// // Copyright 2014 The ANGLE Project Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // #include "compiler/translator/hlsl/BuiltInFunctionEmulatorHLSL.h" #include "angle_gl.h" #include "compiler/translator/BuiltInFunctionEmulator.h" #include "compiler/translator/tree_util/BuiltIn.h" namespace sh { // Defined in emulated_builtin_functions_hlsl_autogen.cpp. const char *FindHLSLFunction(int uniqueId); void InitBuiltInIsnanFunctionEmulatorForHLSLWorkarounds(BuiltInFunctionEmulator *emu, int targetGLSLVersion) { if (targetGLSLVersion < 130) return; emu->addEmulatedFunction(BuiltInId::isnan_Float1, "bool isnan_emu(float x)\n" "{\n" " return (x > 0.0 || x < 0.0) ? false : x != 0.0;\n" "}\n" "\n"); emu->addEmulatedFunction( BuiltInId::isnan_Float2, "bool2 isnan_emu(float2 x)\n" "{\n" " bool2 isnan;\n" " for (int i = 0; i < 2; i++)\n" " {\n" " isnan[i] = (x[i] > 0.0 || x[i] < 0.0) ? false : x[i] != 0.0;\n" " }\n" " return isnan;\n" "}\n"); emu->addEmulatedFunction( BuiltInId::isnan_Float3, "bool3 isnan_emu(float3 x)\n" "{\n" " bool3 isnan;\n" " for (int i = 0; i < 3; i++)\n" " {\n" " isnan[i] = (x[i] > 0.0 || x[i] < 0.0) ? false : x[i] != 0.0;\n" " }\n" " return isnan;\n" "}\n"); emu->addEmulatedFunction( BuiltInId::isnan_Float4, "bool4 isnan_emu(float4 x)\n" "{\n" " bool4 isnan;\n" " for (int i = 0; i < 4; i++)\n" " {\n" " isnan[i] = (x[i] > 0.0 || x[i] < 0.0) ? false : x[i] != 0.0;\n" " }\n" " return isnan;\n" "}\n"); } void InitBuiltInFunctionEmulatorForHLSL(BuiltInFunctionEmulator *emu) { emu->addFunctionMap(FindHLSLFunction); // (a + b2^16) * (c + d2^16) = ac + (ad + bc) * 2^16 + bd * 2^32 // Also note that below, a * d + ((a * c) >> 16) is guaranteed not to overflow, because: // a <= 0xffff, d <= 0xffff, ((a * c) >> 16) <= 0xffff and 0xffff * 0xffff + 0xffff = 0xffff0000 emu->addEmulatedFunction(BuiltInId::umulExtended_UInt1_UInt1_UInt1_UInt1, "void umulExtended_emu(uint x, uint y, out uint msb, out uint lsb)\n" "{\n" " lsb = x * y;\n" " uint a = (x & 0xffffu);\n" " uint b = (x >> 16);\n" " uint c = (y & 0xffffu);\n" " uint d = (y >> 16);\n" " uint ad = a * d + ((a * c) >> 16);\n" " uint bc = b * c;\n" " uint carry = uint(ad > (0xffffffffu - bc));\n" " msb = ((ad + bc) >> 16) + (carry << 16) + b * d;\n" "}\n"); emu->addEmulatedFunctionWithDependency( BuiltInId::umulExtended_UInt1_UInt1_UInt1_UInt1, BuiltInId::umulExtended_UInt2_UInt2_UInt2_UInt2, "void umulExtended_emu(uint2 x, uint2 y, out uint2 msb, out uint2 lsb)\n" "{\n" " umulExtended_emu(x.x, y.x, msb.x, lsb.x);\n" " umulExtended_emu(x.y, y.y, msb.y, lsb.y);\n" "}\n"); emu->addEmulatedFunctionWithDependency( BuiltInId::umulExtended_UInt1_UInt1_UInt1_UInt1, BuiltInId::umulExtended_UInt3_UInt3_UInt3_UInt3, "void