/*********************************************************************** * retro-b5500/emulator B5500CentralControl.js ************************************************************************ * Copyright (c) 2012, Nigel Williams and Paul Kimpel. * Licensed under the MIT License, * see http://www.opensource.org/licenses/mit-license.php ************************************************************************ * B5500 Central Control module. ************************************************************************ * 2012-06-03 P.Kimpel * Original version, from thin air. ***********************************************************************/ "use strict"; /**************************************/ function B5500CentralControl(global) { /* Constructor for the Central Control module object */ this.mnemonic = "CC"; // Unit mnemonic this.global = global; // Javascript global object (e.g., "window" for browsers) /* Global system modules */ this.DD = null; // Distribution & Display unit this.PA = null; // Processor A (PA) this.PB = null; // Processor B (PB) this.IO1 = null; // I/O unit 1 this.IO2 = null; // I/O unit 2 this.IO3 = null; // I/O unit 3 this.IO4 = null; // I/O unit 4 this.P1 = null; // Reference for Processor 1 (control) [PA or PB] this.P2 = null; // Reference for Processor 2 (slave) [PA or PB] this.addressSpace = [ // Array of memory module address spaces (8 x 32KB each) null, null, null, null, null, null, null, null]; this.memMod = [ // Array of memory module words as Float64s (8 x 4KW each) null, null, null, null, null, null, null, null]; this.unit = [ // Array of peripheral units, indexed by ready-mask bit number null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null, null]; // Instance variables and flags this.poweredUp = 0; // System power indicator this.unitStatusMask = 0; // Peripheral unit ready-status bitmask this.PB1L = 0; // 0=> PA is P1, 1=> PB is P1 this.inhCCI03F = 0; // 0=> allow timer interrupts; 1=> inhibit 'em this.cardLoadSelect = 0; // 0=> load from disk/drum; 1=> load from cards this.nextTimeStamp = 0; // Next actual Date.getTime() for timer tick this.timer = null; // Reference to the RTC setCallback id. // Establish contexts for asynchronously-called methods this.boundTock = B5500CentralControl.bindMethod(this.tock, this); this.clear(); // Create and initialize the Central Control state } /**************************************/ /* Global constants */ B5500CentralControl.version = "0.16"; B5500CentralControl.memReadCycles = 2; // assume 2 µs memory read cycle time (the other option was 3 µs) B5500CentralControl.memWriteCycles = 3; // assume 4 µs memory write cycle time (the other option was 6 µs) B5500CentralControl.rtcTick = 1000/60; // Real-time clock period, milliseconds B5500CentralControl.pow2 = [ // powers of 2 from 0 to 52 0x1, 0x2, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, 0x100, 0x200, 0x400, 0x800, 0x1000, 0x2000, 0x4000, 0x8000, 0x10000, 0x20000, 0x40000, 0x80000, 0x100000, 0x200000, 0x400000, 0x800000, 0x1000000, 0x2000000, 0x4000000, 0x8000000, 0x10000000, 0x20000000, 0x40000000, 0x80000000, 0x100000000, 0x200000000, 0x400000000, 0x800000000, 0x1000000000, 0x2000000000, 0x4000000000, 0x8000000000, 0x10000000000, 0x20000000000, 0x40000000000, 0x80000000000, 0x100000000000, 0x200000000000, 0x400000000000, 0x800000000000, 0x1000000000000, 0x2000000000000, 0x4000000000000, 0x8000000000000, 0x10000000000000]; B5500CentralControl.mask2 = [ // (2**n)-1 For n From 0 to 52 0x0, 0x1, 0x3, 0x7, 0x0F, 0x1F, 0x3F, 0x7F, 0x0FF, 0x1FF, 0x3FF, 0x7FF, 0x0FFF, 0x1FFF, 0x3FFF, 0x7FFF, 0x0FFFF, 0x1FFFF, 0x3FFFF, 0x7FFFF, 0x0FFFFF, 0x1FFFFF, 0x3FFFFF, 0x7FFFFF, 0x0FFFFFF, 0x1FFFFFF, 0x3FFFFFF, 0x7FFFFFF, 0x0FFFFFFF, 0x1FFFFFFF, 0x3FFFFFFF, 0x7FFFFFFF, 0x0FFFFFFFF, 0x1FFFFFFFF, 0x3FFFFFFFF, 0x7FFFFFFFF, 0x0FFFFFFFFF, 0x1FFFFFFFFF, 0x3FFFFFFFFF, 0x7FFFFFFFFF, 0x0FFFFFFFFFF, 0x1FFFFFFFFFF, 0x3FFFFFFFFFF, 0x7FFFFFFFFFF, 0x0FFFFFFFFFFF, 0x1FFFFFFFFFFF, 0x3FFFFFFFFFFF , 0x7FFFFFFFFFFF, 0x0FFFFFFFFFFFF, 0x1FFFFFFFFFFFF, 0x3FFFFFFFFFFFF, 0x7FFFFFFFFFFFF, 0x0FFFFFFFFFFFFF] ; // The following two-dimensional array translates unit designates to a unique 1-relative // peripheral unit index. This index is the same as the unit's ready-status bit number, // which is why they are in the range 17..47. The [0] dimension determines the index // when writing; the [1] dimension determines the index when reading. This approach // is necessary since some unit designates map to two different devices depending // on the read bit in IOD.