doxygen/CPUCore_8cc_source.html

 // MEMORY EMULATION

 // ----------------

 //

 // Memory access emulation is a very important part of the CPU emulation.

 // Because they happen so frequently they really need to be executed as fast as

 // possible otherwise they will completely bring down the speed of the CPU

 // emulation.

 //

 // A very fast way to emulate memory accesses is by simply reading/writing to a

 // 64kb array (for a 16-bit address space). Unfortunately this doesn't allow

 // for memory mapped IO (MMIO). These are memory regions where read/writes

 // trigger side effects, so where we need to execute device-specific code on

 // read or writes. An alternative that does work with MMIO is for every access

 // execute a virtual method call, (this is the approach taken by most current

 // MSX emulators). Unfortunately this is also a lot slower.

 //

 // It is possible to combine the speed of array accesses with the flexibility

 // of virtual methods. In openMSX it's implemented as follows: the 64kb address

 // space is divided in 256 regions of 256 bytes (called cacheLines in the code

 // below). For each such region we store a pointer, if this pointer is nullptr

 // then we have to use the slow way (=virtual method call). If it is not nullptr,

 // the pointer points to a block of memory that can be directly accessed. In

 // some contexts accesses via the pointer are known as backdoor accesses while

 // the accesses directly to the device are known as frontdoor accesses.

 //

 // We keep different pointers for read and write accesses. This allows to also

 // implement ROMs efficiently: read is handled as regular RAM, but writes end

 // up in some dummy memory region. This region is called 'unmappedWrite' in the

 // code. There is also a special region 'unmappedRead', this region is filled

 // with 0xFF and can be used to model (parts of) a device that don't react to

 // reads (so reads return 0xFF).

 //

 // Because of bankswitching (the MSX slot select mechanism, but also e.g.

 // MegaROM backswitching) the memory map as seen by the Z80 is not static. This

 // means that the cacheLine pointers also need to change during runtime. To

 // solve this we made the bankswitch code also responsible for invalidating the

 // cacheLines of the switched region. These pointers are filled-in again in a

 // lazy way: the first read or write to a cache line will first get this

 // pointer (see getReadCacheLine() and getWriteCacheLine() in the code below),

 // from then on this pointer is used for all further accesses to this region,

 // until the cache is invalidated again.

 //

 //

 // INSTRUCTION EMULATION

 // ---------------------

 //

 // UPDATE: the 'threaded interpreter model' is not enabled by default

 //         main reason is the huge memory requirement while compiling

 //         and that it doesn't work on non-gcc compilers

 //

 // The current implementation is based on a 'threaded interpreter model'. In

 // the text below I'll call the older implementation the 'traditional

 // interpreter model'. From a very high level these two models look like this:

 //

 //     Traditional model:

 //         while (!needExit()) {

 //             byte opcode = fetch(PC++);

 //             switch (opcode) {

 //                 case 0x00: nop(); break;

 //                 case 0x01: ld_bc_nn(); break;

 //                 ...

 //             }

 //         }

 //

 //     Threaded model:

 //         byte opcode = fetch(PC++);   //

 //         goto *(table[opcode]);       // fetch-and-dispatch

 //         // note: the goto * syntax is a gcc extension called computed-gotos

 //

 //         op00: nop();      if (!needExit()) [fetch-and-dispatch];

 //         op01: ld_bc_nn(); if (!needExit()) [fetch-and-dispatch];

 //         ...

 //

 // In the first model there is a central place in the code that fetches (the

 // first byte of) the instruction and based on this byte jumps to the

 // appropriate routine. In the second model, this fetch-and-dispatch logic is

 // duplicated at the end of each instruction.

 //

 // Typically the 'dispatch' part in above paragraph is implemented (either by

 // the compiler or manually using computed goto's) via a jump table. Thus on

 // assembler level via an indirect jump. For the host CPU it's hard to predict

 // the destination address of such an indirect jump, certainly if there's only

 // one such jump for all dispatching (the traditional model). If each

 // instruction has its own indirect jump instruction (the threaded model), it

 // becomes a bit easier, because often one particular z80 instructions is

 // followed by a specific other z80 instruction (or one from a small subset).

 // For example a z80 'cp' instruction is most likely followed by a 'conditional

 // jump' z80 instruction. Modern CPUs are quite sensitive to

 // branch-(mis)predictions, so the above optimization helps quite a lot. I

 // measured a speedup of more than 10%!

 //

 // There is another advantage to the threaded model. Because also the

 // needExit() test is duplicated for each instruction, it becomes possible to

 // tweak it for individual instructions. But first let me explain this

 // exit-test in more detail.

 //

 // These are the main reasons why the emulator should stop emulating CPU

 // instructions:

 //  1) When other devices than the CPU must be emulated (e.g. video frame

 //     rendering). In openMSX this is handled by the Scheduler class and

 //     actually we don't exit the CPU loop (anymore) for this. Instead we

 //     simply execute the device code as a subroutine. Each time right before

 //     we access an IO port or do a frontdoor memory access, there is a check

 //     whether we should emulate device code (search for schedule() in the code

 //     below).

 //  2) To keep the inner CPU loop as fast as possible we don't check for IRQ,

 //     NMI or HALT status in this loop. Instead this condition is checked only

 //     once at the beginning outside of the loop (if there wasn't a pending IRQ

 //     on the first instruction there also won't be one on the second

 //     instruction, if all we did was emulating cpu instructions). Now when one

 //     of these conditions changes, we must exit the inner loop and re-evaluate

 //     them. For example after an EI instruction we must check the IRQ status

 //     again.

 //  3) Various reasons like:

 //      * Z80/R800 switch

 //      * executing a Tcl command (could be a cpu-register debug read)

 //      * exit the emulator

 //  4) 'once-in-a-while': To avoid threading problems and race conditions,

 //     several threads in openMSX only 'schedule' work that will later be

 //     executed by the main emulation thread. The main thread checks for such

 //     task outside of the cpu emulation loop. So once-in-a-while we need to

 //     exit the loop. The exact timing doesn't matter here because anyway the

 //     relative timing between threads is undefined.

 // So for 1) we don't need to do anything (we don't actually exit). For 2) and

 // 3) we need to exit the loop as soon as possible (right after the current

 // instruction is finished). For 4) it's OK to exit 'eventually' (a few hundred

 // z80 instructions late is still OK).

 //

 // Condition 2) is implemented with the 'slowInstructions' mechanism. Condition

 // 3) via exitCPULoopSync() (may only get called by the main emulation thread)

 // and condition 4) is implemented via exitCPULoopAsync() (can be called from

 // any thread).

 //

 // Now back to the exit-test optimization: in the threaded model each

 // instruction ends with:

 //

 //     if (needExit()) return

 //     byte opcode = fetch(PC++);

 //     goto *(table[opcode]);

 //

 // And if we look in more detail at fetch():

 //

 //     if (canDoBackdoor(addr)) {

 //         doBackdoorAccess(addr);

 //     } else {

 //         doFrontdoorAccess(addr);

 //     }

 //

 // So there are in fact two checks per instruction. This can be reduced to only

 // one check with the following trick:

 //

 // !!!WRONG!!!

 // In the past we optimized this to only check canDoBackdoor() (and make sure

 // canDoBackdoor() returned false when needExit() would return true). This

 // worked rather well, except for one case: when we exit the CPU loop we also

 // check for pending Syncronization points. It is possible such a SyncPoint

 // raises the IRQ line. So it is important to check for exit after every

 // instruction, otherwise we would enter the IRQ routine a couple of

 // instructions too late.


 #include "CPUCore.hh"

 #include "MSXCPUInterface.hh"

 #include "Scheduler.hh"

 #include "MSXMotherBoard.hh"

 #include "CliComm.hh"

 #include "TclCallback.hh"

 #include "Dasm.hh"

 #include "Z80.hh"

 #include "R800.hh"

 #include "Thread.hh"

 #include "endian.hh"

 #include "likely.hh"

 #include "inline.hh"

 #include "unreachable.hh"

 #include "xrange.hh"

 #include <iostream>

 #include <type_traits>

 #include <cassert>


 //

 // #define USE_COMPUTED_GOTO

 //

 // Computed goto's are not enabled by default:

 // - Computed goto's are a gcc extension, it's not part of the official c++

 //   standard. So this will only work if you use gcc as your compiler (it

 //   won't work with visual c++ for example)

 // - This is only beneficial on CPUs with branch prediction for indirect jumps

 //   and a reasonable amount of cache. For example it is very benefical for a

 //   intel core2 cpu (10% faster), but not for a ARM920 (a few percent slower)

 // - Compiling src/cpu/CPUCore.cc with computed goto's enabled is very demanding

 //   on the compiler. On older gcc versions it requires up to 1.5GB of memory.

 //   But even on more recent gcc versions it still requires around 700MB.

 //

 // Probably the easiest way to enable this, is to pass the -DUSE_COMPUTED_GOTO

 // flag to the compiler. This is for example done in the super-opt flavour.

 // See build/flavour-super-opt.mk


 namespace openmsx {


 enum Reg8  : int { A, F, B, C, D, E, H, L, IXH, IXL, IYH, IYL, REG_I, REG_R, DUMMY };

 enum Reg16 : int { AF, BC, DE, HL, IX, IY, SP };


 // flag positions

 constexpr byte S_FLAG = 0x80;

 constexpr byte Z_FLAG = 0x40;

 constexpr byte Y_FLAG = 0x20;

 constexpr byte H_FLAG = 0x10;

 constexpr byte X_FLAG = 0x08;

 constexpr byte V_FLAG = 0x04;

 constexpr byte P_FLAG = V_FLAG;

 constexpr byte N_FLAG = 0x02;

 constexpr byte C_FLAG = 0x01;


 // flag-register lookup tables

 struct Table {

         byte ZS   [256];

         byte ZSXY [256];

         byte ZSP  [256];

         byte ZSPXY[256];

         byte ZSPH [256];

 };


 constexpr byte ZS0     = Z_FLAG;

 constexpr byte ZSXY0   = Z_FLAG;

 constexpr byte ZSP0    = Z_FLAG | V_FLAG;

 constexpr byte ZSPXY0  = Z_FLAG | V_FLAG;

 constexpr byte ZS255   = S_FLAG;

 constexpr byte ZSXY255 = S_FLAG | X_FLAG | Y_FLAG;


 static constexpr Table initTables()

 {

         Table table = {};


         for (auto i : xrange(256)) {

                 byte zFlag = (i == 0) ? Z_FLAG : 0;

                 byte sFlag = i & S_FLAG;

                 byte xFlag = i & X_FLAG;

                 byte yFlag = i & Y_FLAG;

                 byte vFlag = V_FLAG;

                 for (int v = 128; v != 0; v >>= 1) {

                         if (i & v) vFlag ^= V_FLAG;

                 }

                 table.ZS   [i] = zFlag | sFlag;

                 table.ZSXY [i] = zFlag | sFlag | xFlag | yFlag;

                 table.ZSP  [i] = zFlag | sFlag |                 vFlag;

                 table.ZSPXY[i] = zFlag | sFlag | xFlag | yFlag | vFlag;

                 table.ZSPH [i] = zFlag | sFlag |                 vFlag | H_FLAG;

         }

         assert(table.ZS   [  0] == ZS0);

         assert(table.ZSXY [  0] == ZSXY0);

         assert(table.ZSP  [  0] == ZSP0);

         assert(table.ZSPXY[  0] == ZSPXY0);

         assert(table.ZS   [255] == ZS255);

         assert(table.ZSXY [255] == ZSXY255);


         return table;

 }


 constexpr Table table = initTables();


 // Global variable, because it should be shared between Z80 and R800.

 // It must not be shared between the CPUs of different MSX machines, but

 // the (logical) lifetime of this variable cannot overlap between execution

 // of two MSX machines.

 static word start_pc;


 // conditions

 struct CondC  { bool operator()(byte f) const { return  (f & C_FLAG) != 0; } };

 struct CondNC { bool operator()(byte f) const { return !(f & C_FLAG); } };

 struct CondZ  { bool operator()(byte f) const { return  (f & Z_FLAG) != 0; } };

 struct CondNZ { bool operator()(byte f) const { return !(f & Z_FLAG); } };

 struct CondM  { bool operator()(byte f) const { return  (f & S_FLAG) != 0; } };

 struct CondP  { bool operator()(byte f) const { return !(f & S_FLAG); } };

 struct CondPE { bool operator()(byte f) const { return  (f & V_FLAG) != 0; } };

 struct CondPO { bool operator()(byte f) const { return !(f & V_FLAG); } };

 struct CondTrue { bool operator()(byte /*f*/) const { return true; } };


 template<typename T> CPUCore<T>::CPUCore(

                 MSXMotherBoard& motherboard_, const std::string& name,

                 const BooleanSetting& traceSetting_,

                 TclCallback& diHaltCallback_, EmuTime::param time)

         : CPURegs(T::IS_R800)

         , T(time, motherboard_.getScheduler())

         , motherboard(motherboard_)

         , scheduler(motherboard.getScheduler())

         , interface(nullptr)

         , traceSetting(traceSetting_)

         , diHaltCallback(diHaltCallback_)

         , IRQStatus(motherboard.getDebugger(), name + ".pendingIRQ",

                     "Non-zero if there are pending IRQs (thus CPU would enter "

                     "interrupt routine in EI mode).",

                     0)

         , IRQAccept(motherboard.getDebugger(), name + ".acceptIRQ",

                     "This probe is only useful to set a breakpoint on (the value "

                     "return by read is meaningless). The breakpoint gets triggered "

                     "right after the CPU accepted an IRQ.")

         , freqLocked(

                 motherboard.getCommandController(), tmpStrCat(name, "_freq_locked"),

                 "real (locked) or custom (unlocked) CPU frequency",

                 true)

         , freqValue(

                 motherboard.getCommandController(), tmpStrCat(name, "_freq"),

                 "custom CPU frequency (only valid when unlocked)",

                 T::CLOCK_FREQ, 1000000, 1000000000)

         , freq(T::CLOCK_FREQ)

         , NMIStatus(0)

         , nmiEdge(false)

         , exitLoop(false)

         , tracingEnabled(traceSetting.getBoolean())

         , isCMOS(motherboard.hasToshibaEngine())  // Toshiba MSX-ENGINEs embed a CMOS Z80

 {

         static_assert(!std::is_polymorphic_v<CPUCore<T>>,

                 "keep CPUCore non-virtual to keep PC at offset 0");

         doSetFreq();

         doReset(time);

 }


 template<typename T> void CPUCore<T>::warp(EmuTime::param time)

 {

         assert(T::getTimeFast() <= time);

         T::setTime(time);

 }


 template<typename T> EmuTime::param CPUCore<T>::getCurrentTime() const

 {

         return T::getTime();

 }


 template<typename T> void CPUCore<T>::doReset(EmuTime::param time)

 {

         // AF and SP are 0xFFFF

         // PC, R, IFF1, IFF2, HALT and IM are 0x0

         // all others are random

         setAF(0xFFFF);

         setBC(0xFFFF);

         setDE(0xFFFF);

         setHL(0xFFFF);

         setIX(0xFFFF);

         setIY(0xFFFF);

         setPC(0x0000);

         setSP(0xFFFF);

         setAF2(0xFFFF);

         setBC2(0xFFFF);

         setDE2(0xFFFF);

         setHL2(0xFFFF);

         setIFF1(false);

         setIFF2(false);

         setHALT(false);

         setExtHALT(false);

         setIM(0);

         setI(0x00);

         setR(0x00);

         T::setMemPtr(0xFFFF);

         clearPrevious();


         // We expect this assert to be valid

         //   assert(T::getTimeFast() <= time); // time shouldn't go backwards

         // But it's disabled for the following reason:

         //   'motion' (IRC nickname) managed to create a replay file that

         //   contains a reset command that falls in the middle of a Z80

         //   instruction. Replayed commands go via the Scheduler, and are

         //   (typically) executed right after a complete CPU instruction. So

         //   the CPU is (slightly) ahead in time of the about to be executed

         //   reset command.

         //   Normally this situation should never occur: console commands,

         //   hotkeys, commands over clicomm, ... are all handled via the global

         //   event mechanism. Such global events are scheduled between CPU

         //   instructions, so also in a replay they should fall between CPU

         //   instructions.

         //   However if for some reason the timing of the emulation changed

         //   (improved emulation accuracy or a bug so that emulation isn't

         //   deterministic or the replay file was edited, ...), then the above

         //   reasoning no longer holds and the assert can trigger.

         // We need to be robust against loading older replays (when emulation

         // timing has changed). So in that respect disabling the assert is

         // good. Though in the example above (motion's replay) it's not clear

         // whether the assert is really triggered by mixing an old replay

         // with a newer openMSX version. In any case so far we haven't been

         // able to reproduce this assert by recording and replaying using a

         // single openMSX version.

         T::setTime(time);


         assert(NMIStatus == 0); // other devices must reset their NMI source

         assert(IRQStatus == 0); // other devices must reset their IRQ source

 }


 // I believe the following two methods are thread safe even without any

 // locking. The worst that can happen is that we occasionally needlessly

 // exit the CPU loop, but that's harmless

 //  TODO thread issues are always tricky, can someone confirm this really

 //       is thread safe

 template<typename T> void CPUCore<T>::exitCPULoopAsync()

 {

         // can get called from non-main threads

         exitLoop = true;

 }

 template<typename T> void CPUCore<T>::exitCPULoopSync()

 {

         assert(Thread::isMainThread());

         exitLoop = true;

         T::disableLimit();

 }

 template<typename T> inline bool CPUCore<T>::needExitCPULoop()

 {

         // always executed in main thread

         if (unlikely(exitLoop)) {

                 // Note: The test-and-set is _not_ atomic! But that's fine.

                 //   An atomic implementation is trivial (see below), but

                 //   this version (at least on x86) avoids the more expensive

                 //   instructions on the likely path.

                 exitLoop = false;

                 return true;

         }

         return false;


         // Alternative implementation:

         //  atomically set to false and return the old value

         //return exitLoop.exchange(false);

 }


 template<typename T> void CPUCore<T>::setSlowInstructions()

 {

         slowInstructions = 2;

         T::disableLimit();

 }


 template<typename T> void CPUCore<T>::raiseIRQ()

 {

         assert(IRQStatus >= 0);

         if (IRQStatus == 0) {

                 setSlowInstructions();

         }

         IRQStatus = IRQStatus + 1;

 }


 template<typename T> void CPUCore<T>::lowerIRQ()

 {

         IRQStatus = IRQStatus - 1;

         assert(IRQStatus >= 0);

 }


 template<typename T> void CPUCore<T>::raiseNMI()

 {

         assert(NMIStatus >= 0);

         if (NMIStatus == 0) {

                 nmiEdge = true;

                 setSlowInstructions();

         }

         NMIStatus++;

 }


 template<typename T> void CPUCore<T>::lowerNMI()

 {

         NMIStatus--;

         assert(NMIStatus >= 0);

 }


 template<typename T> bool CPUCore<T>::isM1Cycle(unsigned address) const

 {

         // This method should only be called from within a MSXDevice::readMem()

         // method. It can be used to check whether the current read action has

         // the M1 pin active. The 'address' parameter that is give to readMem()

         // should be passed (unchanged) to this method.

         //

         // This simple implementation works because the rest of the CPUCore

         // code is careful to only update the PC register on M1 cycles. In

         // practice that means that the PC is (only) updated at the very end of

         // every instruction, even if is a multi-byte instruction. Or for

         // prefix-instructions the PC is also updated after the prefix is

         // fetched (because such instructions activate M1 twice).

         return address == getPC();

 }


 template<typename T> void CPUCore<T>::wait(EmuTime::param time)

 {

         assert(time >= getCurrentTime());

         scheduler.schedule(time);

         T::advanceTime(time);

 }


 template<typename T> EmuTime CPUCore<T>::waitCycles(EmuTime::param time, unsigned cycles)

 {

         T::add(cycles);

         EmuTime time2 = T::calcTime(time, cycles);

         // note: time2 is not necessarily equal to T::getTime() because of the

         // way how WRITE_PORT() is implemented.

         scheduler.schedule(time2);

         return time2;

 }


 template<typename T> void CPUCore<T>::setNextSyncPoint(EmuTime::param time)

 {

         T::setLimit(time);

 }


 static constexpr char toHex(byte x)

 {

         return (x < 10) ? (x + '0') : (x - 10 + 'A');

 }

 static constexpr void toHex(byte x, char* buf)

 {

         buf[0] = toHex(x / 16);

         buf[1] = toHex(x & 15);

 }


 template<typename T> void CPUCore<T>::disasmCommand(

         Interpreter& interp, span<const TclObject> tokens, TclObject& result) const

 {

         word address = (tokens.size() < 3) ? getPC() : tokens[2].getInt(interp);

         byte outBuf[4];

         std::string dasmOutput;

         unsigned len = dasm(*interface, address, outBuf, dasmOutput,

                        T::getTimeFast());

         result.addListElement(dasmOutput);

         char tmp[3]; tmp[2] = 0;

         for (auto i : xrange(len)) {

                 toHex(outBuf[i], tmp);

                 result.addListElement(tmp);

         }

 }


 template<typename T> void CPUCore<T>::update(const Setting& setting) noexcept

 {

         if (&setting == &freqLocked) {

                 doSetFreq();

         } else if (&setting == &freqValue) {

                 doSetFreq();

         } else if (&setting == &traceSetting) {

                 tracingEnabled = traceSetting.getBoolean();

         }

 }


 template<typename T> void CPUCore<T>::setFreq(unsigned freq_)

 {

         freq = freq_;

         doSetFreq();

 }


 template<typename T> void CPUCore<T>::doSetFreq()

 {

         if (freqLocked.getBoolean()) {

                 // locked, use value set via setFreq()

                 T::setFreq(freq);

         } else {

                 // unlocked, use value set by user

                 T::setFreq(freqValue.getInt());

         }

 }


 template<typename T> inline byte CPUCore<T>::READ_PORT(unsigned port, unsigned cc)

 {

         EmuTime time = T::getTimeFast(cc);

         scheduler.schedule(time);

         byte result = interface->readIO(port, time);

         // note: no forced page-break after IO

         return result;

 }


 template<typename T> inline void CPUCore<T>::WRITE_PORT(unsigned port, byte value, unsigned cc)

 {

         EmuTime time = T::getTimeFast(cc);

         scheduler.schedule(time);

         interface->writeIO(port, value, time);

         // note: no forced page-break after IO

 }


 template<typename T> template<bool PRE_PB, bool POST_PB>

 NEVER_INLINE byte CPUCore<T>::RDMEMslow(unsigned address, unsigned cc)

 {

         interface->tick(CacheLineCounters::NonCachedRead);

         // not cached

         unsigned high = address >> CacheLine::BITS;

         if (readCacheLine[high] == nullptr) {

                 // try to cache now (not a valid entry, and not yet tried)

                 unsigned addrBase = address & CacheLine::HIGH;

                 if (const byte* line = interface->getReadCacheLine(addrBase)) {

                         // cached ok

                         T::template PRE_MEM<PRE_PB, POST_PB>(address);

                         T::template POST_MEM<       POST_PB>(address);

                         readCacheLine[high] = line - addrBase;

                         return readCacheLine[high][address];

                 }

         }

         // uncacheable

         readCacheLine[high] = reinterpret_cast<const byte*>(1);

         T::template PRE_MEM<PRE_PB, POST_PB>(address);

         EmuTime time = T::getTimeFast(cc);

         scheduler.schedule(time);

         byte result = interface->readMem(address, time);

         T::template POST_MEM<POST_PB>(address);

         return result;

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE byte CPUCore<T>::RDMEM_impl2(unsigned address, unsigned cc)

 {

         const byte* line = readCacheLine[address >> CacheLine::BITS];

         if (likely(uintptr_t(line) > 1)) {

                 // cached, fast path

                 T::template PRE_MEM<PRE_PB, POST_PB>(address);

                 T::template POST_MEM<       POST_PB>(address);

                 return line[address];

         } else {

                 return RDMEMslow<PRE_PB, POST_PB>(address, cc); // not inlined

         }

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE byte CPUCore<T>::RDMEM_impl(unsigned address, unsigned cc)

 {

         constexpr bool PRE  = T::template Normalize<PRE_PB >::value;

         constexpr bool POST = T::template Normalize<POST_PB>::value;

         return RDMEM_impl2<PRE, POST>(address, cc);

 }

 template<typename T> template<unsigned PC_OFFSET> ALWAYS_INLINE byte CPUCore<T>::RDMEM_OPCODE(unsigned cc)

 {

         // Real Z80 would update the PC register now. In this implementation

         // we've chosen to instead update PC only once at the end of the

         // instruction. (Of course we made sure this difference is not

         // noticeable by the program).

