Exemplo n.º 1
0
    public static void Main(string[] args)
    {
        Console.WriteLine("Started");
        //Validate Args were provided
        if (args.Length != 1)
        {
            Console.WriteLine("missing args");
            System.Environment.Exit(1);
        }

        //open data file
        InFile puzzleData = new InFile(args[0]);

        Console.WriteLine("File read.");
        //exit program if data file unreadable
        if (puzzleData.OpenError())
        {
            Console.WriteLine("Failed to open " + args[0]);
            System.Environment.Exit(1);
        }

        //process data file
        string[] data = new string[9];
        for (int i = 0; i < data.Length; i++)
        {
            data[i] = puzzleData.ReadLine();
        }

        for (int i = 0; i < data.Length; i++)
        {
            Console.WriteLine(data[i]);
        }
    }
Exemplo n.º 2
0
        static void readBoard(string[,] board, int[, ][,] suggestedBoard, InFile data, bool solution)
        {
            int row = 0, col = 0;

            while (row != 9 && !data.NoMoreData())
            {
                int num = data.ReadInt();

                if (num == 0)
                {
                    board[row, col] = "..";
                    if (!solution)
                    {
                        suggestedBoard[row, col] = new int[3, 3] {
                            { 1, 2, 3 }, { 4, 5, 6 }, { 7, 8, 9 }
                        };
                    }
                }
                else
                {
                    board[row, col] = " " + num;
                    if (!solution)
                    {
                        suggestedBoard[row, col] = null;
                        known++;
                    }
                }
                col++;
                if (col == 9)
                {
                    row++;
                    col = 0;
                }
            }

            /*if the board just filled was not the solution then
             * skip next three lines to get to the next board (which is the solution board)*/
            if (!solution)
            {
                data.ReadLine();
                data.ReadLine();
                data.ReadLine();
            }
        }
Exemplo n.º 3
0
        private void Form1_Load(object sender, EventArgs e)
        {
            //Code which Changes the visibility of Form.
            ProductPanel.Visible      = true;
            ButtonPanelOne.Visible    = false;
            ExitButtonTwo.Visible     = true;
            DataGridViewPanel.Visible = false;
            //The Opening stock is loaded from the file and stored in stock array.
            StreamReader InFile;

            InFile = File.OpenText("StockFile.txt");
            for (int i = 0; i < 14; i++)
            {
                for (int j = 0; j < 5; j++)
                {
                    StockArray[i, j] = int.Parse(InFile.ReadLine());
                }
            }
            InFile.Close();
            //code in which loaded Stock is copied to Temporary Array for daily operation.
            Array.Copy(StockArray, TempStockArray, StockArray.Length);
        }
Exemplo n.º 4
0
        } // PVM.InBounds

        public static void Emulator(int initPC, int codeLen, int initSP,
                                    InFile data, OutFile results, bool tracing,
                                    bool traceStack, bool traceHeap)
        {
            // Emulates action of the codeLen instructions stored in mem[0 .. codeLen-1], with
            // program counter initialized to initPC, stack pointer initialized to initSP.
            // data and results are used for I/O.  Tracing at the code level may be requested

            int pcNow;            // current program counter
            int loop;             // internal loops
            int tos, sos;         // values popped from stack
            int adr;              // effective address for memory accesses
            int target;           // destination for branches

            stackBase = initSP;
            heapBase  = codeLen;  // initialize boundaries
            cpu.hp    = heapBase; // initialize registers
            cpu.sp    = stackBase;
            cpu.gp    = stackBase;
            cpu.mp    = stackBase;
            cpu.fp    = stackBase;
            cpu.pc    = initPC;   // initialize program counter
            for (int i = heapBase; i < stackBase; i++)
            {
                mem[i] = 0;       // set entire memory to null or 0
            }
            ps = running;         // prepare to execute
            int ops = 0;

            timer.Start();
            do
            {
                ops++;
                pcNow = cpu.pc;   // retain for tracing/postmortem
                if (cpu.pc < 0 || cpu.pc >= codeLen)
                {
                    ps = badAdr;
                    break;
                }
                cpu.ir = Next();  // fetch
                if (tracing)
                {
                    Trace(results, pcNow, traceStack, traceHeap);
                }
                switch (cpu.ir)   // execute
                {
                case PVM.nop:     // no operation
                    break;

                case PVM.dsp:     // decrement stack pointer (allocate space for variables)
                    int localSpace = Next();
                    cpu.sp -= localSpace;
                    if (InBounds(cpu.sp)) // initialize all local variables to zero/null
                    {
                        for (loop = 0; loop < localSpace; loop++)
                        {
                            mem[cpu.sp + loop] = 0;
                        }
                    }
                    break;

                case PVM.ldc:     // push constant value
                    Push(Next());
                    break;

                case PVM.ldc_m1:  // push constant -1
                    Push(-1);
                    break;

                case PVM.ldc_0:   // push constant 0
                    Push(0);
                    break;

                case PVM.ldc_1:   // push constant 1
                    Push(1);
                    break;

                case PVM.ldc_2:   // push constant 2
                    Push(2);
                    break;

                case PVM.ldc_3:   // push constant 3
                    Push(3);
                    break;

                case PVM.ldc_4:   // push constant 4
                    Push(4);
                    break;

                case PVM.ldc_5:   // push constant 5
                    Push(5);
                    break;

                case PVM.dup:     // duplicate top of stack
                    tos = Pop();
                    Push(tos); Push(tos);
                    break;

                case PVM.rdup:    // Remove top of stack
                    tos = Pop();
                    break;

                case PVM.lda:     // push local address
                    adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_0:   // push local address 0
                    adr = cpu.fp - 1;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_1:   // push local address 1
                    adr = cpu.fp - 2;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_2:   // push local address 2
                    adr = cpu.fp - 3;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_3:   // push local address 3
                    adr = cpu.fp - 4;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_4:   // push local address 4
                    adr = cpu.fp - 5;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_5:   // push local address 5
                    adr = cpu.fp - 6;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldl:     // push local value
                    adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_0:   // push value of local variable 0
                    adr = cpu.fp - 1;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_1:   // push value of local variable 1
                    adr = cpu.fp - 2;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_2:   // push value of local variable 2
                    adr = cpu.fp - 3;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_3:   // push value of local variable 3
                    adr = cpu.fp - 4;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_4:   // push value of local variable 4
                    adr = cpu.fp - 5;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_5:   // push value of local variable 5
                    adr = cpu.fp - 6;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.stl:     // store local value
                    adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stlc:    // character checked pop to local variable
                    tos = Pop(); adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        if (tos >= 0 && tos <= maxChar)
                        {
                            mem[adr] = tos;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case PVM.stl_0:   // pop to local variable 0
                    adr = cpu.fp - 1;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_1:   // pop to local variable 1
                    adr = cpu.fp - 2;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_2:   // pop to local variable 2
                    adr = cpu.fp - 3;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_3:   // pop to local variable 3
                    adr = cpu.fp - 4;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_4:   // pop to local variable 4
                    adr = cpu.fp - 5;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_5:   // pop to local variable 5
                    adr = cpu.fp - 6;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.ldv:     // dereference
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.sto:     // store
                    tos = Pop(); adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = tos;
                    }
                    break;

                case PVM.stoc:    // character checked store
                    tos = Pop(); adr = Pop();
                    if (InBounds(adr))
                    {
                        if (tos >= 0 && tos <= maxChar)
                        {
                            mem[adr] = tos;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case PVM.ldxa:    // heap array indexing
                    adr = Pop();
                    int heapPtr = Pop();
                    if (heapPtr == 0)
                    {
                        ps = nullRef;
                    }
                    else if (heapPtr < heapBase || heapPtr >= cpu.hp)
                    {
                        ps = badMem;
                    }
                    else if (adr < 0 || adr >= mem[heapPtr])
                    {
                        ps = badInd;
                    }
                    else
                    {
                        Push(heapPtr + adr + 1);
                    }
                    break;

