| /external/freetype/src/tools/ |
| cordic.py | 17 angle = math.atan(x) # arctangent variable
18 angle2 = round(angle*scale) # arctangent in FT_Angle units
|
| /external/freetype/include/freetype/ |
| fttrigon.h | 48 * This type is used to model angle values in FreeType. Note that the
49 * angle is a 16.16 fixed-point value expressed in degrees.
61 * The angle pi expressed in @FT_Angle units.
73 * The angle 2*pi expressed in @FT_Angle units.
85 * The angle pi/2 expressed in @FT_Angle units.
97 * The angle pi/4 expressed in @FT_Angle units.
109 * Return the sinus of a given angle in fixed-point format.
112 * angle ::
113 * The input angle.
119 * If you need both the sinus and cosinus for a given angle, use th
124 FT_Sin( FT_Angle angle ); variable
148 FT_Cos( FT_Angle angle ); variable
168 FT_Tan( FT_Angle angle ); variable
[all...] |
| /external/skia/samplecode/ |
| SampleStringArt.cpp | 16 // generating an angle from 0 to 1.
32 SkScalar angle = fAngle*SK_ScalarPI + SkScalarHalf(SK_ScalarPI); variable
36 SkScalar step = angle;
46 length += angle / SkScalarHalf(SK_ScalarPI);
47 step += angle;
|
| SampleArc.cpp | 191 SkScalar angle = SkDoubleToScalar(fmod(timer.secs() * 360 / 24, 360)); variable
192 fAnimatingDrawable->setSweep(angle);
|
| SampleCircle.cpp | 79 SkScalar angle = 0; local
81 angle += step;
82 SkScalar c, s = SkScalarSinCos(angle, &c);
|
| /external/skqp/samplecode/ |
| SampleStringArt.cpp | 16 // generating an angle from 0 to 1.
32 SkScalar angle = fAngle*SK_ScalarPI + SkScalarHalf(SK_ScalarPI); variable
36 SkScalar step = angle;
46 length += angle / SkScalarHalf(SK_ScalarPI);
47 step += angle;
|
| SampleArc.cpp | 191 SkScalar angle = SkDoubleToScalar(fmod(timer.secs() * 360 / 24, 360)); variable
192 fAnimatingDrawable->setSweep(angle);
|
| SampleCircle.cpp | 79 SkScalar angle = 0; local
81 angle += step;
82 SkScalar c, s = SkScalarSinCos(angle, &c);
|
| /external/eigen/demos/opengl/ |
| trackball.cpp | 28 float angle = 2. * acos(cos_angle); local
30 mpCamera->rotateAroundTarget(Quaternionf(AngleAxisf(angle, axis)));
32 mpCamera->localRotate(Quaternionf(AngleAxisf(-angle, axis)));
|
| gpuhelper.cpp | 67 float angle = 180.f/M_PI * acos(tmp.z()); local
68 if (angle>1e-3)
69 glRotatef(angle, ax.x(), ax.y(), ax.z());
88 float angle = 180.f/M_PI * acos(tmp.z()); local
89 if (angle>1e-3)
90 glRotatef(angle, ax.x(), ax.y(), ax.z());
|
| /external/freetype/src/autofit/ |
| afangles.c | 33 * The trick here is to realize that we don't need a very accurate angle
35 * only compare the sign of angle differences, or check whether its
48 AF_Angle angle;
61 angle = 0;
64 angle = ( AF_ANGLE_PI2 * dy ) / ( ax + ay );
67 if ( angle >= 0 )
68 angle = AF_ANGLE_PI - angle;
70 angle = -AF_ANGLE_PI - angle;
127 AF_Angle angle; local
[all...] |
| /external/eigen/unsupported/test/ |
| matrix_exponential.cpp | 30 T angle; local
35 angle = static_cast<T>(pow(10, i / 5. - 2));
36 B << std::cos(angle), std::sin(angle), -std::sin(angle), std::cos(angle);
38 C = (angle*A).matrixFunction(expfn);
42 C = (angle*A).exp();
53 T angle, ch, sh; local
57 angle = static_cast<T>((i-10) / 2.0)
[all...] |
| /cts/hostsidetests/angle/src/android/angle/cts/ |
| CtsAngleRulesFileTest.java | 16 package android.angle.cts;
18 import static android.angle.cts.CtsAngleCommon.*;
37 * Tests ANGLE Rules File Opt-In/Out functionality.