[24:1], e.g. designate 14=CPA/CRA (status bits 23/24). B5500CentralControl.unitIndex = [ // 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 [null, 47,null, 46, 31, 45, 29, 44, 30, 43, 25, 42, 28, 41,null, 40, 17, 39, 21, 38, 18, 37, 27, 36,null, 35, 26, 34,null, 33, 22, 32], [null, 47,null, 46, 31, 45, 29, 44, 30, 43, 24, 42, 28, 41, 23, 40, 17, 39, 20, 38, 19, 37,null, 36,null, 35,null, 34,null, 33, 22, 32]]; // The following object maps the unit mnemonics from B5500SystemConfiguration.units // to the attributes needed to configure the CC unit[] array. B5500CentralControl.unitSpecs = { DCA: {unitIndex: 17, designate: 16, unitClass: "B5500DatacomUnit"}, PPB: {unitIndex: 18, designate: 20, unitClass: null}, PRB: {unitIndex: 19, designate: 20, unitClass: null}, PRA: {unitIndex: 20, designate: 18, unitClass: null}, PPA: {unitIndex: 21, designate: 18, unitClass: null}, SPO: {unitIndex: 22, designate: 30, unitClass: "B5500SPOUnit"}, CRB: {unitIndex: 23, designate: 14, unitClass: "B5500CardReader"}, CRA: {unitIndex: 24, designate: 10, unitClass: "B5500CardReader"}, CPA: {unitIndex: 25, designate: 10, unitClass: "B5500CardPunch"}, LPB: {unitIndex: 26, designate: 26, unitClass: "B5500DummyPrinter"}, LPA: {unitIndex: 27, designate: 22, unitClass: "B5500DummyPrinter"}, DKB: {unitIndex: 28, designate: 12, unitClass: "B5500DiskUnit"}, DKA: {unitIndex: 29, designate: 6, unitClass: "B5500DiskUnit"}, DRB: {unitIndex: 30, designate: 8, unitClass: null}, DRA: {unitIndex: 31, designate: 4, unitClass: null}, MTT: {unitIndex: 32, designate: 31, unitClass: null}, MTS: {unitIndex: 33, designate: 29, unitClass: null}, MTR: {unitIndex: 34, designate: 27, unitClass: null}, MTP: {unitIndex: 35, designate: 25, unitClass: null}, MTN: {unitIndex: 36, designate: 23, unitClass: null}, MTM: {unitIndex: 37, designate: 21, unitClass: null}, MTL: {unitIndex: 38, designate: 19, unitClass: null}, MTK: {unitIndex: 39, designate: 17, unitClass: null}, MTJ: {unitIndex: 40, designate: 15, unitClass: null}, MTH: {unitIndex: 41, designate: 13, unitClass: null}, MTF: {unitIndex: 42, designate: 11, unitClass: null}, MTE: {unitIndex: 43, designate: 9, unitClass: null}, MTD: {unitIndex: 44, designate: 7, unitClass: null}, MTC: {unitIndex: 45, designate: 5, unitClass: null}, MTB: {unitIndex: 46, designate: 3, unitClass: null}, MTA: {unitIndex: 47, designate: 1, unitClass: "B5500MagTapeDrive"}}; /**************************************/ B5500CentralControl.bindMethod = function bindMethod(f, context) { /* Returns a new function that binds the function "f" to the object "context". Note that this is a constructor property function, NOT an instance method of the CC object */ return function bindMethodAnon() {f.apply(context, arguments)}; }; /**************************************/ B5500CentralControl.prototype.clear = function clear() { /* Initializes (and if necessary, creates) the system and starts the real-time clock */ if (this.timer) { clearCallback(this.timer); this.timer = null; } this.IAR = 0; // Interrupt address register this.TM = 0; // Real-time clock (6 bits, 60 ticks per second) this.CCI03F = 0; // Time interval interrupt this.CCI04F = 0; // I/O busy interrupt this.CCI05F = 0; // Keyboard request interrupt this.CCI06F = 0; // Printer 1 finished interrupt this.CCI07F = 0; // Printer 2 finished interrupt this.CCI08F = 0; // I/O unit 1 finished interrupt (RD in @14) this.CCI09F = 0; // I/O unit 2 finished interrupt (RD in @15) this.CCI10F = 0; // I/O unit 3 