/* * mops.c * * This file is part of Emu48 * * Copyright (C) 1995 Sebastien Carlier * */ #include "pch.h" #include "Emu48.h" #include "ops.h" #include "opcodes.h" #include "io.h" #include "i28f160.h" // flash support // #define DEBUG_SERIAL // switch for SERIAL debug purpose // #define DEBUG_IO // switch for I/O debug purpose // #define DEBUG_FLASH // switch for FLASH MEMORY debug purpose // defines for reading an open data bus #define READEVEN 0x0D #define READODD 0x0E // on mapping boundary adjusted base addresses #define P0MAPBASE ((BYTE)(Chipset.P0Base & ~Chipset.P0Size)) #define P1MAPBASE ((BYTE)(Chipset.P1Base & ~Chipset.P1Size)) #define P2MAPBASE ((BYTE)(Chipset.P2Base & ~Chipset.P2Size)) #define BSMAPBASE ((BYTE)(Chipset.BSBase & ~Chipset.BSSize)) BOOL bFlashRomArray = TRUE; // flag ROM mode BYTE disp = 0; // flag for update display area static LPBYTE pbyRomView[2] = {NULL, NULL}; // HP49G ROM views static __inline UINT MIN(UINT a, UINT b) { return (ab)?a:b; } // generate UCK signal static __inline BYTE UckBit(BYTE byBaudIndex) { // table content = baudrate * 16 const DWORD dwBaudrates[] = { 19200, 30720, 38400, 61440, 76800, 122880, 153600, 245760 }; LARGE_INTEGER lLC; _ASSERT(byBaudIndex < ARRAYSIZEOF(dwBaudrates)); if ((Chipset.IORam[IOC] & SON) == 0) // UART off return UCK; // UCK bit always set QueryPerformanceCounter(&lLC); // get counter value // calculate UCK frequency return (((BYTE)(((lLC.QuadPart - lAppStart.QuadPart) * dwBaudrates[byBaudIndex]) / lFreq.QuadPart) & 0x1) << 3); } // calculate nibble based linear flash address static __inline DWORD FlashROMAddr(DWORD d) { DWORD dwLinAddr; // 6 bit of latch (was A6-A1 of address bus) dwLinAddr = (Chipset.Bank_FF >> 1) & 0x3f; // decode A21-A18 dwLinAddr = ((d & 0x40000) ? (dwLinAddr & 0xf) : (dwLinAddr >> 4)) << 18; // decode A21-A18, A17-A0 dwLinAddr |= d & 0x3FFFF; return dwLinAddr; } // update display static __inline VOID UpdateDisplay(DWORD d, UINT s) { BYTE p[16]; DWORD u; UINT c; // address in display main area? if ((dChipset.start12)) { // write to display main area u = d; // copy destination ptr c = MIN(s,Chipset.end1-d); // number of nibbles to copy if (d < Chipset.start12) // first address is out of display area { u = Chipset.start12; // set destination ptr to start of display area c -= Chipset.start12 - d; // - number of bytes that aren't in display area } _ASSERT(c <= ARRAYSIZEOF(p)); Npeek(p,u,c); // get source data WriteToMainDisplay(p,u,c); } // address in display menu area? if ((dChipset.start2)) { // write to display menu area u = d; // copy destination ptr c = MIN(s,Chipset.end2-d); // number of nibbles to copy if (d < Chipset.start2) // first address is out of display area { u = Chipset.start2; // set destination ptr to start of display area c -= Chipset.start2 - d; // - number of bytes that are not in display area } _ASSERT(c <= ARRAYSIZEOF(p)); Npeek(p,u,c); // get source data WriteToMenuDisplay(p,u,c); } return; } // port mapping LPBYTE RMap[256] = {NULL,}; LPBYTE WMap[256] = {NULL,}; static VOID MapP0(BYTE a, BYTE b) { UINT i; DWORD p, m; a = (BYTE)MAX(a,P0MAPBASE); // adjust base to mapping boundary b = (BYTE)MIN(b,Chipset.P0End); m = (Chipset.Port0Size*2048)-1; p = (a<<12)&m; // offset to begin of P0 in nibbles for (i=a; i<=b; i++) { // mapping area may have holes if (((i ^ Chipset.P0Base) & ~Chipset.P0Size) == 0) { RMap[i]=Port0 + p; WMap[i]=Port0 + p; } p = (p+0x1000)&m; } return; } static VOID MapBS(BYTE a, BYTE b) { UINT i; a = (BYTE)MAX(a,BSMAPBASE); // adjust base to mapping boundary b = (BYTE)MIN(b,Chipset.BSEnd); for (i=a;i<=b;i++) { // mapping area may have holes if (((i ^ Chipset.BSBase) & ~Chipset.BSSize) == 0) { RMap[i]=NULL; // no read cycle, open data bus WMap[i]=NULL; } } return; } static VOID MapP1(BYTE a, BYTE b) { UINT i; DWORD p, m; // clear mapping area if port1 is configured but not plugged a = (BYTE)MAX(a,P1MAPBASE); // lowest address for use is P1Base b = (BYTE)MIN(b,Chipset.P1End); // highest address for use is P1End // port1 not plugged if (Port1 == NULL || !(Chipset.cards_status & PORT1_PRESENT)) { for (i=a; i<=b; i++) // scan each 2KB page { if (((i ^ Chipset.P1Base) & ~Chipset.P1Size) == 0) { RMap[i]=NULL; WMap[i]=NULL; } } return; } m = (Chipset.Port1Size*2048)-1; // real size of module, address mask for mirroring p = (a<<12)&m; // offset to begin of P1 in nibbles if (Chipset.cards_status & PORT1_WRITE) // port1 write enabled { for (i=a; i<=b; i++) // scan each 2KB page { // mapping area may have holes if (((i ^ Chipset.P1Base) & ~Chipset.P1Size) == 0) { RMap[i]=Port1 + p; // save page address for read WMap[i]=Port1 + p; // save page address for write } p = (p+0x1000)&m; // next page, mirror page if real size smaller allocated size } } else // port1 read only { for (i=a; i<=b; i++) // scan each 2KB page { // mapping area may have holes if (((i ^ Chipset.P1Base) & ~Chipset.P1Size) == 0) { RMap[i]=Port1 + p; // save page address for read WMap[i]=NULL; // no writing } p = (p+0x1000)&m; // next page, mirror page if real size smaller allocated size } } return; } static VOID MapP2(BYTE a, BYTE b) { UINT i; DWORD p, m; LPBYTE pbyTemp; // clear mapping area if port2 is configured but not plugged a = (BYTE)MAX(a,P2MAPBASE); // adjust base to mapping boundary b = (BYTE)MIN(b,Chipset.P2End); if (Chipset.Port2Size) // internal port2 { m = (Chipset.Port2Size*2048)-1; p = (a<<12)&m; // offset to begin of P0 in nibbles for (i=a; i<=b; i++) { // mapping area may have holes if (((i ^ Chipset.P2Base) & ~Chipset.P2Size) == 0) { RMap[i]=Port2 + p; WMap[i]=Port2 + p; } p = (p+0x1000)&m; } return; } // HP48SX / HP48GX // only fill mapping table when CE2.2 is set for (i=a; i<=b; i++) // fill mapping area with not configured { // mapping area may have holes if (((i ^ Chipset.P2Base) & ~Chipset.P2Size) == 0) { RMap[i]=NULL; WMap[i]=NULL; } } // port2 not plugged if (pbyPort2 == NULL || !