85 * Test ANGLE is not loaded when an empty rules file is used.
101 * Test ANGLE is loaded for only the PKG the rules file specifies.
|
| /device/google/bonito/sdm710/kernel-headers/media/ |
| msm_fd.h | 37 __u32 angle; member in struct:msm_fd_face_data
|
| /device/google/bonito/sdm710/original-kernel-headers/media/ |
| msm_fd.h | 33 * @angle: Face angle
40 __u32 angle; member in struct:msm_fd_face_data
|
| /device/google/crosshatch/sdm845/kernel-headers/media/ |
| msm_fd.h | 37 __u32 angle; member in struct:msm_fd_face_data
|
| /device/google/crosshatch/sdm845/original-kernel-headers/media/ |
| msm_fd.h | 33 * @angle: Face angle
40 __u32 angle; member in struct:msm_fd_face_data
|
| /external/skia/gm/ |
| anisotropic.cpp | 43 SkScalar angle = 0.0f, sin, cos; variable
46 for (int i = 0; i < kNumLines; ++i, angle += kAngleStep) {
47 sin = SkScalarSinCos(angle, &cos);
|
| strokedlines.cpp | 24 static void draw_fins(SkCanvas* canvas, const SkPoint& offset, float angle, const SkPaint& paint) {
28 sin = SkScalarSinCos(angle + (SK_ScalarPI/4), &cos);
38 sin = SkScalarSinCos(angle - (SK_ScalarPI/4), &cos);
53 SkScalar sin, cos, angle = 0.0f; local
54 for (int i = 0; i < kNumSpokes/2; ++i, angle += SK_ScalarPI/(kNumSpokes/2)) {
55 sin = SkScalarSinCos(angle, &cos);
67 draw_fins(canvas, posOffset, angle, paint);
71 draw_fins(canvas, negOffset, angle+SK_ScalarPI, paint);
|
| tallstretchedbitmaps.cpp | 33 SkScalar angle = kStartAngle; local
52 canvas.drawArc(bounds, angle, kSweep, false, paint);
53 angle += kDAngle;
|
| /external/skia/tools/skqp/ |
| jitter_gms.cpp | 35 // this is the angle (in radians) for the first one.
59 float angle = i * (6.2831853f / kNumberOfJitters) + kPhase; local
60 do_gm(&experimental, gm, SkPoint{kJitterMagnitude * cosf(angle),
61 kJitterMagnitude * sinf(angle)});
|
| /external/skqp/gm/ |
| anisotropic.cpp | 43 SkScalar angle = 0.0f, sin, cos; variable
46 for (int i = 0; i < kNumLines; ++i, angle += kAngleStep) {
47 sin = SkScalarSinCos(angle, &cos);
|
| strokedlines.cpp | 24 static void draw_fins(SkCanvas* canvas, const SkPoint& offset, float angle, const SkPaint& paint) {
28 sin = SkScalarSinCos(angle + (SK_ScalarPI/4), &cos);
38 sin = SkScalarSinCos(angle - (SK_ScalarPI/4), &cos);
53 SkScalar sin, cos, angle = 0.0f; local
54 for (int i = 0; i < kNumSpokes/2; ++i, angle += SK_ScalarPI/(kNumSpokes/2)) {
55 sin = SkScalarSinCos(angle, &cos);
67 draw_fins(canvas, posOffset, angle, paint);
71 draw_fins(canvas, negOffset, angle+SK_ScalarPI, paint);
|
| tallstretchedbitmaps.cpp | 33 SkScalar angle = kStartAngle; local
52 canvas.drawArc(bounds, angle, kSweep, false, paint);
53 angle += kDAngle;
|
| /external/skqp/tools/skqp/ |
| jitter_gms.cpp | 35 // this is the angle (in radians) for the first one.
59 float angle = i * (6.2831853f / kNumberOfJitters) + kPhase; local
60 do_gm(&experimental, gm, SkPoint{kJitterMagnitude * cosf(angle),
61 kJitterMagnitude * sinf(angle)});
|