finished interrupt (RD in @16) this.CCI11F = 0; // I/O unit 4 finished interrupt (RD in @17) this.CCI12F = 0; // P2 busy interrupt this.CCI13F = 0; // Remote inquiry request interrupt this.CCI14F = 0; // Special interrupt #1 (not used) this.CCI15F = 0; // Disk file #1 read check finished this.CCI16F = 0; // Disk file #2 read check finished this.MCYF = 0; // Memory cycle FFs (one bit per M0..M7) this.PAXF = 0; // PA memory exchange select (M0..M7) this.PBXF = 0; // PB memory exchange select (M0..M7) this.I1XF = 0; // I/O unit 1 exchange select (M0..M7) this.I2XF = 0; // I/O unit 2 exchange select (M0..M7) this.I3XF = 0; // I/O unit 3 exchange select (M0..M7) this.I4XF = 0; // I/O unit 4 exchange select (M0..M7) this.AD1F = 0; // I/O unit 1 busy this.AD2F = 0; // I/O unit 2 busy this.AD3F = 0; // I/O unit 3 busy this.AD4F = 0; // I/O unit 4 busy this.LOFF = 0; // Load button pressed on console this.CTMF = 0; // Commence timing FF this.P2BF = 0; // Processor 2 busy FF this.HP2F = 1; // Halt processor 2 FF this.interruptMask = 0; // Interrupt status mask this.interruptLatch = 0; // Interrupt latched status (reset by console UI) this.iouMask = 0; // I/O Unit busy status mask this.iouLatch = 0; // I/O Unit busy latched status (reset by console UI) this.unitBusyLatch = 0; // Peripheral unit latched status (reset by console UI) this.unitBusyMask = 0; // Peripheral unit busy-status bitmask if (this.PA) { this.PA.clear(); } if (this.PB) { this.PB.clear(); } this.P1 = (this.PB1L ? this.PB : this.PA); this.P2 = (this.PB1L ? this.PA : this.PB); if (!this.P2) { this.P2BF = 1; // mark non-existent P2 as busy } }; /**************************************/ B5500CentralControl.prototype.bitTest = function bitTest(word, bit) { /* Extracts and returns the specified bit from the word */ var e = 47-bit; // word lower power exponent var p; // bottom portion of word power of 2 if (e > 0) { return ((word - word % (p = B5500CentralControl.pow2[e]))/p) % 2; } else { return word % 2; } }; /**************************************/ B5500CentralControl.prototype.bitSet = function bitSet(word, bit) { /* Sets the specified bit in word and returns the updated word */ var ue = 48-bit; // word upper power exponent var le = ue-1; // word lower power exponent var bpower = 1; // bottom portion of word power of 2 var bottom = // unaffected bottom portion of word (le == 0 ? 0 : (word % (bpower = B5500CentralControl.pow2[le]))); var top = // unaffected top portion of word (bit == 0 ? 0 : (word - (word % B5500CentralControl.pow2[ue]))); return bpower + top + bottom; }; /**************************************/ B5500CentralControl.prototype.bitReset = function bitReset(word, bit) { /* Resets the specified bit in word and returns the updated word */ var ue = 48-bit; // word upper power exponent var le = ue-1; // word lower power exponent var bottom = // unaffected bottom portion of word (le == 0 ? 0 : (word % B5500CentralControl.pow2[le])); var top = // unaffected top portion of word (bit == 0 ? 0 : (word - (word % B5500CentralControl.pow2[ue]))); return top + bottom; }; /**************************************/ B5500CentralControl.prototype.fieldIsolate = function fieldIsolate(word, start, width) { /* Extracts a bit field [start:width] from word and returns the field */ var le = 48-start-width; // lower power exponent var p; // bottom portion of word power of 2 return (le == 0 ? word : (word - word % (p = B5500CentralControl.pow2[le]))/p ) % B5500CentralControl.pow2[width]; }; /**************************************/ B5500CentralControl.prototype.fieldInsert = function fieldInsert(word, start, width, value) { /* Inserts a bit field from the low-order bits of value ([48-width:width]) into word.[start:width] and returns the updated word */ var ue = 48-start; // word upper power exponent var le = ue-width; // word lower power exponent var bpower = 1; // bottom portion of word power of 2 var bottom = // unaffected bottom portion of word (le == 0 ? 