(Chipset.cards_status & PORT2_PRESENT)) return; pbyTemp = pbyPort2; if (cCurrentRomType != 'S') // bank switching only with GX { // Chipset.Port2_Bank is the saved port2 FF content pbyTemp += (((Chipset.Bank_FF>>1)-1)&dwPort2Mask) << 18; } // max. size per bank is 128KB m = (dwPort2Size > 128) ? 128 : dwPort2Size; m = (m * 2048) - 1; // real size of module, address mask for mirroring p = (a << 12) & m; // offset to begin of P2 in nibbles // SX: CE2.2 = CE2 // GX: CE2.2 = BEN & /DA19 & /NCE3 if (cCurrentRomType == 'S' || ((Chipset.IORam[0x29]&DA19) == 0 && (Chipset.Bank_FF&0x40))) { if (bPort2Writeable) { for (i=a; i<=b; i++) { // mapping area may have holes if (((i ^ Chipset.P2Base) & ~Chipset.P2Size) == 0) { RMap[i]=pbyTemp + p; WMap[i]=pbyTemp + p; } p = (p+0x1000)&m; } } else { for (i=a; i<=b; i++) { // mapping area may have holes if (((i ^ Chipset.P2Base) & ~Chipset.P2Size) == 0) { RMap[i]=pbyTemp + p; } p = (p+0x1000)&m; } } } return; } static VOID MapROM(BYTE a, BYTE b) { UINT i; DWORD p, m; // HP39/49G, HP49G if (cCurrentRomType == 'E' || cCurrentRomType == 'X') { if (bFlashRomArray) // view flash ROM data { _ASSERT(pbyRomView[0]); // check ROM bank set _ASSERT(pbyRomView[1]); m = (128*1024*2)-1; // mapped in 128KB pages p = (a<<12)&m; // offset to the begin of ROM in nibbles for (i=a; i<=b; i++) // scan each 2KB page { RMap[i]=pbyRomView[(i & 0x40)!=0] + p; WMap[i]=NULL; // no writing p = (p+0x1000)&m; } } else // view flash ROM register { for (i=a; i<=b; i++) // scan each 2KB page { RMap[i]=NULL; // view flash register WMap[i]=NULL; // no writing } } return; } // HP38G / HP48SX / HP48GX m = dwRomSize - 1; // ROM address mask for mirroring // when 512KB ROM and DA19=0 (ROM disabled) if ((m & 0x80000) != 0 && (Chipset.IORam[0x29]&DA19) == 0) m >>= 1; // mirror ROM at #80000 (AR18=0) p = (a*0x1000)&m; // data offset in nibbles for (i=a;i<=b;i++) // scan each 2KB page { RMap[i]=pbyRom + p; // save page address for read WMap[i]=NULL; // no writing p = (p+0x1000)&m; // next page, mirror page if real size smaller allocated size } return; } VOID Map(BYTE a, BYTE b) // maps 2KB pages with priority { // On HP39/40G and HP49G Chipset.cards_status must be 0xF _ASSERT((cCurrentRomType!='E' && cCurrentRomType!