         //

         // See the comments in isM1Cycle() for the motivation for this

         // deviation. Apart from that functional aspect it also turns out to be

         // faster to only update PC once per instruction instead of after each

         // fetch.

         unsigned address = (getPC() + PC_OFFSET) & 0xFFFF;

         return RDMEM_impl<false, false>(address, cc);

 }

 template<typename T> ALWAYS_INLINE byte CPUCore<T>::RDMEM(unsigned address, unsigned cc)

 {

         return RDMEM_impl<true, true>(address, cc);

 }


 template<typename T> template<bool PRE_PB, bool POST_PB>

 NEVER_INLINE unsigned CPUCore<T>::RD_WORD_slow(unsigned address, unsigned cc)

 {

         unsigned res = RDMEM_impl<PRE_PB,  false>(address, cc);

         res         += RDMEM_impl<false, POST_PB>((address + 1) & 0xFFFF, cc + T::CC_RDMEM) << 8;

         return res;

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE unsigned CPUCore<T>::RD_WORD_impl2(unsigned address, unsigned cc)

 {

         const byte* line = readCacheLine[address >> CacheLine::BITS];

         if (likely(((address & CacheLine::LOW) != CacheLine::LOW) && (uintptr_t(line) > 1))) {

                 // fast path: cached and two bytes in same cache line

                 T::template PRE_WORD<PRE_PB, POST_PB>(address);

                 T::template POST_WORD<       POST_PB>(address);

                 return Endian::read_UA_L16(&line[address]);

         } else {

                 // slow path, not inline

                 return RD_WORD_slow<PRE_PB, POST_PB>(address, cc);

         }

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE unsigned CPUCore<T>::RD_WORD_impl(unsigned address, unsigned cc)

 {

         constexpr bool PRE  = T::template Normalize<PRE_PB >::value;

         constexpr bool POST = T::template Normalize<POST_PB>::value;

         return RD_WORD_impl2<PRE, POST>(address, cc);

 }

 template<typename T> template<unsigned PC_OFFSET> ALWAYS_INLINE unsigned CPUCore<T>::RD_WORD_PC(unsigned cc)

 {

         unsigned addr = (getPC() + PC_OFFSET) & 0xFFFF;

         return RD_WORD_impl<false, false>(addr, cc);

 }

 template<typename T> ALWAYS_INLINE unsigned CPUCore<T>::RD_WORD(

         unsigned address, unsigned cc)

 {

         return RD_WORD_impl<true, true>(address, cc);

 }


 template<typename T> template<bool PRE_PB, bool POST_PB>

 NEVER_INLINE void CPUCore<T>::WRMEMslow(unsigned address, byte value, unsigned cc)

 {

         interface->tick(CacheLineCounters::NonCachedWrite);

         // not cached

         unsigned high = address >> CacheLine::BITS;

         if (writeCacheLine[high] == nullptr) {

                 // try to cache now

                 unsigned addrBase = address & CacheLine::HIGH;

                 if (byte* line = interface->getWriteCacheLine(addrBase)) {

                         // cached ok

                         T::template PRE_MEM<PRE_PB, POST_PB>(address);

                         T::template POST_MEM<       POST_PB>(address);

                         writeCacheLine[high] = line - addrBase;

                         writeCacheLine[high][address] = value;

                         return;

                 }

         }

         // uncacheable

         writeCacheLine[high] = reinterpret_cast<byte*>(1);

         T::template PRE_MEM<PRE_PB, POST_PB>(address);

         EmuTime time = T::getTimeFast(cc);

         scheduler.schedule(time);

         interface->writeMem(address, value, time);

         T::template POST_MEM<POST_PB>(address);

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE void CPUCore<T>::WRMEM_impl2(

         unsigned address, byte value, unsigned cc)

 {

         byte* line = writeCacheLine[address >> CacheLine::BITS];

         if (likely(uintptr_t(line) > 1)) {

                 // cached, fast path

                 T::template PRE_MEM<PRE_PB, POST_PB>(address);

                 T::template POST_MEM<       POST_PB>(address);

                 line[address] = value;

         } else {

                 WRMEMslow<PRE_PB, POST_PB>(address, value, cc); // not inlined

         }

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE void CPUCore<T>::WRMEM_impl(

         unsigned address, byte value, unsigned cc)

 {

         constexpr bool PRE  = T::template Normalize<PRE_PB >::value;

         constexpr bool POST = T::template Normalize<POST_PB>::value;

         WRMEM_impl2<PRE, POST>(address, value, cc);

 }

 template<typename T> ALWAYS_INLINE void CPUCore<T>::WRMEM(

         unsigned address, byte value, unsigned cc)

 {

         WRMEM_impl<true, true>(address, value, cc);

 }


 template<typename T> NEVER_INLINE void CPUCore<T>::WR_WORD_slow(

         unsigned address, unsigned value, unsigned cc)

 {

         WRMEM_impl<true, false>( address,               value & 255, cc);

         WRMEM_impl<false, true>((address + 1) & 0xFFFF, value >> 8,  cc + T::CC_WRMEM);

 }

 template<typename T> ALWAYS_INLINE void CPUCore<T>::WR_WORD(

         unsigned address, unsigned value, unsigned cc)

 {

         byte* line = writeCacheLine[address >> CacheLine::BITS];

         if (likely(((address & CacheLine::LOW) != CacheLine::LOW) && (uintptr_t(line) > 1))) {

                 // fast path: cached and two bytes in same cache line

                 T::template PRE_WORD<true, true>(address);

                 T::template POST_WORD<     true>(address);

                 Endian::write_UA_L16(&line[address], value);

         } else {

                 // slow path, not inline

                 WR_WORD_slow(address, value, cc);

         }

 }


 // same as WR_WORD, but writes high byte first

 template<typename T> template<bool PRE_PB, bool POST_PB>

 NEVER_INLINE void CPUCore<T>::WR_WORD_rev_slow(

         unsigned address, unsigned value, unsigned cc)

 {

         WRMEM_impl<PRE_PB,  false>((address + 1) & 0xFFFF, value >> 8,  cc);

         WRMEM_impl<false, POST_PB>( address,               value & 255, cc + T::CC_WRMEM);

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE void CPUCore<T>::WR_WORD_rev2(

         unsigned address, unsigned value, unsigned cc)

 {

         byte* line = writeCacheLine[address >> CacheLine::BITS];

         if (likely(((address & CacheLine::LOW) != CacheLine::LOW) && (uintptr_t(line) > 1))) {

                 // fast path: cached and two bytes in same cache line

                 T::template PRE_WORD<PRE_PB, POST_PB>(address);

                 T::template POST_WORD<       POST_PB>(address);

                 Endian::write_UA_L16(&line[address], value);

         } else {

                 // slow path, not inline

                 WR_WORD_rev_slow<PRE_PB, POST_PB>(address, value, cc);

         }

 }

 template<typename T> template<bool PRE_PB, bool POST_PB>

 ALWAYS_INLINE void CPUCore<T>::WR_WORD_rev(

         unsigned address, unsigned value, unsigned cc)

 {

         constexpr bool PRE  = T::template Normalize<PRE_PB >::value;

         constexpr bool POST = T::template Normalize<POST_PB>::value;

         WR_WORD_rev2<PRE, POST>(address, value, cc);

 }


 // NMI interrupt

 template<typename T> inline void CPUCore<T>::nmi()

 {

         incR(1);

         setHALT(false);

         setIFF1(false);

         PUSH<T::EE_NMI_1>(getPC());

         setPC(0x0066);

         T::add(T::CC_NMI);

 }


 // IM0 interrupt

 template<typename T> inline void CPUCore<T>::irq0()

 {

         // TODO current implementation only works for 1-byte instructions

         //      ok for MSX

         assert(interface->readIRQVector() == 0xFF);

         incR(1);

         setHALT(false);

         setIFF1(false);

         setIFF2(false);

         PUSH<T::EE_IRQ0_1>(getPC());

         setPC(0x0038);

         T::setMemPtr(getPC());

         T::add(T::CC_IRQ0);

 }


 // IM1 interrupt

 template<typename T> inline void CPUCore<T>::irq1()

 {

         incR(1);

         setHALT(false);

         setIFF1(false);

         setIFF2(false);

         PUSH<T::EE_IRQ1_1>(getPC());

         setPC(0x0038);

         T::setMemPtr(getPC());

         T::add(T::CC_IRQ1);

 }


 // IM2 interrupt

 template<typename T> inline void CPUCore<T>::irq2()

 {

         incR(1);

         setHALT(false);

         setIFF1(false);

         setIFF2(false);

         PUSH<T::EE_IRQ2_1>(getPC());

         unsigned x = interface->readIRQVector() | (getI() << 8);

         setPC(RD_WORD(x, T::CC_IRQ2_2));

         T::setMemPtr(getPC());

         T::add(T::CC_IRQ2);

 }


 template<typename T>

 void CPUCore<T>::executeInstructions()

 {

         checkNoCurrentFlags();

 #ifdef USE_COMPUTED_GOTO

         // Addresses of all main-opcode routines,

         // Note that 40/49/53/5B/64/6D/7F is replaced by 00 (ld r,r == nop)

         static void* opcodeTable[256] = {

                 &&op00, &&op01, &&op02, &&op03, &&op04, &&op05, &&op06, &&op07,

                 &&op08, &&op09, &&op0A, &&op0B, &&op0C, &&op0D, &&op0E, &&op0F,

                 &&op10, &&op11, &&op12, &&op13, &&op14, &&op15, &&op16, &&op17,

                 &&op18, &&op19, &&op1A, &&op1B, &&op1C, &&op1D, &&op1E, &&op1F,

                 &&op20, &&op21, &&op22, &&op23, &&op24, &&op25, &&op26, &&op27,

                 &&op28, &&op29, &&op2A, &&op2B, &&op2C, &&op2D, &&op2E, &&op2F,

                 &&op30, &&op31, &&op32, &&op33, &&op34, &&op35, &&op36, &&op37,

                 &&op38, &&op39, &&op3A, &&op3B, &&op3C, &&op3D, &&op3E, &&op3F,

                 &&op00, &&op41, &&op42, &&op43, &&op44, &&op45, &&op46, &&op47,

                 &&op48, &&op00, &&op4A, &&op4B, &&op4C, &&op4D, &&op4E, &&op4F,

                 &&op50, &&op51, &&op00, &&op53, &&op54, &&op55, &&op56, &&op57,

                 &&op58, &&op59, &&op5A, &&op00, &&op5C, &&op5D, &&op5E, &&op5F,

                 &&op60, &&op61, &&op62, &&op63, &&op00, &&op65, &&op66, &&op67,

                 &&op68, &&op69, &&op6A, &&op6B, &&op6C, &&op00, &&op6E, &&op6F,

                 &&op70, &&op71, &&op72, &&op73, &&op74, &&op75, &&op76, &&op77,

                 &&op78, &&op79, &&op7A, &&op7B, &&op7C, &&op7D, &&op7E, &&op00,

                 &&op80, &&op81, &&op82, &&op83, &&op84, &&op85, &&op86, &&op87,

                 &&op88, &&op89, &&op8A, &&op8B, &&op8C, &&op8D, &&op8E, &&op8F,

                 &&op90, &&op91, &&op92, &&op93, &&op94, &&op95, &&op96, &&op97,

                 &&op98, &&op99, &&op9A, &&op9B, &&op9C, &&op9D, &&op9E, &&op9F,

                 &&opA0, &&opA1, &&opA2, &&opA3, &&opA4, &&opA5, &&opA6, &&opA7,

                 &&opA8, &&opA9, &&opAA, &&opAB, &&opAC, &&opAD, &&opAE, &&opAF,

                 &&opB0, &&opB1, &&opB2, &&opB3, &&opB4, &&opB5, &&opB6, &&opB7,

                 &&opB8, &&opB9, &&opBA, &&opBB, &&opBC, &&opBD, &&opBE, &&opBF,

                 &&opC0, &&opC1, &&opC2, &&opC3, &&opC4, &&opC5, &&opC6, &&opC7,

                 &&opC8, &&opC9, &&opCA, &&opCB, &&opCC, &&opCD, &&opCE, &&opCF,

                 &&opD0, &&opD1, &&opD2, &&opD3, &&opD4, &&opD5, &&opD6, &&opD7,

                 &&opD8, &&opD9, &&opDA, &&opDB, &&opDC, &&opDD, &&opDE, &&opDF,

                 &&opE0, &&opE1, &&opE2, &&opE3, &&opE4, &&opE5, &&opE6, &&opE7,

                 &&opE8, &&opE9, &&opEA, &&opEB, &&opEC, &&opED, &&opEE, &&opEF,

                 &&opF0, &&opF1, &&opF2, &&opF3, &&opF4, &&opF5, &&opF6, &&opF7,

                 &&opF8, &&opF9, &&opFA, &&opFB, &&opFC, &&opFD, &&opFE, &&opFF,

         };


 // Check T::limitReached(). If it's OK to continue,

 // fetch and execute next instruction.

 #define NEXT \

         setPC(getPC() + ii.length); \

         T::add(ii.cycles); \

         T::R800Refresh(*this); \

         if (likely(!T::limitReached())) { \

                 incR(1); \

                 unsigned address = getPC(); \

                 const byte* line = readCacheLine[address >> CacheLine::BITS]; \

                 if (likely(uintptr_t(line) > 1)) { \

                         T::template PRE_MEM<false, false>(address); \

                         T::template POST_MEM<      false>(address); \

                         byte op = line[address]; \

                         goto *(opcodeTable[op]); \

                 } else { \

                         goto fetchSlow; \

                 } \

         } \

         return;


 // After some instructions we must always exit the CPU loop (ei, halt, retn)

 #define NEXT_STOP \

         setPC(getPC() + ii.length); \

         T::add(ii.cycles); \

         T::R800Refresh(*this); \

         assert(T::limitReached()); \

         return;


 #define NEXT_EI \

         setPC(getPC() + ii.length); \

         T::add(ii.cycles); \

         /* !! NO T::R800Refresh(*this); !! */ \

         assert(T::limitReached()); \

         return;


 // Define a label (instead of case in a switch statement)

 #define CASE(X) op##X:


 #else // USE_COMPUTED_GOTO


 #define NEXT \

         setPC(getPC() + ii.length); \

         T::add(ii.cycles); \

         T::R800Refresh(*this); \

         if (likely(!T::limitReached())) { \

                 goto start; \

         } \

         return;


 #define NEXT_STOP \

         setPC(getPC() + ii.length); \

         T::add(ii.cycles); \

         T::R800Refresh(*this); \

         assert(T::limitReached()); \

         return;


 #define NEXT_EI \

         setPC(getPC() + ii.length); \

         T::add(ii.cycles); \

         /* !! NO T::R800Refresh(*this); !! */ \

         assert(T::limitReached()); \

         return;


 #define CASE(X) case 0x##X:


 #endif // USE_COMPUTED_GOTO


 #ifndef USE_COMPUTED_GOTO

 start:

 #endif

         unsigned ixy; // for dd_cb/fd_cb

         byte opcodeMain = RDMEM_OPCODE<0>(T::CC_MAIN);

         incR(1);

 #ifdef USE_COMPUTED_GOTO

         goto *(opcodeTable[opcodeMain]);


 fetchSlow: {

         unsigned address = getPC();

         byte opcodeSlow = RDMEMslow<false, false>(address, T::CC_MAIN);

         goto *(opcodeTable[opcodeSlow]);

 }

 #endif


 #ifndef USE_COMPUTED_GOTO

 switchopcode:

         switch (opcodeMain) {

 CASE(40) // ld b,b

 CASE(49) // ld c,c

 CASE(52) // ld d,d

 CASE(5B) // ld e,e

 CASE(64) // ld h,h

 CASE(6D) // ld l,l

 CASE(7F) // ld a,a

 #endif

 CASE(00) { II ii = nop(); NEXT; }

 CASE(07) { II ii = rlca(); NEXT; }

 CASE(0F) { II ii = rrca(); NEXT; }

 CASE(17) { II ii = rla();  NEXT; }

 CASE(1F) { II ii = rra();  NEXT; }

 CASE(08) { II ii = ex_af_af(); NEXT; }

 CASE(27) { II ii = daa(); NEXT; }

 CASE(2F) { II ii = cpl(); NEXT; }

 CASE(37) { II ii = scf(); NEXT; }

 CASE(3F) { II ii = ccf(); NEXT; }

 CASE(20) { II ii = jr(CondNZ()); NEXT; }

 CASE(28) { II ii = jr(CondZ ()); NEXT; }

 CASE(30) { II ii = jr(CondNC()); NEXT; }

 CASE(38) { II ii = jr(CondC ()); NEXT; }

 CASE(18) { II ii = jr(CondTrue()); NEXT; }

 CASE(10) { II ii = djnz(); NEXT; }

 CASE(32) { II ii = ld_xbyte_a(); NEXT; }

 CASE(3A) { II ii = ld_a_xbyte(); NEXT; }

 CASE(22) { II ii = ld_xword_SS<HL,0>(); NEXT; }

 CASE(2A) { II ii = ld_SS_xword<HL,0>(); NEXT; }

 CASE(02) { II ii = ld_SS_a<BC>(); NEXT; }

 CASE(12) { II ii = ld_SS_a<DE>(); NEXT; }

 CASE(1A) { II ii = ld_a_SS<DE>(); NEXT; }

 CASE(0A) { II ii = ld_a_SS<BC>(); NEXT; }

 CASE(03) { II ii = inc_SS<BC,0>(); NEXT; }

 CASE(13) { II ii = inc_SS<DE,0>(); NEXT; }

 CASE(23) { II ii = inc_SS<HL,0>(); NEXT; }

 CASE(33) { II ii = inc_SS<SP,0>(); NEXT; }

 CASE(0B) { II ii = dec_SS<BC,0>(); NEXT; }

 CASE(1B) { II ii = dec_SS<DE,0>(); NEXT; }

 CASE(2B) { II ii = dec_SS<HL,0>(); NEXT; }

 CASE(3B) { II ii = dec_SS<SP,0>(); NEXT; }

 CASE(09) { II ii = add_SS_TT<HL,BC,0>(); NEXT; }

 CASE(19) { II ii = add_SS_TT<HL,DE,0>(); NEXT; }

 CASE(29) { II ii = add_SS_SS<HL   ,0>(); NEXT; }

 CASE(39) { II ii = add_SS_TT<HL,SP,0>(); NEXT; }

 CASE(01) { II ii = ld_SS_word<BC,0>(); NEXT; }

 CASE(11) { II ii = ld_SS_word<DE,0>(); NEXT; }

 CASE(21) { II ii = ld_SS_word<HL,0>(); NEXT; }

 CASE(31) { II ii = ld_SS_word<SP,0>(); NEXT; }

 CASE(04) { II ii = inc_R<B,0>(); NEXT; }

 CASE(0C) { II ii = inc_R<C,0>(); NEXT; }

 CASE(14) { II ii = inc_R<D,0>(); NEXT; }

 CASE(1C) { II ii = inc_R<E,0>(); NEXT; }

 CASE(24) { II ii = inc_R<H,0>(); NEXT; }

 CASE(2C) { II ii = inc_R<L,0>(); NEXT; }

 CASE(3C) { II ii = inc_R<A,0>(); NEXT; }

 CASE(34) { II ii = inc_xhl();  NEXT; }

 CASE(05) { II ii = dec_R<B,0>(); NEXT; }

 CASE(0D) { II ii = dec_R<C,0>(); NEXT; }

 CASE(15) { II ii = dec_R<D,0>(); NEXT; }

 CASE(1D) { II ii = dec_R<E,0>(); NEXT; }

 CASE(25) { II ii = dec_R<H,0>(); NEXT; }

 CASE(2D) { II ii = dec_R<L,0>(); NEXT; }

 CASE(3D) { II ii = dec_R<A,0>(); NEXT; }

 CASE(35) { II ii = dec_xhl();  NEXT; }

 CASE(06) { II ii = ld_R_byte<B,0>(); NEXT; }

 CASE(0E) { II ii = ld_R_byte<C,0>(); NEXT; }

 CASE(16) { II ii = ld_R_byte<D,0>(); NEXT; }

 CASE(1E) { II ii = ld_R_byte<E,0>(); NEXT; }

 CASE(26) { II ii = ld_R_byte<H,0>(); NEXT; }

 CASE(2E) { II ii = ld_R_byte<L,0>(); NEXT; }

 CASE(3E) { II ii = ld_R_byte<A,0>(); NEXT; }

 CASE(36) { II ii = ld_xhl_byte();  NEXT; }


 CASE(41) { II ii = ld_R_R<B,C,0>(); NEXT; }

 CASE(42) { II ii = ld_R_R<B,D,0>(); NEXT; }

 CASE(43) { II ii = ld_R_R<B,E,0>(); NEXT; }

 CASE(44) { II ii = ld_R_R<B,H,0>(); NEXT; }

 CASE(45) { II ii = ld_R_R<B,L,0>(); NEXT; }

 CASE(47) { II ii = ld_R_R<B,A,0>(); NEXT; }

 CASE(48) { II ii = ld_R_R<C,B,0>(); NEXT; }

 CASE(4A) { II ii = ld_R_R<C,D,0>(); NEXT; }

 CASE(4B) { II ii = ld_R_R<C,E,0>(); NEXT; }

 CASE(4C) { II ii = ld_R_R<C,H,0>(); NEXT; }

 CASE(4D) { II ii = ld_R_R<C,L,0>(); NEXT; }

 CASE(4F) { II ii = ld_R_R<C,A,0>(); NEXT; }

 CASE(50) { II ii = ld_R_R<D,B,0>(); NEXT; }

 CASE(51) { II ii = ld_R_R<D,C,0>(); NEXT; }

 CASE(53) { II ii = ld_R_R<D,E,0>(); NEXT; }

 CASE(54) { II ii = ld_R_R<D,H,0>(); NEXT; }

 CASE(55) { II ii = ld_R_R<D,L,0>(); NEXT; }

 CASE(57) { II ii = ld_R_R<D,A,0>(); NEXT; }

 CASE(58) { II ii = ld_R_R<E,B,0>(); NEXT; }

 CASE(59) { II ii = ld_R_R<E,C,0>(); NEXT; }

 CASE(5A) { II ii = ld_R_R<E,D,0>(); NEXT; }

 CASE(5C) { II ii = ld_R_R<E,H,0>(); NEXT; }

 CASE(5D) { II ii = ld_R_R<E,L,0>(); NEXT; }

 CASE(5F) { II ii = ld_R_R<E,A,0>(); NEXT; }

 CASE(60) { II ii = ld_R_R<H,B,0>(); NEXT; }

 CASE(61) { II ii = ld_R_R<H,C,0>(); NEXT; }

 CASE(62) { II ii = ld_R_R<H,D,0>(); NEXT; }

 CASE(63) { II ii = ld_R_R<H,E,0>(); NEXT; }

 CASE(65) { II ii = ld_R_R<H,L,0>(); NEXT; }

 CASE(67) { II ii = ld_R_R<H,A,0>(); NEXT; }

 CASE(68) { II ii = ld_R_R<L,B,0>(); NEXT; }

 CASE(69) { II ii = ld_R_R<L,C,0>(); NEXT; }

 CASE(6A) { II ii = ld_R_R<L,D,0>(); NEXT; }

 CASE(6B) { II ii = ld_R_R<L,E,0>(); NEXT; }

 CASE(6C) { II ii = ld_R_R<L,H,0>(); NEXT; }

 CASE(6F) { II ii = ld_R_R<L,A,0>(); NEXT; }

 CASE(78) { II ii = ld_R_R<A,B,0>(); NEXT; }

 CASE(79) { II ii = ld_R_R<A,C,0>(); NEXT; }

 CASE(7A) { II ii = ld_R_R<A,D,0>(); NEXT; }

 CASE(7B) { II ii = ld_R_R<A,E,0>(); NEXT; }

 CASE(7C) { II ii = ld_R_R<A,H,0>(); NEXT; }

 CASE(7D) { II ii = ld_R_R<A,L,0>(); NEXT; }

 CASE(70) { II ii = ld_xhl_R<B>(); NEXT; }

 CASE(71) { II ii = ld_xhl_R<C>(); NEXT; }

 CASE(72) { II ii = ld_xhl_R<D>(); NEXT; }

 CASE(73) { II ii = ld_xhl_R<E>(); NEXT; }

 CASE(74) { II ii = ld_xhl_R<H>(); NEXT; }

 CASE(75) { II ii = ld_xhl_R<L>(); NEXT; }

 CASE(77) { II ii = ld_xhl_R<A>(); NEXT; }

 CASE(46) { II ii = ld_R_xhl<B>(); NEXT; }

 CASE(4E) { II ii = ld_R_xhl<C>(); NEXT; }

 CASE(56) { II ii = ld_R_xhl<D>(); NEXT; }

 CASE(5E) { II ii = ld_R_xhl<E>(); NEXT; }

 CASE(66) { II ii = ld_R_xhl<H>(); NEXT; }

 CASE(6E) { II ii = ld_R_xhl<L>(); NEXT; }

 CASE(7E) { II ii = ld_R_xhl<A>(); NEXT; }

 CASE(76) { II ii = halt(); NEXT_STOP; }


 CASE(80) { II ii = add_a_R<B,0>(); NEXT; }

 CASE(81) { II ii = add_a_R<C,0>(); NEXT; }

 CASE(82) { II ii = add_a_R<D,0>(); NEXT; }

 CASE(83) { II ii = add_a_R<E,0>(); NEXT; }

 CASE(84) { II ii = add_a_R<H,0>(); NEXT; }

 CASE(85) { II ii = add_a_R<L,0>(); NEXT; }

 CASE(86) { II ii = add_a_xhl();   NEXT; }

 CASE(87) { II ii = add_a_a();     NEXT; }

 CASE(88) { II ii = adc_a_R<B,0>(); NEXT; }

 CASE(89) { II ii = adc_a_R<C,0>(); NEXT; }

 CASE(8A) { II ii = adc_a_R<D,0>(); NEXT; }

 CASE(8B) { II ii = adc_a_R<E,0>(); NEXT; }

 CASE(8C) { II ii = adc_a_R<H,0>(); NEXT; }

 CASE(8D) { II ii = adc_a_R<L,0>(); NEXT; }

 CASE(8E) { II ii = adc_a_xhl();   NEXT; }

 CASE(8F) { II ii = adc_a_a();     NEXT; }

 CASE(90) { II ii = sub_R<B,0>(); NEXT; }

 CASE(91) { II ii = sub_R<C,0>(); NEXT; }

 CASE(92) { II ii = sub_R<D,0>(); NEXT; }

 CASE(93) { II ii = sub_R<E,0>(); NEXT; }

 CASE(94) { II ii = sub_R<H,0>(); NEXT; }

 CASE(95) { II ii = sub_R<L,0>(); NEXT; }

 CASE(96) { II ii = sub_xhl();   NEXT; }

 CASE(97) { II ii = sub_a();     NEXT; }

 CASE(98) { II ii = sbc_a_R<B,0>(); NEXT; }

 CASE(99) { II ii = sbc_a_R<C,0>(); NEXT; }

 CASE(9A) { II ii = sbc_a_R<D,0>(); NEXT; }

 CASE(9B) { II ii = sbc_a_R<E,0>(); NEXT; }

 CASE(9C) { II ii = sbc_a_R<H,0>(); NEXT; }

 CASE(9D) { II ii = sbc_a_R<L,0>(); NEXT; }

 CASE(9E) { II ii = sbc_a_xhl();   NEXT; }

 CASE(9F) { II ii = sbc_a_a();     NEXT; }

 CASE(A0) { II ii = and_R<B,0>(); NEXT; }

 CASE(A1) { II ii = and_R<C,0>(); NEXT; }

 CASE(A2) { II ii = and_R<D,0>(); NEXT; }

 CASE(A3) { II ii = and_R<E,0>(); NEXT; }

 CASE(A4) { II ii = and_R<H,0>(); NEXT; }

 CASE(A5) { II ii = and_R<L,0>(); NEXT; }

 CASE(A6) { II ii = and_xhl();   NEXT; }

 CASE(A7) { II ii = and_a();     NEXT; }

 CASE(A8) { II ii = xor_R<B,0>(); NEXT; }

 CASE(A9) { II ii = xor_R<C,0>(); NEXT; }

 CASE(AA) { II ii = xor_R<D,0>(); NEXT; }

 CASE(AB) { II ii = xor_R<E,0>(); NEXT; }

 CASE(AC) { II ii = xor_R<H,0>(); NEXT; }

 CASE(AD) { II ii = xor_R<L,0>(); NEXT; }

 CASE(AE) { II ii = xor_xhl();   NEXT; }

 CASE(AF) { II ii = xor_a();     NEXT; }

 CASE(B0) { II ii = or_R<B,0>(); NEXT; }

 CASE(B1) { II ii = or_R<C,0>(); NEXT; }

 CASE(B2) { II ii = or_R<D,0>(); NEXT; }

 CASE(B3) { II ii = or_R<E,0>(); NEXT; }

 CASE(B4) { II ii = or_R<H,0>(); NEXT; }

 CASE(B5) { II ii = or_R<L,0>(); NEXT; }

 CASE(B6) { II ii = or_xhl();   NEXT; }

 CASE(B7) { II ii = or_a();     NEXT; }

 CASE(B8) { II ii = cp_R<B,0>(); NEXT; }

 CASE(B9) { II ii = cp_R<C,0>(); NEXT; }

 CASE(BA) { II ii = cp_R<D,0>(); NEXT; }

 CASE(BB) { II ii = cp_R<E,0>(); NEXT; }

 CASE(BC) { II ii = cp_R<H,0>(); NEXT; }

 CASE(BD) { II ii = cp_R<L,0>(); NEXT; }

 CASE(BE) { II ii = cp_xhl();   NEXT; }

 CASE(BF) { II ii = cp_a();     NEXT; }


 CASE(D3) { II ii = out_byte_a(); NEXT; }

 CASE(DB) { II ii = in_a_byte();  NEXT; }

 CASE(D9) { II ii = exx(); NEXT; }

 CASE(E3) { II ii = ex_xsp_SS<HL,0>(); NEXT; }

 CASE(EB) { II ii = ex_de_hl(); NEXT; }

 CASE(E9) { II ii = jp_SS<HL,0>(); NEXT; }

 CASE(F9) { II ii = ld_sp_SS<HL,0>(); NEXT; }

 CASE(F3) { II ii = di(); NEXT; }

 CASE(FB) { II ii = ei(); NEXT_EI; }

 CASE(C6) { II ii = add_a_byte(); NEXT; }

 CASE(CE) { II ii = adc_a_byte(); NEXT; }

 CASE(D6) { II ii = sub_byte();   NEXT; }

 CASE(DE) { II ii = sbc_a_byte(); NEXT; }

 CASE(E6) { II ii = and_byte();   NEXT; }

 CASE(EE) { II ii = xor_byte();   NEXT; }

 CASE(F6) { II ii = or_byte();    NEXT; }

 CASE(FE) { II ii = cp_byte();    NEXT; }

 CASE(C0) { II ii = ret(CondNZ()); NEXT; }

 CASE(C8) { II ii = ret(CondZ ()); NEXT; }

 CASE(D0) { II ii = ret(CondNC()); NEXT; }

 CASE(D8) { II ii = ret(CondC ()); NEXT; }

 CASE(E0) { II ii = ret(CondPO()); NEXT; }

 CASE(E8) { II ii = ret(CondPE()); NEXT; }

 CASE(F0) { II ii = ret(CondP ()); NEXT; }

 CASE(F8) { II ii = ret(CondM ()); NEXT; }

 CASE(C9) { II ii = ret();         NEXT; }

 CASE(C2) { II ii = jp(CondNZ()); NEXT; }

 CASE(CA) { II ii = jp(CondZ ()); NEXT; }

 CASE(D2) { II ii = jp(CondNC()); NEXT; }

 CASE(DA) { II ii = jp(CondC ()); NEXT; }

 CASE(E2) { II ii = jp(CondPO()); NEXT; }

 CASE(EA) { II ii = jp(CondPE()); NEXT; }

 CASE(F2) { II ii = jp(CondP ()); NEXT; }

 CASE(FA) { II ii = jp(CondM ()); NEXT; }

 CASE(C3) { II ii = jp(CondTrue()); NEXT; }

 CASE(C4) { II ii = call(CondNZ()); NEXT; }

 CASE(CC) { II ii = call(CondZ ()); NEXT; }

 CASE(D4) { II ii = call(CondNC()); NEXT; }

 CASE(DC) { II ii = call(CondC ()); NEXT; }

 CASE(E4) { II ii = call(CondPO()); NEXT; }

 CASE(EC) { II ii = call(CondPE()); NEXT; }

 CASE(F4) { II ii = call(CondP ()); NEXT; }

 CASE(FC) { II ii = call(CondM ()); NEXT; }

 CASE(CD) { II ii = call(CondTrue()); NEXT; }

 CASE(C1) { II ii = pop_SS <BC,0>(); NEXT; }

 CASE(D1) { II ii = pop_SS <DE,0>(); NEXT; }

 CASE(E1) { II ii = pop_SS <HL,0>(); NEXT; }

 CASE(F1) { II ii = pop_SS <AF,0>(); NEXT; }

 CASE(C5) { II ii = push_SS<BC,0>(); NEXT; }

 CASE(D5) { II ii = push_SS<DE,0>(); NEXT; }

 CASE(E5) { II ii = push_SS<HL,0>(); NEXT; }

 CASE(F5) { II ii = push_SS<AF,0>(); NEXT; }

 CASE(C7) { II ii = rst<0x00>(); NEXT; }

 CASE(CF) { II ii = rst<0x08>(); NEXT; }

 CASE(D7) { II ii = rst<0x10>(); NEXT; }

 CASE(DF) { II ii = rst<0x18>(); NEXT; }

 CASE(E7) { II ii = rst<0x20>(); NEXT; }

 CASE(EF) { II ii = rst<0x28>(); NEXT; }

 CASE(F7) { II ii = rst<0x30>(); NEXT; }

 CASE(FF) { II ii = rst<0x38>(); NEXT; }

 CASE(CB) {

         setPC(getPC() + 1); // M1 cycle at this point

         byte cb_opcode = RDMEM_OPCODE<0>(T::CC_PREFIX);

         incR(1);

         switch (cb_opcode) {

                 case 0x00: { II ii = rlc_R<B>(); NEXT; }

                 case 0x01: { II ii = rlc_R<C>(); NEXT; }

                 case 0x02: { II ii = rlc_R<D>(); NEXT; }

                 case 0x03: { II ii = rlc_R<E>(); NEXT; }

                 case 0x04: { II ii = rlc_R<H>(); NEXT; }

                 case 0x05: { II ii = rlc_R<L>(); NEXT; }

                 case 0x07: { II ii = rlc_R<A>(); NEXT; }

                 case 0x06: { II ii = rlc_xhl();  NEXT; }

                 case 0x08: { II ii = rrc_R<B>(); NEXT; }

                 case 0x09: { II ii = rrc_R<C>(); NEXT; }

                 case 0x0a: { II ii = rrc_R<D>(); NEXT; }

                 case 0x0b: { II ii = rrc_R<E>(); NEXT; }

                 case 0x0c: { II ii = rrc_R<H>(); NEXT; }

                 case 0x0d: { II ii = rrc_R<L>(); NEXT; }

                 case 0x0f: { II ii = rrc_R<A>(); NEXT; }

                 case 0x0e: { II ii = rrc_xhl();  NEXT; }

                 case 0x10: { II ii = rl_R<B>(); NEXT; }

                 case 0x11: { II ii = rl_R<C>(); NEXT; }

                 case 0x12: { II ii = rl_R<D>(); NEXT; }

                 case 0x13: { II ii = rl_R<E>(); NEXT; }

                 case 0x14: { II ii = rl_R<H>(); NEXT; }

                 case 0x15: { II ii = rl_R<L>(); NEXT; }

                 case 0x17: { II ii = rl_R<A>(); NEXT; }

                 case 0x16: { II ii = rl_xhl();  NEXT; }

                 case 0x18: { II ii = rr_R<B>(); NEXT; }

                 case 0x19: { II ii = rr_R<C>(); NEXT; }

                 case 0x1a: { II ii = rr_R<D>(); NEXT; }

                 case 0x1b: { II ii = rr_R<E>(); NEXT; }

                 case 0x1c: { II ii = rr_R<H>(); NEXT; }

                 case 0x1d: { II ii = rr_R<L>(); NEXT; }

                 case 0x1f: { II ii = rr_R<A>(); NEXT; }

                 case 0x1e: { II ii = rr_xhl();  NEXT; }

                 case 0x20: { II ii = sla_R<B>(); NEXT; }

                 case 0x21: { II ii = sla_R<C>(); NEXT; }

                 case 0x22: { II ii = sla_R<D>(); NEXT; }

                 case 0x23: { II ii = sla_R<E>(); NEXT; }

                 case 0x24: { II ii = sla_R<H>(); NEXT; }

                 case 0x25: { II ii = sla_R<L>(); NEXT; }

                 case 0x27: { II ii = sla_R<A>(); NEXT; }

                 case 0x26: { II ii = sla_xhl();  NEXT; }

                 case 0x28: { II ii = sra_R<B>(); NEXT; }

                 case 0x29: { II ii = sra_R<C>(); NEXT; }

                 case 0x2a: { II ii = sra_R<D>(); NEXT; }

                 case 0x2b: { II ii = sra_R<E>(); NEXT; }

                 case 0x2c: { II ii = sra_R<H>(); NEXT; }

                 case 0x2d: { II ii = sra_R<L>(); NEXT; }

                 case 0x2f: { II ii = sra_R<A>(); NEXT; }

                 case 0x2e: { II ii = sra_xhl();  NEXT; }

                 case 0x30: { II ii = T::IS_R800 ? sla_R<B>() : sll_R<B>(); NEXT; }

                 case 0x31: { II ii = T::IS_R800 ? sla_R<C>() : sll_R<C>(); NEXT; }

                 case 0x32: { II ii = T::IS_R800 ? sla_R<D>() : sll_R<D>(); NEXT; }

                 case 0x33: { II ii = T::IS_R800 ? sla_R<E>() : sll_R<E>(); NEXT; }

                 case 0x34: { II ii = T::IS_R800 ? sla_R<H>() : sll_R<H>(); NEXT; }

                 case 0x35: { II ii = T::IS_R800 ? sla_R<L>() : sll_R<L>(); NEXT; }

                 case 0x37: { II ii = T::IS_R800 ? sla_R<A>() : sll_R<A>(); NEXT; }

                 case 0x36: { II ii = T::IS_R800 ? sla_xhl()  : sll_xhl();  NEXT; }

                 case 0x38: { II ii = srl_R<B>(); NEXT; }

                 case 0x39: { II ii = srl_R<C>(); NEXT; }

                 case 0x3a: { II ii = srl_R<D>(); NEXT; }

                 case 0x3b: { II ii = srl_R<E>(); NEXT; }

                 case 0x3c: { II ii = srl_R<H>(); NEXT; }

                 case 0x3d: { II ii = srl_R<L>(); NEXT; }

                 case 0x3f: { II ii = srl_R<A>(); NEXT; }

                 case 0x3e: { II ii = srl_xhl();  NEXT; }


                 case 0x40: { II ii = bit_N_R<0,B>(); NEXT; }

                 case 0x41: { II ii = bit_N_R<0,C>(); NEXT; }

                 case 0x42: { II ii = bit_N_R<0,D>(); NEXT; }

                 case 0x43: { II ii = bit_N_R<0,E>(); NEXT; }

                 case 0x44: { II ii = bit_N_R<0,H>(); NEXT; }

                 case 0x45: { II ii = bit_N_R<0,L>(); NEXT; }

                 case 0x47: { II ii = bit_N_R<0,A>(); NEXT; }

                 case 0x48: { II ii = bit_N_R<1,B>(); NEXT; }

                 case 0x49: { II ii = bit_N_R<1,C>(); NEXT; }

                 case 0x4a: { II ii = bit_N_R<1,D>(); NEXT; }

                 case 0x4b: { II ii = bit_N_R<1,E>(); NEXT; }

                 case 0x4c: { II ii = bit_N_R<1,H>(); NEXT; }

                 case 0x4d: { II ii = bit_N_R<1,L>(); NEXT; }

                 case 0x4f: { II ii = bit_N_R<1,A>(); NEXT; }

                 case 0x50: { II ii = bit_N_R<2,B>(); NEXT; }

                 case 0x51: { II ii = bit_N_R<2,C>(); NEXT; }

                 case 0x52: { II ii = bit_N_R<2,D>(); NEXT; }

                 case 0x53: { II ii = bit_N_R<2,E>(); NEXT; }

                 case 0x54: { II ii = bit_N_R<2,H>(); NEXT; }

                 case 0x55: { II ii = bit_N_R<2,L>(); NEXT; }

                 case 0x57: { II ii = bit_N_R<2,A>(); NEXT; }

                 case 0x58: { II ii = bit_N_R<3,B>(); NEXT; }

                 case 0x59: { II ii = bit_N_R<3,C>(); NEXT; }

                 case 0x5a: { II ii = bit_N_R<3,D>(); NEXT; }

                 case 0x5b: { II ii = bit_N_R<3,E>(); NEXT; }

                 case 0x5c: { II ii = bit_N_R<3,H>(); NEXT; }

                 case 0x5d: { II ii = bit_N_R<3,L>(); NEXT; }

                 case 0x5f: { II ii = bit_N_R<3,A>(); NEXT; }

                 case 0x60: { II ii = bit_N_R<4,B>(); NEXT; }

                 case 0x61: { II ii = bit_N_R<4,C>(); NEXT; }

                 case 0x62: { II ii = bit_N_R<4,D>(); NEXT; }

                 case 0x63: { II ii = bit_N_R<4,E>(); NEXT; }

                 case 0x64: { II ii = bit_N_R<4,H>(); NEXT; }

                 case 0x65: { II ii = bit_N_R<4,L>(); NEXT; }

                 case 0x67: { II ii = bit_N_R<4,A>(); NEXT; }

                 case 0x68: { II ii = bit_N_R<5,B>(); NEXT; }

                 case 0x69: { II ii = bit_N_R<5,C>(); NEXT; }

                 case 0x6a: { II ii = bit_N_R<5,D>(); NEXT; }

                 case 0x6b: { II ii = bit_N_R<5,E>(); NEXT; }

                 case 0x6c: { II ii = bit_N_R<5,H>(); NEXT; }

                 case 0x6d: { II ii = bit_N_R<5,L>(); NEXT; }

                 case 0x6f: { II ii = bit_N_R<5,A>(); NEXT; }

                 case 0x70: { II ii = bit_N_R<6,B>(); NEXT; }

                 case 0x71: { II ii = bit_N_R<6,C>(); NEXT; }

                 case 0x72: { II ii = bit_N_R<6,D>(); NEXT; }

                 case 0x73: { II ii = bit_N_R<6,E>(); NEXT; }

                 case 0x74: { II ii = bit_N_R<6,H>(); NEXT; }

                 case 0x75: { II ii = bit_N_R<6,L>(); NEXT; }

                 case 0x77: { II ii = bit_N_R<6,A>(); NEXT; }

                 case 0x78: { II ii = bit_N_R<7,B>(); NEXT; }

                 case 0x79: { II ii = bit_N_R<7,C>(); NEXT; }

                 case 0x7a: { II ii = bit_N_R<7,D>(); NEXT; }

                 case 0x7b: { II ii = bit_N_R<7,E>(); NEXT; }

                 case 0x7c: { II ii = bit_N_R<7,H>(); NEXT; }

                 case 0x7d: { II ii = bit_N_R<7,L>(); NEXT; }

                 case 0x7f: { II ii = bit_N_R<7,A>(); NEXT; }

                 case 0x46: { II ii = bit_N_xhl<0>(); NEXT; }

                 case 0x4e: { II ii = bit_N_xhl<1>(); NEXT; }

                 case 0x56: { II ii = bit_N_xhl<2>(); NEXT; }

                 case 0x5e: { II ii = bit_N_xhl<3>(); NEXT; }

                 case 0x66: { II ii = bit_N_xhl<4>(); NEXT; }

                 case 0x6e: { II ii = bit_N_xhl<5>(); NEXT; }

                 case 0x76: { II ii = bit_N_xhl<6>(); NEXT; }

                 case 0x7e: { II ii = bit_N_xhl<7>(); NEXT; }


                 case 0x80: { II ii = res_N_R<0,B>(); NEXT; }

                 case 0x81: { II ii = res_N_R<0,C>(); NEXT; }

                 case 0x82: { II ii = res_N_R<0,D>(); NEXT; }

                 case 0x83: { II ii = res_N_R<0,E>(); NEXT; }

                 case 0x84: { II ii = res_N_R<0,H>(); NEXT; }

                 case 0x85: { II ii = res_N_R<0,L>(); NEXT; }

                 case 0x87: { II ii = res_N_R<0,A>(); NEXT; }

                 case 0x88: { II ii = res_N_R<1,B>(); NEXT; }

                 case 0x89: { II ii = res_N_R<1,C>(); NEXT; }

                 case 0x8a: { II ii = res_N_R<1,D>(); NEXT; }

                 case 0x8b: { II ii = res_N_R<1,E>(); NEXT; }

                 case 0x8c: { II ii = res_N_R<1,H>(); NEXT; }

                 case 0x8d: { II ii = res_N_R<1,L>(); NEXT; }

                 case 0x8f: { II ii = res_N_R<1,A>(); NEXT; }

                 case 0x90: { II ii = res_N_R<2,B>(); NEXT; }

                 case 0x91: { II ii = res_N_R<2,C>(); NEXT; }

                 case 0x92: { II ii = res_N_R<2,D>(); NEXT; }

                 case 0x93: { II ii = res_N_R<2,E>(); NEXT; }

                 case 0x94: { II ii = res_N_R<2,H>(); NEXT; }

                 case 0x95: { II ii = res_N_R<2,L>(); NEXT; }

                 case 0x97: { II ii = res_N_R<2,A>(); NEXT; }

                 case 0x98: { II ii = res_N_R<3,B>(); NEXT; }

                 case 0x99: { II ii = res_N_R<3,C>(); NEXT; }

                 case 0x9a: { II ii = res_N_R<3,D>(); NEXT; }

                 case 0x9b: { II ii = res_N_R<3,E>(); NEXT; }

                 case 0x9c: { II ii = res_N_R<3,H>(); NEXT; }

                 case 0x9d: { II ii = res_N_R<3,L>(); NEXT; }

                 case 0x9f: { II ii = res_N_R<3,A>(); NEXT; }

                 case 0xa0: { II ii = res_N_R<4,B>(); NEXT; }

                 case 0xa1: { II ii = res_N_R<4,C>(); NEXT; }

                 case 0xa2: { II ii = res_N_R<4,D>(); NEXT; }

                 case 0xa3: { II ii = res_N_R<4,E>(); NEXT; }

                 case 0xa4: { II ii = res_N_R<4,H>(); NEXT; }

                 case 0xa5: { II ii = res_N_R<4,L>(); NEXT; }

                 case 0xa7: { II ii = res_N_R<4,A>(); NEXT; }

                 case 0xa8: { II ii = res_N_R<5,B>(); NEXT; }

                 case 0xa9: { II ii = res_N_R<5,C>(); NEXT; }

                 case 0xaa: { II ii = res_N_R<5,D>(); NEXT; }

                 case 0xab: { II ii = res_N_R<5,E>(); NEXT; }

                 case 0xac: { II ii = res_N_R<5,H>(); NEXT; }

                 case 0xad: { II ii = res_N_R<5,L>(); NEXT; }

                 case 0xaf: { II ii = res_N_R<5,A>(); NEXT; }

                 case 0xb0: { II ii = res_N_R<6,B>(); NEXT; }

                 case 0xb1: { II ii = res_N_R<6,C>(); NEXT; }

                 case 0xb2: { II ii = res_N_R<6,D>(); NEXT; }

                 case 0xb3: { II ii = res_N_R<6,E>(); NEXT; }

                 case 0xb4: { II ii = res_N_R<6,H>(); NEXT; }

                 case 0xb5: { II ii = res_N_R<6,L>(); NEXT; }

                 case 0xb7: { II ii = res_N_R<6,A>(); NEXT; }

                 case 0xb8: { II ii = res_N_R<7,B>(); NEXT; }

                 case 0xb9: { II ii = res_N_R<7,C>(); NEXT; }

                 case 0xba: { II ii = res_N_R<7,D>(); NEXT; }

                 case 0xbb: { II ii = res_N_R<7,E>(); NEXT; }

                 case 0xbc: { II ii = res_N_R<7,H>(); NEXT; }

                 case 0xbd: { II ii = res_N_R<7,L>(); NEXT; }

                 case 0xbf: { II ii = res_N_R<7,A>(); NEXT; }

                 case 0x86: { II ii = res_N_xhl<0>(); NEXT; }

                 case 0x8e: { II ii = res_N_xhl<1>(); NEXT; }

                 case 0x96: { II ii = res_N_xhl<2>(); NEXT; }

                 case 0x9e: { II ii = res_N_xhl<3>(); NEXT; }

                 case 0xa6: { II ii = res_N_xhl<4>(); NEXT; }

                 case 0xae: { II ii = res_N_xhl<5>(); NEXT; }

                 case 0xb6: { II ii = res_N_xhl<6>(); NEXT; }

                 case 0xbe: { II ii = res_N_xhl<7>(); NEXT; }


                 case 0xc0: { II ii = set_N_R<0,B>(); NEXT; }

                 case 0xc1: { II ii = set_N_R<0,C>(); NEXT; }

                 case 0xc2: { II ii = set_N_R<0,D>(); NEXT; }

                 case 0xc3: { II ii = set_N_R<0,E>(); NEXT; }

                 case 0xc4: { II ii = set_N_R<0,H>(); NEXT; }

                 case 0xc5: { II ii = set_N_R<0,L>(); NEXT; }

                 case 0xc7: { II ii = set_N_R<0,A>(); NEXT; }

                 case 0xc8: { II ii = set_N_R<1,B>(); NEXT; }

                 case 0xc9: { II ii = set_N_R<1,C>(); NEXT; }

                 case 0xca: { II ii = set_N_R<1,D>(); NEXT; }

                 case 0xcb: { II ii = set_N_R<1,E>(); NEXT; }

                 case 0xcc: { II ii = set_N_R<1,H>(); NEXT; }

                 case 0xcd: { II ii = set_N_R<1,L>(); NEXT; }

                 case 0xcf: { II ii = set_N_R<1,A>(); NEXT; }

                 case 0xd0: { II ii = set_N_R<2,B>(); NEXT; }

                 case 0xd1: { II ii = set_N_R<2,C>(); NEXT; }

                 case 0xd2: { II ii = set_N_R<2,D>(); NEXT; }

                 case 0xd3: { II ii = set_N_R<2,E>(); NEXT; }

                 case 0xd4: { II ii = set_N_R<2,H>(); NEXT; }

                 case 0xd5: { II ii = set_N_R<2,L>(); NEXT; }

                 case 0xd7: { II ii = set_N_R<2,A>(); NEXT; }

                 case 0xd8: { II ii = set_N_R<3,B>(); NEXT; }

                 case 0xd9: { II ii = set_N_R<3,C>(); NEXT; }

                 case 0xda: { II ii = set_N_R<3,D>(); NEXT; }

                 case 0xdb: { II ii = set_N_R<3,E>(); NEXT; }

                 case 0xdc: { II ii = set_N_R<3,H>(); NEXT; }

                 case 0xdd: { II ii = set_N_R<3,L>(); NEXT; }

                 case 0xdf: { II ii = set_N_R<3,A>(); NEXT; }

                 case 0xe0: { II ii = set_N_R<4,B>(); NEXT; }

                 case 0xe1: { II ii = set_N_R<4,C>(); NEXT; }

                 case 0xe2: { II ii = set_N_R<4,D>(); NEXT; }

                 case 0xe3: { II ii = set_N_R<4,E>(); NEXT; }

                 case 0xe4: { II ii = set_N_R<4,H>(); NEXT; }

                 case 0xe5: { II ii = set_N_R<4,L>(); NEXT; }

                 case 0xe7: { II ii = set_N_R<4,A>(); NEXT; }

                 case 0xe8: { II ii = set_N_R<5,B>(); NEXT; }

                 case 0xe9: { II ii = set_N_R<5,C>(); NEXT; }

                 case 0xea: { II ii = set_N_R<5,D>(); NEXT; }

                 case 0xeb: { II ii = set_N_R<5,E>(); NEXT; }

                 case 0xec: { II ii = set_N_R<5,H>(); NEXT; }

                 case 0xed: { II ii = set_N_R<5,L>(); NEXT; }

                 case 0xef: { II ii = set_N_R<5,A>(); NEXT; }

                 case 0xf0: { II ii = set_N_R<6,B>(); NEXT; }

                 case 0xf1: { II ii = set_N_R<6,C>(); NEXT; }

                 case 0xf2: { II ii = set_N_R<6,D>(); NEXT; }

                 case 0xf3: { II ii = set_N_R<6,E>(); NEXT; }

                 case 0xf4: { II ii = set_N_R<6,H>(); NEXT; }

                 case 0xf5: { II ii = set_N_R<6,L>(); NEXT; }

                 case 0xf7: { II ii = set_N_R<6,A>(); NEXT; }

                 case 0xf8: { II ii = set_N_R<7,B>(); NEXT; }

                 case 0xf9: { II ii = set_N_R<7,C>(); NEXT; }

                 case 0xfa: { II ii = set_N_R<7,D>(); NEXT; }

                 case 0xfb: { II ii = set_N_R<7,E>(); NEXT; }

                 case 0xfc: { II ii = set_N_R<7,H>(); NEXT; }

                 case 0xfd: { II ii = set_N_R<7,L>(); NEXT; }

                 case 0xff: { II ii = set_N_R<7,A>(); NEXT; }

                 case 0xc6: { II ii = set_N_xhl<0>(); NEXT; }

                 case 0xce: { II ii = set_N_xhl<1>(); NEXT; }

                 case 0xd6: { II ii = set_N_xhl<2>(); NEXT; }

                 case 0xde: { II ii = set_N_xhl<3>(); NEXT; }

                 case 0xe6: { II ii = set_N_xhl<4>(); NEXT; }

                 case 0xee: { II ii = set_N_xhl<5>(); NEXT; }

                 case 0xf6: { II ii = set_N_xhl<6>(); NEXT; }

                 case 0xfe: { II ii = set_N_xhl<7>(); NEXT; }

                 default: UNREACHABLE; return;

         }

 }

 CASE(ED) {

         setPC(getPC() + 1); // M1 cycle at this point

         byte ed_opcode = RDMEM_OPCODE<0>(T::CC_PREFIX);

         incR(1);

         switch (ed_opcode) {

                 case 0x00: case 0x01: case 0x02: case 0x03:

                 case 0x04: case 0x05: case 0x06: case 0x07:

                 case 0x08: case 0x09: case 0x0a: case 0x0b:

                 case 0x0c: case 0x0d: case 0x0e: case 0x0f:

                 case 0x10: case 0x11: case 0x12: case 0x13:

                 case 0x14: case 0x15: case 0x16: case 0x17:

                 case 0x18: case 0x19: case 0x1a: case 0x1b:

                 case 0x1c: case 0x1d: case 0x1e: case 0x1f:

                 case 0x20: case 0x21: case 0x22: case 0x23:

                 case 0x24: case 0x25: case 0x26: case 0x27:

                 case 0x28: case 0x29: case 0x2a: case 0x2b:

                 case 0x2c: case 0x2d: case 0x2e: case 0x2f:

                 case 0x30: case 0x31: case 0x32: case 0x33:

                 case 0x34: case 0x35: case 0x36: case 0x37:

                 case 0x38: case 0x39: case 0x3a: case 0x3b:

                 case 0x3c: case 0x3d: case 0x3e: case 0x3f:


                 case 0x77: case 0x7f:


                 case 0x80: case 0x81: case 0x82: case 0x83:

                 case 0x84: case 0x85: case 0x86: case 0x87:

                 case 0x88: case 0x89: case 0x8a: case 0x8b:

                 case 0x8c: case 0x8d: case 0x8e: case 0x8f:

                 case 0x90: case 0x91: case 0x92: case 0x93:

                 case 0x94: case 0x95: case 0x96: case 0x97:

                 case 0x98: case 0x99: case 0x9a: case 0x9b:

                 case 0x9c: case 0x9d: case 0x9e: case 0x9f:

                 case 0xa4: case 0xa5: case 0xa6: case 0xa7:

                 case 0xac: case 0xad: case 0xae: case 0xaf:

                 case 0xb4: case 0xb5: case 0xb6: case 0xb7:

                 case 0xbc: case 0xbd: case 0xbe: case 0xbf:


                 case 0xc0:            case 0xc2:

                 case 0xc4: case 0xc5: case 0xc6: case 0xc7:

                 case 0xc8: case 0xca: case 0xcb:

                 case 0xcc: case 0xcd: case 0xce: case 0xcf:

                 case 0xd0:            case 0xd2: case 0xd3:

                 case 0xd4: case 0xd5: case 0xd6: case 0xd7:

                 case 0xd8:            case 0xda: case 0xdb:

                 case 0xdc: case 0xdd: case 0xde: case 0xdf:

                 case 0xe0: case 0xe1: case 0xe2: case 0xe3:

                 case 0xe4: case 0xe5: case 0xe6: case 0xe7:

                 case 0xe8: case 0xe9: case 0xea: case 0xeb:

                 case 0xec: case 0xed: case 0xee: case 0xef:

                 case 0xf0: case 0xf1: case 0xf2:

                 case 0xf4: case 0xf5: case 0xf6: case 0xf7:

                 case 0xf8: case 0xf9: case 0xfa: case 0xfb:

                 case 0xfc: case 0xfd: case 0xfe: case 0xff:

                            { II ii = nop(); NEXT; }


                 case 0x40: { II ii = in_R_c<B>(); NEXT; }

                 case 0x48: { II ii = in_R_c<C>(); NEXT; }

                 case 0x50: { II ii = in_R_c<D>(); NEXT; }

                 case 0x58: { II ii = in_R_c<E>(); NEXT; }

                 case 0x60: { II ii = in_R_c<H>(); NEXT; }

                 case 0x68: { II ii = in_R_c<L>(); NEXT; }

                 case 0x70: { II ii = in_R_c<DUMMY>(); NEXT; }

                 case 0x78: { II ii = in_R_c<A>(); NEXT; }


                 case 0x41: { II ii = out_c_R<B>(); NEXT; }

                 case 0x49: { II ii = out_c_R<C>(); NEXT; }

                 case 0x51: { II ii = out_c_R<D>(); NEXT; }

                 case 0x59: { II ii = out_c_R<E>(); NEXT; }

                 case 0x61: { II ii = out_c_R<H>(); NEXT; }

                 case 0x69: { II ii = out_c_R<L>(); NEXT; }

                 case 0x71: { II ii = out_c_0();    NEXT; }

                 case 0x79: { II ii = out_c_R<A>(); NEXT; }


                 case 0x42: { II ii = sbc_hl_SS<BC>(); NEXT; }

                 case 0x52: { II ii = sbc_hl_SS<DE>(); NEXT; }

                 case 0x62: { II ii = sbc_hl_hl    (); NEXT; }

                 case 0x72: { II ii = sbc_hl_SS<SP>(); NEXT; }


                 case 0x4a: { II ii = adc_hl_SS<BC>(); NEXT; }

                 case 0x5a: { II ii = adc_hl_SS<DE>(); NEXT; }

                 case 0x6a: { II ii = adc_hl_hl    (); NEXT; }

                 case 0x7a: { II ii = adc_hl_SS<SP>(); NEXT; }


                 case 0x43: { II ii = ld_xword_SS_ED<BC>(); NEXT; }

                 case 0x53: { II ii = ld_xword_SS_ED<DE>(); NEXT; }

                 case 0x63: { II ii = ld_xword_SS_ED<HL>(); NEXT; }

                 case 0x73: { II ii = ld_xword_SS_ED<SP>(); NEXT; }


                 case 0x4b: { II ii = ld_SS_xword_ED<BC>(); NEXT; }

                 case 0x5b: { II ii = ld_SS_xword_ED<DE>(); NEXT; }

                 case 0x6b: { II ii = ld_SS_xword_ED<HL>(); NEXT; }

                 case 0x7b: { II ii = ld_SS_xword_ED<SP>(); NEXT; }


                 case 0x47: { II ii = ld_i_a(); NEXT; }

                 case 0x4f: { II ii = ld_r_a(); NEXT; }

                 case 0x57: { II ii = ld_a_IR<REG_I>(); if (T::IS_R800) { NEXT; } else { NEXT_STOP; }}

                 case 0x5f: { II ii = ld_a_IR<REG_R>(); if (T::IS_R800) { NEXT; } else { NEXT_STOP; }}


                 case 0x67: { II ii = rrd(); NEXT; }

                 case 0x6f: { II ii = rld(); NEXT; }


                 case 0x45: case 0x4d: case 0x55: case 0x5d:

                 case 0x65: case 0x6d: case 0x75: case 0x7d:

                            { II ii = retn(); NEXT_STOP; }

                 case 0x46: case 0x4e: case 0x66: case 0x6e:

                            { II ii = im_N<0>(); NEXT; }

                 case 0x56: case 0x76:

                            { II ii = im_N<1>(); NEXT; }

                 case 0x5e: case 0x7e:

                            { II ii = im_N<2>(); NEXT; }

                 case 0x44: case 0x4c: case 0x54: case 0x5c:

                 case 0x64: case 0x6c: case 0x74: case 0x7c:

                            { II ii = neg(); NEXT; }


                 case 0xa0: { II ii = ldi();  NEXT; }

                 case 0xa1: { II ii = cpi();  NEXT; }

                 case 0xa2: { II ii = ini();  NEXT; }

                 case 0xa3: { II ii = outi(); NEXT; }

                 case 0xa8: { II ii = ldd();  NEXT; }

                 case 0xa9: { II ii = cpd();  NEXT; }

                 case 0xaa: { II ii = ind();  NEXT; }

                 case 0xab: { II ii = outd(); NEXT; }

                 case 0xb0: { II ii = ldir(); NEXT; }

                 case 0xb1: { II ii = cpir(); NEXT; }

                 case 0xb2: { II ii = inir(); NEXT; }

                 case 0xb3: { II ii = otir(); NEXT; }

                 case 0xb8: { II ii = lddr(); NEXT; }

                 case 0xb9: { II ii = cpdr(); NEXT; }

                 case 0xba: { II ii = indr(); NEXT; }

                 case 0xbb: { II ii = otdr(); NEXT; }


                 case 0xc1: { II ii = T::IS_R800 ? mulub_a_R<B>() : nop(); NEXT; }

                 case 0xc9: { II ii = T::IS_R800 ? mulub_a_R<C>() : nop(); NEXT; }

                 case 0xd1: { II ii = T::IS_R800 ? mulub_a_R<D>() : nop(); NEXT; }

                 case 0xd9: { II ii = T::IS_R800 ? mulub_a_R<E>() : nop(); NEXT; }

                 case 0xc3: { II ii = T::IS_R800 ? muluw_hl_SS<BC>() : nop(); NEXT; }

                 case 0xf3: { II ii = T::IS_R800 ? muluw_hl_SS<SP>() : nop(); NEXT; }

                 default: UNREACHABLE; return;

         }

 }

 opDD_2:

 CASE(DD) {

         setPC(getPC() + 1); // M1 cycle at this point

         byte opcodeDD = RDMEM_OPCODE<0>(T::CC_DD + T::CC_MAIN);

         incR(1);

         switch (opcodeDD) {

                 case 0x00: // nop();

                 case 0x01: // ld_bc_word();

                 case 0x02: // ld_xbc_a();

                 case 0x03: // inc_bc();

                 case 0x04: // inc_b();

                 case 0x05: // dec_b();

                 case 0x06: // ld_b_byte();

                 case 0x07: // rlca();

                 case 0x08: // ex_af_af();

                 case 0x0a: // ld_a_xbc();

                 case 0x0b: // dec_bc();

                 case 0x0c: // inc_c();

                 case 0x0d: // dec_c();

                 case 0x0e: // ld_c_byte();

                 case 0x0f: // rrca();

                 case 0x10: // djnz();

                 case 0x11: // ld_de_word();

                 case 0x12: // ld_xde_a();

                 case 0x13: // inc_de();

                 case 0x14: // inc_d();

                 case 0x15: // dec_d();

                 case 0x16: // ld_d_byte();

                 case 0x17: // rla();

                 case 0x18: // jr();

                 case 0x1a: // ld_a_xde();

                 case 0x1b: // dec_de();

                 case 0x1c: // inc_e();

                 case 0x1d: // dec_e();

                 case 0x1e: // ld_e_byte();

                 case 0x1f: // rra();

                 case 0x20: // jr_nz();

                 case 0x27: // daa();

                 case 0x28: // jr_z();

                 case 0x2f: // cpl();

                 case 0x30: // jr_nc();

                 case 0x31: // ld_sp_word();

                 case 0x32: // ld_xbyte_a();

                 case 0x33: // inc_sp();

                 case 0x37: // scf();

                 case 0x38: // jr_c();

                 case 0x3a: // ld_a_xbyte();

                 case 0x3b: // dec_sp();

                 case 0x3c: // inc_a();

                 case 0x3d: // dec_a();

                 case 0x3e: // ld_a_byte();

                 case 0x3f: // ccf();


                 case 0x40: // ld_b_b();

                 case 0x41: // ld_b_c();

                 case 0x42: // ld_b_d();

                 case 0x43: // ld_b_e();

                 case 0x47: // ld_b_a();

                 case 0x48: // ld_c_b();

                 case 0x49: // ld_c_c();

                 case 0x4a: // ld_c_d();

                 case 0x4b: // ld_c_e();

                 case 0x4f: // ld_c_a();

                 case 0x50: // ld_d_b();

                 case 0x51: // ld_d_c();

                 case 0x52: // ld_d_d();

                 case 0x53: // ld_d_e();

                 case 0x57: // ld_d_a();

                 case 0x58: // ld_e_b();

                 case 0x59: // ld_e_c();

                 case 0x5a: // ld_e_d();

                 case 0x5b: // ld_e_e();

                 case 0x5f: // ld_e_a();

                 case 0x64: // ld_ixh_ixh(); == nop

                 case 0x6d: // ld_ixl_ixl(); == nop

                 case 0x76: // halt();

                 case 0x78: // ld_a_b();

                 case 0x79: // ld_a_c();

                 case 0x7a: // ld_a_d();

                 case 0x7b: // ld_a_e();

                 case 0x7f: // ld_a_a();


                 case 0x80: // add_a_b();

                 case 0x81: // add_a_c();

                 case 0x82: // add_a_d();

                 case 0x83: // add_a_e();

                 case 0x87: // add_a_a();

                 case 0x88: // adc_a_b();

                 case 0x89: // adc_a_c();

                 case 0x8a: // adc_a_d();

                 case 0x8b: // adc_a_e();

                 case 0x8f: // adc_a_a();

                 case 0x90: // sub_b();

                 case 0x91: // sub_c();

                 case 0x92: // sub_d();

                 case 0x93: // sub_e();

                 case 0x97: // sub_a();

                 case 0x98: // sbc_a_b();

                 case 0x99: // sbc_a_c();

                 case 0x9a: // sbc_a_d();

                 case 0x9b: // sbc_a_e();

                 case 0x9f: // sbc_a_a();

                 case 0xa0: // and_b();

                 case 0xa1: // and_c();

                 case 0xa2: // and_d();

                 case 0xa3: // and_e();

                 case 0xa7: // and_a();

                 case 0xa8: // xor_b();

                 case 0xa9: // xor_c();

                 case 0xaa: // xor_d();

                 case 0xab: // xor_e();

                 case 0xaf: // xor_a();

                 case 0xb0: // or_b();

                 case 0xb1: // or_c();

                 case 0xb2: // or_d();

                 case 0xb3: // or_e();

                 case 0xb7: // or_a();

                 case 0xb8: // cp_b();

                 case 0xb9: // cp_c();

                 case 0xba: // cp_d();

                 case 0xbb: // cp_e();

                 case 0xbf: // cp_a();


                 case 0xc0: // ret_nz();

                 case 0xc1: // pop_bc();

                 case 0xc2: // jp_nz();

                 case 0xc3: // jp();

                 case 0xc4: // call_nz();

                 case 0xc5: // push_bc();

                 case 0xc6: // add_a_byte();

                 case 0xc7: // rst_00();

                 case 0xc8: // ret_z();

                 case 0xc9: // ret();

                 case 0xca: // jp_z();

                 case 0xcc: // call_z();

                 case 0xcd: // call();

                 case 0xce: // adc_a_byte();

                 case 0xcf: // rst_08();

                 case 0xd0: // ret_nc();

                 case 0xd1: // pop_de();

                 case 0xd2: // jp_nc();

                 case 0xd3: // out_byte_a();

                 case 0xd4: // call_nc();

                 case 0xd5: // push_de();

                 case 0xd6: // sub_byte();

                 case 0xd7: // rst_10();

                 case 0xd8: // ret_c();

                 case 0xd9: // exx();

                 case 0xda: // jp_c();

                 case 0xdb: // in_a_byte();

                 case 0xdc: // call_c();

                 case 0xde: // sbc_a_byte();

                 case 0xdf: // rst_18();

                 case 0xe0: // ret_po();

                 case 0xe2: // jp_po();

                 case 0xe4: // call_po();

                 case 0xe6: // and_byte();

                 case 0xe7: // rst_20();

                 case 0xe8: // ret_pe();

                 case 0xea: // jp_pe();

                 case 0xeb: // ex_de_hl();

                 case 0xec: // call_pe();

                 case 0xed: // ed();

                 case 0xee: // xor_byte();

                 case 0xef: // rst_28();

                 case 0xf0: // ret_p();

                 case 0xf1: // pop_af();

                 case 0xf2: // jp_p();

                 case 0xf3: // di();

                 case 0xf4: // call_p();

                 case 0xf5: // push_af();

                 case 0xf6: // or_byte();

                 case 0xf7: // rst_30();

                 case 0xf8: // ret_m();

                 case 0xfa: // jp_m();

                 case 0xfb: // ei();

                 case 0xfc: // call_m();

                 case 0xfe: // cp_byte();

                 case 0xff: // rst_38();

                         if /*constexpr*/ (T::IS_R800) {

                                 II ii = nop();

                                 ii.cycles += T::CC_DD;

                                 NEXT;

                         } else {

                                 T::add(T::CC_DD);

                                 #ifdef USE_COMPUTED_GOTO

                                 goto *(opcodeTable[opcodeDD]);

                                 #else

                                 opcodeMain = opcodeDD;

                                 goto switchopcode;

                                 #endif

                         }


                 case 0x09: { II ii = add_SS_TT<IX,BC,T::CC_DD>(); NEXT; }

                 case 0x19: { II ii = add_SS_TT<IX,DE,T::CC_DD>(); NEXT; }

                 case 0x29: { II ii = add_SS_SS<IX   ,T::CC_DD>(); NEXT; }

                 case 0x39: { II ii = add_SS_TT<IX,SP,T::CC_DD>(); NEXT; }

                 case 0x21: { II ii = ld_SS_word<IX,T::CC_DD>();  NEXT; }

                 case 0x22: { II ii = ld_xword_SS<IX,T::CC_DD>(); NEXT; }

                 case 0x2a: { II ii = ld_SS_xword<IX,T::CC_DD>(); NEXT; }

                 case 0x23: { II ii = inc_SS<IX,T::CC_DD>(); NEXT; }

                 case 0x2b: { II ii = dec_SS<IX,T::CC_DD>(); NEXT; }

                 case 0x24: { II ii = inc_R<IXH,T::CC_DD>(); NEXT; }

                 case 0x2c: { II ii = inc_R<IXL,T::CC_DD>(); NEXT; }

                 case 0x25: { II ii = dec_R<IXH,T::CC_DD>(); NEXT; }

                 case 0x2d: { II ii = dec_R<IXL,T::CC_DD>(); NEXT; }

                 case 0x26: { II ii = ld_R_byte<IXH,T::CC_DD>(); NEXT; }

                 case 0x2e: { II ii = ld_R_byte<IXL,T::CC_DD>(); NEXT; }

                 case 0x34: { II ii = inc_xix<IX>(); NEXT; }

                 case 0x35: { II ii = dec_xix<IX>(); NEXT; }

                 case 0x36: { II ii = ld_xix_byte<IX>(); NEXT; }


                 case 0x44: { II ii = ld_R_R<B,IXH,T::CC_DD>(); NEXT; }

                 case 0x45: { II ii = ld_R_R<B,IXL,T::CC_DD>(); NEXT; }

                 case 0x4c: { II ii = ld_R_R<C,IXH,T::CC_DD>(); NEXT; }

                 case 0x4d: { II ii = ld_R_R<C,IXL,T::CC_DD>(); NEXT; }

                 case 0x54: { II ii = ld_R_R<D,IXH,T::CC_DD>(); NEXT; }

                 case 0x55: { II ii = ld_R_R<D,IXL,T::CC_DD>(); NEXT; }

                 case 0x5c: { II ii = ld_R_R<E,IXH,T::CC_DD>(); NEXT; }

                 case 0x5d: { II ii = ld_R_R<E,IXL,T::CC_DD>(); NEXT; }

                 case 0x7c: { II ii = ld_R_R<A,IXH,T::CC_DD>(); NEXT; }

                 case 0x7d: { II ii = ld_R_R<A,IXL,T::CC_DD>(); NEXT; }

                 case 0x60: { II ii = ld_R_R<IXH,B,T::CC_DD>(); NEXT; }

                 case 0x61: { II ii = ld_R_R<IXH,C,T::CC_DD>(); NEXT; }

                 case 0x62: { II ii = ld_R_R<IXH,D,T::CC_DD>(); NEXT; }

                 case 0x63: { II ii = ld_R_R<IXH,E,T::CC_DD>(); NEXT; }

                 case 0x65: { II ii = ld_R_R<IXH,IXL,T::CC_DD>(); NEXT; }

                 case 0x67: { II ii = ld_R_R<IXH,A,T::CC_DD>(); NEXT; }

                 case 0x68: { II ii = ld_R_R<IXL,B,T::CC_DD>(); NEXT; }

                 case 0x69: { II ii = ld_R_R<IXL,C,T::CC_DD>(); NEXT; }

                 case 0x6a: { II ii = ld_R_R<IXL,D,T::CC_DD>(); NEXT; }

                 case 0x6b: { II ii = ld_R_R<IXL,E,T::CC_DD>(); NEXT; }

                 case 0x6c: { II ii = ld_R_R<IXL,IXH,T::CC_DD>(); NEXT; }

                 case 0x6f: { II ii = ld_R_R<IXL,A,T::CC_DD>(); NEXT; }

                 case 0x70: { II ii = ld_xix_R<IX,B>(); NEXT; }

                 case 0x71: { II ii = ld_xix_R<IX,C>(); NEXT; }

                 case 0x72: { II ii = ld_xix_R<IX,D>(); NEXT; }

                 case 0x73: { II ii = ld_xix_R<IX,E>(); NEXT; }

                 case 0x74: { II ii = ld_xix_R<IX,H>(); NEXT; }

                 case 0x75: { II ii = ld_xix_R<IX,L>(); NEXT; }

                 case 0x77: { II ii = ld_xix_R<IX,A>(); NEXT; }

                 case 0x46: { II ii = ld_R_xix<B,IX>(); NEXT; }

                 case 0x4e: { II ii = ld_R_xix<C,IX>(); NEXT; }

                 case 0x56: { II ii = ld_R_xix<D,IX>(); NEXT; }

                 case 0x5e: { II ii = ld_R_xix<E,IX>(); NEXT; }

                 case 0x66: { II ii = ld_R_xix<H,IX>(); NEXT; }

                 case 0x6e: { II ii = ld_R_xix<L,IX>(); NEXT; }

                 case 0x7e: { II ii = ld_R_xix<A,IX>(); NEXT; }


                 case 0x84: { II ii = add_a_R<IXH,T::CC_DD>(); NEXT; }

                 case 0x85: { II ii = add_a_R<IXL,T::CC_DD>(); NEXT; }

                 case 0x86: { II ii = add_a_xix<IX>(); NEXT; }

                 case 0x8c: { II ii = adc_a_R<IXH,T::CC_DD>(); NEXT; }

                 case 0x8d: { II ii = adc_a_R<IXL,T::CC_DD>(); NEXT; }

                 case 0x8e: { II ii = adc_a_xix<IX>(); NEXT; }

                 case 0x94: { II ii = sub_R<IXH,T::CC_DD>(); NEXT; }

                 case 0x95: { II ii = sub_R<IXL,T::CC_DD>(); NEXT; }

                 case 0x96: { II ii = sub_xix<IX>(); NEXT; }

                 case 0x9c: { II ii = sbc_a_R<IXH,T::CC_DD>(); NEXT; }

                 case 0x9d: { II ii = sbc_a_R<IXL,T::CC_DD>(); NEXT; }

                 case 0x9e: { II ii = sbc_a_xix<IX>(); NEXT; }

                 case 0xa4: { II ii = and_R<IXH,T::CC_DD>(); NEXT; }

                 case 0xa5: { II ii = and_R<IXL,T::CC_DD>(); NEXT; }

                 case 0xa6: { II ii = and_xix<IX>(); NEXT; }

                 case 0xac: { II ii = xor_R<IXH,T::CC_DD>(); NEXT; }

                 case 0xad: { II ii = xor_R<IXL,T::CC_DD>(); NEXT; }

                 case 0xae: { II ii = xor_xix<IX>(); NEXT; }

                 case 0xb4: { II ii = or_R<IXH,T::CC_DD>(); NEXT; }

                 case 0xb5: { II ii = or_R<IXL,T::CC_DD>(); NEXT; }

                 case 0xb6: { II ii = or_xix<IX>(); NEXT; }

                 case 0xbc: { II ii = cp_R<IXH,T::CC_DD>(); NEXT; }

                 case 0xbd: { II ii = cp_R<IXL,T::CC_DD>(); NEXT; }

                 case 0xbe: { II ii = cp_xix<IX>(); NEXT; }


                 case 0xe1: { II ii = pop_SS <IX,T::CC_DD>(); NEXT; }

                 case 0xe5: { II ii = push_SS<IX,T::CC_DD>(); NEXT; }

                 case 0xe3: { II ii = ex_xsp_SS<IX,T::CC_DD>(); NEXT; }

                 case 0xe9: { II ii = jp_SS<IX,T::CC_DD>(); NEXT; }

                 case 0xf9: { II ii = ld_sp_SS<IX,T::CC_DD>(); NEXT; }

                 case 0xcb: ixy = getIX(); goto xx_cb;

                 case 0xdd: T::add(T::CC_DD); goto opDD_2;

                 case 0xfd: T::add(T::CC_DD); goto opFD_2;

                 default: UNREACHABLE; return;

         }

 }

 opFD_2:

 CASE(FD) {

         setPC(getPC() + 1); // M1 cycle at this point

         byte opcodeFD = RDMEM_OPCODE<0>(T::CC_DD + T::CC_MAIN);

         incR(1);

         switch (opcodeFD) {

                 case 0x00: // nop();

                 case 0x01: // ld_bc_word();

                 case 0x02: // ld_xbc_a();

                 case 0x03: // inc_bc();

                 case 0x04: // inc_b();

                 case 0x05: // dec_b();

                 case 0x06: // ld_b_byte();

                 case 0x07: // rlca();

                 case 0x08: // ex_af_af();

                 case 0x0a: // ld_a_xbc();

                 case 0x0b: // dec_bc();

                 case 0x0c: // inc_c();

                 case 0x0d: // dec_c();

                 case 0x0e: // ld_c_byte();

                 case 0x0f: // rrca();

                 case 0x10: // djnz();

                 case 0x11: // ld_de_word();

                 case 0x12: // ld_xde_a();

                 case 0x13: // inc_de();

                 case 0x14: // inc_d();

                 case 0x15: // dec_d();

                 case 0x16: // ld_d_byte();

                 case 0x17: // rla();

                 case 0x18: // jr();

                 case 0x1a: // ld_a_xde();

                 case 0x1b: // dec_de();

                 case 0x1c: // inc_e();

                 case 0x1d: // dec_e();

                 case 0x1e: // ld_e_byte();

                 case 0x1f: // rra();

                 case 0x20: // jr_nz();

                 case 0x27: // daa();

                 case 0x28: // jr_z();

                 case 0x2f: // cpl();

                 case 0x30: // jr_nc();

                 case 0x31: // ld_sp_word();

                 case 0x32: // ld_xbyte_a();

                 case 0x33: // inc_sp();

                 case 0x37: // scf();

                 case 0x38: // jr_c();

                 case 0x3a: // ld_a_xbyte();

                 case 0x3b: // dec_sp();

                 case 0x3c: // inc_a();

                 case 0x3d: // dec_a();

                 case 0x3e: // ld_a_byte();

                 case 0x3f: // ccf();


                 case 0x40: // ld_b_b();

                 case 0x41: // ld_b_c();

                 case 0x42: // ld_b_d();

                 case 0x43: // ld_b_e();

                 case 0x47: // ld_b_a();

                 case 0x48: // ld_c_b();

                 case 0x49: // ld_c_c();

                 case 0x4a: // ld_c_d();

                 case 0x4b: // ld_c_e();

                 case 0x4f: // ld_c_a();

                 case 0x50: // ld_d_b();

                 case 0x51: // ld_d_c();

                 case 0x52: // ld_d_d();

                 case 0x53: // ld_d_e();

                 case 0x57: // ld_d_a();

                 case 0x58: // ld_e_b();

                 case 0x59: // ld_e_c();

                 case 0x5a: // ld_e_d();

                 case 0x5b: // ld_e_e();

                 case 0x5f: // ld_e_a();

                 case 0x64: // ld_ixh_ixh(); == nop

                 case 0x6d: // ld_ixl_ixl(); == nop

                 case 0x76: // halt();

                 case 0x78: // ld_a_b();

                 case 0x79: // ld_a_c();

                 case 0x7a: // ld_a_d();

                 case 0x7b: // ld_a_e();

                 case 0x7f: // ld_a_a();


                 case 0x80: // add_a_b();

                 case 0x81: // add_a_c();

                 case 0x82: // add_a_d();

                 case 0x83: // add_a_e();

                 case 0x87: // add_a_a();

                 case 0x88: // adc_a_b();

                 case 0x89: // adc_a_c();

                 case 0x8a: // adc_a_d();

                 case 0x8b: // adc_a_e();

                 case 0x8f: // adc_a_a();

                 case 0x90: // sub_b();

                 case 0x91: // sub_c();

                 case 0x92: // sub_d();

                 case 0x93: // sub_e();

                 case 0x97: // sub_a();

                 case 0x98: // sbc_a_b();

                 case 0x99: // sbc_a_c();

                 case 0x9a: // sbc_a_d();

                 case 0x9b: // sbc_a_e();

                 case 0x9f: // sbc_a_a();

                 case 0xa0: // and_b();

                 case 0xa1: // and_c();

                 case 0xa2: // and_d();

                 case 0xa3: // and_e();

                 case 0xa7: // and_a();

                 case 0xa8: // xor_b();

                 case 0xa9: // xor_c();

                 case 0xaa: // xor_d();

                 case 0xab: // xor_e();

                 case 0xaf: // xor_a();

                 case 0xb0: // or_b();

                 case 0xb1: // or_c();

                 case 0xb2: // or_d();

                 case 0xb3: // or_e();

                 case 0xb7: // or_a();

                 case 0xb8: // cp_b();

                 case 0xb9: // cp_c();

                 case 0xba: // cp_d();

                 case 0xbb: // cp_e();

                 case 0xbf: // cp_a();


                 case 0xc0: // ret_nz();

                 case 0xc1: // pop_bc();

                 case 0xc2: // jp_nz();

                 case 0xc3: // jp();

                 case 0xc4: // call_nz();

                 case 0xc5: // push_bc();

                 case 0xc6: // add_a_byte();

                 case 0xc7: // rst_00();

                 case 0xc8: // ret_z();

                 case 0xc9: // ret();

                 case 0xca: // jp_z();

                 case 0xcc: // call_z();

                 case 0xcd: // call();

                 case 0xce: // adc_a_byte();

                 case 0xcf: // rst_08();

                 case 0xd0: // ret_nc();

                 case 0xd1: // pop_de();

                 case 0xd2: // jp_nc();

                 case 0xd3: // out_byte_a();

                 case 0xd4: // call_nc();

                 case 0xd5: // push_de();

                 case 0xd6: // sub_byte();

                 case 0xd7: // rst_10();

                 case 0xd8: // ret_c();

                 case 0xd9: // exx();

                 case 0xda: // jp_c();

                 case 0xdb: // in_a_byte();

                 case 0xdc: // call_c();

                 case 0xde: // sbc_a_byte();

                 case 0xdf: // rst_18();

                 case 0xe0: // ret_po();

                 case 0xe2: // jp_po();

                 case 0xe4: // call_po();

                 case 0xe6: // and_byte();

                 case 0xe7: // rst_20();

                 case 0xe8: // ret_pe();

                 case 0xea: // jp_pe();

                 case 0xeb: // ex_de_hl();

                 case 0xec: // call_pe();

                 case 0xed: // ed();

                 case 0xee: // xor_byte();

                 case 0xef: // rst_28();

                 case 0xf0: // ret_p();

                 case 0xf1: // pop_af();

                 case 0xf2: // jp_p();

                 case 0xf3: // di();

                 case 0xf4: // call_p();

                 case 0xf5: // push_af();

                 case 0xf6: // or_byte();

                 case 0xf7: // rst_30();

                 case 0xf8: // ret_m();

                 case 0xfa: // jp_m();

                 case 0xfb: // ei();

                 case 0xfc: // call_m();

                 case 0xfe: // cp_byte();

                 case 0xff: // rst_38();