0 : (word % (bpower = B5500CentralControl.pow2[le]))); var top = // unaffected top portion of word (ue == 0 ? 0 : (word - (word % B5500CentralControl.pow2[ue]))); return (value % B5500CentralControl.pow2[width])*bpower + top + bottom; }; /**************************************/ B5500CentralControl.prototype.fieldTransfer = function fieldTransfer(word, wstart, width, value, vstart) { /* Inserts a bit field from value.[vstart:width] into word.[wstart:width] and returns the updated word */ var ue = 48-wstart; // word upper power exponent var le = ue-width; // word lower power exponent var ve = 48-vstart-width; // value lower power exponent var vpower; // bottom port of value power of 2 var bpower = 1; // bottom portion of word power of 2 var bottom = // unaffected bottom portion of word (le == 0 ? 0 : (word % (bpower = B5500CentralControl.pow2[le]))); var top = // unaffected top portion of word (ue == 0 ? 0 : (word - (word % B5500CentralControl.pow2[ue]))); return ((ve == 0 ? value : (value - value % (vpower = B5500CentralControl.pow2[ve]))/vpower ) % B5500CentralControl.pow2[width] )*bpower + top + bottom; }; /**************************************/ B5500CentralControl.prototype.fetch = function fetch(acc) { /* Called by a requestor module passing accessor object "acc" to fetch a word from memory. */ var addr = acc.addr; var modNr = addr >>> 12; var modAddr = addr & 0x0FFF; var modMask = 1 << modNr; this.MCYF |= modMask; // !! need to figure out when to turn this off for display purposes // (odd/even addresses? fetch vs. store? XOR the mask?) switch (acc.requestorID) { case "A": this.PAXF = modMask; break; case "B": this.PBXF = modMask; break; case "1": this.I1XF = modMask; break; case "2": this.I2XF = modMask; break; case "3": this.I3XF = modMask; break; case "4": this.I4XF = modMask; break; } // For now, we assume memory parity can never happen if (acc.MAIL || !this.memMod[modNr]) { acc.MPED = 0; // no memory parity error acc.MAED = 1; // memory address error // no .word value is returned in this case } else { acc.MPED = 0; // no parity error acc.MAED = 0; // no address error acc.word = this.memMod[modNr][modAddr]; } }; /**************************************/ B5500CentralControl.prototype.store = function store(acc) { /* Called by requestor module passing accessor object "acc" to store a word into memory. */ var addr = acc.addr; var modNr = addr >>> 12; var modAddr = addr & 0x0FFF; var modMask = 1 << modNr; this.MCYF |= modMask; // !! need to figure out when to turn this off for display purposes // (odd/even addresses? fetch vs. store? XOR the mask?) switch (acc.requestorID) { case "A": this.PAXF = modMask; break; case "B": this.PBXF = modMask; break; case "1": this.I1XF = modMask; break; case "2": this.I2XF = modMask; break; case "3": this.I3XF = modMask; break; case "4": this.I4XF = modMask; break; } // For now, we assume memory parity can never happen if (acc.MAIL || !this.memMod[modNr]) { acc.MPED = 0; // no memory parity error acc.MAED = 1; // memory address error // no word is stored in this case } else { acc.MPED = 0; // no parity error acc.MAED = 0; // no address error this.memMod[modNr][modAddr] = acc.word; } }; /**************************************/ B5500CentralControl.prototype.signalInterrupt = function signalInterrupt() { /* Called by all modules to signal that an interrupt has occurred and to invoke the interrupt prioritization mechanism. This will result in an updated vector address in the IAR. Can also be called to reprioritize any remaining interrupts after an interrupt is handled. If no interrupt condition exists, this.IAR is set to zero. */ var p1 = this.P1; var p2; this.IAR = p1.I & 0x01 ? 0x30 // @60: P1 memory parity error : p1.I & 0x02 ? 0x31 // @61: P1 invalid address error : this.CCI03F ? 0x12 // @22: Time interval : this.CCI04F ? 0x13 // @23: I/O busy : this.CCI05F ? 0x14 // @24: Keyboard request : this.CCI08F ? 0x17 // @27: I/O 1 finished : this.CCI09F ? 0x18 // @30: I/O 2 finished : this.CCI10F ? 0x19 // @31: I/O 3 finished : this.CCI11F ? 