umulExtended_emu(uint3 x, uint3 y, out uint3 msb, out uint3 lsb)\n" "{\n" " umulExtended_emu(x.x, y.x, msb.x, lsb.x);\n" " umulExtended_emu(x.y, y.y, msb.y, lsb.y);\n" " umulExtended_emu(x.z, y.z, msb.z, lsb.z);\n" "}\n"); emu->addEmulatedFunctionWithDependency( BuiltInId::umulExtended_UInt1_UInt1_UInt1_UInt1, BuiltInId::umulExtended_UInt4_UInt4_UInt4_UInt4, "void umulExtended_emu(uint4 x, uint4 y, out uint4 msb, out uint4 lsb)\n" "{\n" " umulExtended_emu(x.x, y.x, msb.x, lsb.x);\n" " umulExtended_emu(x.y, y.y, msb.y, lsb.y);\n" " umulExtended_emu(x.z, y.z, msb.z, lsb.z);\n" " umulExtended_emu(x.w, y.w, msb.w, lsb.w);\n" "}\n"); // The imul emulation does two's complement negation on the lsb and msb manually in case the // result needs to be negative. // TODO(oetuaho): Note that this code doesn't take one edge case into account, where x or y is // -2^31. abs(-2^31) is undefined. emu->addEmulatedFunctionWithDependency( BuiltInId::umulExtended_UInt1_UInt1_UInt1_UInt1, BuiltInId::imulExtended_Int1_Int1_Int1_Int1, "void imulExtended_emu(int x, int y, out int msb, out int lsb)\n" "{\n" " uint unsignedMsb;\n" " uint unsignedLsb;\n" " bool negative = (x < 0) != (y < 0);\n" " umulExtended_emu(uint(abs(x)), uint(abs(y)), unsignedMsb, unsignedLsb);\n" " lsb = asint(unsignedLsb);\n" " msb = asint(unsignedMsb);\n" " if (negative)\n" " {\n" " lsb = ~lsb;\n" " msb = ~msb;\n" " if (lsb == 0xffffffff)\n" " {\n" " lsb = 0;\n" " msb += 1;\n" " }\n" " else\n" " {\n" " lsb += 1;\n" " }\n" " }\n" "}\n"); emu->addEmulatedFunctionWithDependency( BuiltInId::imulExtended_Int1_Int1_Int1_Int1, BuiltInId::imulExtended_Int2_Int2_Int2_Int2, "void imulExtended_emu(int2 x, int2 y, out int2 msb, out int2 lsb)\n" "{\n" " imulExtended_emu(x.x, y.x, msb.x, lsb.x);\n" " imulExtended_emu(x.y, y.y, msb.y, lsb.y);\n" "}\n"); emu->addEmulatedFunctionWithDependency( BuiltInId::imulExtended_Int1_Int1_Int1_Int1, BuiltInId::imulExtended_Int3_Int3_Int3_Int3, "void imulExtended_emu(int3 x, int3 y, out int3 msb, out int3 lsb)\n" "{\n" " imulExtended_emu(x.x, y.x, msb.x, lsb.x);\n" " imulExtended_emu(x.y, y.y, msb.y, lsb.y);\n" " imulExtended_emu(x.z, y.z, msb.z, lsb.z);\n" "}\n"); emu->addEmulatedFunctionWithDependency( BuiltInId::imulExtended_Int1_Int1_Int1_Int1, BuiltInId::imulExtended_Int4_Int4_Int4_Int4, "void imulExtended_emu(int4 x, int4 y, out int4 msb, out int4 lsb)\n" "{\n" " imulExtended_emu(x.x, y.x, msb.x, lsb.x);\n" " imulExtended_emu(x.y, y.y, msb.y, lsb.y);\n" " imulExtended_emu(x.z, y.z, msb.z, lsb.z);\n" " imulExtended_emu(x.w, y.w, msb.w, lsb.w);\n" "}\n"); } } // namespace sh