                         if constexpr (T::IS_R800) {

                                 II ii = nop();

                                 ii.cycles += T::CC_DD;

                                 NEXT;

                         } else {

                                 T::add(T::CC_DD);

                                 #ifdef USE_COMPUTED_GOTO

                                 goto *(opcodeTable[opcodeFD]);

                                 #else

                                 opcodeMain = opcodeFD;

                                 goto switchopcode;

                                 #endif

                         }


                 case 0x09: { II ii = add_SS_TT<IY,BC,T::CC_DD>(); NEXT; }

                 case 0x19: { II ii = add_SS_TT<IY,DE,T::CC_DD>(); NEXT; }

                 case 0x29: { II ii = add_SS_SS<IY   ,T::CC_DD>(); NEXT; }

                 case 0x39: { II ii = add_SS_TT<IY,SP,T::CC_DD>(); NEXT; }

                 case 0x21: { II ii = ld_SS_word<IY,T::CC_DD>();  NEXT; }

                 case 0x22: { II ii = ld_xword_SS<IY,T::CC_DD>(); NEXT; }

                 case 0x2a: { II ii = ld_SS_xword<IY,T::CC_DD>(); NEXT; }

                 case 0x23: { II ii = inc_SS<IY,T::CC_DD>(); NEXT; }

                 case 0x2b: { II ii = dec_SS<IY,T::CC_DD>(); NEXT; }

                 case 0x24: { II ii = inc_R<IYH,T::CC_DD>(); NEXT; }

                 case 0x2c: { II ii = inc_R<IYL,T::CC_DD>(); NEXT; }

                 case 0x25: { II ii = dec_R<IYH,T::CC_DD>(); NEXT; }

                 case 0x2d: { II ii = dec_R<IYL,T::CC_DD>(); NEXT; }

                 case 0x26: { II ii = ld_R_byte<IYH,T::CC_DD>(); NEXT; }

                 case 0x2e: { II ii = ld_R_byte<IYL,T::CC_DD>(); NEXT; }

                 case 0x34: { II ii = inc_xix<IY>(); NEXT; }

                 case 0x35: { II ii = dec_xix<IY>(); NEXT; }

                 case 0x36: { II ii = ld_xix_byte<IY>(); NEXT; }


                 case 0x44: { II ii = ld_R_R<B,IYH,T::CC_DD>(); NEXT; }

                 case 0x45: { II ii = ld_R_R<B,IYL,T::CC_DD>(); NEXT; }

                 case 0x4c: { II ii = ld_R_R<C,IYH,T::CC_DD>(); NEXT; }

                 case 0x4d: { II ii = ld_R_R<C,IYL,T::CC_DD>(); NEXT; }

                 case 0x54: { II ii = ld_R_R<D,IYH,T::CC_DD>(); NEXT; }

                 case 0x55: { II ii = ld_R_R<D,IYL,T::CC_DD>(); NEXT; }

                 case 0x5c: { II ii = ld_R_R<E,IYH,T::CC_DD>(); NEXT; }

                 case 0x5d: { II ii = ld_R_R<E,IYL,T::CC_DD>(); NEXT; }

                 case 0x7c: { II ii = ld_R_R<A,IYH,T::CC_DD>(); NEXT; }

                 case 0x7d: { II ii = ld_R_R<A,IYL,T::CC_DD>(); NEXT; }

                 case 0x60: { II ii = ld_R_R<IYH,B,T::CC_DD>(); NEXT; }

                 case 0x61: { II ii = ld_R_R<IYH,C,T::CC_DD>(); NEXT; }

                 case 0x62: { II ii = ld_R_R<IYH,D,T::CC_DD>(); NEXT; }

                 case 0x63: { II ii = ld_R_R<IYH,E,T::CC_DD>(); NEXT; }

                 case 0x65: { II ii = ld_R_R<IYH,IYL,T::CC_DD>(); NEXT; }

                 case 0x67: { II ii = ld_R_R<IYH,A,T::CC_DD>(); NEXT; }

                 case 0x68: { II ii = ld_R_R<IYL,B,T::CC_DD>(); NEXT; }

                 case 0x69: { II ii = ld_R_R<IYL,C,T::CC_DD>(); NEXT; }

                 case 0x6a: { II ii = ld_R_R<IYL,D,T::CC_DD>(); NEXT; }

                 case 0x6b: { II ii = ld_R_R<IYL,E,T::CC_DD>(); NEXT; }

                 case 0x6c: { II ii = ld_R_R<IYL,IYH,T::CC_DD>(); NEXT; }

                 case 0x6f: { II ii = ld_R_R<IYL,A,T::CC_DD>(); NEXT; }

                 case 0x70: { II ii = ld_xix_R<IY,B>(); NEXT; }

                 case 0x71: { II ii = ld_xix_R<IY,C>(); NEXT; }

                 case 0x72: { II ii = ld_xix_R<IY,D>(); NEXT; }

                 case 0x73: { II ii = ld_xix_R<IY,E>(); NEXT; }

                 case 0x74: { II ii = ld_xix_R<IY,H>(); NEXT; }

                 case 0x75: { II ii = ld_xix_R<IY,L>(); NEXT; }

                 case 0x77: { II ii = ld_xix_R<IY,A>(); NEXT; }

                 case 0x46: { II ii = ld_R_xix<B,IY>(); NEXT; }

                 case 0x4e: { II ii = ld_R_xix<C,IY>(); NEXT; }

                 case 0x56: { II ii = ld_R_xix<D,IY>(); NEXT; }

                 case 0x5e: { II ii = ld_R_xix<E,IY>(); NEXT; }

                 case 0x66: { II ii = ld_R_xix<H,IY>(); NEXT; }

                 case 0x6e: { II ii = ld_R_xix<L,IY>(); NEXT; }

                 case 0x7e: { II ii = ld_R_xix<A,IY>(); NEXT; }


                 case 0x84: { II ii = add_a_R<IYH,T::CC_DD>(); NEXT; }

                 case 0x85: { II ii = add_a_R<IYL,T::CC_DD>(); NEXT; }

                 case 0x86: { II ii = add_a_xix<IY>(); NEXT; }

                 case 0x8c: { II ii = adc_a_R<IYH,T::CC_DD>(); NEXT; }

                 case 0x8d: { II ii = adc_a_R<IYL,T::CC_DD>(); NEXT; }

                 case 0x8e: { II ii = adc_a_xix<IY>(); NEXT; }

                 case 0x94: { II ii = sub_R<IYH,T::CC_DD>(); NEXT; }

                 case 0x95: { II ii = sub_R<IYL,T::CC_DD>(); NEXT; }

                 case 0x96: { II ii = sub_xix<IY>(); NEXT; }

                 case 0x9c: { II ii = sbc_a_R<IYH,T::CC_DD>(); NEXT; }

                 case 0x9d: { II ii = sbc_a_R<IYL,T::CC_DD>(); NEXT; }

                 case 0x9e: { II ii = sbc_a_xix<IY>(); NEXT; }

                 case 0xa4: { II ii = and_R<IYH,T::CC_DD>(); NEXT; }

                 case 0xa5: { II ii = and_R<IYL,T::CC_DD>(); NEXT; }

                 case 0xa6: { II ii = and_xix<IY>(); NEXT; }

                 case 0xac: { II ii = xor_R<IYH,T::CC_DD>(); NEXT; }

                 case 0xad: { II ii = xor_R<IYL,T::CC_DD>(); NEXT; }

                 case 0xae: { II ii = xor_xix<IY>(); NEXT; }

                 case 0xb4: { II ii = or_R<IYH,T::CC_DD>(); NEXT; }

                 case 0xb5: { II ii = or_R<IYL,T::CC_DD>(); NEXT; }

                 case 0xb6: { II ii = or_xix<IY>(); NEXT; }

                 case 0xbc: { II ii = cp_R<IYH,T::CC_DD>(); NEXT; }

                 case 0xbd: { II ii = cp_R<IYL,T::CC_DD>(); NEXT; }

                 case 0xbe: { II ii = cp_xix<IY>(); NEXT; }


                 case 0xe1: { II ii = pop_SS <IY,T::CC_DD>(); NEXT; }

                 case 0xe5: { II ii = push_SS<IY,T::CC_DD>(); NEXT; }

                 case 0xe3: { II ii = ex_xsp_SS<IY,T::CC_DD>(); NEXT; }

                 case 0xe9: { II ii = jp_SS<IY,T::CC_DD>(); NEXT; }

                 case 0xf9: { II ii = ld_sp_SS<IY,T::CC_DD>(); NEXT; }

                 case 0xcb: ixy = getIY(); goto xx_cb;

                 case 0xdd: T::add(T::CC_DD); goto opDD_2;

                 case 0xfd: T::add(T::CC_DD); goto opFD_2;

                 default: UNREACHABLE; return;

         }

 }

 #ifndef USE_COMPUTED_GOTO

         default: UNREACHABLE; return;

 }

 #endif


 xx_cb: {

                 unsigned tmp = RD_WORD_PC<1>(T::CC_DD + T::CC_DD_CB);

                 int8_t ofst = tmp & 0xFF;

                 unsigned addr = (ixy + ofst) & 0xFFFF;

                 byte xxcb_opcode = tmp >> 8;

                 switch (xxcb_opcode) {

                         case 0x00: { II ii = rlc_xix_R<B>(addr); NEXT; }

                         case 0x01: { II ii = rlc_xix_R<C>(addr); NEXT; }

                         case 0x02: { II ii = rlc_xix_R<D>(addr); NEXT; }

                         case 0x03: { II ii = rlc_xix_R<E>(addr); NEXT; }

                         case 0x04: { II ii = rlc_xix_R<H>(addr); NEXT; }

                         case 0x05: { II ii = rlc_xix_R<L>(addr); NEXT; }

                         case 0x06: { II ii = rlc_xix_R<DUMMY>(addr); NEXT; }

                         case 0x07: { II ii = rlc_xix_R<A>(addr); NEXT; }

                         case 0x08: { II ii = rrc_xix_R<B>(addr); NEXT; }

                         case 0x09: { II ii = rrc_xix_R<C>(addr); NEXT; }

                         case 0x0a: { II ii = rrc_xix_R<D>(addr); NEXT; }

                         case 0x0b: { II ii = rrc_xix_R<E>(addr); NEXT; }

                         case 0x0c: { II ii = rrc_xix_R<H>(addr); NEXT; }

                         case 0x0d: { II ii = rrc_xix_R<L>(addr); NEXT; }

                         case 0x0e: { II ii = rrc_xix_R<DUMMY>(addr); NEXT; }

                         case 0x0f: { II ii = rrc_xix_R<A>(addr); NEXT; }

                         case 0x10: { II ii = rl_xix_R<B>(addr); NEXT; }

                         case 0x11: { II ii = rl_xix_R<C>(addr); NEXT; }

                         case 0x12: { II ii = rl_xix_R<D>(addr); NEXT; }

                         case 0x13: { II ii = rl_xix_R<E>(addr); NEXT; }

                         case 0x14: { II ii = rl_xix_R<H>(addr); NEXT; }

                         case 0x15: { II ii = rl_xix_R<L>(addr); NEXT; }

                         case 0x16: { II ii = rl_xix_R<DUMMY>(addr); NEXT; }

                         case 0x17: { II ii = rl_xix_R<A>(addr); NEXT; }

                         case 0x18: { II ii = rr_xix_R<B>(addr); NEXT; }

                         case 0x19: { II ii = rr_xix_R<C>(addr); NEXT; }

                         case 0x1a: { II ii = rr_xix_R<D>(addr); NEXT; }

                         case 0x1b: { II ii = rr_xix_R<E>(addr); NEXT; }

                         case 0x1c: { II ii = rr_xix_R<H>(addr); NEXT; }

                         case 0x1d: { II ii = rr_xix_R<L>(addr); NEXT; }

                         case 0x1e: { II ii = rr_xix_R<DUMMY>(addr); NEXT; }

                         case 0x1f: { II ii = rr_xix_R<A>(addr); NEXT; }

                         case 0x20: { II ii = sla_xix_R<B>(addr); NEXT; }

                         case 0x21: { II ii = sla_xix_R<C>(addr); NEXT; }

                         case 0x22: { II ii = sla_xix_R<D>(addr); NEXT; }

                         case 0x23: { II ii = sla_xix_R<E>(addr); NEXT; }

                         case 0x24: { II ii = sla_xix_R<H>(addr); NEXT; }

                         case 0x25: { II ii = sla_xix_R<L>(addr); NEXT; }

                         case 0x26: { II ii = sla_xix_R<DUMMY>(addr); NEXT; }

                         case 0x27: { II ii = sla_xix_R<A>(addr); NEXT; }

                         case 0x28: { II ii = sra_xix_R<B>(addr); NEXT; }

                         case 0x29: { II ii = sra_xix_R<C>(addr); NEXT; }

                         case 0x2a: { II ii = sra_xix_R<D>(addr); NEXT; }

                         case 0x2b: { II ii = sra_xix_R<E>(addr); NEXT; }

                         case 0x2c: { II ii = sra_xix_R<H>(addr); NEXT; }

                         case 0x2d: { II ii = sra_xix_R<L>(addr); NEXT; }

                         case 0x2e: { II ii = sra_xix_R<DUMMY>(addr); NEXT; }

                         case 0x2f: { II ii = sra_xix_R<A>(addr); NEXT; }

                         case 0x30: { II ii = T::IS_R800 ? sll2() : sll_xix_R<B>(addr); NEXT; }

                         case 0x31: { II ii = T::IS_R800 ? sll2() : sll_xix_R<C>(addr); NEXT; }

                         case 0x32: { II ii = T::IS_R800 ? sll2() : sll_xix_R<D>(addr); NEXT; }

                         case 0x33: { II ii = T::IS_R800 ? sll2() : sll_xix_R<E>(addr); NEXT; }

                         case 0x34: { II ii = T::IS_R800 ? sll2() : sll_xix_R<H>(addr); NEXT; }

                         case 0x35: { II ii = T::IS_R800 ? sll2() : sll_xix_R<L>(addr); NEXT; }

                         case 0x36: { II ii = T::IS_R800 ? sll2() : sll_xix_R<DUMMY>(addr); NEXT; }

                         case 0x37: { II ii = T::IS_R800 ? sll2() : sll_xix_R<A>(addr); NEXT; }

                         case 0x38: { II ii = srl_xix_R<B>(addr); NEXT; }

                         case 0x39: { II ii = srl_xix_R<C>(addr); NEXT; }

                         case 0x3a: { II ii = srl_xix_R<D>(addr); NEXT; }

                         case 0x3b: { II ii = srl_xix_R<E>(addr); NEXT; }

                         case 0x3c: { II ii = srl_xix_R<H>(addr); NEXT; }

                         case 0x3d: { II ii = srl_xix_R<L>(addr); NEXT; }

                         case 0x3e: { II ii = srl_xix_R<DUMMY>(addr); NEXT; }

                         case 0x3f: { II ii = srl_xix_R<A>(addr); NEXT; }


                         case 0x40: case 0x41: case 0x42: case 0x43:

                         case 0x44: case 0x45: case 0x46: case 0x47:

                                    { II ii = bit_N_xix<0>(addr); NEXT; }

                         case 0x48: case 0x49: case 0x4a: case 0x4b:

                         case 0x4c: case 0x4d: case 0x4e: case 0x4f:

                                    { II ii = bit_N_xix<1>(addr); NEXT; }

                         case 0x50: case 0x51: case 0x52: case 0x53:

                         case 0x54: case 0x55: case 0x56: case 0x57:

                                    { II ii = bit_N_xix<2>(addr); NEXT; }

                         case 0x58: case 0x59: case 0x5a: case 0x5b:

                         case 0x5c: case 0x5d: case 0x5e: case 0x5f:

                                    { II ii = bit_N_xix<3>(addr); NEXT; }

                         case 0x60: case 0x61: case 0x62: case 0x63:

                         case 0x64: case 0x65: case 0x66: case 0x67:

                                    { II ii = bit_N_xix<4>(addr); NEXT; }

                         case 0x68: case 0x69: case 0x6a: case 0x6b:

                         case 0x6c: case 0x6d: case 0x6e: case 0x6f:

                                    { II ii = bit_N_xix<5>(addr); NEXT; }

                         case 0x70: case 0x71: case 0x72: case 0x73:

                         case 0x74: case 0x75: case 0x76: case 0x77:

                                    { II ii = bit_N_xix<6>(addr); NEXT; }

                         case 0x78: case 0x79: case 0x7a: case 0x7b:

                         case 0x7c: case 0x7d: case 0x7e: case 0x7f:

                                    { II ii = bit_N_xix<7>(addr); NEXT; }


                         case 0x80: { II ii = res_N_xix_R<0,B>(addr); NEXT; }

                         case 0x81: { II ii = res_N_xix_R<0,C>(addr); NEXT; }

                         case 0x82: { II ii = res_N_xix_R<0,D>(addr); NEXT; }

                         case 0x83: { II ii = res_N_xix_R<0,E>(addr); NEXT; }

                         case 0x84: { II ii = res_N_xix_R<0,H>(addr); NEXT; }

                         case 0x85: { II ii = res_N_xix_R<0,L>(addr); NEXT; }

                         case 0x87: { II ii = res_N_xix_R<0,A>(addr); NEXT; }

                         case 0x88: { II ii = res_N_xix_R<1,B>(addr); NEXT; }

                         case 0x89: { II ii = res_N_xix_R<1,C>(addr); NEXT; }

                         case 0x8a: { II ii = res_N_xix_R<1,D>(addr); NEXT; }

                         case 0x8b: { II ii = res_N_xix_R<1,E>(addr); NEXT; }

                         case 0x8c: { II ii = res_N_xix_R<1,H>(addr); NEXT; }

                         case 0x8d: { II ii = res_N_xix_R<1,L>(addr); NEXT; }

                         case 0x8f: { II ii = res_N_xix_R<1,A>(addr); NEXT; }

                         case 0x90: { II ii = res_N_xix_R<2,B>(addr); NEXT; }

                         case 0x91: { II ii = res_N_xix_R<2,C>(addr); NEXT; }

                         case 0x92: { II ii = res_N_xix_R<2,D>(addr); NEXT; }

                         case 0x93: { II ii = res_N_xix_R<2,E>(addr); NEXT; }

                         case 0x94: { II ii = res_N_xix_R<2,H>(addr); NEXT; }

                         case 0x95: { II ii = res_N_xix_R<2,L>(addr); NEXT; }

                         case 0x97: { II ii = res_N_xix_R<2,A>(addr); NEXT; }

                         case 0x98: { II ii = res_N_xix_R<3,B>(addr); NEXT; }

                         case 0x99: { II ii = res_N_xix_R<3,C>(addr); NEXT; }

                         case 0x9a: { II ii = res_N_xix_R<3,D>(addr); NEXT; }

                         case 0x9b: { II ii = res_N_xix_R<3,E>(addr); NEXT; }

                         case 0x9c: { II ii = res_N_xix_R<3,H>(addr); NEXT; }

                         case 0x9d: { II ii = res_N_xix_R<3,L>(addr); NEXT; }

                         case 0x9f: { II ii = res_N_xix_R<3,A>(addr); NEXT; }

                         case 0xa0: { II ii = res_N_xix_R<4,B>(addr); NEXT; }

                         case 0xa1: { II ii = res_N_xix_R<4,C>(addr); NEXT; }

                         case 0xa2: { II ii = res_N_xix_R<4,D>(addr); NEXT; }

                         case 0xa3: { II ii = res_N_xix_R<4,E>(addr); NEXT; }

                         case 0xa4: { II ii = res_N_xix_R<4,H>(addr); NEXT; }

                         case 0xa5: { II ii = res_N_xix_R<4,L>(addr); NEXT; }

                         case 0xa7: { II ii = res_N_xix_R<4,A>(addr); NEXT; }

                         case 0xa8: { II ii = res_N_xix_R<5,B>(addr); NEXT; }

                         case 0xa9: { II ii = res_N_xix_R<5,C>(addr); NEXT; }

                         case 0xaa: { II ii = res_N_xix_R<5,D>(addr); NEXT; }

                         case 0xab: { II ii = res_N_xix_R<5,E>(addr); NEXT; }

                         case 0xac: { II ii = res_N_xix_R<5,H>(addr); NEXT; }

                         case 0xad: { II ii = res_N_xix_R<5,L>(addr); NEXT; }

                         case 0xaf: { II ii = res_N_xix_R<5,A>(addr); NEXT; }

                         case 0xb0: { II ii = res_N_xix_R<6,B>(addr); NEXT; }

                         case 0xb1: { II ii = res_N_xix_R<6,C>(addr); NEXT; }

                         case 0xb2: { II ii = res_N_xix_R<6,D>(addr); NEXT; }

                         case 0xb3: { II ii = res_N_xix_R<6,E>(addr); NEXT; }

                         case 0xb4: { II ii = res_N_xix_R<6,H>(addr); NEXT; }

                         case 0xb5: { II ii = res_N_xix_R<6,L>(addr); NEXT; }

                         case 0xb7: { II ii = res_N_xix_R<6,A>(addr); NEXT; }

                         case 0xb8: { II ii = res_N_xix_R<7,B>(addr); NEXT; }

                         case 0xb9: { II ii = res_N_xix_R<7,C>(addr); NEXT; }

                         case 0xba: { II ii = res_N_xix_R<7,D>(addr); NEXT; }

                         case 0xbb: { II ii = res_N_xix_R<7,E>(addr); NEXT; }

                         case 0xbc: { II ii = res_N_xix_R<7,H>(addr); NEXT; }

                         case 0xbd: { II ii = res_N_xix_R<7,L>(addr); NEXT; }

                         case 0xbf: { II ii = res_N_xix_R<7,A>(addr); NEXT; }

                         case 0x86: { II ii = res_N_xix_R<0,DUMMY>(addr); NEXT; }

                         case 0x8e: { II ii = res_N_xix_R<1,DUMMY>(addr); NEXT; }

                         case 0x96: { II ii = res_N_xix_R<2,DUMMY>(addr); NEXT; }

                         case 0x9e: { II ii = res_N_xix_R<3,DUMMY>(addr); NEXT; }

                         case 0xa6: { II ii = res_N_xix_R<4,DUMMY>(addr); NEXT; }

                         case 0xae: { II ii = res_N_xix_R<5,DUMMY>(addr); NEXT; }

                         case 0xb6: { II ii = res_N_xix_R<6,DUMMY>(addr); NEXT; }

                         case 0xbe: { II ii = res_N_xix_R<7,DUMMY>(addr); NEXT; }


                         case 0xc0: { II ii = set_N_xix_R<0,B>(addr); NEXT; }

                         case 0xc1: { II ii = set_N_xix_R<0,C>(addr); NEXT; }

                         case 0xc2: { II ii = set_N_xix_R<0,D>(addr); NEXT; }

                         case 0xc3: { II ii = set_N_xix_R<0,E>(addr); NEXT; }

                         case 0xc4: { II ii = set_N_xix_R<0,H>(addr); NEXT; }

                         case 0xc5: { II ii = set_N_xix_R<0,L>(addr); NEXT; }

                         case 0xc7: { II ii = set_N_xix_R<0,A>(addr); NEXT; }

                         case 0xc8: { II ii = set_N_xix_R<1,B>(addr); NEXT; }

                         case 0xc9: { II ii = set_N_xix_R<1,C>(addr); NEXT; }

                         case 0xca: { II ii = set_N_xix_R<1,D>(addr); NEXT; }

                         case 0xcb: { II ii = set_N_xix_R<1,E>(addr); NEXT; }

                         case 0xcc: { II ii = set_N_xix_R<1,H>(addr); NEXT; }

                         case 0xcd: { II ii = set_N_xix_R<1,L>(addr); NEXT; }

                         case 0xcf: { II ii = set_N_xix_R<1,A>(addr); NEXT; }

                         case 0xd0: { II ii = set_N_xix_R<2,B>(addr); NEXT; }

                         case 0xd1: { II ii = set_N_xix_R<2,C>(addr); NEXT; }

                         case 0xd2: { II ii = set_N_xix_R<2,D>(addr); NEXT; }

                         case 0xd3: { II ii = set_N_xix_R<2,E>(addr); NEXT; }

                         case 0xd4: { II ii = set_N_xix_R<2,H>(addr); NEXT; }

                         case 0xd5: { II ii = set_N_xix_R<2,L>(addr); NEXT; }

                         case 0xd7: { II ii = set_N_xix_R<2,A>(addr); NEXT; }

                         case 0xd8: { II ii = set_N_xix_R<3,B>(addr); NEXT; }

                         case 0xd9: { II ii = set_N_xix_R<3,C>(addr); NEXT; }

                         case 0xda: { II ii = set_N_xix_R<3,D>(addr); NEXT; }

                         case 0xdb: { II ii = set_N_xix_R<3,E>(addr); NEXT; }

                         case 0xdc: { II ii = set_N_xix_R<3,H>(addr); NEXT; }

                         case 0xdd: { II ii = set_N_xix_R<3,L>(addr); NEXT; }

                         case 0xdf: { II ii = set_N_xix_R<3,A>(addr); NEXT; }

                         case 0xe0: { II ii = set_N_xix_R<4,B>(addr); NEXT; }

                         case 0xe1: { II ii = set_N_xix_R<4,C>(addr); NEXT; }

                         case 0xe2: { II ii = set_N_xix_R<4,D>(addr); NEXT; }

                         case 0xe3: { II ii = set_N_xix_R<4,E>(addr); NEXT; }

                         case 0xe4: { II ii = set_N_xix_R<4,H>(addr); NEXT; }

                         case 0xe5: { II ii = set_N_xix_R<4,L>(addr); NEXT; }

                         case 0xe7: { II ii = set_N_xix_R<4,A>(addr); NEXT; }

                         case 0xe8: { II ii = set_N_xix_R<5,B>(addr); NEXT; }

                         case 0xe9: { II ii = set_N_xix_R<5,C>(addr); NEXT; }

                         case 0xea: { II ii = set_N_xix_R<5,D>(addr); NEXT; }

                         case 0xeb: { II ii = set_N_xix_R<5,E>(addr); NEXT; }

                         case 0xec: { II ii = set_N_xix_R<5,H>(addr); NEXT; }

                         case 0xed: { II ii = set_N_xix_R<5,L>(addr); NEXT; }

                         case 0xef: { II ii = set_N_xix_R<5,A>(addr); NEXT; }

                         case 0xf0: { II ii = set_N_xix_R<6,B>(addr); NEXT; }

                         case 0xf1: { II ii = set_N_xix_R<6,C>(addr); NEXT; }

                         case 0xf2: { II ii = set_N_xix_R<6,D>(addr); NEXT; }

                         case 0xf3: { II ii = set_N_xix_R<6,E>(addr); NEXT; }

                         case 0xf4: { II ii = set_N_xix_R<6,H>(addr); NEXT; }

                         case 0xf5: { II ii = set_N_xix_R<6,L>(addr); NEXT; }

                         case 0xf7: { II ii = set_N_xix_R<6,A>(addr); NEXT; }

                         case 0xf8: { II ii = set_N_xix_R<7,B>(addr); NEXT; }

                         case 0xf9: { II ii = set_N_xix_R<7,C>(addr); NEXT; }

                         case 0xfa: { II ii = set_N_xix_R<7,D>(addr); NEXT; }

                         case 0xfb: { II ii = set_N_xix_R<7,E>(addr); NEXT; }

                         case 0xfc: { II ii = set_N_xix_R<7,H>(addr); NEXT; }

                         case 0xfd: { II ii = set_N_xix_R<7,L>(addr); NEXT; }

                         case 0xff: { II ii = set_N_xix_R<7,A>(addr); NEXT; }

                         case 0xc6: { II ii = set_N_xix_R<0,DUMMY>(addr); NEXT; }

                         case 0xce: { II ii = set_N_xix_R<1,DUMMY>(addr); NEXT; }

                         case 0xd6: { II ii = set_N_xix_R<2,DUMMY>(addr); NEXT; }

                         case 0xde: { II ii = set_N_xix_R<3,DUMMY>(addr); NEXT; }

                         case 0xe6: { II ii = set_N_xix_R<4,DUMMY>(addr); NEXT; }

                         case 0xee: { II ii = set_N_xix_R<5,DUMMY>(addr); NEXT; }

                         case 0xf6: { II ii = set_N_xix_R<6,DUMMY>(addr); NEXT; }

                         case 0xfe: { II ii = set_N_xix_R<7,DUMMY>(addr); NEXT; }

                         default: UNREACHABLE;