                case PVM.inpi:    // integer input
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = data.ReadInt();
                        if (data.Error())
                        {
                            ps = badData;
                        }
                    }
                    break;

                case PVM.inpb:    // boolean input
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = data.ReadBool() ? 1 : 0;
                        if (data.Error())
                        {
                            ps = badData;
                        }
                    }
                    break;

                case PVM.inpc:    // character input
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = data.ReadChar();
                        if (data.Error())
                        {
                            ps = badData;
                        }
                    }
                    break;

                case PVM.inpl:    // skip to end of input line
                    data.ReadLine();
                    break;

                case PVM.i2c:     // check (char) cast is in range
                    if (mem[cpu.sp] < 0 || mem[cpu.sp] > maxChar)
                    {
                        ps = badVal;
                    }
                    break;

                case PVM.prni:    // integer output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    results.Write(Pop(), 0);
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prnb:    // boolean output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    if (Pop() != 0)
                    {
                        results.Write(" true  ");
                    }
                    else
                    {
                        results.Write(" false ");
                    }
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prnc:    // character output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    results.Write((char)(Math.Abs(Pop()) % (maxChar + 1)), 1);
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prns:    // string output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    loop = Next();
                    while (ps == running && mem[loop] != 0)
                    {
                        results.Write((char)mem[loop]); loop--;
                        if (loop < stackBase)
                        {
                            ps = badMem;
                        }
                    }
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.fprns:    // string output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    loop = Next();
                    StringBuilder str = new StringBuilder();
                    while (ps == running && mem[loop] != 0)
                    {
                        //results.Write((char) mem[loop]); loop--;
                        str.Append((char)mem[loop]); loop--;
                        if (loop < stackBase)
                        {
                            ps = badMem;
                        }
                    }
                    results.Write(str.ToString(), Pop());
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prnl:    // newline
                    results.WriteLine();
                    break;

                case PVM.fprint:
                    tos = Pop();
                    sos = Pop();
                    results.Write(sos, tos);
                    break;

                case PVM.neg:     // integer negation
                    Push(-Pop());
                    break;

                case PVM.add:     // integer addition
                    tos = Pop(); Push(Pop() + tos);
                    break;

                case PVM.sub:     // integer subtraction
                    tos = Pop(); Push(Pop() - tos);
                    break;

                case PVM.mul:     // integer multiplication
                    tos = Pop();
                    sos = Pop();
                    if (tos != 0 && Math.Abs(sos) > maxInt / Math.Abs(tos))
                    {
                        ps = badVal;
                    }
                    else
                    {
                        Push(sos * tos);
                    }
                    break;

                case PVM.div:     // integer division (quotient)
                    tos = Pop();
                    if (tos == 0)
                    {
                        ps = divZero;
                    }
                    else
                    {
                        Push(Pop() / tos);
                    }
                    break;

                case PVM.max:     // Finds max. First Pops elements off stack
                                  // to see how many elements.
                    int numElements = Pop();
                    if (numElements == 0)
                    {
                        ps = noData;
                    }
                    else
                    {
                        List <int> maxElements = new List <int> ();
                        for (int i = 0; i < numElements; i++)
                        {
                            maxElements.Add(Pop());
                        }
                        maxElements.Sort();
                        maxElements.Reverse();
                        Push(maxElements[0]);
                    }
                    break;

                case PVM.min:     // Finds min. First Pops elements off stack
                                  // to see how many elements
                    int numMin = Pop();
                    if (numMin == 0)
                    {
                        ps = noData;
                    }
                    else
                    {
                        List <int> minElements = new List <int> ();
                        for (int i = 0; i < numMin; i++)
                        {
                            minElements.Add(Pop());
                        }
                        minElements.Sort();
                        Push(minElements[0]);
                    }
                    break;

                case PVM.sqrt:     // Square root
                    tos = Pop();
                    Push(Convert.ToInt32(System.Math.Sqrt(tos)));
                    break;

                case PVM.rem:     // integer division (remainder)
                    tos = Pop();
                    if (tos == 0)
                    {
                        ps = divZero;
                    }
                    else
                    {
                        Push(Pop() % tos);
                    }
                    break;

                case PVM.not:     // logical negation
                    Push(Pop() == 0 ? 1 : 0);
                    break;

                case PVM.and:     // logical and
                    tos = Pop(); Push(Pop() & tos);
                    break;

                case PVM.or:      // logical or
                    tos = Pop(); Push(Pop() | tos);
                    break;

                case PVM.ceq:     // logical equality
                    tos = Pop(); Push(Pop() == tos ? 1 : 0);
                    break;

                case PVM.cne:     // logical inequality
                    tos = Pop(); Push(Pop() != tos ? 1 : 0);
                    break;

                case PVM.clt:     // logical less
                    tos = Pop(); Push(Pop() < tos ? 1 : 0);
                    break;

                case PVM.cle:     // logical less or equal
                    tos = Pop(); Push(Pop() <= tos ? 1 : 0);
                    break;

                case PVM.cgt:     // logical greater
                    tos = Pop(); Push(Pop() > tos ? 1 : 0);
                    break;

                case PVM.cge:     // logical greater or equal
                    tos = Pop(); Push(Pop() >= tos ? 1 : 0);
                    break;

                case PVM.brn:     // unconditional branch
                    cpu.pc = Next();
                    if (cpu.pc < 0 || cpu.pc >= codeLen)
                    {
                        ps = badAdr;
                    }
                    break;

                case PVM.bze:     // pop top of stack, branch if false
                    target = Next();
                    if (Pop() == 0)
                    {
                        cpu.pc = target;
                        if (cpu.pc < 0 || cpu.pc >= codeLen)
                        {
                            ps = badAdr;
                        }
                    }
                    break;

                case PVM.bfalse:  // conditional short circuit "and" branch
                    target = Next();
                    if (mem[cpu.sp] == 0)
                    {
                        cpu.pc = target;
                    }
                    else
                    {
                        cpu.sp++;
                    }
                    break;

                case PVM.btrue:   // conditional short circuit "or" branch
                    target = Next();
                    if (mem[cpu.sp] == 1)
                    {
                        cpu.pc = target;
                    }
                    else
                    {
                        cpu.sp++;
                    }
                    break;

                case PVM.anew:    // heap array allocation
                    int size = Pop();
                    if (size <= 0 || size + 1 > cpu.sp - cpu.hp - 2)
                    {
                        ps = badAll;
                    }
                    else
                    {
                        mem[cpu.hp] = size; // first element stores size for bounds checking
                        Push(cpu.hp);
                        cpu.hp += size + 1; // bump heap pointer
                                            // elements are already initialized to 0 / null (why?)
                    }
                    break;

                case PVM.halt:    // halt
                    ps = finished;
                    break;

                case PVM.inc:     // integer ++
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr]++;
                    }
                    break;

                case PVM.dec:     // integer --
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr]--;
                    }
                    break;

                case PVM.incc:    // ++ characters
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        if (mem[adr] < maxChar)
                        {
                            mem[adr]++;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case PVM.decc:    // -- characters
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        if (mem[adr] > 0)
                        {
                            mem[adr]--;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case cpy:

                    int addrC1       = Pop();
                    int addrC2       = Pop();
                    int addrLengthC1 = mem[mem[addrC1]];
                    int addrLengthC2 = mem[mem[addrC2]];
                    if (addrLengthC1 != addrLengthC2)
                    {
                        ps = badVal;
                    }
                    else
                    {
                        int i = 1;
                        while ((i <= addrLengthC1))
                        {
                            mem[mem[addrC2] + i] = mem[mem[addrC1] + i];
                            i++;
                        }
                    }
                    break;

