRectApplyAffineTransform(NSRectToCGRect([self teardropBaseRect]), [self teardropTransform]));
|
|
|
|
// outset a bit for the shadow
|
|
result = NSInsetRect(result, -8, -8);
|
|
return result;
|
|
}
|
|
|
|
@end
|