                 }

         }

 }


 template<typename T> inline void CPUCore<T>::cpuTracePre()

 {

         start_pc = getPC();

 }

 template<typename T> inline void CPUCore<T>::cpuTracePost()

 {

         if (unlikely(tracingEnabled)) {

                 cpuTracePost_slow();

         }

 }

 template<typename T> void CPUCore<T>::cpuTracePost_slow()

 {

         byte opBuf[4];

         std::string dasmOutput;

         dasm(*interface, start_pc, opBuf, dasmOutput, T::getTimeFast());

         std::cout << strCat(hex_string<4>(start_pc),

                             " : ", dasmOutput,

                             " AF=", hex_string<4>(getAF()),

                             " BC=", hex_string<4>(getBC()),

                             " DE=", hex_string<4>(getDE()),

                             " HL=", hex_string<4>(getHL()),

                             " IX=", hex_string<4>(getIX()),

                             " IY=", hex_string<4>(getIY()),

                             " SP=", hex_string<4>(getSP()),

                             '\n')

                   << std::flush;

 }


 template<typename T> ExecIRQ CPUCore<T>::getExecIRQ() const

 {

         if (unlikely(nmiEdge)) return ExecIRQ::NMI;

         if (unlikely(IRQStatus && getIFF1() && !prevWasEI())) return ExecIRQ::IRQ;

         return ExecIRQ::NONE;

 }


 template<typename T> void CPUCore<T>::executeSlow(ExecIRQ execIRQ)

 {

         if (unlikely(execIRQ == ExecIRQ::NMI)) {

                 nmiEdge = false;

                 nmi(); // NMI occurred

         } else if (unlikely(execIRQ == ExecIRQ::IRQ)) {

                 // normal interrupt

                 if (unlikely(prevWasLDAI())) {

                         // HACK!!!

                         // The 'ld a,i' or 'ld a,r' instruction copies the IFF2

                         // bit to the V flag. Though when the Z80 accepts an

                         // IRQ directly after this instruction, the V flag is 0

                         // (instead of the expected value 1). This can probably

                         // be explained if you look at the pipeline of the Z80.

                         // But for speed reasons we implement it here as a

                         // fix-up (a hack) in the IRQ routine. This behaviour

                         // is actually a bug in the Z80.

                         // Thanks to n_n for reporting this behaviour. I think

                         // this was discovered by GuyveR800. Also thanks to

                         // n_n for writing a test program that demonstrates

                         // this quirk.

                         // I also wrote a test program that demonstrates this

                         // behaviour is the same whether 'ld a,i' is preceded

                         // by a 'ei' instruction or not (so it's not caused by

                         // the 'delayed IRQ acceptance of ei').

                         assert(getF() & V_FLAG);

                         setF(getF() & ~V_FLAG);

                 }

                 IRQAccept.signal();

                 switch (getIM()) {

                         case 0: irq0();

                                 break;

                         case 1: irq1();

                                 break;

                         case 2: irq2();

                                 break;

                         default:

                                 UNREACHABLE;

                 }

         } else if (unlikely(getHALT())) {

                 // in halt mode

                 incR(T::advanceHalt(T::HALT_STATES, scheduler.getNext()));

                 setSlowInstructions();

         } else {

                 cpuTracePre();

                 assert(T::limitReached()); // we want only one instruction

                 executeInstructions();

                 endInstruction();


                 if constexpr (T::IS_R800) {

                         if (unlikely(prev2WasCall()) && likely(!prevWasPopRet())) {

                                 // On R800 a CALL or RST instruction not _immediately_

                                 // followed by a (single-byte) POP or RET instruction

                                 // causes an extra cycle in that following instruction.

                                 // No idea why yet. See doc/internal/r800-call.txt

                                 // for more information.

                                 //

                                 // TODO this implementation adds the extra cycle at

                                 // the end of the instruction POP/RET. It is not known

                                 // where in the instruction the real R800 adds this cycle.

                                 T::add(1);

                         }

                 }

                 cpuTracePost();

         }

 }


 template<typename T> void CPUCore<T>::execute(bool fastForward)

 {

         // In fast-forward mode, breakpoints, watchpoints or debug condtions

         // won't trigger. It is possible we already are in break mode, but

         // break is ignored in fast-forward mode.

         assert(fastForward || !interface->isBreaked());

         if (fastForward) {

                 interface->setFastForward(true);

         }

         execute2(fastForward);

         interface->setFastForward(false);

 }


 template<typename T> void CPUCore<T>::execute2(bool fastForward)

 {

         // note: Don't use getTimeFast() here, because 'once in a while' we

         //       need to CPUClock::sync() to avoid overflow.

         //       Should be done at least once per second (approx). So only

         //       once in this method is enough.

         scheduler.schedule(T::getTime());

         setSlowInstructions();


         // Note: we call scheduler _after_ executing the instruction and before

         // deciding between executeFast() and executeSlow() (because a

         // SyncPoint could set an IRQ and then we must choose executeSlow())

         if (fastForward ||

             (!interface->anyBreakPoints() && !tracingEnabled)) {

                 // fast path, no breakpoints, no tracing

                 do {

                         if (slowInstructions) {

                                 --slowInstructions;

                                 executeSlow(getExecIRQ());

                                 scheduler.schedule(T::getTimeFast());

                         } else {

                                 while (slowInstructions == 0) {

                                         T::enableLimit(); // does CPUClock::sync()

                                         if (likely(!T::limitReached())) {

                                                 // multiple instructions

                                                 executeInstructions();

                                                 // note: pipeline only shifted one

                                                 // step for multiple instructions

                                                 endInstruction();

                                         }

                                         scheduler.schedule(T::getTimeFast());

                                         if (needExitCPULoop()) return;

                                 }

                         }

                 } while (!needExitCPULoop());

         } else {

                 do {

                         if (slowInstructions == 0) {

                                 cpuTracePre();

                                 assert(T::limitReached()); // only one instruction

                                 executeInstructions();

                                 endInstruction();

                                 cpuTracePost();

                         } else {

                                 --slowInstructions;

                                 executeSlow(getExecIRQ());

                         }

                         // Don't use getTimeFast() here, we need a call to

                         // CPUClock::sync() 'once in a while'. (During a

                         // reverse fast-forward this wasn't always the case).

                         scheduler.schedule(T::getTime());


                         // Only check for breakpoints when we're not about to jump to an IRQ handler.

                         //

                         // This fixes the following problem reported by Grauw:

                         //

                         //   I found a breakpoints bug: sometimes a breakpoint gets hit twice even

                         //   though the code is executed once. This manifests itself in my profiler

                         //   as an imbalance between section begin- and end-calls.

                         //

                         //   Turns out this occurs when an interrupt occurs exactly on the line of

                         //   the breakpoint, then the breakpoint gets hit before immediately going

                         //   to the ISR, as well as when returning from the ISR.

                         //

                         //   The IRQ is handled by the Z80 at the end of an instruction. So it

                         //   should change the PC before the next instruction is fetched and the

                         //   breakpoints should be evaluated during instruction fetch.

                         //

                         // I think Grauw's analysis is correct. Though for performance reasons we

                         // don't emulate the Z80 like that: we don't check for IRQs at the end of

                         // every instruction. In the openMSX emulation model, we can only enter an

                         // ISR:

                         //  - (One instruction after) switching from DI to EI mode.

                         //  - After emulating device code. This can be:

                         //    * When the Z80 communicated with the device (IO or memory mapped IO).

                         //    * The device had set a synchronization point.

                         //  In all cases disableLimit() gets called which will cause

                         //  limitReached() to return true (and possibly slowInstructions to be > 0).

                         // So after most emulated Z80 instructions there can't be a pending IRQ, so

                         // checking for it is wasteful. Also synchronization points are handled

                         // between emulated Z80 instructions, that means me must check for pending

                         // IRQs at the start (instead of end) of an instruction.

                         //

                         auto execIRQ = getExecIRQ();

                         if ((execIRQ == ExecIRQ::NONE) &&

                             interface->checkBreakPoints(getPC())) {

                                 assert(interface->isBreaked());

                                 break;

                         }

                 } while (!needExitCPULoop());

         }

 }


 template<typename T> template<Reg8 R8> ALWAYS_INLINE byte CPUCore<T>::get8() const {

         if      constexpr (R8 == A)     { return getA(); }

         else if constexpr (R8 == F)     { return getF(); }

         else if constexpr (R8 == B)     { return getB(); }

         else if constexpr (R8 == C)     { return getC(); }

         else if constexpr (R8 == D)     { return getD(); }

         else if constexpr (R8 == E)     { return getE(); }

         else if constexpr (R8 == H)     { return getH(); }

         else if constexpr (R8 == L)     { return getL(); }

         else if constexpr (R8 == IXH)   { return getIXh(); }

         else if constexpr (R8 == IXL)   { return getIXl(); }

         else if constexpr (R8 == IYH)   { return getIYh(); }

         else if constexpr (R8 == IYL)   { return getIYl(); }

         else if constexpr (R8 == REG_I) { return getI(); }

         else if constexpr (R8 == REG_R) { return getR(); }

         else if constexpr (R8 == DUMMY) { return 0; }

         else { UNREACHABLE; return 0; }

 }

 template<typename T> template<Reg16 R16> ALWAYS_INLINE unsigned CPUCore<T>::get16() const {

         if      constexpr (R16 == AF) { return getAF(); }

         else if constexpr (R16 == BC) { return getBC(); }

         else if constexpr (R16 == DE) { return getDE(); }

         else if constexpr (R16 == HL) { return getHL(); }

         else if constexpr (R16 == IX) { return getIX(); }

         else if constexpr (R16 == IY) { return getIY(); }

         else if constexpr (R16 == SP) { return getSP(); }

         else { UNREACHABLE; return 0; }

 }

 template<typename T> template<Reg8 R8> ALWAYS_INLINE void CPUCore<T>::set8(byte x) {

         if      constexpr (R8 == A)     { setA(x); }

         else if constexpr (R8 == F)     { setF(x); }

         else if constexpr (R8 == B)     { setB(x); }

         else if constexpr (R8 == C)     { setC(x); }

         else if constexpr (R8 == D)     { setD(x); }

         else if constexpr (R8 == E)     { setE(x); }

         else if constexpr (R8 == H)     { setH(x); }

         else if constexpr (R8 == L)     { setL(x); }

         else if constexpr (R8 == IXH)   { setIXh(x); }

         else if constexpr (R8 == IXL)   { setIXl(x); }

         else if constexpr (R8 == IYH)   { setIYh(x); }

         else if constexpr (R8 == IYL)   { setIYl(x); }

         else if constexpr (R8 == REG_I) { setI(x); }

         else if constexpr (R8 == REG_R) { setR(x); }

         else if constexpr (R8 == DUMMY) { /* nothing */ }

         else { UNREACHABLE; }

 }

 template<typename T> template<Reg16 R16> ALWAYS_INLINE void CPUCore<T>::set16(unsigned x) {

         if      constexpr (R16 == AF) { setAF(x); }

         else if constexpr (R16 == BC) { setBC(x); }

         else if constexpr (R16 == DE) { setDE(x); }

         else if constexpr (R16 == HL) { setHL(x); }

         else if constexpr (R16 == IX) { setIX(x); }

         else if constexpr (R16 == IY) { setIY(x); }

         else if constexpr (R16 == SP) { setSP(x); }

         else { UNREACHABLE; }

 }


 // LD r,r

 template<typename T> template<Reg8 DST, Reg8 SRC, int EE> II CPUCore<T>::ld_R_R() {

         set8<DST>(get8<SRC>()); return {1, T::CC_LD_R_R + EE};

 }


 // LD SP,ss

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::ld_sp_SS() {

         setSP(get16<REG>()); return {1, T::CC_LD_SP_HL + EE};

 }


 // LD (ss),a

 template<typename T> template<Reg16 REG> II CPUCore<T>::ld_SS_a() {

         T::setMemPtr((getA() << 8) | ((get16<REG>() + 1) & 0xFF));

         WRMEM(get16<REG>(), getA(), T::CC_LD_SS_A_1);

         return {1, T::CC_LD_SS_A};

 }


 // LD (HL),r

 template<typename T> template<Reg8 SRC> II CPUCore<T>::ld_xhl_R() {

         WRMEM(getHL(), get8<SRC>(), T::CC_LD_HL_R_1);

         return {1, T::CC_LD_HL_R};

 }


 // LD (IXY+e),r

 template<typename T> template<Reg16 IXY, Reg8 SRC> II CPUCore<T>::ld_xix_R() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_LD_XIX_R_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         WRMEM(addr, get8<SRC>(), T::CC_DD + T::CC_LD_XIX_R_2);

         return {2, T::CC_DD + T::CC_LD_XIX_R};

 }


 // LD (HL),n

 template<typename T> II CPUCore<T>::ld_xhl_byte() {

         byte val = RDMEM_OPCODE<1>(T::CC_LD_HL_N_1);

         WRMEM(getHL(), val, T::CC_LD_HL_N_2);

         return {2, T::CC_LD_HL_N};

 }


 // LD (IXY+e),n

 template<typename T> template<Reg16 IXY> II CPUCore<T>::ld_xix_byte() {

         unsigned tmp = RD_WORD_PC<1>(T::CC_DD + T::CC_LD_XIX_N_1);

         int8_t ofst = tmp & 0xFF;

         byte val = tmp >> 8;

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         WRMEM(addr, val, T::CC_DD + T::CC_LD_XIX_N_2);

         return {3, T::CC_DD + T::CC_LD_XIX_N};

 }


 // LD (nn),A

 template<typename T> II CPUCore<T>::ld_xbyte_a() {

         unsigned x = RD_WORD_PC<1>(T::CC_LD_NN_A_1);

         T::setMemPtr((getA() << 8) | ((x + 1) & 0xFF));

         WRMEM(x, getA(), T::CC_LD_NN_A_2);

         return {3, T::CC_LD_NN_A};

 }


 // LD (nn),ss

 template<typename T> template<int EE> inline II CPUCore<T>::WR_NN_Y(unsigned reg) {

         unsigned addr = RD_WORD_PC<1>(T::CC_LD_XX_HL_1 + EE);

         T::setMemPtr(addr + 1);

         WR_WORD(addr, reg, T::CC_LD_XX_HL_2 + EE);

         return {3, T::CC_LD_XX_HL + EE};

 }

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::ld_xword_SS() {

         return WR_NN_Y<EE      >(get16<REG>());

 }

 template<typename T> template<Reg16 REG> II CPUCore<T>::ld_xword_SS_ED() {

         return WR_NN_Y<T::EE_ED>(get16<REG>());

 }


 // LD A,(ss)

 template<typename T> template<Reg16 REG> II CPUCore<T>::ld_a_SS() {

         T::setMemPtr(get16<REG>() + 1);

         setA(RDMEM(get16<REG>(), T::CC_LD_A_SS_1));

         return {1, T::CC_LD_A_SS};

 }


 // LD A,(nn)

 template<typename T> II CPUCore<T>::ld_a_xbyte() {

         unsigned addr = RD_WORD_PC<1>(T::CC_LD_A_NN_1);

         T::setMemPtr(addr + 1);

         setA(RDMEM(addr, T::CC_LD_A_NN_2));

         return {3, T::CC_LD_A_NN};

 }


 // LD r,n

 template<typename T> template<Reg8 DST, int EE> II CPUCore<T>::ld_R_byte() {

         set8<DST>(RDMEM_OPCODE<1>(T::CC_LD_R_N_1 + EE)); return {2, T::CC_LD_R_N + EE};

 }


 // LD r,(hl)

 template<typename T> template<Reg8 DST> II CPUCore<T>::ld_R_xhl() {

         set8<DST>(RDMEM(getHL(), T::CC_LD_R_HL_1)); return {1, T::CC_LD_R_HL};

 }


 // LD r,(IXY+e)

 template<typename T> template<Reg8 DST, Reg16 IXY> II CPUCore<T>::ld_R_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_LD_R_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         set8<DST>(RDMEM(addr, T::CC_DD + T::CC_LD_R_XIX_2));

         return {2, T::CC_DD + T::CC_LD_R_XIX};

 }


 // LD ss,(nn)

 template<typename T> template<int EE> inline unsigned CPUCore<T>::RD_P_XX() {

         unsigned addr = RD_WORD_PC<1>(T::CC_LD_HL_XX_1 + EE);

         T::setMemPtr(addr + 1);

         unsigned result = RD_WORD(addr, T::CC_LD_HL_XX_2 + EE);

         return result;

 }

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::ld_SS_xword() {

         set16<REG>(RD_P_XX<EE>());       return {3, T::CC_LD_HL_XX + EE};

 }

 template<typename T> template<Reg16 REG> II CPUCore<T>::ld_SS_xword_ED() {

         set16<REG>(RD_P_XX<T::EE_ED>()); return {3, T::CC_LD_HL_XX + T::EE_ED};

 }


 // LD ss,nn

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::ld_SS_word() {

         set16<REG>(RD_WORD_PC<1>(T::CC_LD_SS_NN_1 + EE)); return {3, T::CC_LD_SS_NN + EE};

 }


 // ADC A,r

 template<typename T> inline void CPUCore<T>::ADC(byte reg) {

         unsigned res = getA() + reg + ((getF() & C_FLAG) ? 1 : 0);

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  ((getA() ^ res ^ reg) & H_FLAG) |

                  (((getA() ^ res) & (reg ^ res) & 0x80) >> 5) | // V_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

 }

 template<typename T> inline II CPUCore<T>::adc_a_a() {

         unsigned res = 2 * getA() + ((getF() & C_FLAG) ? 1 : 0);

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  (res & H_FLAG) |

                  (((getA() ^ res) & 0x80) >> 5) | // V_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::adc_a_R() {

         ADC(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::adc_a_byte() {

         ADC(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::adc_a_xhl() {

         ADC(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::adc_a_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         ADC(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // ADD A,r

 template<typename T> inline void CPUCore<T>::ADD(byte reg) {

         unsigned res = getA() + reg;

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  ((getA() ^ res ^ reg) & H_FLAG) |

                  (((getA() ^ res) & (reg ^ res) & 0x80) >> 5) | // V_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

 }

 template<typename T> inline II CPUCore<T>::add_a_a() {

         unsigned res = 2 * getA();

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  (res & H_FLAG) |

                  (((getA() ^ res) & 0x80) >> 5) | // V_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::add_a_R() {

         ADD(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::add_a_byte() {

         ADD(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::add_a_xhl() {

         ADD(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::add_a_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         ADD(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // AND r

 template<typename T> inline void CPUCore<T>::AND(byte reg) {

         setA(getA() & reg);

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSPH[getA()];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[getA()] | H_FLAG;

         }

         setF(f);

 }

 template<typename T> II CPUCore<T>::and_a() {

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSPH[getA()];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[getA()] | H_FLAG;

         }

         setF(f);

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::and_R() {

         AND(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::and_byte() {

         AND(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::and_xhl() {

         AND(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::and_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         AND(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // CP r

 template<typename T> inline void CPUCore<T>::CP(byte reg) {

         unsigned q = getA() - reg;

         byte f = table.ZS[q & 0xFF] |

                  ((q & 0x100) ? C_FLAG : 0) |

                  N_FLAG |

                  ((getA() ^ q ^ reg) & H_FLAG) |

                  (((reg ^ getA()) & (getA() ^ q) & 0x80) >> 5); // V_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= reg & (X_FLAG | Y_FLAG); // XY from operand, not from result

         }

         setF(f);

 }

 template<typename T> II CPUCore<T>::cp_a() {

         byte f = ZS0 | N_FLAG;

         if constexpr (T::IS_R800) {

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= getA() & (X_FLAG | Y_FLAG); // XY from operand, not from result

         }

         setF(f);

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::cp_R() {

         CP(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::cp_byte() {

         CP(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::cp_xhl() {

         CP(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::cp_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         CP(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // OR r

 template<typename T> inline void CPUCore<T>::OR(byte reg) {

         setA(getA() | reg);

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[getA()];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[getA()];

         }

         setF(f);

 }

 template<typename T> II CPUCore<T>::or_a() {

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[getA()];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[getA()];

         }

         setF(f);

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::or_R() {

         OR(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::or_byte() {

         OR(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::or_xhl() {

         OR(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::or_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         OR(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // SBC A,r

 template<typename T> inline void CPUCore<T>::SBC(byte reg) {

         unsigned res = getA() - reg - ((getF() & C_FLAG) ? 1 : 0);

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  N_FLAG |

                  ((getA() ^ res ^ reg) & H_FLAG) |

                  (((reg ^ getA()) & (getA() ^ res) & 0x80) >> 5); // V_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

 }

 template<typename T> II CPUCore<T>::sbc_a_a() {

         if constexpr (T::IS_R800) {

                 word t = (getF() & C_FLAG)

                        ? (255 * 256 | ZS255 | C_FLAG | H_FLAG | N_FLAG)

                        : (  0 * 256 | ZS0   |                   N_FLAG);

                 setAF(t | (getF() & (X_FLAG | Y_FLAG)));

         } else {

                 setAF((getF() & C_FLAG) ?

