{ "__type__": "cc.EffectAsset", "_name": "__builtin-editor-gizmo", "_objFlags": 0, "_native": "", "properties": null, "techniques": [ { "passes": [ { "stage": "transparent", "blendState": { "targets": [ { "blend": true, "blendEq": 32774, "blendAlphaEq": 32774, "blendSrcAlpha": 1, "blendDstAlpha": 771 } ] }, "rasterizerState": { "cullMode": 0 }, "depthStencilState": { "depthTest": false, "depthWrite": false }, "properties": { "diffuseColor": { "value": [ 1, 1, 1, 1 ], "editor": { "type": "color" }, "type": 16 } }, "program": "__builtin-editor-gizmo|vs|fs" } ] } ], "shaders": [ { "hash": 2992916359, "glsl3": { "vert": "\nprecision highp float;\nuniform CCGlobal {\n mat4 cc_matView;\n mat4 cc_matViewInv;\n mat4 cc_matProj;\n mat4 cc_matProjInv;\n mat4 cc_matViewProj;\n mat4 cc_matViewProjInv;\n vec4 cc_cameraPos;\n vec4 cc_time;\n mediump vec4 cc_screenSize;\n mediump vec4 cc_screenScale;\n};\nuniform CCLocal {\n mat4 cc_matWorld;\n mat4 cc_matWorldIT;\n};\nvarying vec3 v_worldNormal;\nvarying vec3 v_worldPosition;\nvarying vec3 v_localPosition;\nvarying vec3 v_right;\nvarying vec3 v_up;\nvarying vec3 v_forward;\nattribute vec3 a_position;\nattribute vec3 a_normal;\nvoid main () {\n vec4 pos = vec4(a_position, 1);\n v_localPosition = a_position;\n v_worldPosition = (cc_matWorld * pos).xyz;\n v_worldNormal = (cc_matWorldIT * vec4(a_normal, 0)).xyz;\n v_right = vec3(cc_matView[0][0], cc_matView[1][0], cc_matView[2][0]);\n v_up = vec3(cc_matView[0][1], cc_matView[1][1], cc_matView[2][1]);\n v_forward = vec3(cc_matView[0][2], cc_matView[1][2], cc_matView[2][2]);\n gl_Position = cc_matViewProj * cc_matWorld * pos;\n}", "frag": "\nprecision highp float;\nvec4 CCFragOutput (vec4 color) {\n #if OUTPUT_TO_GAMMA\n color.rgb = sqrt(color.rgb);\n #endif\n\treturn color;\n}\nmat3 transpose(mat3 v) {\n mat3 tmp;\n tmp[0] = vec3(v[0].x, v[1].x, v[2].x);\n tmp[1] = vec3(v[0].y, v[1].y, v[2].y);\n tmp[2] = vec3(v[0].z, v[1].z, v[2].z);\n return tmp;\n}\nvoid ClipQuadToHorizon(inout vec3 L[5], out int n) {\n int config = 0;\n if (L[0].z > 0.0) config += 1;\n if (L[1].z > 0.0) config += 2;\n if (L[2].z > 0.0) config += 4;\n if (L[3].z > 0.0) config += 8;\n config = 15;\n n = 0;\n if (config == 0)\n {\n }\n else if (config == 1)\n {\n n = 3;\n L[1] = -L[1].z * L[0] + L[0].z * L[1];\n L[2] = -L[3].z * L[0] + L[0].z * L[3];\n }\n else if (config == 2)\n {\n n = 3;\n L[0] = -L[0].z * L[1] + L[1].z * L[0];\n L[2] = -L[2].z * L[1] + L[1].z * L[2];\n }\n else if (config == 3)\n {\n n = 4;\n L[2] = -L[2].z * L[1] + L[1].z * L[2];\n L[3] = -L[3].z * L[0] + L[0].z * L[3];\n }\n else if (config == 4)\n {\n n = 3;\n L[0] = -L[3].z * L[2] + L[2].z * L[3];\n L[1] = -L[1].z * L[2] + L[2].z * L[1];\n }\n else if (config == 5)\n {\n n = 0;\n }\n else if (config == 6)\n {\n n = 4;\n L[0] = -L[0].z * L[1] + L[1].z * L[0];\n L[3] = -L[3].z * L[2] + L[2].z * L[3];\n }\n else if (config == 7)\n {\n n = 5;\n L[4] = -L[3].z * L[0] + L[0].z * L[3];\n L[3] = -L[3].z * L[2] + L[2].z * L[3];\n }\n else if (config == 8)\n {\n n = 3;\n L[0] = -L[0].z * L[3] + L[3].z * L[0];\n L[1] = -L[2].z * L[3] + L[3].z * L[2];\n L[2] = L[3];\n }\n else if (config == 9)\n {\n n = 4;\n L[1] = -L[1].z * L[0] + L[0].z * L[1];\n L[2] = -L[2].z * L[3] + L[3].z * L[2];\n }\n else if (config == 10)\n {\n n = 0;\n }\n else if (config == 11)\n {\n n = 5;\n L[4] = L[3];\n L[3] = -L[2].z * L[3] + L[3].z * L[2];\n L[2] = -L[2].z * L[1] + L[1].z * L[2];\n }\n else if (config == 12)\n {\n n = 4;\n L[1] = -L[1].z * L[2] + L[2].z * L[1];\n L[0] = -L[0].z * L[3] + L[3].z * L[0];\n }\n else if (config == 13)\n {\n n = 5;\n L[4] = L[3];\n L[3] = L[2];\n L[2] = -L[1].z * L[2] + L[2].z * L[1];\n L[1] = -L[1].z * L[0] + L[0].z * L[1];\n }\n else if (config == 14)\n {\n n = 5;\n L[4] = -L[0].z * L[3] + L[3].z * L[0];\n L[0] = -L[0].z * L[1] + L[1].z * L[0];\n }\n else if (config == 15)\n {\n n = 4;\n }\n if (n == 3)\n L[3] = L[0];\n if (n == 4)\n L[4] = L[0];\n}\nfloat IntegrateEdge(vec3 v1, vec3 v2) {\n float cosTheta = dot(v1, v2);\n float theta = acos(cosTheta);\n return cross(v1, v2).z * ((theta > 0.001) ? theta/sin(theta) : 4.0);\n}\nvec3 LTC_Evaluate(vec3 N, vec3 V, vec3 P, mat3 Minv, vec3 points[4]) {\n vec3 T1, T2;\n T1 = normalize(V - N*dot(V, N));\n T2 = cross(N, T1);\n Minv = Minv * transpose(mat3(T1, T2, N));\n vec3 L[5];\n L[0] = Minv * (points[0] - P);\n L[1] = Minv * (points[1] - P);\n L[2] = Minv * (points[2] - P);\n L[3] = Minv * (points[3] - P);\n int n;\n ClipQuadToHorizon(L, n);\n if (n == 0)\n return vec3(0, 0, 0);\n L[0] = normalize(L[0]);\n L[1] = normalize(L[1]);\n L[2] = normalize(L[2]);\n L[3] = normalize(L[3]);\n L[4] = normalize(L[4]);\n float sum = 0.0;\n sum += IntegrateEdge(L[0], L[1]);\n sum += IntegrateEdge(L[1], L[2]);\n sum += IntegrateEdge(L[2], L[3]);\n if (n >= 4)\n sum += IntegrateEdge(L[3], L[4]);\n if (n == 5)\n sum += IntegrateEdge(L[4], L[0]);\n sum = max(0.0, sum);\n vec3 Lo_i = vec3(sum, sum, sum);\n return Lo_i;\n}\nuniform CCGlobal {\n mat4 cc_matView;\n mat4 cc_matViewInv;\n mat4 cc_matProj;\n mat4 cc_matProjInv;\n mat4 cc_matViewProj;\n mat4 cc_matViewProjInv;\n vec4 cc_cameraPos;\n vec4 cc_time;\n mediump vec4 cc_screenSize;\n mediump vec4 cc_screenScale;\n};\nuniform DIFFUSE_COLOR {\n vec4 diffuseColor;\n};\nvarying vec3 v_worldNormal;\nvarying vec3 v_worldPosition;\nvarying vec3 v_localPosition;\nvarying vec3 v_right;\nvarying vec3 v_up;\nvarying vec3 v_forward;\nvoid main () {\n vec3 N = normalize(v_worldNormal);\n vec3 V = normalize(cc_cameraPos.xyz - v_worldPosition);\n vec3 points[4];\n vec3 up = vec3(0, 1, 0);\n points[0] = (v_forward * 3.0 + v_right + up) * 40.0;\n points[1] = (v_forward * 3.0 - v_right + up) * 