using System;
using System.Linq;
// using System.Collections.Generic;
// using System.IO;
//
// using CPU = Cosmos.Assembler.x86;
// using System.Reflection;
using Cosmos.Assembler;
using Cosmos.IL2CPU.ILOpCodes;
using CPUx86 = Cosmos.Assembler.x86;

namespace Cosmos.IL2CPU.X86.IL
{
    /// <summary>
    /// Finds the value of a field in the object whose reference is currently on the evaluation stack.
    /// </summary>
    /// <remarks>
    /// MSDN:
    /// The stack transitional behavior, in sequential order, is:
    /// 1. An object reference (or pointer) is pushed onto the stack.
    /// 2. The object reference (or pointer) is popped from the stack; the value of the specified field in the object is found.
    /// 3. The value stored in the field is pushed onto the stack.
    /// The ldfld instruction pushes the value of a field located in an object onto the stack.
    /// The object must be on the stack as an object reference (type O), a managed pointer (type &),
    /// an unmanaged pointer (type native int), a transient pointer (type *), or an instance of a value type.
    /// The use of an unmanaged pointer is not permitted in verifiable code.
    /// The object's field is specified by a metadata token that must refer to a field member.
    /// The return type is the same as the one associated with the field. The field may be either an instance field
    /// (in which case the object must not be a null reference) or a static field.
    ///
    /// The ldfld instruction can be preceded by either or both of the Unaligned and Volatile prefixes.
    ///
    /// NullReferenceException is thrown if the object is null and the field is not static.
    ///
    /// MissingFieldException is thrown if the specified field is not found in the metadata.
    ///
    /// This is typically checked when Microsoft Intermediate Language (MSIL) instructions are converted to native code, not at run time.
    /// </remarks>
    [Cosmos.IL2CPU.OpCode( ILOpCode.Code.Ldfld )]
    public class Ldfld : ILOp
    {
        public Ldfld( Cosmos.Assembler.Assembler aAsmblr )
            : base( aAsmblr )
        {
        }

        public override void Execute( MethodInfo aMethod, ILOpCode aOpCode )
        {
          var xOpCode = (ILOpCodes.OpField)aOpCode;
          DoExecute(Assembler, xOpCode.Value.DeclaringType, xOpCode.Value.GetFullName(), true, DebugEnabled);
        }

        public static int GetFieldOffset(Type aDeclaringType, string aFieldId) {
          int xExtraOffset = 0;
          var xFieldInfo = ResolveField(aDeclaringType, aFieldId, true);
          bool xNeedsGC = aDeclaringType.IsClass && !aDeclaringType.IsValueType;
          if (xNeedsGC) {
            xExtraOffset = 12;
          }
          return (int)(xExtraOffset + xFieldInfo.Offset);
        }

        public static void DoExecute(Cosmos.Assembler.Assembler Assembler, Type aDeclaringType, string xFieldId, bool aDerefExternalField, bool debugEnabled) {
          var xOffset = GetFieldOffset(aDeclaringType, xFieldId);
          var xFields = GetFieldsInfo(aDeclaringType, false);
          var xFieldInfo = (from item in xFields
                            where item.Id == xFieldId
                            select item).Single();
          new Comment("Field = '" + xFieldId + "'");

            DoNullReferenceCheck(Assembler, debugEnabled, 0);

          new CPUx86.Pop { DestinationReg = CPUx86.Registers.ECX };

#if DOTNETCOMPATIBLE
			// pushed size is always 4 or 8
			var xSize = ILOp.Align(xFieldInfo.Size, 4);
#else
			var xSize = xFieldInfo.Size;
#endif

          new CPUx86.Add { DestinationReg = CPUx86.Registers.ECX, SourceValue = (uint)(xOffset) };

          if( xFieldInfo.IsExternalValue && aDerefExternalField)
          {
              new CPUx86.Mov { DestinationReg = CPUx86.Registers.ECX, SourceReg = CPUx86.Registers.ECX, SourceIsIndirect = true };
          }

          for (int i = 1; i <= (xSize / 4); i++) {
            new CPUx86.Mov { DestinationReg = CPUx86.Registers.EAX, SourceReg = CPUx86.Registers.ECX, SourceIsIndirect = true, SourceDisplacement = (int)(xSize - (i * 4)) };
            new CPUx86.Push { DestinationReg = CPUx86.Registers.EAX };
          }
          switch (xSize % 4) {
            case 1: {
                new CPUx86.Mov { DestinationReg = CPUx86.Registers.EAX, SourceValue = 0 };
                new CPUx86.Mov { DestinationReg = CPUx86.Registers.AL, SourceReg = CPUx86.Registers.ECX, SourceIsIndirect = true };
                new CPUx86.Push { DestinationReg = CPUx86.Registers.EAX };
                break;
              }
            case 2: {
                new CPUx86.Mov { DestinationReg = CPUx86.Registers.EAX, SourceValue = 0 };
                new CPUx86.Mov { DestinationReg = CPUx86.Registers.AX, SourceReg = CPUx86.Registers.ECX, SourceIsIndirect = true };
                new CPUx86.Push { DestinationReg = CPUx86.Registers.EAX };
                break;
              }

            case 3: //For Release
                    {
                new CPUx86.Mov { DestinationReg = CPUx86.Registers.EAX, SourceValue = 0 };
                new CPUx86.Mov { DestinationReg = CPUx86.Registers.EAX, SourceReg = CPUx86.Registers.ECX, SourceIsIndirect = true };
                new CPUx86.ShiftRight { DestinationReg = CPUx86.Registers.EAX, SourceValue = 8 };
                new CPUx86.Push { DestinationReg = CPUx86.Registers.EAX };
                break;
              }
            case 0: {
                      break;
                    }
            default:
              throw new Exception(string.Format("Remainder size {0:D} {1:D} not supported!", xFieldInfo.FieldType.ToString(), xSize));
          }
        }
    }
}