                case eql:
                    int addr1       = Pop();
                    int addr2       = Pop();
                    int addrLength1 = mem[mem[addr1]];
                    int addrLength2 = mem[mem[addr2]];
                    if (addrLength1 != addrLength2)
                    {
                        Push(0); // push flase if lenghts arnt ==
                    }
                    else
                    {
                        bool isEqual = true;
                        int  i       = 1;
                        while (i < addrLength1 + 1)
                        {
                            if (mem[mem[addr1] + i] != mem[mem[addr2] + i])
                            {
                                isEqual = false;
                            }
                            i++;
                        }
                        if (isEqual)
                        {
                            Push(1);
                        }
                        else
                        {
                            Push(0);
                        }
                    }
                    break;

                case PVM.stack:   // stack dump (debugging)
                    StackDump(results, pcNow);
                    break;

                case PVM.heap:    // heap dump (debugging)
                    HeapDump(results, pcNow);
                    break;

                case PVM.fhdr:    // allocate frame header
                    if (InBounds(cpu.sp - headerSize))
                    {
                        mem[cpu.sp - headerSize] = cpu.mp;
                        cpu.mp  = cpu.sp;
                        cpu.sp -= headerSize;
                    }
                    break;

                case PVM.call:    // call function
                    if (mem[cpu.pc] < 0)
                    {
                        ps = badAdr;
                    }
                    else
                    {
                        mem[cpu.mp - 2] = cpu.fp;
                        mem[cpu.mp - 3] = cpu.pc + 1;
                        cpu.fp          = cpu.mp;
                        cpu.pc          = mem[cpu.pc];
                    }
                    break;

                case PVM.retv:    // return from void function
                    cpu.sp = cpu.fp;
                    cpu.mp = mem[cpu.fp - 4];
                    cpu.pc = mem[cpu.fp - 3];
                    cpu.fp = mem[cpu.fp - 2];
                    break;

                default:          // unrecognized opcode
                    ps = badOp;
                    break;
                } // switch(cpu.ir)
            } while (ps == running);
            if (ps != finished)
            {
                PostMortem(results, pcNow);
            }
            TimeSpan ts          = timer.Elapsed;
            string   elapsedTime = String.Format("{0:00}:{1:00}:{2:00}.{3:00}",
                                                 ts.Hours, ts.Minutes, ts.Seconds, ts.Milliseconds / 10);

            Console.WriteLine("\n" + ops + " operations.  Run Time " + elapsedTime);
            timer.Reset();
            timer.Stop();
        } // PVM.Emulator
Exemplo n.º 5
0
        } // PVM.PostMortem

        // The interpreters and utility methods

        public static void Emulator(int initPC, int codeLen, int initSP,
                                    InFile data, OutFile results, bool tracing,
                                    bool traceStack, bool traceHeap)
        {
            // Emulates action of the codeLen instructions stored in mem[0 .. codeLen-1], with
            // program counter initialized to initPC, stack pointer initialized to initSP.
            // data and results are used for I/O.  Tracing at the code level may be requested

            int pcNow;                  // current program counter
            int loop;                   // internal loops
            int tos, sos;               // value popped from stack
            int adr;
            stackBase = initSP;
            heapBase = codeLen;         // initialize boundaries
            cpu.hp = heapBase;          // initialize registers
            cpu.sp = stackBase;
            cpu.gp = stackBase;
            cpu.mp = stackBase;
            cpu.fp = stackBase;
            cpu.pc = initPC;            // initialize program counter
            ps = running;               // prepare to execute
            int ops = 0;
            timer.Start();
            do
            {
                ops++;
                pcNow = cpu.pc;           // retain for tracing/postmortem
                cpu.ir = mem[cpu.pc++];          // fetch
                                                 //        if (tracing) Trace(results, pcNow, traceStack, traceHeap);
                switch (cpu.ir)
                {         // execute
                    case PVM.nop:           // no operation
                        break;

                    case PVM.dsp:           // decrement stack pointer (allocate space for variables)
                        cpu.sp -= mem[cpu.pc++];
                        break;

                    case PVM.ldc:           // push constant value
                        mem[--cpu.sp] = mem[cpu.pc++];
                        break;

                    case PVM.lda:           // push local address
                        mem[--cpu.sp] = cpu.fp - 1 - mem[cpu.pc++];
                        break;

                    case PVM.ldv:           // dereference
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        break;

                    case PVM.sto:           // store
                        tos = mem[cpu.sp++]; mem[mem[cpu.sp++]] = tos;
                        break;

                    case PVM.ldxa:          // heap array indexing
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] + tos;
                        break;

                    case PVM.inpi:          // integer input
                        mem[mem[cpu.sp++]] = data.ReadInt();
                        break;

                    case PVM.prni:          // integer output
                                            //            if (tracing) results.Write(padding);
                        results.Write(mem[cpu.sp++], 0);
                        //            if (tracing) results.WriteLine();
                        break;

                    case PVM.inpb:          // boolean input
                        mem[mem[cpu.sp++]] = data.ReadBool() ? 1 : 0;
                        break;

                    case PVM.prnb:          // boolean output
                                            //            if (tracing) results.Write(padding);
                        if (mem[cpu.sp++] != 0) results.Write(" true  "); else results.Write(" false ");
                        //            if (tracing) results.WriteLine();
                        break;

                    case PVM.prns:          // string output
                                            //            if (tracing) results.Write(padding);
                        loop = mem[cpu.pc++];
                        while (mem[loop] != 0)
                        {
                            results.Write((char)mem[loop]); loop--;
                        }
                        //            if (tracing) results.WriteLine();
                        break;

                    case PVM.prnl:          // newline
                        results.WriteLine();
                        break;

                    case PVM.neg:           // integer negation
                        mem[cpu.sp] = -mem[cpu.sp];
                        break;

                    case PVM.add:           // integer addition
                        tos = mem[cpu.sp++]; mem[cpu.sp] += tos;
                        break;

                    case PVM.sub:           // integer subtraction
                        tos = mem[cpu.sp++]; mem[cpu.sp] -= tos;
                        break;

                    case PVM.mul:           // integer multiplication
                        tos = mem[cpu.sp++];
                        int temp = mem[cpu.sp];
                        int answer = temp * tos;
                        if (((tos > 0 && temp > 0) && answer < 0) || ((tos < 0 && temp < 0) && answer > 0) || ((tos > 0 || temp > 0) && answer < 0) || ((tos < 0 || temp < 0) && answer > 0) || answer > maxInt || answer < -maxInt)
                        {
                            PostMortem(results, pcNow);
                            break;
                        }
                        mem[cpu.sp] *= tos;
                        break;

                    case PVM.div:           // integer division (quotient)
                        tos = mem[cpu.sp++];
                        if (tos == 0)
                        {
                            PostMortem(results, pcNow);
                            break;
                        }
                        mem[cpu.sp] /= tos;
                        break;

                    case PVM.rem:           // integer division (remainder)
                        tos = mem[cpu.sp++]; mem[cpu.sp] %= tos;
                        break;

                    case PVM.not:           // logical negation
                        mem[cpu.sp] = mem[cpu.sp] == 0 ? 1 : 0;
                        break;

                    case PVM.and:           // logical and
                        tos = mem[cpu.sp++]; mem[cpu.sp] &= tos;
                        break;

                    case PVM.or:            // logical or
                        tos = mem[cpu.sp++]; mem[cpu.sp] |= tos;
                        break;

                    case PVM.ceq:           // logical equality
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] == tos ? 1 : 0;
                        break;

                    case PVM.cne:           // logical inequality
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] != tos ? 1 : 0;
                        break;

                    case PVM.clt:           // logical less
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] < tos ? 1 : 0;
                        break;

                    case PVM.cle:           // logical less or equal
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] <= tos ? 1 : 0;
                        break;

                    case PVM.cgt:           // logical greater
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] > tos ? 1 : 0;
                        break;

                    case PVM.cge:           // logical greater or equal
                        tos = mem[cpu.sp++]; mem[cpu.sp] = mem[cpu.sp] >= tos ? 1 : 0;
                        break;