0x1A // @32: I/O 4 finished : this.CCI06F ? 0x15 // @25: Printer 1 finished : this.CCI07F ? 0x16 // @26: Printer 2 finished : this.CCI12F ? 0x1B // @33: P2 busy : this.CCI13F ? 0x1C // @34: Inquiry request : this.CCI14F ? 0x1D // @35: Special interrupt 1 : this.CCI15F ? 0x1E // @36: Disk file 1 read check finished : this.CCI16F ? 0x1F // @37: Disk file 2 read check finished : p1.I & 0x04 ? 0x32 // @62: P1 stack overflow : p1.I & 0xF0 ? (p1.I >>> 4) + 0x30 // @64-75: P1 syllable-dependent : (p2 = this.P2) ? // Yes, Virginia, this should actually be an assignment... ( p2.I & 0x01 ? 0x20 // @40: P2 memory parity error : p2.I & 0x02 ? 0x21 // @41: P2 invalid address error : p2.I & 0x04 ? 0x22 // @42: P2 stack overflow : p2.I & 0xF0 ? (p2.I >>> 4) + 0x20 // @44-55: P2 syllable-dependent : 0 ) : 0; // no interrupt set if (this.IAR) { this.interruptMask = this.bitSet(this.interruptMask, 65-this.IAR); this.interruptLatch = this.bitSet(this.interruptLatch, 65-this.IAR); } }; /**************************************/ B5500CentralControl.prototype.clearInterrupt = function clearInterrupt() { /* Resets an interrupt based on the current setting of this.IAR, then reprioritizes any remaining interrupts, leaving the new vector address in this.IAR. */ var p1 = this.P1; var p2 = this.P2; if (this.IAR) { this.interruptMask = this.bitReset(this.interruptMask, 65-this.IAR) switch (this.IAR) { case 0x12: // @22: Time interval this.CCI03F = 0; break; case 0x13: // @23: I/O busy this.CCI04F = 0; break; case 0x14: // @24: Keyboard request this.CCI05F = 0; break; case 0x15: // @25: Printer 1 finished this.CCI06F = 0; break; case 0x16: // @26: Printer 2 finished this.CCI07F = 0; break; case 0x17: // @27: I/O 1 finished this.CCI08F = 0; this.AD1F = 0; // make unit non-busy this.iouMask &= 0xE; break; case 0x18: // @30: I/O 2 finished this.CCI09F = 0; this.AD2F = 0; // make unit non-busy this.iouMask &= 0xD; break; case 0x19: // @31: I/O 3 finished this.CCI10F = 0; this.AD3F = 0; // make unit non-busy this.iouMask &= 0xB; break; case 0x1A: // @32: I/O 4 finished this.CCI11F = 0; this.AD4F = 0; // make unit non-busy this.iouMask &= 0x7; break; case 0x1B: // @33: P2 busy this.CCI12F = 0; break; case 0x1C: // @34: Inquiry request this.CCI13F = 0; break; case 0x1D: // @35: Special interrupt 1 this.CCI14F = 0; break; case 0x1E: // @36: Disk file 1 read check finished this.CCI15F = 0; break; case 0x1F: // @37: Disk file 2 read check finished this.CCI16F = 0; break; case 0x20: // @40: P2 memory parity error if (p2) {p2.I &= 0xFE} break; case 0x21: // @41: P2 invalid address error if (p2) {p2.I &= 0xFD} break; case 0x22: // @42: P2 stack overflow if (p2) {p2.I &= 0xFB} break; case 0x24: // @44-55: P2 syllable-dependent case 0x25: case 0x26: case 0x27: case 0x28: case 0x29: case 0x2A: case 0x2B: case 0x2C: case 0x2D: if (p2) {p2.I &= 0x0F} break; case 0x30: // @60: P1 memory parity error p1.I &= 0xFE; break; case 0x31: // @61: P1 invalid address error p1.I &= 0xFD; break; case 0x32: // @62: P1 stack overflow p1.I &= 0xFB; break; case 0x34: // @64-75: P1 syllable-dependent case 0x35: case 0x36: case 0x37: case 0x38: case 0x39: case 0x3A: case 0x3B: case 0x3C: case 0x3D: p1.I &= 0x0F; break; default: // no interrupt vector was set break; } } this.signalInterrupt(); }; /**************************************/ B5500CentralControl.prototype.tock = function tock() { /* Handles the 1/60th second real-time clock tick */ var interval; // milliseconds to next tick var thisTime = new Date().getTime(); if (this.TM < 63) { this.TM++; } else { this.TM = 0; if (!this.inhCCI03F) { this.CCI03F = 1; // set timer interrupt this.signalInterrupt(); } } interval = (this.nextTimeStamp += B5500CentralControl.rtcTick) - thisTime; this.timer = setCallback(this.boundTock, this, interval); }; /**************************************/ B5500CentralControl.prototype.readTimer = function readTimer() { /* Returns the value of the 1/60th second timer */ var thisTime = new Date().getTime(); return this.CCI03F*64 + this.TM; }; /**************************************/ B5500CentralControl.prototype.haltP2 = function haltP2() { /* Called by P1 to halt P2. storeForInterrupt() will set P2BF=0 */ this.HP2F = 1; // We know P2 is not currently running on this thread, so save its registers if (this.P2 && this.P2.busy) { this.P2.storeForInterrupt(1, 0); } }; /**************************************/ B5500CentralControl.prototype.initiateP2 = function initiateP2() { /* Called by P1 to initiate P2. Assumes that an INCW has been stored at memory location @10. If P2 is busy or not present, sets the P2 busy interrupt. Otherwise, loads the INCW into P2's A register and initiates the processor. */ if (this.P2BF || !this.P2) { this.CCI12F = 1; // set P2 busy interrupt this.signalInterrupt(); } else { this.P2BF = 1; this.HP2F = 0; this.P2.initiateAsP2(); } }; /**************************************/ B5500CentralControl.prototype.initiateIO = function initiateIO() { /* Selects an I/O unit and initiates an I/O */ if (this.IO1 && this.IO1.REMF && !this.AD1F) { this.AD1F = 1; this.iouMask |= 0x1; this.iouLatch |= 0x1; this.IO1.initiate(); } else if (this.IO2 && this.IO2.REMF && !this.AD2F) { this.AD2F = 1; this.iouMask |= 0x2; this.iouLatch |= 0x2; this.IO2.initiate(); } else if (this.IO3 && this.IO3.REMF && !this.AD3F) { this.AD3F = 1; this.iouMask |= 0x4; this.iouLatch |= 0x4; this.IO3.initiate(); } else if (this.IO4 && this.IO4.REMF && !this.AD4F) { this.AD4F = 1; this.iouMask |= 0x8; this.iouLatch |= 0x8; this.IO4.initiate(); } else { this.CCI04F = 1; // set I/O busy interrupt this.signalInterrupt(); } }; /**************************************/ B5500CentralControl.prototype.interrogateIOChannel = function interrogateIOChannel() { /* Returns a value as for the processor TIO syllable indicating the first available and non-busy I/O Unit */ if (this.IO1 && this.IO1.REMF && !this.AD1F) { return 1; } else if (this.IO2 && this.IO2.REMF && !this.AD2F) { return 2; } else if (this.IO3 && this.IO3.REMF && !this.AD3F) { return 3; } else if (this.IO4 && this.IO4.REMF && !this.AD4F) { return 4; } else { return 0; // All I/O Units busy } }; /**************************************/ B5500CentralControl.prototype.interrogateUnitStatus = function interrogateUnitStatus() { /* Returns a bitmask as for the processor TUS syllable indicating the ready status of all peripheral units */ return this.unitStatusMask; }; /**************************************/ B5500CentralControl.prototype.testUnitReady = function testUnitReady(index) { /* Determines whether the unit index "index" is currently in ready status. Returns 1 if ready, 0 if not ready */ return (index ? this.bitTest(this.unitStatusMask, index) : 0); }; /**************************************/ B5500CentralControl.prototype.testUnitBusy = function testUnitBusy(index) { /* Determines whether the unit index "index" is currently in use by any other I/O Unit. Returns 1 if busy, 0 if not busy */ return (index ? this.bitTest(this.unitBusyMask, index) : 0); }; /**************************************/ B5500CentralControl.prototype.setUnitBusy = function setUnitBusy(index, busy) { /* Sets or resets the unit-busy mask bit for unit index "index" */ if (index) { if (busy) { this.unitBusyMask = this.bitSet(this.unitBusyMask, index); this.unitBusyLatch = this.bitSet(this.unitBusyLatch, index); } else { this.unitBusyMask = this.bitReset(this.unitBusyMask, index); } } }; /**************************************/ B5500CentralControl.prototype.fetchInterruptLatch = function fetchInterruptLatch() { /* Returns and resets this.interruptLatch; used by console UI */ var latch = this.interruptLatch; this.interruptLatch = this.interruptMask; return latch; }; /**************************************/ B5500CentralControl.prototype.fetchIOUnitLatch = function fetchIOUnitLatch() { /* Returns and resets this.iouLatch; used by console UI */ var latch = this.iouLatch; this.iouLatch = this.iouMask; return latch; }; /**************************************/ B5500CentralControl.prototype.fetchUnitBusyLatch = function fetchUnitBusyLatch() { /* Returns and resets this.unitBusyLatch; used by console UI */ var latch = this.unitBusyLatch; this.unitBusyLatch = this.unitBusyMask; return latch; }; /**************************************/ B5500CentralControl.prototype.halt = function halt() { /* Halts the processors. Any in-process I/Os are allowed to complete */ if (this.timer) { clearCallback(this.timer); this.timer = null; } if (this.PA && this.PA.busy) { this.PA.stop(); } if (this.PB && this.PB.busy) { this.PB.stop(); } }; /**************************************/ B5500CentralControl.prototype.loadComplete = function loadComplete(dontStart) { /* Monitors an initial load I/O operation for complete status. When complete, initiates P1 */ var completed = false; // true if some I/O Unit finished if (this.CCI08F) { // I/O Unit 1 finished completed = true; this.CCI08F = 0; this.AD1F = 0; this.iouMask &= 0xE; } else if (this.CCI09F) { // I/O Unit 2 finished completed = true; this.CCI09F = 0; this.AD2F = 0; this.iouMask &= 0xD; } else if (this.CCI10F) { // I/O Unit 3 finished completed = true; this.CCI10F = 0; this.AD3F = 0; this.iouMask &= 0xB; } else if (this.CCI11F) { // I/O Unit 4 finished completed = true; this.CCI11F = 0; this.AD4F = 0; this.iouMask &= 0x7; } if (completed) { this.signalInterrupt(); // reset the pending I/O complete interrupt this.LOFF = 0; this.P1.preset(0x10); // start execution at C=@20 if (!dontStart) { this.P1.start(); // let'er rip } } }; /**************************************/ B5500CentralControl.prototype.load = function load(dontStart) { /* Initiates a Load operation to start the system. If "dontStart" is truthy, then only the MCP bootstrap is loaded into memory -- P1 is not started */ var result; var boundLoadComplete = (function boundLoadComplete(that, dontStart) { return function boundLoadCompleteAnon() {return that.loadComplete(dontStart)} }(this, dontStart)); if (!this.P1 || this.P1.busy) { // P1 is busy or not available result = 1; } else if (!this.testUnitReady(22)) { // SPO not ready result = 2; } else if (this.testUnitBusy(22)) { // SPO is busy result = 3; } else { // ready to rock 'n roll this.clear(); this.nextTimeStamp = new Date().getTime(); this.tock(); this.LOFF = 1; if (this.IO1 && this.IO1.REMF && !this.AD1F) { this.AD1F = 1; this.iouMask |= 0x1; this.iouLatch |= 0x1; this.IO1.initiateLoad(this.cardLoadSelect, boundLoadComplete); } else if (this.IO2 && this.IO2.REMF && !this.AD2F) { this.AD2F = 1; this.iouMask |= 0x2; this.iouLatch |= 0x2; this.IO2.initiateLoad(this.cardLoadSelect, boundLoadComplete); } else if (this.IO3 && this.IO3.REMF && !this.AD3F) { this.AD3F = 1; this.iouMask |= 0x4; this.iouLatch |= 0x4; this.IO3.initiateLoad(this.cardLoadSelect, boundLoadComplete); } else if (this.IO4 && this.IO4.REMF && !this.AD4F) { this.AD4F = 1; this.iouMask |= 0x8; this.iouLatch |= 0x8; this.IO4.initiateLoad(this.cardLoadSelect, boundLoadComplete); } else { this.CCI04F = 1; // set I/O busy interrupt } result = 0; // all is copacetic } return result; }; /**************************************/ B5500CentralControl.prototype.loadTest = function loadTest(buf, loadAddr) { /* Loads a test codestream into memory starting at B5500 word address "loadAddr" from the ArrayBuffer "buf". Returns the number of B5500 words loaded into memory. Note that when loading an ESPOL "DISK" file, the first executable location is @20, so you will typically want to load to address 0 and call cc.runTest(0x10) [where 0x10 = @20]. This routine should not be used to load ESPOL "DECK" files */ var addr = loadAddr; // starting B5500 memory address var bytes = buf.byteLength; var data = new DataView(buf); // use DataView() to avoid problems with littleendians. var power = 0x10000000000; var word = 0; var x = 0; function store(addr, word) { /* Stores a 48-bit word at the specified B5500 address. Invalid addresses and parity errors are ignored */ var modNr = addr >>> 12; var modAddr = addr & 