using Ryujinx.Graphics.Shader.IntermediateRepresentation; using Ryujinx.Graphics.Shader.StructuredIr; using Ryujinx.Graphics.Shader.Translation; using System; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenBallot; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenCall; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenFSI; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenHelper; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenMemory; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenPacking; using static Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions.InstGenVector; using static Ryujinx.Graphics.Shader.StructuredIr.InstructionInfo; namespace Ryujinx.Graphics.Shader.CodeGen.Glsl.Instructions { static class InstGen { public static string GetExpression(CodeGenContext context, IAstNode node) { if (node is AstOperation operation) { return GetExpression(context, operation); } else if (node is AstOperand operand) { return context.OperandManager.GetExpression(context, operand); } throw new ArgumentException($"Invalid node type \"{node?.GetType().Name ?? "null"}\"."); } public static string Negate(CodeGenContext context, AstOperation operation, InstInfo info) { IAstNode src = operation.GetSource(0); AggregateType type = GetSrcVarType(operation.Inst, 0); string srcExpr = GetSoureExpr(context, src, type); string zero; if (type == AggregateType.FP64) { zero = "0.0"; } else { NumberFormatter.TryFormat(0, type, out zero); } // Starting in the 496.13 NVIDIA driver, there's an issue with assigning variables to negated expressions. // (-expr) does not work, but (0.0 - expr) does. This should be removed once the issue is resolved. return $"{zero} - {Enclose(srcExpr, src, operation.Inst, info, false)}"; } private static string GetExpression(CodeGenContext context, AstOperation operation) { Instruction inst = operation.Inst; InstInfo info = GetInstructionInfo(inst); if ((info.Type & InstType.Call) != 0) { bool atomic = (info.Type & InstType.Atomic) != 0; int arity = (int)(info.Type & InstType.ArityMask); string args = string.Empty; for (int argIndex = 0; argIndex < arity; argIndex++) { // For shared memory access, the second argument is unused and should be ignored. // It is there to make both storage and shared access have the same number of arguments. // For storage, both inputs are consumed when the argument index is 0, so we should skip it here. if (argIndex == 1 && (atomic || operation.StorageKind == StorageKind.SharedMemory)) { continue; } if (argIndex != 0) { args += ", "; } if (argIndex == 0 && atomic) { switch (operation.StorageKind) { case StorageKind.SharedMemory: args += LoadShared(context, operation); break; case StorageKind.StorageBuffer: args += LoadStorage(context, operation); break; default: throw new InvalidOperationException($"Invalid storage kind \"{operation.StorageKind}\"."); } } else { AggregateType dstType = GetSrcVarType(inst, argIndex); args += GetSoureExpr(context, operation.GetSource(argIndex), dstType); } } return info.OpName + '(' + args + ')'; } else if ((info.Type & InstType.Op) != 0) { string op = info.OpName; // Return may optionally have a return value (and in this case it is unary). if (inst == Instruction.Return && operation.SourcesCount != 0) { return $"{op} {GetSoureExpr(context, operation.GetSource(0), context.CurrentFunction.ReturnType)}"; } int arity = (int)(info.Type & InstType.ArityMask); string[] expr = new string[arity]; for (int index = 0; index < arity; index++) { IAstNode src = operation.GetSource(index); string srcExpr = GetSoureExpr(context, src, GetSrcVarType(inst, index)); bool isLhs = arity == 2 && index == 0; expr[index] = Enclose(srcExpr, src, inst, info, isLhs); } switch (arity) { case 0: return op; case 1: return op + expr[0]; case 2: return $"{expr[0]} {op} {expr[1]}"; case 3: return $"{expr[0]} {op[0]} {expr[1]} {op[1]} {expr[2]}"; } } else if ((info.Type & InstType.Special) != 0) { switch (inst & Instruction.Mask) { case Instruction.Ballot: return Ballot(context, operation); case Instruction.Call: return Call(context, operation); case Instruction.FSIBegin: return FSIBegin(context); case Instruction.FSIEnd: return FSIEnd(context); case Instruction.ImageLoad: case Instruction.ImageStore: case Instruction.ImageAtomic: return ImageLoadOrStore(context, operation); case Instruction.Load: return Load(context, operation); case Instruction.LoadConstant: return LoadConstant(context, operation); case Instruction.LoadLocal: return LoadLocal(context, operation); case Instruction.LoadShared: return LoadShared(context, operation); case Instruction.LoadStorage: return LoadStorage(context, operation); case Instruction.Lod: return Lod(context, operation); case Instruction.Negate: return Negate(context, operation, info); case Instruction.PackDouble2x32: return PackDouble2x32(context, operation); case Instruction.PackHalf2x16: return PackHalf2x16(context, operation); case Instruction.Store: return Store(context, operation); case Instruction.StoreLocal: return StoreLocal(context, operation); case Instruction.StoreShared: return StoreShared(context, operation); case Instruction.StoreShared16: return StoreShared16(context, operation); case Instruction.StoreShared8: return StoreShared8(context, operation); case Instruction.StoreStorage: return StoreStorage(context, operation); case Instruction.StoreStorage16: return StoreStorage16(context, operation); case Instruction.StoreStorage8: return StoreStorage8(context, operation); case Instruction.TextureSample: return TextureSample(context, operation); case Instruction.TextureSize: return TextureSize(context, operation); case Instruction.UnpackDouble2x32: return UnpackDouble2x32(context, operation); case Instruction.UnpackHalf2x16: return UnpackHalf2x16(context, operation); case Instruction.VectorExtract: return VectorExtract(context, operation); } } throw new InvalidOperationException($"Unexpected instruction type \"{info.Type}\"."); } } }