40.0;\n points[2] = (v_forward * 3.0 - v_right - up) * 40.0;\n points[3] = (v_forward * 3.0 + v_right - up) * 40.0;\n vec3 diffuse = diffuseColor.rgb * (0.2 + LTC_Evaluate(N, V, v_localPosition, mat3(1), points) * 0.8);\n gl_FragColor = CCFragOutput(vec4(diffuse, diffuseColor.a));\n}" }, "glsl1": { "vert": "\nprecision highp float;\nuniform mat4 cc_matView;\nuniform mat4 cc_matViewProj;\nuniform mat4 cc_matWorld;\nuniform mat4 cc_matWorldIT;\nvarying vec3 v_worldNormal;\nvarying vec3 v_worldPosition;\nvarying vec3 v_localPosition;\nvarying vec3 v_right;\nvarying vec3 v_up;\nvarying vec3 v_forward;\nattribute vec3 a_position;\nattribute vec3 a_normal;\nvoid main () {\n vec4 pos = vec4(a_position, 1);\n v_localPosition = a_position;\n v_worldPosition = (cc_matWorld * pos).xyz;\n v_worldNormal = (cc_matWorldIT * vec4(a_normal, 0)).xyz;\n v_right = vec3(cc_matView[0][0], cc_matView[1][0], cc_matView[2][0]);\n v_up = vec3(cc_matView[0][1], cc_matView[1][1], cc_matView[2][1]);\n v_forward = vec3(cc_matView[0][2], cc_matView[1][2], cc_matView[2][2]);\n gl_Position = cc_matViewProj * cc_matWorld * pos;\n}", "frag": "\nprecision highp float;\nvec4 CCFragOutput (vec4 color) {\n #if OUTPUT_TO_GAMMA\n color.rgb = sqrt(color.rgb);\n #endif\n\treturn color;\n}\nmat3 transpose(mat3 v) {\n mat3 tmp;\n tmp[0] = vec3(v[0].x, v[1].x, v[2].x);\n tmp[1] = vec3(v[0].y, v[1].y, v[2].y);\n tmp[2] = vec3(v[0].z, v[1].z, v[2].z);\n return tmp;\n}\nvoid ClipQuadToHorizon(inout vec3 L[5], out int n) {\n int config = 0;\n if (L[0].z > 0.0) config += 1;\n if (L[1].z > 0.0) config += 2;\n if (L[2].z > 0.0) config += 4;\n if (L[3].z > 0.0) config += 8;\n config = 15;\n n = 0;\n if (config == 0)\n {\n }\n else if (config == 1)\n {\n n = 3;\n L[1] = -L[1].z * L[0] + L[0].z * L[1];\n L[2] = -L[3].z * L[0] + L[0].z * L[3];\n }\n else if (config == 2)\n {\n n = 3;\n L[0] = -L[0].z * L[1] + L[1].z * L[0];\n L[2] = -L[2].z * L[1] + L[1].z * L[2];\n }\n else if (config == 3)\n {\n n = 4;\n L[2] = -L[2].z * L[1] + L[1].z * L[2];\n L[3] = -L[3].z * L[0] + L[0].z * L[3];\n }\n else if (config == 4)\n {\n n = 3;\n L[0] = -L[3].z * L[2] + L[2].z * L[3];\n L[1] = -L[1].z * L[2] + L[2].z * L[1];\n }\n else if (config == 5)\n {\n n = 0;\n }\n else if (config == 6)\n {\n n = 4;\n L[0] = -L[0].z * L[1] + L[1].z * L[0];\n L[3] = -L[3].z * L[2] + L[2].z * L[3];\n }\n else if (config == 7)\n {\n n = 5;\n L[4] = -L[3].z * L[0] + L[0].z * L[3];\n L[3] = -L[3].z * L[2] + L[2].z * L[3];\n }\n else if (config == 8)\n {\n n = 3;\n L[0] = -L[0].z * L[3] + L[3].z * L[0];\n L[1] = -L[2].z * L[3] + L[3].z * L[2];\n L[2] = L[3];\n }\n else if (config == 9)\n {\n n = 4;\n L[1] = -L[1].z * L[0] + L[0].z * L[1];\n L[2] = -L[2].z * L[3] + L[3].z * L[2];\n }\n else if (config == 10)\n {\n n = 0;\n }\n else if (config == 11)\n {\n n = 5;\n L[4] = L[3];\n