                         (255 * 256 | ZSXY255 | C_FLAG | H_FLAG | N_FLAG) :

                         (  0 * 256 | ZSXY0   |                   N_FLAG));

         }

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::sbc_a_R() {

         SBC(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::sbc_a_byte() {

         SBC(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::sbc_a_xhl() {

         SBC(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::sbc_a_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         SBC(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // SUB r

 template<typename T> inline void CPUCore<T>::SUB(byte reg) {

         unsigned res = getA() - reg;

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  N_FLAG |

                  ((getA() ^ res ^ reg) & H_FLAG) |

                  (((reg ^ getA()) & (getA() ^ res) & 0x80) >> 5); // V_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

 }

 template<typename T> II CPUCore<T>::sub_a() {

         if constexpr (T::IS_R800) {

                 word t = 0 * 256 | ZS0 | N_FLAG;

                 setAF(t | (getF() & (X_FLAG | Y_FLAG)));

         } else {

                 setAF(0 * 256 | ZSXY0 | N_FLAG);

         }

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::sub_R() {

         SUB(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::sub_byte() {

         SUB(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::sub_xhl() {

         SUB(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::sub_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         SUB(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // XOR r

 template<typename T> inline void CPUCore<T>::XOR(byte reg) {

         setA(getA() ^ reg);

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[getA()];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[getA()];

         }

         setF(f);

 }

 template<typename T> II CPUCore<T>::xor_a() {

         if constexpr (T::IS_R800) {

                 word t = 0 * 256 + ZSP0;

                 setAF(t | (getF() & (X_FLAG | Y_FLAG)));

         } else {

                 setAF(0 * 256 + ZSPXY0);

         }

         return {1, T::CC_CP_R};

 }

 template<typename T> template<Reg8 SRC, int EE> II CPUCore<T>::xor_R() {

         XOR(get8<SRC>()); return {1, T::CC_CP_R + EE};

 }

 template<typename T> II CPUCore<T>::xor_byte() {

         XOR(RDMEM_OPCODE<1>(T::CC_CP_N_1)); return {2, T::CC_CP_N};

 }

 template<typename T> II CPUCore<T>::xor_xhl() {

         XOR(RDMEM(getHL(), T::CC_CP_XHL_1)); return {1, T::CC_CP_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::xor_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_CP_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         XOR(RDMEM(addr, T::CC_DD + T::CC_CP_XIX_2));

         return {2, T::CC_DD + T::CC_CP_XIX};

 }


 // DEC r

 template<typename T> inline byte CPUCore<T>::DEC(byte reg) {

         byte res = reg - 1;

         byte f = ((reg & ~res & 0x80) >> 5) | // V_FLAG

                  (((res & 0x0F) + 1) & H_FLAG) |

                  N_FLAG;

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

                 f |= table.ZS[res];

         } else {

                 f |= getF() & C_FLAG;

                 f |= table.ZSXY[res];

         }

         setF(f);

         return res;

 }

 template<typename T> template<Reg8 REG, int EE> II CPUCore<T>::dec_R() {

         set8<REG>(DEC(get8<REG>())); return {1, T::CC_INC_R + EE};

 }

 template<typename T> template<int EE> inline void CPUCore<T>::DEC_X(unsigned x) {

         byte val = DEC(RDMEM(x, T::CC_INC_XHL_1 + EE));

         WRMEM(x, val, T::CC_INC_XHL_2 + EE);

 }

 template<typename T> II CPUCore<T>::dec_xhl() {

         DEC_X<0>(getHL());

         return {1, T::CC_INC_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::dec_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_INC_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         DEC_X<T::CC_DD + T::EE_INC_XIX>(addr);

         return {2, T::CC_INC_XHL + T::CC_DD + T::EE_INC_XIX};

 }


 // INC r

 template<typename T> inline byte CPUCore<T>::INC(byte reg) {

         reg++;

         byte f = ((reg & -reg & 0x80) >> 5) | // V_FLAG

                  (((reg & 0x0F) - 1) & H_FLAG) |

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

                 f |= table.ZS[reg];

         } else {

                 f |= getF() & C_FLAG;

                 f |= table.ZSXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<Reg8 REG, int EE> II CPUCore<T>::inc_R() {

         set8<REG>(INC(get8<REG>())); return {1, T::CC_INC_R + EE};

 }

 template<typename T> template<int EE> inline void CPUCore<T>::INC_X(unsigned x) {

         byte val = INC(RDMEM(x, T::CC_INC_XHL_1 + EE));

         WRMEM(x, val, T::CC_INC_XHL_2 + EE);

 }

 template<typename T> II CPUCore<T>::inc_xhl() {

         INC_X<0>(getHL());

         return {1, T::CC_INC_XHL};

 }

 template<typename T> template<Reg16 IXY> II CPUCore<T>::inc_xix() {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_DD + T::CC_INC_XIX_1);

         unsigned addr = (get16<IXY>() + ofst) & 0xFFFF;

         T::setMemPtr(addr);

         INC_X<T::CC_DD + T::EE_INC_XIX>(addr);

         return {2, T::CC_INC_XHL + T::CC_DD + T::EE_INC_XIX};

 }


 // ADC HL,ss

 template<typename T> template<Reg16 REG> inline II CPUCore<T>::adc_hl_SS() {

         unsigned reg = get16<REG>();

         T::setMemPtr(getHL() + 1);

         unsigned res = getHL() + reg + ((getF() & C_FLAG) ? 1 : 0);

         byte f = (res >> 16) | // C_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (X_FLAG | Y_FLAG);

         }

         if (res & 0xFFFF) {

                 f |= ((getHL() ^ res ^ reg) >> 8) & H_FLAG;

                 f |= 0; // Z_FLAG

                 f |= ((getHL() ^ res) & (reg ^ res) & 0x8000) >> 13; // V_FLAG

                 if constexpr (T::IS_R800) {

                         f |= (res >> 8) & S_FLAG;

                 } else {

                         f |= (res >> 8) & (S_FLAG | X_FLAG | Y_FLAG);

                 }

         } else {

                 f |= ((getHL() ^ reg) >> 8) & H_FLAG;

                 f |= Z_FLAG;

                 f |= (getHL() & reg & 0x8000) >> 13; // V_FLAG

                 f |= 0; // S_FLAG (X_FLAG Y_FLAG)

         }

         setF(f);

         setHL(res);

         return {1, T::CC_ADC_HL_SS};

 }

 template<typename T> II CPUCore<T>::adc_hl_hl() {

         T::setMemPtr(getHL() + 1);

         unsigned res = 2 * getHL() + ((getF() & C_FLAG) ? 1 : 0);

         byte f = (res >> 16) | // C_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (X_FLAG | Y_FLAG);

         }

         if (res & 0xFFFF) {

                 f |= 0; // Z_FLAG

                 f |= ((getHL() ^ res) & 0x8000) >> 13; // V_FLAG

                 if constexpr (T::IS_R800) {

                         f |= (res >> 8) & (H_FLAG | S_FLAG);

                 } else {

                         f |= (res >> 8) & (H_FLAG | S_FLAG | X_FLAG | Y_FLAG);

                 }

         } else {

                 f |= Z_FLAG;

                 f |= (getHL() & 0x8000) >> 13; // V_FLAG

                 f |= 0; // H_FLAG S_FLAG (X_FLAG Y_FLAG)

         }

         setF(f);

         setHL(res);

         return {1, T::CC_ADC_HL_SS};

 }


 // ADD HL/IX/IY,ss

 template<typename T> template<Reg16 REG1, Reg16 REG2, int EE> II CPUCore<T>::add_SS_TT() {

         unsigned reg1 = get16<REG1>();

         unsigned reg2 = get16<REG2>();

         T::setMemPtr(reg1 + 1);

         unsigned res = reg1 + reg2;

         byte f = (((reg1 ^ res ^ reg2) >> 8) & H_FLAG) |

                  (res >> 16) | // C_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | V_FLAG | X_FLAG | Y_FLAG);

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | V_FLAG);

                 f |= (res >> 8) & (X_FLAG | Y_FLAG);

         }

         setF(f);

         set16<REG1>(res & 0xFFFF);

         return {1, T::CC_ADD_HL_SS + EE};

 }

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::add_SS_SS() {

         unsigned reg = get16<REG>();

         T::setMemPtr(reg + 1);

         unsigned res = 2 * reg;

         byte f = (res >> 16) | // C_FLAG

                  0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | V_FLAG | X_FLAG | Y_FLAG);

                 f |= (res >> 8) & H_FLAG;

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | V_FLAG);

                 f |= (res >> 8) & (H_FLAG | X_FLAG | Y_FLAG);

         }

         setF(f);

         set16<REG>(res & 0xFFFF);

         return {1, T::CC_ADD_HL_SS + EE};

 }


 // SBC HL,ss

 template<typename T> template<Reg16 REG> inline II CPUCore<T>::sbc_hl_SS() {

         unsigned reg = get16<REG>();

         T::setMemPtr(getHL() + 1);

         unsigned res = getHL() - reg - ((getF() & C_FLAG) ? 1 : 0);

         byte f = ((res & 0x10000) ? C_FLAG : 0) |

                  N_FLAG;

         if constexpr (T::IS_R800) {

                 f |= getF() & (X_FLAG | Y_FLAG);

         }

         if (res & 0xFFFF) {

                 f |= ((getHL() ^ res ^ reg) >> 8) & H_FLAG;

                 f |= 0; // Z_FLAG

                 f |= ((reg ^ getHL()) & (getHL() ^ res) & 0x8000) >> 13; // V_FLAG

                 if constexpr (T::IS_R800) {

                         f |= (res >> 8) & S_FLAG;

                 } else {

                         f |= (res >> 8) & (S_FLAG | X_FLAG | Y_FLAG);

                 }

         } else {

                 f |= ((getHL() ^ reg) >> 8) & H_FLAG;

                 f |= Z_FLAG;

                 f |= ((reg ^ getHL()) & getHL() & 0x8000) >> 13; // V_FLAG

                 f |= 0; // S_FLAG (X_FLAG Y_FLAG)

         }

         setF(f);

         setHL(res);

         return {1, T::CC_ADC_HL_SS};

 }

 template<typename T> II CPUCore<T>::sbc_hl_hl() {

         T::setMemPtr(getHL() + 1);

         byte f = T::IS_R800 ? (getF() & (X_FLAG | Y_FLAG)) : 0;

         if (getF() & C_FLAG) {

                 f |= C_FLAG | H_FLAG | S_FLAG | N_FLAG;

                 if constexpr (!T::IS_R800) {

                         f |= X_FLAG | Y_FLAG;

                 }

                 setHL(0xFFFF);

         } else {

                 f |= Z_FLAG | N_FLAG;

                 setHL(0);

         }

         setF(f);

         return {1, T::CC_ADC_HL_SS};

 }


 // DEC ss

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::dec_SS() {

         set16<REG>(get16<REG>() - 1); return {1, T::CC_INC_SS + EE};

 }


 // INC ss

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::inc_SS() {

         set16<REG>(get16<REG>() + 1); return {1, T::CC_INC_SS + EE};

 }


 // BIT n,r

 template<typename T> template<unsigned N, Reg8 REG> II CPUCore<T>::bit_N_R() {

         byte reg = get8<REG>();

         byte f = 0; // N_FLAG

         if constexpr (T::IS_R800) {

                 // this is very different from Z80 (not only XY flags)

                 f |= getF() & (S_FLAG | V_FLAG | C_FLAG | X_FLAG | Y_FLAG);

                 f |= H_FLAG;

                 f |= (reg & (1 << N)) ? 0 : Z_FLAG;

         } else {

                 f |= table.ZSPH[reg & (1 << N)];

                 f |= getF() & C_FLAG;

                 f |= reg & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {1, T::CC_BIT_R};

 }

 template<typename T> template<unsigned N> inline II CPUCore<T>::bit_N_xhl() {

         byte m = RDMEM(getHL(), T::CC_BIT_XHL_1) & (1 << N);

         byte f = 0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | V_FLAG | C_FLAG | X_FLAG | Y_FLAG);

                 f |= H_FLAG;

                 f |= m ? 0 : Z_FLAG;

         } else {

                 f |= table.ZSPH[m];

                 f |= getF() & C_FLAG;

                 f |= (T::getMemPtr() >> 8) & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {1, T::CC_BIT_XHL};

 }

 template<typename T> template<unsigned N> inline II CPUCore<T>::bit_N_xix(unsigned addr) {

         T::setMemPtr(addr);

         byte m = RDMEM(addr, T::CC_DD + T::CC_BIT_XIX_1) & (1 << N);

         byte f = 0; // N_FLAG

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | V_FLAG | C_FLAG | X_FLAG | Y_FLAG);

                 f |= H_FLAG;

                 f |= m ? 0 : Z_FLAG;

         } else {

                 f |= table.ZSPH[m];

                 f |= getF() & C_FLAG;

                 f |= (addr >> 8) & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {3, T::CC_DD + T::CC_BIT_XIX};

 }


 // RES n,r

 static constexpr byte RES(unsigned b, byte reg) {

         return reg & ~(1 << b);

 }

 template<typename T> template<unsigned N, Reg8 REG> II CPUCore<T>::res_N_R() {

         set8<REG>(RES(N, get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::RES_X(unsigned bit, unsigned addr) {

         byte res = RES(bit, RDMEM(addr, T::CC_SET_XHL_1 + EE));

         WRMEM(addr, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<unsigned N> II CPUCore<T>::res_N_xhl() {

         RES_X<0>(N, getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<unsigned N, Reg8 REG> II CPUCore<T>::res_N_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(RES_X<T::CC_DD + T::EE_SET_XIX>(N, a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // SET n,r

 static constexpr byte SET(unsigned b, byte reg) {

         return reg | (1 << b);

 }

 template<typename T> template<unsigned N, Reg8 REG> II CPUCore<T>::set_N_R() {

         set8<REG>(SET(N, get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::SET_X(unsigned bit, unsigned addr) {

         byte res = SET(bit, RDMEM(addr, T::CC_SET_XHL_1 + EE));

         WRMEM(addr, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<unsigned N> II CPUCore<T>::set_N_xhl() {

         SET_X<0>(N, getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<unsigned N, Reg8 REG> II CPUCore<T>::set_N_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(SET_X<T::CC_DD + T::EE_SET_XIX>(N, a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // RL r

 template<typename T> inline byte CPUCore<T>::RL(byte reg) {

         byte c = reg >> 7;

         reg = (reg << 1) | ((getF() & C_FLAG) ? 0x01 : 0);

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::RL_X(unsigned x) {

         byte res = RL(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rl_R() {

         set8<REG>(RL(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::rl_xhl() {

         RL_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rl_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(RL_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // RLC r

 template<typename T> inline byte CPUCore<T>::RLC(byte reg) {

         byte c = reg >> 7;

         reg = (reg << 1) | c;

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::RLC_X(unsigned x) {

         byte res = RLC(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rlc_R() {

         set8<REG>(RLC(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::rlc_xhl() {

         RLC_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rlc_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(RLC_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // RR r

 template<typename T> inline byte CPUCore<T>::RR(byte reg) {

         byte c = reg & 1;

         reg = (reg >> 1) | ((getF() & C_FLAG) << 7);

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::RR_X(unsigned x) {

         byte res = RR(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rr_R() {

         set8<REG>(RR(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::rr_xhl() {

         RR_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rr_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(RR_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // RRC r

 template<typename T> inline byte CPUCore<T>::RRC(byte reg) {

         byte c = reg & 1;

         reg = (reg >> 1) | (c << 7);

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::RRC_X(unsigned x) {

         byte res = RRC(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rrc_R() {

         set8<REG>(RRC(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::rrc_xhl() {

         RRC_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::rrc_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(RRC_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // SLA r

 template<typename T> inline byte CPUCore<T>::SLA(byte reg) {

         byte c = reg >> 7;

         reg <<= 1;

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::SLA_X(unsigned x) {

         byte res = SLA(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::sla_R() {

         set8<REG>(SLA(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::sla_xhl() {

         SLA_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::sla_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(SLA_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // SLL r

 template<typename T> inline byte CPUCore<T>::SLL(byte reg) {

         assert(!T::IS_R800); // this instruction is Z80-only

         byte c = reg >> 7;

         reg = (reg << 1) | 1;

         byte f = c ? C_FLAG : 0;

         f |= table.ZSPXY[reg];

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::SLL_X(unsigned x) {

         byte res = SLL(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::sll_R() {

         set8<REG>(SLL(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::sll_xhl() {

         SLL_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::sll_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(SLL_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }

 template<typename T> II CPUCore<T>::sll2() {

         assert(T::IS_R800); // this instruction is R800-only

         byte f = (getF() & (X_FLAG | Y_FLAG)) |

                  (getA() >> 7) | // C_FLAG

                  0; // all other flags zero

         setF(f);

         return {3, T::CC_DD + T::CC_SET_XIX}; // TODO

 }


 // SRA r

 template<typename T> inline byte CPUCore<T>::SRA(byte reg) {

         byte c = reg & 1;

         reg = (reg >> 1) | (reg & 0x80);

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::SRA_X(unsigned x) {

         byte res = SRA(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::sra_R() {

         set8<REG>(SRA(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::sra_xhl() {

         SRA_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::sra_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(SRA_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // SRL R

 template<typename T> inline byte CPUCore<T>::SRL(byte reg) {

         byte c = reg & 1;

         reg >>= 1;

         byte f = c ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= table.ZSP[reg];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSPXY[reg];

         }

         setF(f);

         return reg;

 }

 template<typename T> template<int EE> inline byte CPUCore<T>::SRL_X(unsigned x) {

         byte res = SRL(RDMEM(x, T::CC_SET_XHL_1 + EE));

         WRMEM(x, res, T::CC_SET_XHL_2 + EE);

         return res;

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::srl_R() {

         set8<REG>(SRL(get8<REG>())); return {1, T::CC_SET_R};

 }

 template<typename T> II CPUCore<T>::srl_xhl() {

         SRL_X<0>(getHL()); return {1, T::CC_SET_XHL};

 }

 template<typename T> template<Reg8 REG> II CPUCore<T>::srl_xix_R(unsigned a) {

         T::setMemPtr(a);

         set8<REG>(SRL_X<T::CC_DD + T::EE_SET_XIX>(a));

         return {3, T::CC_DD + T::CC_SET_XIX};

 }


 // RLA RLCA RRA RRCA

 template<typename T> II CPUCore<T>::rla() {

         byte c = getF() & C_FLAG;

         byte f = (getA() & 0x80) ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | X_FLAG | Y_FLAG);

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG);

         }

         setA((getA() << 1) | (c ? 1 : 0));

         if constexpr (!T::IS_R800) {

                 f |= getA() & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {1, T::CC_RLA};

 }

 template<typename T> II CPUCore<T>::rlca() {

         setA((getA() << 1) | (getA() >> 7));

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | X_FLAG | Y_FLAG);

                 f |= getA() & C_FLAG;

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG);

                 f |= getA() & (Y_FLAG | X_FLAG | C_FLAG);

         }

         setF(f);

         return {1, T::CC_RLA};

 }

 template<typename T> II CPUCore<T>::rra() {

         byte c = (getF() & C_FLAG) << 7;

         byte f = (getA() & 0x01) ? C_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | X_FLAG | Y_FLAG);

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG);

         }

         setA((getA() >> 1) | c);

         if constexpr (!T::IS_R800) {

                 f |= getA() & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {1, T::CC_RLA};

 }

 template<typename T> II CPUCore<T>::rrca() {

         byte f = getA() & C_FLAG;

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | X_FLAG | Y_FLAG);

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG);

         }

         setA((getA() >> 1) | (getA() << 7));

         if constexpr (!T::IS_R800) {

                 f |= getA() & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {1, T::CC_RLA};

 }


 // RLD

 template<typename T> II CPUCore<T>::rld() {

         byte val = RDMEM(getHL(), T::CC_RLD_1);

         T::setMemPtr(getHL() + 1);

         WRMEM(getHL(), (val << 4) | (getA() & 0x0F), T::CC_RLD_2);

         setA((getA() & 0xF0) | (val >> 4));

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

                 f |= table.ZSP[getA()];

         } else {

                 f |= getF() & C_FLAG;

                 f |= table.ZSPXY[getA()];

         }

         setF(f);

         return {1, T::CC_RLD};

 }


 // RRD

 template<typename T> II CPUCore<T>::rrd() {

         byte val = RDMEM(getHL(), T::CC_RLD_1);

         T::setMemPtr(getHL() + 1);

         WRMEM(getHL(), (val >> 4) | (getA() << 4), T::CC_RLD_2);

         setA((getA() & 0xF0) | (val & 0x0F));

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

                 f |= table.ZSP[getA()];

         } else {

                 f |= getF() & C_FLAG;

                 f |= table.ZSPXY[getA()];

         }

         setF(f);

         return {1, T::CC_RLD};

 }


 // PUSH ss

 template<typename T> template<int EE> inline void CPUCore<T>::PUSH(unsigned reg) {

         setSP(getSP() - 2);

         WR_WORD_rev<true, true>(getSP(), reg, T::CC_PUSH_1 + EE);

 }

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::push_SS() {

         PUSH<EE>(get16<REG>()); return {1, T::CC_PUSH + EE};

 }


 // POP ss

 template<typename T> template<int EE> inline unsigned CPUCore<T>::POP() {

         unsigned addr = getSP();

         setSP(addr + 2);

         if constexpr (T::IS_R800) {

                 // handles both POP and RET instructions (RET with condition = true)

                 if constexpr (EE == 0) { // not reti/retn, not pop ix/iy

                         setCurrentPopRet();

                         // No need for setSlowInstructions()

                         // -> this only matters directly after a CALL

                         //    instruction and in that case we're still

                         //    executing slow instructions.

                 }

         }

         return RD_WORD(addr, T::CC_POP_1 + EE);

 }

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::pop_SS() {

         set16<REG>(POP<EE>()); return {1, T::CC_POP + EE};

 }


 // CALL nn / CALL cc,nn

 template<typename T> template<typename COND> II CPUCore<T>::call(COND cond) {

         unsigned addr = RD_WORD_PC<1>(T::CC_CALL_1);

         T::setMemPtr(addr);

         if (cond(getF())) {

                 PUSH<T::EE_CALL>(getPC() + 3);

                 setPC(addr);

                 if constexpr (T::IS_R800) {

                         setCurrentCall();

                         setSlowInstructions();

                 }

                 return {0/*3*/, T::CC_CALL_A};

         } else {

                 return {3, T::CC_CALL_B};

         }

 }


 // RST n

 template<typename T> template<unsigned ADDR> II CPUCore<T>::rst() {

         PUSH<0>(getPC() + 1);

         T::setMemPtr(ADDR);

         setPC(ADDR);

         if constexpr (T::IS_R800) {

                 setCurrentCall();

                 setSlowInstructions();

         }

         return {0/*1*/, T::CC_RST};

 }


 // RET

 template<typename T> template<int EE, typename COND> inline II CPUCore<T>::RET(COND cond) {

         if (cond(getF())) {

                 unsigned addr = POP<EE>();

                 T::setMemPtr(addr);

                 setPC(addr);

                 return {0/*1*/, T::CC_RET_A + EE};

         } else {

                 return {1, T::CC_RET_B + EE};

         }

 }

 template<typename T> template<typename COND> II CPUCore<T>::ret(COND cond) {

         return RET<T::EE_RET_C>(cond);

 }

 template<typename T> II CPUCore<T>::ret() {

         return RET<0>(CondTrue());

 }

 template<typename T> II CPUCore<T>::retn() { // also reti

         setIFF1(getIFF2());

         setSlowInstructions();

         return RET<T::EE_RETN>(CondTrue());

 }


 // JP ss

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::jp_SS() {

         setPC(get16<REG>()); T::R800ForcePageBreak(); return {0/*1*/, T::CC_JP_HL + EE};

 }


 // JP nn / JP cc,nn

 template<typename T> template<typename COND> II CPUCore<T>::jp(COND cond) {

         unsigned addr = RD_WORD_PC<1>(T::CC_JP_1);

         T::setMemPtr(addr);

         if (cond(getF())) {

                 setPC(addr);

                 T::R800ForcePageBreak();

                 return {0/*3*/, T::CC_JP_A};

         } else {

                 return {3, T::CC_JP_B};

         }

 }


 // JR e

 template<typename T> template<typename COND> II CPUCore<T>::jr(COND cond) {

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_JR_1);

         if (cond(getF())) {

                 if (((getPC() + 2) & 0xFF) == 0) {

                         // On R800, when this instruction is located in the

                         // last two byte of a page (a page is a 256-byte

                         // (aligned) memory block) and even if we jump back,

                         // thus fetching the next opcode byte does not cause a

                         // page-break, there still is one cycle overhead. It's

                         // as-if there is a page-break.

                         //

                         // This could be explained by some (very limited)

                         // pipeline behaviour in R800: it seems that the

                         // decision to cause a page-break on the next

                         // instruction is already made before the jump

                         // destination address for the current instruction is

                         // calculated (though a destination address in another

                         // page is also a reason for a page-break).

                         //

                         // It's likely all instructions behave like this, but I

                         // think we can get away with only explicitly emulating

                         // this behaviour in the djnz and the jr (conditional

                         // or not) instructions: all other instructions that

                         // cause the PC to change in a non-incremental way do

                         // already force a pagebreak for another reason, so

                         // this effect is masked. Examples of such instructions

                         // are: JP, RET, CALL, RST, all repeated block

                         // instructions, accepting an IRQ, (are there more

                         // instructions or events that change PC?)

                         //

                         // See doc/r800-djnz.txt for more details.