                    case PVM.brn:           // unconditional branch
                        cpu.pc = mem[cpu.pc++];
                        break;
                    case PVM.bze:           // pop top of stack, branch if false
                        int target = mem[cpu.pc++];
                        if (mem[cpu.sp++] == 0) cpu.pc = target;
                        break;
                    case PVM.anew:          // heap array allocation
                        int size = mem[cpu.sp];
                        mem[cpu.sp] = cpu.hp;
                        cpu.hp += size;
                        break;
                    case PVM.halt:          // halt
                        ps = finished;
                        break;
                    case PVM.stk:           // stack dump (debugging)
                        StackDump(results, pcNow);
                        break;
                    case PVM.heap:           // heap dump (debugging)
                        HeapDump(results, pcNow);
                        break;
                    case PVM.ldc_0:         // push constant 0
                        mem[--cpu.sp] = 0;
                        break;
                    case PVM.ldc_1:         // push constant 1
                        mem[--cpu.sp] = 1;
                        break;
                    case PVM.ldc_2:         // push constant 2
                        mem[--cpu.sp] = 2;
                        break;
                    case PVM.ldc_3:         // push constant 3
                        mem[--cpu.sp] = 3;
                        break;
                    case PVM.lda_0:         // push local address 0
                     mem[--cpu.sp] = cpu.fp - mem[cpu.pc++];
                     break;
                    case PVM.lda_1:         // push local address 1
                        mem[--cpu.sp] = cpu.fp -1 -mem[cpu.pc++];
                        break;
                    case PVM.lda_2:         // push local address 2
                        mem[--cpu.sp] = cpu.fp -2- mem[cpu.pc++];
                        break;
                    case PVM.lda_3:         // push local address 3
                        mem[--cpu.sp] = cpu.fp -3- mem[cpu.pc++];
                        break;
                    case PVM.ldl_0:         // push value of local variable 0
                        mem[--cpu.sp] = cpu.fp - mem[cpu.pc++];
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        break;
                    case PVM.ldl_1:         // push value of local variable 1
                        mem[--cpu.sp] = cpu.fp -1- mem[cpu.pc++];
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        break;
                    case PVM.ldl_2:         // push value of local variable 2
                        mem[--cpu.sp] = cpu.fp -2- mem[cpu.pc++];
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        break;
                    case PVM.ldl_3:         // push value of local variable 3
                        mem[--cpu.sp] = cpu.fp -3- mem[cpu.pc++];
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        break;
                    case PVM.stl:           // store local value
                        // we have bug here with PushPop, test here shows:
                        adr = cpu.fp - 1 - mem[cpu.pc++];
                        mem[cpu.sp++] = mem[adr];
                        break;
                    case PVM.stl_0:         // pop to local variable 0
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        mem[--cpu.sp] = cpu.fp - mem[cpu.pc++];
                        break;
                    case PVM.stl_1:         // pop to local variable 1
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        mem[--cpu.sp] = cpu.fp -1- mem[cpu.pc++];
                        break;
                    case PVM.stl_2:         // pop to local variable 2
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        mem[--cpu.sp] = cpu.fp -2- mem[cpu.pc++];
                        break;
                    case PVM.stl_3:         // pop to local variable 3
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        mem[--cpu.sp] = cpu.fp -3-mem[cpu.pc++];
                        break;
                    case PVM.inpc: // character input
                        var line = data.ReadLine();
                        char tempChar = string.IsNullOrEmpty(line) ? ' ' : line[0];
                        mem[cpu.sp++] = tempChar;
                        if (data.Error()) ps = badData;
                        break;
                    case PVM.prnc:          // character output
                        if (tracing) results.WriteLine(padding);
                        int readIn = mem[mem[cpu.sp++]];
                        results.WriteLine((char)readIn);
                        if (tracing) results.WriteLine();
                        break;

                    case PVM.cap:           // toUpperCase
                        int cUp = mem[cpu.sp++];
                        cUp = (int)char.ToUpper((char)cUp);
                        mem[cpu.sp++] = cUp;
                        break;
                    case PVM.low:           // toLowerCase
                        int cLow = mem[cpu.sp++];
                        cLow = (int)char.ToLower((char)cLow);
                        mem[cpu.sp++] = cLow;
                        break;

                    case PVM.islet:         // isLetter
                        int val = mem[mem[cpu.sp]];
                        results.WriteLine("Character readIn: " + ((char)val).ToString());
                        if (Char.IsLetter((char)val)) mem[cpu.sp] = 1; else mem[cpu.sp] = 0;
                        break;

                    case PVM.inc:           // ++
                        int inc_a = mem[cpu.sp++] + 1;
                        mem[cpu.sp++] = inc_a;
                        break;
                    case PVM.dec:           // --
                        int dec_a = mem[cpu.sp++] - 1;
                        mem[cpu.sp++] = dec_a;
                        break;

                    case PVM.ldl: // push local value
                        mem[--cpu.sp] = mem[cpu.pc++];
                        var N = mem[cpu.sp];
                        mem[--cpu.sp] = cpu.fp - 1 - N;
                        mem[cpu.sp] = mem[mem[cpu.sp]];
                        break;
                    case PVM.stlc:          // store local value
                        tos = mem[cpu.sp++]; mem[mem[cpu.sp++]] = tos;
                        break;
                    case PVM.stoc:          // character checked store
                    default:                // unrecognized opcode
                        ps = badOp;
                        break;
                }
            } while (ps == running);
            TimeSpan ts = timer.Elapsed;

            // Format and display the TimeSpan value.
            string elapsedTime = String.Format("{0:00}:{1:00}:{2:00}.{3:00}",
                                               ts.Hours, ts.Minutes, ts.Seconds, ts.Milliseconds / 10);
            Console.WriteLine("\n\n" + ops + " operations.  Run Time " + elapsedTime + "\n\n");
            if (ps != finished) PostMortem(results, pcNow);
            timer.Reset();
            timer.Stop();
        } // PVM.Emulator
Exemplo n.º 6
0
    } // PVM.InBounds

    public static void Emulator(int initPC, int codeLen, int initSP,
                                InFile data, OutFile results, bool tracing,
                                bool traceStack, bool traceHeap) {
    // Emulates action of the codeLen instructions stored in mem[0 .. codeLen-1], with
    // program counter initialized to initPC, stack pointer initialized to initSP.
    // data and results are used for I/O.  Tracing at the code level may be requested

      int pcNow;                  // current program counter
      int loop;                   // internal loops
      int tos, sos;               // values popped from stack
      int adr;                    // effective address for memory accesses
      int target;                 // destination for branches

      stackBase = initSP;
      heapBase = codeLen;         // initialize boundaries
      cpu.hp = heapBase;          // initialize registers
      cpu.sp = stackBase;
      cpu.gp = stackBase;
      cpu.mp = stackBase;
      cpu.fp = stackBase;
      cpu.pc = initPC;            // initialize program counter
      for (int i = heapBase; i < stackBase; i++)
        mem[i] = 0;               // set entire memory to null or 0