L[3] = -L[2].z * L[3] + L[3].z * L[2];\n L[2] = -L[2].z * L[1] + L[1].z * L[2];\n }\n else if (config == 12)\n {\n n = 4;\n L[1] = -L[1].z * L[2] + L[2].z * L[1];\n L[0] = -L[0].z * L[3] + L[3].z * L[0];\n }\n else if (config == 13)\n {\n n = 5;\n L[4] = L[3];\n L[3] = L[2];\n L[2] = -L[1].z * L[2] + L[2].z * L[1];\n L[1] = -L[1].z * L[0] + L[0].z * L[1];\n }\n else if (config == 14)\n {\n n = 5;\n L[4] = -L[0].z * L[3] + L[3].z * L[0];\n L[0] = -L[0].z * L[1] + L[1].z * L[0];\n }\n else if (config == 15)\n {\n n = 4;\n }\n if (n == 3)\n L[3] = L[0];\n if (n == 4)\n L[4] = L[0];\n}\nfloat IntegrateEdge(vec3 v1, vec3 v2) {\n float cosTheta = dot(v1, v2);\n float theta = acos(cosTheta);\n return cross(v1, v2).z * ((theta > 0.001) ? theta/sin(theta) : 4.0);\n}\nvec3 LTC_Evaluate(vec3 N, vec3 V, vec3 P, mat3 Minv, vec3 points[4]) {\n vec3 T1, T2;\n T1 = normalize(V - N*dot(V, N));\n T2 = cross(N, T1);\n Minv = Minv * transpose(mat3(T1, T2, N));\n vec3 L[5];\n L[0] = Minv * (points[0] - P);\n L[1] = Minv * (points[1] - P);\n L[2] = Minv * (points[2] - P);\n L[3] = Minv * (points[3] - P);\n int n;\n ClipQuadToHorizon(L, n);\n if (n == 0)\n return vec3(0, 0, 0);\n L[0] = normalize(L[0]);\n L[1] = normalize(L[1]);\n L[2] = normalize(L[2]);\n L[3] = normalize(L[3]);\n L[4] = normalize(L[4]);\n float sum = 0.0;\n sum += IntegrateEdge(L[0], L[1]);\n sum += IntegrateEdge(L[1], L[2]);\n sum += IntegrateEdge(L[2], L[3]);\n if (n >= 4)\n sum += IntegrateEdge(L[3], L[4]);\n if (n == 5)\n sum += IntegrateEdge(L[4], L[0]);\n sum = max(0.0, sum);\n vec3 Lo_i = vec3(sum, sum, sum);\n return Lo_i;\n}\nuniform vec4 cc_cameraPos;\nuniform vec4 diffuseColor;\nvarying vec3 v_worldNormal;\nvarying vec3 v_worldPosition;\nvarying vec3 v_localPosition;\nvarying vec3 v_right;\nvarying vec3 v_up;\nvarying vec3 v_forward;\nvoid main () {\n vec3 N = normalize(v_worldNormal);\n vec3 V = normalize(cc_cameraPos.xyz - v_worldPosition);\n vec3 points[4];\n vec3 up = vec3(0, 1, 0);\n points[0] = (v_forward * 3.0 + v_right + up) * 40.0;\n points[1] = (v_forward * 3.0 - v_right + up) * 40.0;\n points[2] = (v_forward * 3.0 - v_right - up) * 40.0;\n points[3] = (v_forward * 3.0 + v_right - up) * 40.0;\n vec3 diffuse = diffuseColor.rgb * (0.2 + LTC_Evaluate(N, V, v_localPosition, mat3(1), points) * 0.8);\n gl_FragColor = CCFragOutput(vec4(diffuse, diffuseColor.a));\n}" }, "builtins": { "globals": { "blocks": [ { "name": "CCGlobal", "defines": [] } ], "samplers": [] }, "locals": { "blocks": [ { "name": "CCLocal", "defines": [] } ], "samplers": [] } }, "defines": [ { "name": "OUTPUT_TO_GAMMA", "type": "boolean", "defines": [] } ], "blocks": [ { "name": "DIFFUSE_COLOR", "members": [ { "name": "diffuseColor", "type": 16, "count": 1 } ], "defines": [], "binding": 0 } ], "samplers": [], "record": null, "name": "__builtin-editor-gizmo|vs|fs" } ] }