0x0FFF; if (modNr < 8 && this.memMod[modNr]) { this.memMod[modNr][modAddr] = word; } } if (!this.poweredUp) { throw "cc.loadTest: Cannot load with system powered off"; } else { while (bytes > 6) { word = data.getUint8(x)* 0x10000000000 + data.getUint8(x+1)* 0x100000000 + data.getUint8(x+2)* 0x1000000 + data.getUint8(x+3)* 0x10000 + data.getUint8(x+4)* 0x100 + data.getUint8(x+5); store.call(this, addr, word); x += 6; bytes -= 6; if (++addr > 0x7FFF) { break; } } // Store any partial word that may be left while (bytes > 0) { word += data.getUint8(x, false)*power; x++; bytes--; power /= 0x100; } store.call(this, addr, word); } return addr-loadAddr+1; }; /**************************************/ B5500CentralControl.prototype.runTest = function runTest(runAddr) { /* Executes a test program previously loaded by this.loadTest on processor P1. "runAddr" is the B5500 word address at which execution will begin (typically 0x10 [octal 20]) */ this.clear(); this.LOFF = 0; this.P1.preset(runAddr); this.P1.start(); }; /**************************************/ B5500CentralControl.prototype.configureSystem = function configureSystem() { /* Establishes the hardware module configuration from the B5500SystemConfiguration module */ var cfg = B5500SystemConfiguration; var mnem; var signal = null; var specs; var u; var unitClass; var x; function makeChange(cc, maskBit) { return function statusChange(ready) { cc.unitStatusMask = (ready ? cc.bitSet(cc.unitStatusMask, maskBit) : cc.bitReset(cc.unitStatusMask, maskBit)); }; } function makeSignal(cc, mnemonic) { switch (mnemonic) { case "SPO": return function signalSPO() { cc.CCI05F = 1; cc.signalInterrupt(); }; break; case "LPA": return function signalLPA() { cc.CCI06F = 1; cc.signalInterrupt(); }; break; case "LPB": return function signalLPB() { cc.CCI07F = 1; cc.signalInterrupt(); }; break; case "DCA": return function signalDCA() { cc.CCI13F = 1; cc.signalInterrupt(); }; break; case "DKA": return function signalDKA() { cc.setUnitBusy(29, 0); // Is this needed here ?? cc.CCI15F = 1; cc.signalInterrupt(); }; break; case "DKB": return function signalDKB() { cc.setUnitBusy(28, 0); // Is this needed here ?? cc.CCI16F = 1; cc.signalInterrupt(); }; break; default: return function signalDefault() {}; break; } } // ***** !! inhibit for now ***** // this.DD = new B5500DistributionAndDisplay(this); // Configure the processors if (cfg.PA) {this.PA = new B5500Processor("A", this)} if (cfg.PB) {this.PB = new B5500Processor("B", this)} // Determine P1/P2 this.PB1L = (cfg.PB1L ? 1 : 0); // Configure the I/O Units if (cfg.IO1) {this.IO1 = new B5500IOUnit("1", this)} if (cfg.IO2) {this.IO2 = new B5500IOUnit("2", this)} if (cfg.IO3) {this.IO3 = new B5500IOUnit("3", this)} if (cfg.IO4) {this.IO4 = new B5500IOUnit("4", this)} // Configure memory for (x=0; x<8; x++) { if (cfg.memMod[x]) { this.addressSpace[x] = new ArrayBuffer(32768); // 4K B5500 words @ 8 bytes each this.memMod[x] = new Float64Array(this.addressSpace[x]); } } // Configure the peripheral units for (mnem in cfg.units) { if (cfg.units[mnem]) { specs = B5500CentralControl.unitSpecs[mnem]; if (specs) { unitClass = this.global[specs.unitClass || "B5500DummyUnit"]; if (unitClass) { u = new unitClass(mnem, specs.unitIndex, specs.designate, makeChange(this, specs.unitIndex), makeSignal(this, mnem)); this.unit[specs.unitIndex] = u; } } } } this.clear(); }; /**************************************/ B5500CentralControl.prototype.powerOn = function powerOn() { /* Powers up the system and establishes the hardware module configuration. Redundant power-ons are ignored. */ if (!this.poweredUp) { this.configureSystem(); this.poweredUp = 1; } }; /**************************************/ B5500CentralControl.prototype.powerOff = function powerOff() { /* Powers down the system and deallocates the hardware modules. Redundant power-offs are ignored. */ function shutDown() { var x; if (this.timer) { clearCallback(this.timer); this.timer = null; } // Shut down the peripheral devices for (x=0; x