      ps = running;               // prepare to execute
      int ops = 0;
      timer.Start();
      do {
        ops++;
        pcNow = cpu.pc;           // retain for tracing/postmortem
        if (cpu.pc < 0 || cpu.pc >= codeLen) {
          ps = badAdr;
          break;
        }
        cpu.ir = Next();          // fetch
        if (tracing) Trace(results, pcNow, traceStack, traceHeap);
        switch (cpu.ir) {         // execute
          case PVM.nop:           // no operation
            break;
          case PVM.dsp:           // decrement stack pointer (allocate space for variables)
            int localSpace = Next();
            cpu.sp -= localSpace;
            if (InBounds(cpu.sp)) // initialize all local variables to zero/null
              for (loop = 0; loop < localSpace; loop++)
                mem[cpu.sp + loop] = 0;
            break;
          case PVM.ldc:           // push constant value
            Push(Next());
            break;
          case PVM.ldc_m1:        // push constant -1
            Push(-1);
            break;
          case PVM.ldc_0:         // push constant 0
            Push(0);
            break;
          case PVM.ldc_1:         // push constant 1
            Push(1);
            break;
          case PVM.ldc_2:         // push constant 2
            Push(2);
            break;
          case PVM.ldc_3:         // push constant 3
            Push(3);
            break;
          case PVM.ldc_4:         // push constant 4
            Push(4);
            break;
          case PVM.ldc_5:         // push constant 5
            Push(5);
            break;
          case PVM.dup:           // duplicate top of stack
            tos = Pop();
            Push(tos); Push(tos);
            break;
          case PVM.lda:           // push local address
            adr = cpu.fp - 1 - Next();
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.lda_0:         // push local address 0
            adr = cpu.fp - 1;
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.lda_1:         // push local address 1
            adr = cpu.fp - 2;
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.lda_2:         // push local address 2
            adr = cpu.fp - 3;
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.lda_3:         // push local address 3
            adr = cpu.fp - 4;
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.lda_4:         // push local address 4
            adr = cpu.fp - 5;
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.lda_5:         // push local address 5
            adr = cpu.fp - 6;
            if (InBounds(adr)) Push(adr);
            break;
          case PVM.ldl:           // push local value
            adr = cpu.fp - 1 - Next();
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.ldl_0:         // push value of local variable 0
            adr = cpu.fp - 1;
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.ldl_1:         // push value of local variable 1
            adr = cpu.fp - 2;
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.ldl_2:         // push value of local variable 2
            adr = cpu.fp - 3;
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.ldl_3:         // push value of local variable 3
            adr = cpu.fp - 4;
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.ldl_4:         // push value of local variable 4
            adr = cpu.fp - 5;
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.ldl_5:         // push value of local variable 5
            adr = cpu.fp - 6;
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.stl:           // store local value
            adr = cpu.fp - 1 - Next();
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.stlc:          // character checked pop to local variable
            tos = Pop(); adr = cpu.fp - 1 - Next();
            if (InBounds(adr))
              if (tos >= 0 && tos <= maxChar) mem[adr] = tos;
              else ps = badVal;
            break;
          case PVM.stl_0:         // pop to local variable 0
            adr = cpu.fp - 1;
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.stl_1:         // pop to local variable 1
            adr = cpu.fp - 2;
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.stl_2:         // pop to local variable 2
            adr = cpu.fp - 3;
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.stl_3:         // pop to local variable 3
            adr = cpu.fp - 4;
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.stl_4:         // pop to local variable 4
            adr = cpu.fp - 5;
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.stl_5:         // pop to local variable 5
            adr = cpu.fp - 6;
            if (InBounds(adr)) mem[adr] = Pop();
            break;
          case PVM.ldv:           // dereference
            adr = Pop();
            if (InBounds(adr)) Push(mem[adr]);
            break;
          case PVM.sto:           // store
            tos = Pop(); adr = Pop();
            if (InBounds(adr)) mem[adr] = tos;
            break;
          case PVM.stoc:          // character checked store
            tos = Pop(); adr = Pop();
            if (InBounds(adr))
              if (tos >= 0 && tos <= maxChar) mem[adr] = tos;
              else ps = badVal;
            break;
          case PVM.ldxa:          // heap array indexing
            adr = Pop();
            int heapPtr = Pop();
            if (heapPtr == 0) ps = nullRef;
            else if (heapPtr < heapBase || heapPtr >= cpu.hp) ps = badMem;
            else if (adr < 0 || adr >= mem[heapPtr]) ps = badInd;
            else Push(heapPtr + adr + 1); 
            break;
          case PVM.inpi:          // integer input
            adr = Pop();
            if (InBounds(adr)) {
              mem[adr] = data.ReadInt();
              if (data.Error()) ps = badData;
            }
            break;
          case PVM.inpb:          // boolean input
            adr = Pop();
            if (InBounds(adr)) {
              mem[adr] = data.ReadBool() ? 1 : 0;
              if (data.Error()) ps = badData;
            }
            break;
          case PVM.inpc:          // character input
            adr = Pop();
            if (InBounds(adr)) {
              mem[adr] = data.ReadChar();
              if (data.Error()) ps = badData;
            }
            break;
          case PVM.inpl:          // skip to end of input line
            data.ReadLine();
            break;
          case PVM.i2c:           // check (char) cast is in range
            if (mem[cpu.sp] < 0 || mem[cpu.sp] > maxChar) ps = badVal;
            break;
          case PVM.prni:          // integer output
            if (tracing) results.Write(padding);
            results.Write(Pop(), 0);
            if (tracing) results.WriteLine();
            break;
          case PVM.prnb:          // boolean output
            if (tracing) results.Write(padding);
            if (Pop() != 0) results.Write(" true  "); else results.Write(" false ");
            if (tracing) results.WriteLine();
            break;
          case PVM.prnc:          // character output
            if (tracing) results.Write(padding);
            results.Write((char) (Math.Abs(Pop()) % (maxChar + 1)), 1);
            if (tracing) results.WriteLine();
            break;
          case PVM.prns:          // string output
            if (tracing) results.Write(padding);
            loop = Next();
            while (ps == running && mem[loop] != 0) {
              results.Write((char) mem[loop]); loop--;
              if (loop < stackBase) ps = badMem;
            }
            if (tracing) results.WriteLine();
            break;
          case PVM.prnl:          // newline
            results.WriteLine();
            break;
          case PVM.neg:           // integer negation
            Push(-Pop());
            break;
          case PVM.add:           // integer addition
            tos = Pop(); Push(Pop() + tos);
            break;
          case PVM.sub:           // integer subtraction
            tos = Pop(); Push(Pop() - tos);
            break;
          case PVM.mul:           // integer multiplication
            tos = Pop();
            sos = Pop();
            if (tos != 0 && Math.Abs(sos) > maxInt / Math.Abs(tos)) ps = badVal;
            else Push(sos * tos);
            break;
          case PVM.div:           // integer division (quotient)
            tos = Pop();
            if (tos == 0) ps = divZero;
            else Push(Pop() / tos);
            break;
          case PVM.rem:           // integer division (remainder)
            tos = Pop();
            if (tos == 0) ps = divZero;
            else Push(Pop() % tos);
            break;
          case PVM.not:           // logical negation
            Push(Pop() == 0 ? 1 : 0);
            break;
          case PVM.and:           // logical and
            tos = Pop(); Push(Pop() & tos);
            break;
          case PVM.or:            // logical or
            tos = Pop(); Push(Pop() | tos);
            break;
          case PVM.ceq:           // logical equality
            tos = Pop(); Push(Pop() == tos ? 1 : 0);
            break;
          case PVM.cne:           // logical inequality
            tos = Pop(); Push(Pop() != tos ? 1 : 0);
            break;
          case PVM.clt:           // logical less
            tos = Pop(); Push(Pop() <  tos ? 1 : 0);
            break;
          case PVM.cle:           // logical less or equal
            tos = Pop(); Push(Pop() <= tos ? 1 : 0);
            break;
          case PVM.cgt:           // logical greater
            tos = Pop(); Push(Pop() >  tos ? 1 : 0);
            break;
          case PVM.cge:           // logical greater or equal
            tos = Pop(); Push(Pop() >= tos ? 1 : 0);
            break;
          case PVM.brn:           // unconditional branch
            cpu.pc = Next();
            if (cpu.pc < 0 || cpu.pc >= codeLen) ps = badAdr;
            break;
          case PVM.bze:           // pop top of stack, branch if false
            target = Next();
            if (Pop() == 0) {
              cpu.pc = target;
              if (cpu.pc < 0 || cpu.pc >= codeLen) ps = badAdr;
            }
            break;
          case PVM.bfalse:        // conditional short circuit "and" branch
            target = Next();
            if (mem[cpu.sp] == 0) cpu.pc = target; else cpu.sp++;
            break;
          case PVM.btrue:         // conditional short circuit "or" branch
            target = Next();
            if (mem[cpu.sp] == 1) cpu.pc = target; else cpu.sp++;
            break;
          case PVM.anew:          // heap array allocation
            int size = Pop();
            if (size <= 0 || size + 1 > cpu.sp - cpu.hp - 2)
              ps = badAll;
            else {
              mem[cpu.hp] = size; // first element stores size for bounds checking
              Push(cpu.hp);
              cpu.hp += size + 1; // bump heap pointer
                                  // elements are already initialized to 0 / null (why?)
            }
            break;
          case PVM.halt:          // halt
            ps = finished;
            break;
          case PVM.inc:           // integer ++
            adr = Pop();
            if (InBounds(adr)) mem[adr]++;
            break;
          case PVM.dec:           // integer --
            adr = Pop();
            if (InBounds(adr)) mem[adr]--;
            break;
          case PVM.incc:          // ++ characters
            adr = Pop();
            if (InBounds(adr))
              if (mem[adr] < maxChar) mem[adr]++;
              else ps = badVal;
            break;
          case PVM.decc:          // -- characters
            adr = Pop();
            if (InBounds(adr))
              if (mem[adr] > 0) mem[adr]--;
              else ps = badVal;
            break;
          case PVM.stack:         // stack dump (debugging)
            StackDump(results, pcNow);
            break;
          case PVM.heap:          // heap dump (debugging)
            HeapDump(results, pcNow);
            break;
          case PVM.fhdr:          // allocate frame header
            if (InBounds(cpu.sp - headerSize)) {
              mem[cpu.sp - headerSize] = cpu.mp;
              cpu.mp = cpu.sp;
              cpu.sp -= headerSize;
            }
            break;
          case PVM.call:          // call function
            if (mem[cpu.pc] < 0) ps = badAdr;
            else {
              mem[cpu.mp - 2] = cpu.fp;
              mem[cpu.mp - 3] = cpu.pc + 1;
              cpu.fp = cpu.mp;
              cpu.pc = mem[cpu.pc];
            }
            break;
          case PVM.retv:          // return from void function
            cpu.sp = cpu.fp;
            cpu.mp = mem[cpu.fp - 4];
            cpu.pc = mem[cpu.fp - 3];
            cpu.fp = mem[cpu.fp - 2];
            break;
		  case PVM.max:
			tos = Pop();
			sos = Pop();
			if (tos > sos) Push(tos);				
			else Push(sos);
		    break;
		  case PVM.min:
			tos = Pop();
			sos = Pop();
			if (tos < sos) Push(tos);				
			else Push(sos);
		    break;
		  case PVM.sqr:
			tos = Pop();
			Push((int)Math.Sqrt(tos));
		    break;
		  case PVM.aceq:
		    tos =Pop(); //address of array 1
			sos = Pop(); //address of array 1
			int len_1 = mem[tos];
			int len_2 = mem[sos];
			if(len_1!=len_2){ 
				Push(0); // if lengths aren't equal then arrays can't be equal
			}
			else{
				int i=0;
				while(i<len_1 && mem[tos+1+i] == mem[sos+1+i]){
					i++;
				}
				if(i==len_1) 
					Push(1);
				else
					Push(0);	  		
			}
			break;
			case PVM.acpy:
			    tos =Pop(); //address to be copied
			    sos = Pop(); //address of array to be assigned 
				if(mem[tos]==mem[sos]){ //if the lengths are not the same leave it
				  int i=0;
				  while(i<mem[tos]){
					  mem[sos+1+i] = mem[tos+1+i];
				  }
				