                         T::R800ForcePageBreak();

                 }

                 setPC((getPC() + 2 + ofst) & 0xFFFF);

                 T::setMemPtr(getPC());

                 return {0/*2*/, T::CC_JR_A};

         } else {

                 return {2, T::CC_JR_B};

         }

 }


 // DJNZ e

 template<typename T> II CPUCore<T>::djnz() {

         byte b = getB() - 1;

         setB(b);

         int8_t ofst = RDMEM_OPCODE<1>(T::CC_JR_1 + T::EE_DJNZ);

         if (b) {

                 if (((getPC() + 2) & 0xFF) == 0) {

                         // See comment in jr()

                         T::R800ForcePageBreak();

                 }

                 setPC((getPC() + 2 + ofst) & 0xFFFF);

                 T::setMemPtr(getPC());

                 return {0/*2*/, T::CC_JR_A + T::EE_DJNZ};

         } else {

                 return {2, T::CC_JR_B + T::EE_DJNZ};

         }

 }


 // EX (SP),ss

 template<typename T> template<Reg16 REG, int EE> II CPUCore<T>::ex_xsp_SS() {

         unsigned res = RD_WORD_impl<true, false>(getSP(), T::CC_EX_SP_HL_1 + EE);

         T::setMemPtr(res);

         WR_WORD_rev<false, true>(getSP(), get16<REG>(), T::CC_EX_SP_HL_2 + EE);

         set16<REG>(res);

         return {1, T::CC_EX_SP_HL + EE};

 }


 // IN r,(c)

 template<typename T> template<Reg8 REG> II CPUCore<T>::in_R_c() {

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_IN_R_C_1);

         T::setMemPtr(getBC() + 1);

         byte res = READ_PORT(getBC(), T::CC_IN_R_C_1);

         byte f = 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

                 f |= table.ZSP[res];

         } else {

                 f |= getF() & C_FLAG;

                 f |= table.ZSPXY[res];

         }

         setF(f);

         set8<REG>(res);

         return {1, T::CC_IN_R_C};

 }


 // IN a,(n)

 template<typename T> II CPUCore<T>::in_a_byte() {

         unsigned y = RDMEM_OPCODE<1>(T::CC_IN_A_N_1) + 256 * getA();

         T::setMemPtr(y + 1);

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_IN_A_N_2);

         setA(READ_PORT(y, T::CC_IN_A_N_2));

         return {2, T::CC_IN_A_N};

 }


 // OUT (c),r

 template<typename T> template<Reg8 REG> II CPUCore<T>::out_c_R() {

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_OUT_C_R_1);

         T::setMemPtr(getBC() + 1);

         WRITE_PORT(getBC(), get8<REG>(), T::CC_OUT_C_R_1);

         return {1, T::CC_OUT_C_R};

 }

 template<typename T> II CPUCore<T>::out_c_0() {

         // TODO not on R800

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_OUT_C_R_1);

         T::setMemPtr(getBC() + 1);

         byte out_c_x = isCMOS ? 255 : 0;

         WRITE_PORT(getBC(), out_c_x, T::CC_OUT_C_R_1);

         return {1, T::CC_OUT_C_R};

 }


 // OUT (n),a

 template<typename T> II CPUCore<T>::out_byte_a() {

         byte port = RDMEM_OPCODE<1>(T::CC_OUT_N_A_1);

         unsigned y = (getA() << 8) |   port;

         T::setMemPtr((getA() << 8) | ((port + 1) & 255));

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_OUT_N_A_2);

         WRITE_PORT(y, getA(), T::CC_OUT_N_A_2);

         return {2, T::CC_OUT_N_A};

 }


 // block CP

 template<typename T> inline II CPUCore<T>::BLOCK_CP(int increase, bool repeat) {

         T::setMemPtr(T::getMemPtr() + increase);

         byte val = RDMEM(getHL(), T::CC_CPI_1);

         byte res = getA() - val;

         setHL(getHL() + increase);

         setBC(getBC() - 1);

         byte f = ((getA() ^ val ^ res) & H_FLAG) |

                  table.ZS[res] |

                  N_FLAG |

                  (getBC() ? V_FLAG : 0);

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

         } else {

                 f |= getF() & C_FLAG;

                 unsigned k = res - ((f & H_FLAG) >> 4);

                 f |= (k << 4) & Y_FLAG; // bit 1 -> flag 5

                 f |= k & X_FLAG;        // bit 3 -> flag 3

         }

         setF(f);

         if (repeat && getBC() && res) {

                 //setPC(getPC() - 2);

                 T::setMemPtr(getPC() + 1);

                 return {-1/*1*/, T::CC_CPIR};

         } else {

                 return {1, T::CC_CPI};

         }

 }

 template<typename T> II CPUCore<T>::cpd()  { return BLOCK_CP(-1, false); }

 template<typename T> II CPUCore<T>::cpi()  { return BLOCK_CP( 1, false); }

 template<typename T> II CPUCore<T>::cpdr() { return BLOCK_CP(-1, true ); }

 template<typename T> II CPUCore<T>::cpir() { return BLOCK_CP( 1, true ); }


 // block LD

 template<typename T> inline II CPUCore<T>::BLOCK_LD(int increase, bool repeat) {

         byte val = RDMEM(getHL(), T::CC_LDI_1);

         WRMEM(getDE(), val, T::CC_LDI_2);

         setHL(getHL() + increase);

         setDE(getDE() + increase);

         setBC(getBC() - 1);

         byte f = getBC() ? V_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | C_FLAG | X_FLAG | Y_FLAG);

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | C_FLAG);

                 f |= ((getA() + val) << 4) & Y_FLAG; // bit 1 -> flag 5

                 f |= (getA() + val) & X_FLAG;        // bit 3 -> flag 3

         }

         setF(f);

         if (repeat && getBC()) {

                 //setPC(getPC() - 2);

                 T::setMemPtr(getPC() + 1);

                 return {-1/*1*/, T::CC_LDIR};

         } else {

                 return {1, T::CC_LDI};

         }

 }

 template<typename T> II CPUCore<T>::ldd()  { return BLOCK_LD(-1, false); }

 template<typename T> II CPUCore<T>::ldi()  { return BLOCK_LD( 1, false); }

 template<typename T> II CPUCore<T>::lddr() { return BLOCK_LD(-1, true ); }

 template<typename T> II CPUCore<T>::ldir() { return BLOCK_LD( 1, true ); }


 // block IN

 template<typename T> inline II CPUCore<T>::BLOCK_IN(int increase, bool repeat) {

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_INI_1);

         T::setMemPtr(getBC() + increase);

         setBC(getBC() - 0x100); // decr before use

         byte val = READ_PORT(getBC(), T::CC_INI_1);

         WRMEM(getHL(), val, T::CC_INI_2);

         setHL(getHL() + increase);

         unsigned k = val + ((getC() + increase) & 0xFF);

         byte b = getB();

         if constexpr (T::IS_R800) {

                 setF((getF() & ~Z_FLAG) | (b ? 0 : Z_FLAG) | N_FLAG);

         } else {

                 setF(((val & S_FLAG) >> 6) | // N_FLAG

                        ((k & 0x100) ? (H_FLAG | C_FLAG) : 0) |

                        table.ZSXY[b] |

                        (table.ZSPXY[(k & 0x07) ^ b] & P_FLAG));

         }

         if (repeat && b) {

                 //setPC(getPC() - 2);

                 return {-1/*1*/, T::CC_INIR};

         } else {

                 return {1, T::CC_INI};

         }

 }

 template<typename T> II CPUCore<T>::ind()  { return BLOCK_IN(-1, false); }

 template<typename T> II CPUCore<T>::ini()  { return BLOCK_IN( 1, false); }

 template<typename T> II CPUCore<T>::indr() { return BLOCK_IN(-1, true ); }

 template<typename T> II CPUCore<T>::inir() { return BLOCK_IN( 1, true ); }


 // block OUT

 template<typename T> inline II CPUCore<T>::BLOCK_OUT(int increase, bool repeat) {

         byte val = RDMEM(getHL(), T::CC_OUTI_1);

         setHL(getHL() + increase);

         if constexpr (T::IS_R800) T::waitForEvenCycle(T::CC_OUTI_2);

         WRITE_PORT(getBC(), val, T::CC_OUTI_2);

         setBC(getBC() - 0x100); // decr after use

         T::setMemPtr(getBC() + increase);

         unsigned k = val + getL();

         byte b = getB();

         if constexpr (T::IS_R800) {

                 setF((getF() & ~Z_FLAG) | (b ? 0 : Z_FLAG) | N_FLAG);

         } else {

                 setF(((val & S_FLAG) >> 6) | // N_FLAG

                        ((k & 0x100) ? (H_FLAG | C_FLAG) : 0) |

                        table.ZSXY[b] |

                        (table.ZSPXY[(k & 0x07) ^ b] & P_FLAG));

         }

         if (repeat && b) {

                 //setPC(getPC() - 2);

                 return {-1/*1*/, T::CC_OTIR};

         } else {

                 return {1, T::CC_OUTI};

         }

 }

 template<typename T> II CPUCore<T>::outd() { return BLOCK_OUT(-1, false); }

 template<typename T> II CPUCore<T>::outi() { return BLOCK_OUT( 1, false); }

 template<typename T> II CPUCore<T>::otdr() { return BLOCK_OUT(-1, true ); }

 template<typename T> II CPUCore<T>::otir() { return BLOCK_OUT( 1, true ); }


 // various

 template<typename T> II CPUCore<T>::nop() { return {1, T::CC_NOP}; }

 template<typename T> II CPUCore<T>::ccf() {

         byte f = 0;

         if constexpr (T::IS_R800) {

                 // H flag is different from Z80 (and as always XY flags as well)

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | C_FLAG | X_FLAG | Y_FLAG | H_FLAG);

         } else {

                 f |= (getF() & C_FLAG) << 4; // H_FLAG

                 // only set X(Y) flag (don't reset if already set)

                 if (isCMOS) {

                         // Y flag is not changed on a CMOS Z80

                         f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | C_FLAG | Y_FLAG);

                         f |= (getF() | getA()) & X_FLAG;

                 } else {

                         f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | C_FLAG);

                         f |= (getF() | getA()) & (X_FLAG | Y_FLAG);

                 }

         }

         f ^= C_FLAG;

         setF(f);

         return {1, T::CC_CCF};

 }

 template<typename T> II CPUCore<T>::cpl() {

         setA(getA() ^ 0xFF);

         byte f = H_FLAG | N_FLAG;

         if constexpr (T::IS_R800) {

                 f |= getF();

         } else {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | C_FLAG);

                 f |= getA() & (X_FLAG | Y_FLAG);

         }

         setF(f);

         return {1, T::CC_CPL};

 }

 template<typename T> II CPUCore<T>::daa() {

         byte a = getA();

         byte f = getF();

         byte adjust = 0;

         if ((f & H_FLAG) || ((getA() & 0xf) > 9)) adjust += 6;

         if ((f & C_FLAG) || (getA() > 0x99)) adjust += 0x60;

         if (f & N_FLAG) a -= adjust; else a += adjust;

         if constexpr (T::IS_R800) {

                 f &= C_FLAG | N_FLAG | X_FLAG | Y_FLAG;

                 f |= table.ZSP[a];

         } else {

                 f &= C_FLAG | N_FLAG;

                 f |= table.ZSPXY[a];

         }

         f |= (getA() > 0x99) | ((getA() ^ a) & H_FLAG);

         setA(a);

         setF(f);

         return {1, T::CC_DAA};

 }

 template<typename T> II CPUCore<T>::neg() {

         // alternative: LUT   word negTable[256]

         unsigned a = getA();

         unsigned res = -signed(a);

         byte f = ((res & 0x100) ? C_FLAG : 0) |

                  N_FLAG |

                  ((res ^ a) & H_FLAG) |

                  ((a & res & 0x80) >> 5); // V_FLAG

         if constexpr (T::IS_R800) {

                 f |= table.ZS[res & 0xFF];

                 f |= getF() & (X_FLAG | Y_FLAG);

         } else {

                 f |= table.ZSXY[res & 0xFF];

         }

         setF(f);

         setA(res);

         return {1, T::CC_NEG};

 }

 template<typename T> II CPUCore<T>::scf() {

         byte f = C_FLAG;

         if constexpr (T::IS_R800) {

                 f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | X_FLAG | Y_FLAG);

         } else {

                 // only set X(Y) flag (don't reset if already set)

                 if (isCMOS) {

                         // Y flag is not changed on a CMOS Z80

                         f |= getF() & (S_FLAG | Z_FLAG | P_FLAG | Y_FLAG);

                         f |= (getF() | getA()) & X_FLAG;

                 } else {

                         f |= getF() & (S_FLAG | Z_FLAG | P_FLAG);

                         f |= (getF() | getA()) & (X_FLAG | Y_FLAG);

                 }

         }

         setF(f);

         return {1, T::CC_SCF};

 }


 template<typename T> II CPUCore<T>::ex_af_af() {

         unsigned t = getAF2(); setAF2(getAF()); setAF(t);

         return {1, T::CC_EX};

 }

 template<typename T> II CPUCore<T>::ex_de_hl() {

         unsigned t = getDE(); setDE(getHL()); setHL(t);

         return {1, T::CC_EX};

 }

 template<typename T> II CPUCore<T>::exx() {

         unsigned t1 = getBC2(); setBC2(getBC()); setBC(t1);

         unsigned t2 = getDE2(); setDE2(getDE()); setDE(t2);

         unsigned t3 = getHL2(); setHL2(getHL()); setHL(t3);

         return {1, T::CC_EX};

 }


 template<typename T> II CPUCore<T>::di() {

         setIFF1(false);

         setIFF2(false);

         return {1, T::CC_DI};

 }

 template<typename T> II CPUCore<T>::ei() {

         setIFF1(true);

         setIFF2(true);

         setCurrentEI(); // no ints directly after this instr

         setSlowInstructions();

         return {1, T::CC_EI};

 }

 template<typename T> II CPUCore<T>::halt() {

         setHALT(true);

         setSlowInstructions();


         if (!(getIFF1() || getIFF2())) {

                 diHaltCallback.execute();

         }

         return {1, T::CC_HALT};

 }

 template<typename T> template<unsigned N> II CPUCore<T>::im_N() {

         setIM(N); return {1, T::CC_IM};

 }


 // LD A,I/R

 template<typename T> template<Reg8 REG> II CPUCore<T>::ld_a_IR() {

         setA(get8<REG>());

         byte f = getIFF2() ? V_FLAG : 0;

         if constexpr (T::IS_R800) {

                 f |= getF() & (C_FLAG | X_FLAG | Y_FLAG);

                 f |= table.ZS[getA()];

         } else {

                 f |= getF() & C_FLAG;

                 f |= table.ZSXY[getA()];

                 // see comment in the IRQ acceptance part of executeSlow().

                 setCurrentLDAI(); // only Z80 (not R800) has this quirk

                 setSlowInstructions();

         }

         setF(f);

         return {1, T::CC_LD_A_I};

 }


 // LD I/R,A

 template<typename T> II CPUCore<T>::ld_r_a() {

         // This code sequence:

         //   XOR A  /  LD R,A   / LD A,R

         // gives A=2 for Z80, but A=1 for R800. The difference can possibly be

         // explained by a difference in the relative time between writing the

         // new value to the R register and increasing the R register per M1

         // cycle. Here we implemented the R800 behaviour by storing 'A-1' into

         // R, that's good enough for now.

         byte val = getA();

         if constexpr (T::IS_R800) val -= 1;

         setR(val);

         return {1, T::CC_LD_A_I};

 }

 template<typename T> II CPUCore<T>::ld_i_a() {

         setI(getA());

         return {1, T::CC_LD_A_I};

 }


 // MULUB A,r

 template<typename T> template<Reg8 REG> II CPUCore<T>::mulub_a_R() {

         assert(T::IS_R800); // this instruction is R800-only

         // Verified on real R800:

         //   YHXN flags are unchanged

         //   SV   flags are reset

         //   Z    flag is set when result is zero

         //   C    flag is set when result doesn't fit in 8-bit

         setHL(unsigned(getA()) * get8<REG>());

         setF((getF() & (N_FLAG | H_FLAG | X_FLAG | Y_FLAG)) |

                0 | // S_FLAG V_FLAG

                (getHL() ? 0 : Z_FLAG) |

                ((getHL() & 0xFF00) ? C_FLAG : 0));

         return {1, T::CC_MULUB};

 }


 // MULUW HL,ss

 template<typename T> template<Reg16 REG> II CPUCore<T>::muluw_hl_SS() {

         assert(T::IS_R800); // this instruction is R800-only

         // Verified on real R800:

         //   YHXN flags are unchanged

         //   SV   flags are reset

         //   Z    flag is set when result is zero

         //   C    flag is set when result doesn't fit in 16-bit

         unsigned res = unsigned(getHL()) * get16<REG>();

         setDE(res >> 16);

         setHL(res & 0xffff);

         setF((getF() & (N_FLAG | H_FLAG | X_FLAG | Y_FLAG)) |

                0 | // S_FLAG V_FLAG

                (res ? 0 : Z_FLAG) |

                ((res & 0xFFFF0000) ? C_FLAG : 0));

         return {1, T::CC_MULUW};

 }


 // versions:

 //  1 -> initial version

 //  2 -> moved memptr from here to Z80TYPE (and not to R800TYPE)

 //  3 -> timing of the emulation changed (no changes in serialization)

 //  4 -> timing of the emulation changed again (see doc/internal/r800-call.txt)

 //  5 -> added serialization of nmiEdge

 template<typename T> template<typename Archive>

 void CPUCore<T>::serialize(Archive& ar, unsigned version)

 {

         T::serialize(ar, version);

         ar.serialize("regs", static_cast<CPURegs&>(*this));

         if (ar.versionBelow(version, 2)) {

                 unsigned mPtr = 0; // dummy value (avoid warning)

                 ar.serialize("memptr", mPtr);

                 T::setMemPtr(mPtr);

         }


         if (ar.versionBelow(version, 5)) {

                 // NMI is unused on MSX and even on systems where it is used nmiEdge

                 // is true only between the moment the NMI request comes in and the

                 // moment the Z80 jumps to the NMI handler, so defaulting to false

                 // is pretty safe.

                 nmiEdge = false;

         } else {

                 // CPU is deserialized after devices, so nmiEdge is restored to the

                 // saved version even if IRQHelpers set it on deserialization.

                 ar.serialize("nmiEdge", nmiEdge);

         }


         // Don't serialize:

         // - IRQStatus, NMIStatus:

         //     the IRQHelper deserialization makes sure these get the right value

         // - slowInstructions, exitLoop:

         //     serialization happens outside the CPU emulation loop


         if constexpr (T::IS_R800) {

                 if (ar.versionBelow(version, 4)) {

                         motherboard.getMSXCliComm().printWarning(

                                 "Loading an old savestate: the timing of the R800 "

                                 "emulation has changed. This may cause synchronization "

                                 "problems in replay.");

                 }

         }

 }


 // Force template instantiation

 template class CPUCore<Z80TYPE>;

 template class CPUCore<R800TYPE>;


 INSTANTIATE_SERIALIZE_METHODS(CPUCore<Z80TYPE>);

 INSTANTIATE_SERIALIZE_METHODS(CPUCore<R800TYPE>);


 } // namespace openmsx

NEXT
#define NEXT

NEXT_EI
#define NEXT_EI

CASE
#define CASE(X)

NEXT_STOP
#define NEXT_STOP

CPUCore.hh

CliComm.hh

Dasm.hh

setting
BaseSetting * setting
Definition: Interpreter.cc:27

MSXCPUInterface.hh

MSXMotherBoard.hh

R800.hh

Scheduler.hh

TclCallback.hh

t
TclObject t
Definition: TclObject_test.cc:264

Thread.hh

Z80.hh

openmsx::BooleanSetting
Definition: BooleanSetting.hh:9

openmsx::CPUCore
Definition: CPUCore.hh:55

openmsx::CPUCore::lowerIRQ
void lowerIRQ()
Lowers the maskable interrupt count.
Definition: CPUCore.cc:437

openmsx::CPUCore::setNextSyncPoint
void setNextSyncPoint(EmuTime::param time)
Definition: CPUCore.cc:492

openmsx::CPUCore::disasmCommand
void disasmCommand(Interpreter &interp, span< const TclObject > tokens, TclObject &result) const
Definition: CPUCore.cc:508

openmsx::CPUCore::setFreq
void setFreq(unsigned freq)
Change the clock freq.
Definition: CPUCore.cc:535

openmsx::CPUCore::execute
void execute(bool fastForward)
Definition: CPUCore.cc:2535

openmsx::CPUCore::warp
void warp(EmuTime::param time)
Definition: CPUCore.cc:319

openmsx::CPUCore::CPUCore
CPUCore(MSXMotherBoard &motherboard, const std::string &name, const BooleanSetting &traceSetting, TclCallback &diHaltCallback, EmuTime::param time)
Definition: CPUCore.cc:279

openmsx::CPUCore::lowerNMI
void lowerNMI()
Lowers the non-maskable interrupt count.
Definition: CPUCore.cc:453

openmsx::CPUCore::exitCPULoopSync
void exitCPULoopSync()
Request to exit the main CPU emulation loop.
Definition: CPUCore.cc:398

openmsx::CPUCore::getCurrentTime
EmuTime::param getCurrentTime() const
Definition: CPUCore.cc:325

openmsx::CPUCore::exitCPULoopAsync
void exitCPULoopAsync()
Similar to exitCPULoopSync(), but this method may be called from any thread.
Definition: CPUCore.cc:393

openmsx::CPUCore::raiseNMI
void raiseNMI()
Raises the non-maskable interrupt count.
Definition: CPUCore.cc:443

openmsx::CPUCore::serialize
void serialize(Archive &ar, unsigned version)
Definition: CPUCore.cc:4393

openmsx::CPUCore::doReset
void doReset(EmuTime::param time)
Reset the CPU.
Definition: CPUCore.cc:330

openmsx::CPUCore::wait
void wait(EmuTime::param time)
Definition: CPUCore.cc:475

openmsx::CPUCore::waitCycles
EmuTime waitCycles(EmuTime::param time, unsigned cycles)
Definition: CPUCore.cc:482

openmsx::CPUCore::isM1Cycle
bool isM1Cycle(unsigned address) const
Definition: CPUCore.cc:459

openmsx::CPUCore::raiseIRQ
void raiseIRQ()
Raises the maskable interrupt count.
Definition: CPUCore.cc:428

openmsx::CPURegs
Definition: CPURegs.hh:20

openmsx::Interpreter
Definition: Interpreter.hh:18

openmsx::MSXMotherBoard
Definition: MSXMotherBoard.hh:61

openmsx::Setting
Definition: Setting.hh:127

openmsx::TclCallback
Definition: TclCallback.hh:15

openmsx::TclObject
Definition: TclObject.hh:23

openmsx::TclObject::addListElement
void addListElement(const T &t)
Definition: TclObject.hh:129

span
Definition: span.hh:126

span::size
constexpr index_type size() const noexcept
Definition: span.hh:296

endian.hh

inline.hh

NEVER_INLINE
#define NEVER_INLINE
Definition: inline.hh:17

ALWAYS_INLINE
#define ALWAYS_INLINE
Definition: inline.hh:16

likely.hh

likely
#define likely(x)
Definition: likely.hh:14

unlikely
#define unlikely(x)
Definition: likely.hh:15

Endian::read_UA_L16
ALWAYS_INLINE uint16_t read_UA_L16(const void *p)
Definition: endian.hh:226

Endian::write_UA_L16
ALWAYS_INLINE void write_UA_L16(void *p, uint16_t x)
Definition: endian.hh:186

openmsx::CacheLine::LOW
constexpr unsigned LOW
Definition: CacheLine.hh:9

openmsx::CacheLine::HIGH
constexpr unsigned HIGH
Definition: CacheLine.hh:10

openmsx::CacheLine::BITS
constexpr unsigned BITS
Definition: CacheLine.hh:6

openmsx::Thread::isMainThread
bool isMainThread()
Returns true when called from the main thread.
Definition: Thread.cc:15

openmsx
This file implemented 3 utility functions:
Definition: Autofire.cc:9

openmsx::N_FLAG
constexpr byte N_FLAG
Definition: CPUCore.cc:212

openmsx::ZSXY0
constexpr byte ZSXY0
Definition: CPUCore.cc:225

openmsx::Y_FLAG
constexpr byte Y_FLAG
Definition: CPUCore.cc:207

openmsx::Z_FLAG
constexpr byte Z_FLAG
Definition: CPUCore.cc:206

openmsx::table
constexpr Table table
Definition: CPUCore.cc:260

openmsx::NonCachedWrite
@ NonCachedWrite
Definition: MSXCPUInterface.hh:31

openmsx::NonCachedRead
@ NonCachedRead
Definition: MSXCPUInterface.hh:30

openmsx::N
constexpr unsigned N
Definition: ResampleHQ.cc:227

openmsx::Reg16
Reg16
Definition: CPUCore.cc:202

openmsx::IX
@ IX
Definition: CPUCore.cc:202

openmsx::BC
@ BC
Definition: CPUCore.cc:202

openmsx::IY
@ IY
Definition: CPUCore.cc:202

openmsx::AF
@ AF
Definition: CPUCore.cc:202

openmsx::DE
@ DE
Definition: CPUCore.cc:202

openmsx::SP
@ SP
Definition: CPUCore.cc:202

openmsx::HL
@ HL
Definition: CPUCore.cc:202

openmsx::dasm
unsigned dasm(const MSXCPUInterface &interf, word pc, byte buf[4], std::string &dest, EmuTime::param time)
Disassemble.
Definition: Dasm.cc:18

openmsx::B4
@ B4
Definition: V9990ModeEnum.hh:8

openmsx::B6
@ B6
Definition: V9990ModeEnum.hh:8

openmsx::B1
@ B1
Definition: V9990ModeEnum.hh:8

openmsx::B0
@ B0
Definition: V9990ModeEnum.hh:8

openmsx::B2
@ B2
Definition: V9990ModeEnum.hh:8

openmsx::B5
@ B5
Definition: V9990ModeEnum.hh:8

openmsx::B7
@ B7
Definition: V9990ModeEnum.hh:8

openmsx::B3
@ B3
Definition: V9990ModeEnum.hh:8

openmsx::Reg8
Reg8
Definition: CPUCore.cc:201

openmsx::REG_I
@ REG_I
Definition: CPUCore.cc:201

openmsx::E
@ E
Definition: CPUCore.cc:201

openmsx::H
@ H
Definition: CPUCore.cc:201

openmsx::IXL
@ IXL
Definition: CPUCore.cc:201

openmsx::REG_R
@ REG_R
Definition: CPUCore.cc:201

openmsx::D
@ D
Definition: CPUCore.cc:201

openmsx::IYH
@ IYH
Definition: CPUCore.cc:201

openmsx::L
@ L
Definition: CPUCore.cc:201

openmsx::C
@ C
Definition: CPUCore.cc:201

openmsx::F
@ F
Definition: CPUCore.cc:201

openmsx::A
@ A
Definition: CPUCore.cc:201

openmsx::IXH
@ IXH
Definition: CPUCore.cc:201

openmsx::DUMMY
@ DUMMY
Definition: CPUCore.cc:201

openmsx::B
@ B
Definition: CPUCore.cc:201

openmsx::IYL
@ IYL
Definition: CPUCore.cc:201

openmsx::V_FLAG
constexpr byte V_FLAG
Definition: CPUCore.cc:210

openmsx::ZSXY255
constexpr byte ZSXY255
Definition: CPUCore.cc:229

openmsx::P_FLAG
constexpr byte P_FLAG
Definition: CPUCore.cc:211

openmsx::C_FLAG
constexpr byte C_FLAG
Definition: CPUCore.cc:213

openmsx::S_FLAG
constexpr byte S_FLAG
Definition: CPUCore.cc:205

openmsx::word
uint16_t word
16 bit unsigned integer
Definition: openmsx.hh:29

openmsx::x
constexpr KeyMatrixPosition x
Keyboard bindings.
Definition: Keyboard.cc:127

openmsx::serialize
void serialize(Archive &ar, T &t, unsigned version)
Definition: serialize_core.hh:50

openmsx::H_FLAG
constexpr byte H_FLAG
Definition: CPUCore.cc:208

openmsx::ZSPXY0
constexpr byte ZSPXY0
Definition: CPUCore.cc:227

openmsx::ExecIRQ
ExecIRQ
Definition: CPUCore.hh:42

openmsx::ExecIRQ::IRQ
@ IRQ

openmsx::ExecIRQ::NMI
@ NMI

openmsx::ExecIRQ::NONE
@ NONE

openmsx::ZSP0
constexpr byte ZSP0
Definition: CPUCore.cc:226

openmsx::ZS0
constexpr byte ZS0
Definition: CPUCore.cc:224

openmsx::X_FLAG
constexpr byte X_FLAG
Definition: CPUCore.cc:209

openmsx::ZS255
constexpr byte ZS255
Definition: CPUCore.cc:228

INSTANTIATE_SERIALIZE_METHODS
#define INSTANTIATE_SERIALIZE_METHODS(CLASS)
Definition: serialize.hh:1009

tmpStrCat
TemporaryString tmpStrCat(Ts &&... ts)
Definition: strCat.hh:659

F
Definition: view_test.cc:239

openmsx::CondC
Definition: CPUCore.cc:269

openmsx::CondC::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:269

openmsx::CondM
Definition: CPUCore.cc:273

openmsx::CondM::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:273

openmsx::CondNC
Definition: CPUCore.cc:270

openmsx::CondNC::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:270

openmsx::CondNZ
Definition: CPUCore.cc:272

openmsx::CondNZ::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:272

openmsx::CondPE
Definition: CPUCore.cc:275

openmsx::CondPE::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:275

openmsx::CondPO
Definition: CPUCore.cc:276

openmsx::CondPO::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:276

openmsx::CondP
Definition: CPUCore.cc:274

openmsx::CondP::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:274

openmsx::CondTrue
Definition: CPUCore.cc:277

openmsx::CondTrue::operator()
bool operator()(byte) const
Definition: CPUCore.cc:277

openmsx::CondZ
Definition: CPUCore.cc:271

openmsx::CondZ::operator()
bool operator()(byte f) const
Definition: CPUCore.cc:271

openmsx::II
Definition: CPUCore.hh:29

openmsx::Table
Definition: CPUCore.cc:216

openmsx::Table::ZSP
byte ZSP[256]
Definition: CPUCore.cc:219

openmsx::Table::ZSXY
byte ZSXY[256]
Definition: CPUCore.cc:218

openmsx::Table::ZSPH
byte ZSPH[256]
Definition: CPUCore.cc:221

openmsx::Table::ZSPXY
byte ZSPXY[256]
Definition: CPUCore.cc:220

openmsx::Table::ZS
byte ZS[256]
Definition: CPUCore.cc:217

unreachable.hh

UNREACHABLE
#define UNREACHABLE
Definition: unreachable.hh:38

xrange.hh

repeat
constexpr void repeat(T n, Op op)
Repeat the given operation 'op' 'n' times.
Definition: xrange.hh:170

xrange
constexpr auto xrange(T e)
Definition: xrange.hh:155