				}
				/*
				else{
					IO.WriteLine("Arrays must be the same size to be copied!");
				    ps=badVal;
				}
				*/
			break;
			case PVM.wprni:          // integer output with wdith
				if (tracing) results.Write(padding);
				tos=Pop();
				results.Write(Pop(),tos);
				if (tracing) results.WriteLine();
            break;
          case PVM.wprnb:          // boolean output with width
            if (tracing) results.Write(padding);
			tos = Pop();
            if (Pop() != 0) results.Write("true",tos); else results.Write("false",tos);
            if (tracing) results.WriteLine();
            break;
          case PVM.wprnc:          // character output with width
            if (tracing) results.Write(padding);
			tos = Pop();
            results.Write((char) (Math.Abs(Pop()) % (maxChar + 1)), tos);
            if (tracing) results.WriteLine();
			break;
          default:                // unrecognized opcode
            ps = badOp;
            break;
        } // switch(cpu.ir)
      } while (ps == running);
      if (ps != finished) PostMortem(results, pcNow);
      TimeSpan ts = timer.Elapsed;
      string elapsedTime = String.Format("{0:00}:{1:00}:{2:00}.{3:00}",
                                         ts.Hours, ts.Minutes, ts.Seconds, ts.Milliseconds / 10);
      Console.WriteLine("\n" + ops + " operations.  Run Time " + elapsedTime);
      timer.Reset();
      timer.Stop();
    } // PVM.Emulator
Exemplo n.º 7
0
        } // PVM.InBounds

        public static void Emulator(int initPC, int codeLen, int initSP,
                                    InFile data, OutFile results, bool tracing,
                                    bool traceStack, bool traceHeap)
        {
            // Emulates action of the codeLen instructions stored in mem[0 .. codeLen-1], with
            // program counter initialized to initPC, stack pointer initialized to initSP.
            // data and results are used for I/O.  Tracing at the code level may be requested

            int pcNow;            // current program counter
            int loop;             // internal loops
            int tos, sos;         // values popped from stack
            int adr;              // effective address for memory accesses
            int target;           // destination for
            int store  = 0;       // saves the next location of
            int store2 = 0;       // compares

            stackBase = initSP;
            heapBase  = codeLen;  // initialize boundaries
            cpu.hp    = heapBase; // initialize registers
            cpu.sp    = stackBase;
            cpu.gp    = stackBase;
            cpu.mp    = stackBase;
            cpu.fp    = stackBase;
            cpu.pc    = initPC;   // initialize program counter
            for (int i = heapBase; i < stackBase; i++)
            {
                mem[i] = 0;       // set entire memory to null or 0
            }
            ps = running;         // prepare to execute
            int ops = 0;

            timer.Start();
            do
            {
                ops++;
                pcNow = cpu.pc;   // retain for tracing/postmortem
                if (cpu.pc < 0 || cpu.pc >= codeLen)
                {
                    ps = badAdr;
                    break;
                }
                cpu.ir = Next();  // fetch
                if (tracing)
                {
                    Trace(results, pcNow, traceStack, traceHeap);
                }
                switch (cpu.ir)   // execute
                {
                case PVM.nop:     // no operation
                    break;

                case PVM.dsp:     // decrement stack pointer (allocate space for variables)
                    int localSpace = Next();
                    cpu.sp -= localSpace;
                    if (InBounds(cpu.sp)) // initialize all local variables to zero/null
                    {
                        for (loop = 0; loop < localSpace; loop++)
                        {
                            mem[cpu.sp + loop] = 0;
                        }
                    }
                    break;

                case PVM.ldc:     // push constant value
                    Push(Next());
                    break;

                case PVM.ldc_m1:  // push constant -1
                    Push(-1);
                    break;

                case PVM.ldc_0:   // push constant 0
                    Push(0);
                    break;

                case PVM.ldc_1:   // push constant 1
                    Push(1);
                    break;

                case PVM.ldc_2:   // push constant 2
                    Push(2);
                    break;

                case PVM.ldc_3:   // push constant 3
                    Push(3);
                    break;

                case PVM.ldc_4:   // push constant 4
                    Push(4);
                    break;

                case PVM.ldc_5:   // push constant 5
                    Push(5);
                    break;

                case PVM.lda:     // push local address
                    adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_0:   // push local address 0
                    adr = cpu.fp - 1;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_1:   // push local address 1
                    adr = cpu.fp - 2;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_2:   // push local address 2
                    adr = cpu.fp - 3;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_3:   // push local address 3
                    adr = cpu.fp - 4;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_4:   // push local address 4
                    adr = cpu.fp - 5;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.lda_5:   // push local address 5
                    adr = cpu.fp - 6;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldga:  // push global address
                    adr = cpu.gp - 1 - Next();
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldg_0:   // push local address 0
                    adr = cpu.gp - 1;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldg_1:   // push local address 1
                    adr = cpu.gp - 2;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldg_2:   // push local address 2
                    adr = cpu.gp - 3;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldg_3:   // push local address 3
                    adr = cpu.gp - 4;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldg_4:   // push local address 4
                    adr = cpu.gp - 5;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldg_5:   // push local address 5
                    adr = cpu.gp - 6;
                    if (InBounds(adr))
                    {
                        Push(adr);
                    }
                    break;

                case PVM.ldl:     // push local value
                    adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_0:   // push value of local variable 0
                    adr = cpu.fp - 1;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_1:   // push value of local variable 1
                    adr = cpu.fp - 2;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_2:   // push value of local variable 2
                    adr = cpu.fp - 3;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_3:   // push value of local variable 3
                    adr = cpu.fp - 4;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_4:   // push value of local variable 4
                    adr = cpu.fp - 5;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.ldl_5:   // push value of local variable 5
                    adr = cpu.fp - 6;
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.stl:     // store local value
                    adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stlc:    // character checked pop to local variable
                    tos = Pop(); adr = cpu.fp - 1 - Next();
                    if (InBounds(adr))
                    {
                        if (tos >= 0 && tos <= maxChar)
                        {
                            mem[adr] = tos;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case PVM.stl_0:   // pop to local variable 0
                    adr = cpu.fp - 1;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_1:   // pop to local variable 1
                    adr = cpu.fp - 2;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_2:   // pop to local variable 2
                    adr = cpu.fp - 3;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_3:   // pop to local variable 3
                    adr = cpu.fp - 4;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_4:   // pop to local variable 4
                    adr = cpu.fp - 5;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.stl_5:   // pop to local variable 5
                    adr = cpu.fp - 6;
                    if (InBounds(adr))
                    {
                        mem[adr] = Pop();
                    }
                    break;

                case PVM.ldv:     // dereference
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        Push(mem[adr]);
                    }
                    break;

                case PVM.sto:     // store
                    tos = Pop(); adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = tos;
                    }
                    break;

                case PVM.stoc:    // character checked store
                    tos = Pop(); adr = Pop();
                    if (InBounds(adr))
                    {
                        if (tos >= 0 && tos <= maxChar)
                        {
                            mem[adr] = tos;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case PVM.ldxa:    // heap array indexing
                    adr = Pop();
                    int heapPtr = Pop();
                    if (heapPtr == 0)
                    {
                        ps = nullRef;
                    }
                    else if (heapPtr < heapBase || heapPtr >= cpu.hp)
                    {
                        ps = badMem;
                    }
                    else if (adr < 0 || adr >= mem[heapPtr])
                    {
                        ps = badInd;
                    }
                    else
                    {
                        Push(heapPtr + adr + 1);
                    }
                    break;

                case PVM.inpi:    // integer input
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = data.ReadInt();
                        if (data.Error())
                        {
                            ps = badData;
                        }
                    }
                    break;

                case PVM.inpb:    // boolean input
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = data.ReadBool() ? 1 : 0;
                        if (data.Error())
                        {
                            ps = badData;
                        }
                    }
                    break;

                case PVM.inpc:    // character input
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr] = data.ReadChar();
                        if (data.Error())
                        {
                            ps = badData;
                        }
                    }
                    break;

                case PVM.inpl:    // skip to end of input line
                    data.ReadLine();
                    break;

                case PVM.i2c:     // check convert character to integer
                    if (mem[cpu.sp] < 0 || mem[cpu.sp] > maxChar)
                    {
                        ps = badVal;
                    }
                    else
                    {
                        Push((int)Pop());
                    }
                    break;

                case PVM.c2i:     // check convert integer to
                    adr = Pop();
                    if ((adr >= 65 && adr <= 90) || (adr >= 97 && adr <= 122))
                    {
                        Push((char)adr);
                    }
                    else
                    {
                        ps = badCast;
                    }
                    break;

                case PVM.prni:    // integer output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    results.Write(Pop(), 0);
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prnb:    // boolean output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    if (Pop() != 0)
                    {
                        results.Write(" true  ");
                    }
                    else
                    {
                        results.Write(" false ");
                    }
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prnc:    // character output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    results.Write((char)(Math.Abs(Pop()) % (maxChar + 1)), 1);
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prns:    // string output
                    if (tracing)
                    {
                        results.Write(padding);
                    }
                    loop = Next();
                    while (ps == running && mem[loop] != 0)
                    {
                        results.Write((char)mem[loop]); loop--;
                        if (loop < stackBase)
                        {
                            ps = badMem;
                        }
                    }
                    if (tracing)
                    {
                        results.WriteLine();
                    }
                    break;

                case PVM.prnl:    // newline
                    results.WriteLine();
                    break;

                case PVM.neg:     // integer negation
                    Push(-Pop());
                    break;

                case PVM.add:     // integer addition
                    tos = Pop(); Push(Pop() + tos);
                    break;

                case PVM.sub:     // integer subtraction
                    tos = Pop(); Push(Pop() - tos);
                    break;

                case PVM.mul:     // integer multiplication
                    tos = Pop();
                    sos = Pop();
                    if (tos != 0 && Math.Abs(sos) > maxInt / Math.Abs(tos))
                    {
                        ps = badVal;
                    }
                    else
                    {
                        Push(sos * tos);
                    }
                    break;

                case PVM.div:     // integer division (quotient)
                    tos = Pop();
                    if (tos == 0)
                    {
                        ps = divZero;
                    }
                    else
                    {
                        Push(Pop() / tos);
                    }
                    break;

                case PVM.rem:     // integer division (remainder)
                    tos = Pop();
                    if (tos == 0)
                    {
                        ps = divZero;
                    }
                    else
                    {
                        Push(Pop() % tos);
                    }
                    break;

                case PVM.not:     // logical negation
                    Push(Pop() == 0 ? 1 : 0);
                    break;

                case PVM.and:     // logical and
                    tos = Pop(); Push(Pop() & tos);
                    break;

                case PVM.or:      // logical or
                    tos = Pop(); Push(Pop() | tos);
                    break;

                case PVM.ceq:     // logical equality
                    tos = Pop(); Push(Pop() == tos ? 1 : 0);
                    break;

                case PVM.cne:     // logical inequality
                    tos = Pop(); Push(Pop() != tos ? 1 : 0);
                    break;

                case PVM.clt:     // logical less
                    tos = Pop(); Push(Pop() < tos ? 1 : 0);
                    break;

                case PVM.cle:     // logical less or equal
                    tos = Pop(); Push(Pop() <= tos ? 1 : 0);
                    break;

                case PVM.cgt:     // logical greater
                    tos = Pop(); Push(Pop() > tos ? 1 : 0);
                    break;

                case PVM.cge:     // logical greater or equal
                    tos = Pop(); Push(Pop() >= tos ? 1 : 0);
                    break;

                case PVM.brn:     // unconditional branch
                    store  = cpu.pc + 1;
                    store2 = Next();
                    cpu.pc = store2;
                    if (cpu.pc < 0 || cpu.pc >= codeLen)
                    {
                        ps = badAdr;
                    }
                    break;

                case PVM.bze:     // pop top of stack, branch if false
                    target = Next();
                    if (Pop() == 0)
                    {
                        cpu.pc = target;
                        if (cpu.pc < 0 || cpu.pc >= codeLen)
                        {
                            ps = badAdr;
                        }
                    }
                    break;

                case PVM.pjp:       // jumps to the location of given parameter
                    if (store == store2)
                    {
                        cpu.pc++;
                    }
                    else
                    {
                        cpu.pc = store;
                    }
                    if (cpu.pc < 0 || cpu.pc >= codeLen)
                    {
                        ps = badAdr;
                    }
                    break;

                case PVM.bfalse:  // conditional short circuit "and" branch
                    target = Next();
                    if (mem[cpu.sp] == 0)
                    {
                        cpu.pc = target;
                    }
                    else
                    {
                        cpu.sp++;
                    }
                    break;

                case PVM.btrue:   // conditional short circuit "or" branch
                    target = Next();
                    if (mem[cpu.sp] == 1)
                    {
                        cpu.pc = target;
                    }
                    else
                    {
                        cpu.sp++;
                    }
                    break;

                case PVM.anew:    // heap array allocation
                    int size = Pop();
                    if (size <= 0 || size + 1 > cpu.sp - cpu.hp - 2)
                    {
                        ps = badAll;
                    }
                    else
                    {
                        mem[cpu.hp] = size; // first element stores size for bounds checking
                        Push(cpu.hp);
                        cpu.hp += size + 1; // bump heap pointer
                                            // elements are already initialized to 0 / null (why?)
                    }
                    break;

                case PVM.halt:    // halt
                    ps = finished;
                    break;

                case PVM.inc:     // integer ++
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr]++;
                    }
                    break;

                case PVM.dec:     // integer --
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        mem[adr]--;
                    }
                    break;

                case PVM.incc:    // ++ characters
                    adr = Pop();
                    if (InBounds(adr))
                    {
                        if (mem[adr] < maxChar)
                        {
                            mem[adr]++;
                        }
                        else
                        {
                            ps = badVal;
                        }
                    }
                    break;

                case PVM.decc:    // -- characters
                    adr = Pop();
                    if (mem[adr] > 0)
                    {
                        mem[adr]--;
                    }
                    else
                    {
                        ps = badVal;
                    }
                    break;

                case PVM.stack:   // stack dump (debugging)
                    StackDump(results, pcNow);
                    break;

                case PVM.heap:    // heap dump (debugging)
                    HeapDump(results, pcNow);
                    break;

                case PVM.fhdr:    // allocate frame header
                    if (InBounds(cpu.sp - headerSize))
                    {
                        mem[cpu.sp - headerSize] = cpu.mp;
                        cpu.mp  = cpu.sp;
                        cpu.sp -= headerSize;
                    }
                    break;

                case PVM.call:    // call function
                    if (mem[cpu.pc] < 0)
                    {
                        ps = badAdr;
                    }
                    else
                    {
                        mem[cpu.mp - 2] = cpu.fp;
                        mem[cpu.mp - 3] = cpu.pc + 1;
                        cpu.fp          = cpu.mp;
                        cpu.pc          = mem[cpu.pc];
                    }
                    break;

                case PVM.retv:    // return from void function
                    cpu.sp = cpu.fp;
                    cpu.mp = mem[cpu.fp - 4];
                    cpu.pc = mem[cpu.fp - 3];
                    cpu.fp = mem[cpu.fp - 2];
                    break;

                case PVM.ret:     // return from non-void function
                    cpu.sp = cpu.fp - 1;
                    cpu.mp = mem[cpu.fp - 4];
                    cpu.pc = mem[cpu.fp - 3];
                    cpu.fp = mem[cpu.fp - 2];
                    break;

                case PVM.trap:    // trap falling off end of function
                    ps = badFun;
                    break;

                case PVM.low:     // toLowerCase
                    Push(Char.ToLower((char)Pop()));
                    break;

                case PVM.cap:     // toUpperCase
                    Push(Char.ToUpper((char)Pop()));
                    break;

                case PVM.islet:   // isLetter
                    tos = Pop();
                    Push(Char.IsLetter((char)tos) ? 1 : 0);
                    break;

                case PVM.pop:     // pop and discard tos
                    tos = Pop();
                    break;

                case PVM.dup:     // duplicate tos
                    tos = Pop();
                    Push(tos); Push(tos);
                    break;

                default:          // unrecognized opcode
                    ps = badOp;
                    break;
                }
            } while (ps == running);
            TimeSpan ts = timer.Elapsed;
            // Format and display the TimeSpan value.
            string elapsedTime = String.Format("{0:00}:{1:00}:{2:00}.{3:00}",
                                               ts.Hours, ts.Minutes, ts.Seconds, ts.Milliseconds / 10);

            Console.WriteLine("\n\n" + ops + " operations.  Run Time " + elapsedTime + "\n\n");
            if (ps != finished)
            {
                PostMortem(results, pcNow);
            }
            timer.Reset();
            timer.Stop();
        } // PVM.Emulator
Exemplo n.º 8
0
        /// <summary>
        /// Main program
        /// </summary>

        private static void Main(string[] args)
        {
            int[,] board = new int[9, 9];
            // Check if a file input is specified
            if (args.Length == 0)
            {
                //some input will be one of the solution files e.g s1
                IO.WriteLine("Nothing was specified for input, rather used \"SudokuPrac1Question12.exe <some input>\"");
                IO.ReadLine();
                return;
            }

            // Load the file
            InFile file = new InFile(args[0]);

            string[] file_lines      = new string[21];
            int      file_line_count = 0;

            while (!file.EOF())
            {
                file_lines[file_line_count] = file.ReadLine();
                file_line_count++;
            }

            // Interpret starting board: first 9 lines
            for (int i = 0; i < 9; i++)
            {
                var points = file_lines[i].Split(" ".ToCharArray(), System.StringSplitOptions.RemoveEmptyEntries);
                for (int j = 0; j < 9; j++)
                {
                    board[j, i] = int.Parse(points[j]);
                }
            }

            // Initiate the board
            CreatePositionPoints();
            CreatePlanningBoard(board);

            bool not_complete = true, endGame = false;
            int  pos_x = 0, pos_y = 0, pos_choice = 0, value_count = 1;

            int[,] ai_chosen_spots = new int[9, 9];
            //main game loop
            while (not_complete && !endGame)
            {
                Console.Clear();
                UpdateSuggestedMoves(board, ref planning_board);

                for (int x = 0; x < 9; x++)
                {
                    for (int y = 0; y < 9; y++)
                    {
                        ai_chosen_spots[x, y] = 0;
                    }
                }

                DrawPlanningBoard();
                int knownCount = 0;
                for (int x = 0; x < 9; x++)
                {
                    for (int y = 0; y < 9; y++)
                    {
                        if (board[x, y] != 0)
                        {
                            knownCount++;
                        }
                    }
                }
                AIGenerateChoices(ref ai_chosen_spots, board, StringPositions);

                //Predicate<int> pre = delegate (int a) { return a == 0; };
                int predictionCount = 0;
                for (int x = 0; x < 9; x++)
                {
                    for (int y = 0; y < 9; y++)
                    {
                        if (ai_chosen_spots[x, y] != 0)
                        {
                            predictionCount++;
                        }
                    }
                }

                if (predictionCount != 0) // if we found an ai choice
                {
                    DrawBoard(board, ai_chosen_spots);

                    IO.WriteLine(knownCount + " known " + predictionCount + " predicted\n");

                    // check if at least 1 is suggested
                    IO.WriteLine("I did these, so press <enter> once:");
                    IO.ReadLine();

                    /*if (playerinput=1){
                     * //AIFillIn();
                     *    }
                     */
                }
                else
                {
                    DrawBoard(board);
                    GetPlayerInput(ref pos_x, ref pos_y, ref pos_choice, ref endGame);
                    if (IsValidMove(board, pos_x, pos_y, pos_choice))
                    {
                        PlaceMoveAtPos(ref board, pos_x, pos_y, pos_choice);

                        UpdateSuggestedMoves(board, ref planning_board);
                    }
                    else
                    {
                        IO.WriteLine("Move is not valid, please try a new one");
                    }
                }
                // board complete check
                value_count = 0;
                for (int i = 0; i < 9; i++)
                {
                    for (int j = 0; j < 9; j++)
                    {
                        if (board[i, j] == 0)
                        {
                            ++value_count;
                        }
                    }
                }
                if (value_count == 0)
                {
                    IO.WriteLine("Game won!");
                    not_complete = false;
                }
            }

            IO.ReadLine();
        }