='X') || !Chipset.P1Cfig || Chipset.cards_status == 0xF); // priority order is HDW, RAM, CE2, CE1, NCE3, ROM MapROM(a,b); // ROM, lowest priority, always mapped if (cCurrentRomType == 'S') // HP48SX { if (Chipset.BSCfig) MapBS(a,b); // NCE3, not used in S(X) if (Chipset.P1Cfig) MapP1(a,b); // CE1, port1 (lower priority than CE2) if (Chipset.P2Cfig) MapP2(a,b); // CE2, port2 (higher priority than CE1) } else // HP48GX / HP49G { if (Chipset.P2Cfig) // NCE3, port2 { // LED bit set on a HP49 if (cCurrentRomType=='X' && (Chipset.IORam[LCR]&LED)) MapROM(a,b); // NCE3, ROM else MapP2(a,b); // NCE3, port2 } if (Chipset.BSCfig) MapBS(a,b); // CE1, bank select (lower priority than CE2) if (Chipset.P1Cfig) MapP1(a,b); // CE2, port1 (higher priority than CE1) } if (Chipset.P0Cfig) MapP0(a,b); // RAM, highest priority (execpt HDW) return; } VOID RomSwitch(DWORD adr) { // only HP39/40G, HP49G if (cCurrentRomType=='E' || cCurrentRomType=='X') { Chipset.Bank_FF = adr; // save address line adr = (adr >> 1) & 0x3f; // 6 bit of latch (was A6-A1 of address bus) // lower 4 bit (16 banks) for 2nd ROM view pbyRomView[1] = pbyRom + (((adr & 0xf) * 128 * 1024 * 2) & (dwRomSize - 1)); // higher 2 bit (4 banks) for 1st ROM view pbyRomView[0] = pbyRom + (((adr >> 4) * 128 * 1024 * 2) & (dwRomSize - 1)); } Map(0x00,0xFF); // update memory mapping return; } //////////////////////////////////////////////////////////////////////////////// // // Bus Commands // //////////////////////////////////////////////////////////////////////////////// VOID Config() // configure modules in fixed order { DWORD d = Npack(Chipset.C,5); // decode size or address BYTE b = (BYTE)(d>>12); // number of 2KB pages or page address BYTE s = (BYTE)(b^0xFF); // size in pages-1, offset to last page // config order is HDW, RAM, CE1, CE2, NCE3 if (!Chipset.IOCfig) // address of HDW, first module, ROM always configured { Chipset.IOCfig = TRUE; Chipset.IOBase = d&0xFFFC0; // save HDW base on a 64 nib boundary Map(b,b); return; } if (!Chipset.P0Cfg2) // RAM size, port0 { Chipset.P0Cfg2 = TRUE; Chipset.P0Size = s; // offset to last used page return; } if (!Chipset.P0Cfig) // RAM address, port0 { Chipset.P0Cfig = TRUE; Chipset.P0Base = b; // save first page address b &= ~Chipset.P0Size; // adjust base to mapping boundary Chipset.P0End = b+Chipset.P0Size; // save last page address Map(b,Chipset.P0End); // refresh mapping return; } if (cCurrentRomType=='S') // HP48SX { if (!Chipset.P1Cfg2) // CE1 size, port1 { Chipset.P1Cfg2 = TRUE; Chipset.P1Size = s; return; } if (!Chipset.P1Cfig) // CE1 address, port1 { Chipset.P1Cfig = TRUE; Chipset.P1Base = b; b &= ~Chipset.P1Size; // adjust base to mapping boundary Chipset.P1End = b+Chipset.P1Size; Map(b,Chipset.P1End); // refresh mapping return; } if (!Chipset.P2Cfg2) // CE2 size, port2 { Chipset.P2Cfg2 = TRUE; Chipset.P2Size = s; return; } if (!Chipset.P2Cfig) // CE2 address, port2 { Chipset.P2Cfig = TRUE; Chipset.P2Base = b; b &= ~Chipset.P2Size; // adjust base to mapping boundary Chipset.P2End = b+Chipset.P2Size; Map(b,Chipset.P2End); // refresh mapping return; } if (!Chipset.BSCfg2) // NCE3 size, not used in S(X) { Chipset.BSCfg2 = TRUE; Chipset.BSSize = s; return; } if (!Chipset.BSCfig) // NCE3 address, not used in S(X) { Chipset.BSCfig = TRUE; Chipset.BSBase = b; b &= ~Chipset.BSSize; // adjust base to mapping boundary Chipset.BSEnd = b+Chipset.BSSize; Map(b,Chipset.BSEnd); // refresh mapping return; } } else // HP48GX / HP49G { if (!Chipset.BSCfg2) // CE1 size, bank select { Chipset.BSCfg2 = TRUE; Chipset.BSSize = s; return; } if (!Chipset.BSCfig) // CE1 address, bank select { Chipset.BSCfig = TRUE; Chipset.BSBase = b; b &= ~Chipset.BSSize; // adjust base to mapping boundary Chipset.BSEnd = b+Chipset.BSSize; Map(b,Chipset.BSEnd); // refresh mapping return; } if (!Chipset.P1Cfg2) // CE2 size, port1 { Chipset.P1Cfg2 = TRUE; Chipset.P1Size = s; return; } if (!Chipset.P1Cfig) // CE2 address, port1 { Chipset.P1Cfig = TRUE; Chipset.P1Base = b; b &= ~Chipset.P1Size; // adjust base to mapping boundary Chipset.P1End = b+Chipset.P1Size; Map(b,Chipset.P1End); // refresh mapping return; } if (!Chipset.P2Cfg2) // NCE3 size, port2 { Chipset.P2Cfg2 = TRUE; Chipset.P2Size = s; return; } if (!Chipset.P2Cfig) // NCE3 address, port2 { Chipset.P2Cfig = TRUE; Chipset.P2Base = b; b &= ~Chipset.P2Size; // adjust base to mapping boundary Chipset.P2End = b+Chipset.P2Size; Map(b,Chipset.P2End); // refresh mapping return; } } return; } VOID Uncnfg() { DWORD d=Npack(Chipset.C,5); // decode address BYTE b=(BYTE)(d>>12); // page address // unconfig order is HDW, RAM, CE2, CE1, NCE3 if ((Chipset.IOCfig)&&((d&0xFFFC0)==Chipset.IOBase)) {Chipset.IOCfig=FALSE;Map(b,b);return;} if ((Chipset.P0Cfig)&&((b&~Chipset.P0Size)==P0MAPBASE)) {Chipset.P0Cfig=FALSE;Chipset.P0Cfg2=FALSE;Map(P0MAPBASE,Chipset.P0End);return;} if (cCurrentRomType=='S') // HP48SX { if ((Chipset.P2Cfig)&&((b&~Chipset.P2Size)==P2MAPBASE)) {Chipset.P2Cfig=FALSE;Chipset.P2Cfg2=FALSE;Map(P2MAPBASE,Chipset.P2End);return;} if ((Chipset.P1Cfig)&&((b&~Chipset.P1Size)==P1MAPBASE)) {Chipset.P1Cfig=FALSE;Chipset.P1Cfg2=FALSE;Map(P1MAPBASE,Chipset.P1End);return;} if ((Chipset.BSCfig)&&((b&~Chipset.BSSize)==BSMAPBASE)) {Chipset.BSCfig=FALSE;Chipset.BSCfg2=FALSE;Map(BSMAPBASE,Chipset.BSEnd);return;} } else // HP48GX / HP49G { if ((Chipset.P1Cfig)&&((b&~Chipset.P1Size)==P1MAPBASE)) {Chipset.P1Cfig=FALSE;Chipset.P1Cfg2=FALSE;Map(P1MAPBASE,Chipset.P1End);return;} if ((Chipset.BSCfig)&&((b&~Chipset.BSSize)==BSMAPBASE)) {Chipset.BSCfig=FALSE;Chipset.BSCfg2=FALSE;Map(BSMAPBASE,Chipset.BSEnd);return;} if ((Chipset.P2Cfig)&&((b&~Chipset.P2Size)==P2MAPBASE)) {Chipset.P2Cfig=FALSE;Chipset.P2Cfg2=FALSE;Map(P2MAPBASE,Chipset.P2End);return;} } return; } VOID Reset() { Chipset.IOCfig=FALSE;Chipset.IOBase=0x100000; Chipset.P0Cfig=FALSE;Chipset.P0Cfg2=FALSE;Chipset.P0Base=0;Chipset.P0Size=0;Chipset.P0End=0; Chipset.BSCfig=FALSE;Chipset.BSCfg2=FALSE;Chipset.BSBase=0;Chipset.BSSize=0;Chipset.BSEnd=0; Chipset.P1Cfig=FALSE;Chipset.P1Cfg2=FALSE;Chipset.P1Base=0;Chipset.P1Size=0;Chipset.P1End=0; Chipset.P2Cfig=FALSE;Chipset.P2Cfg2=FALSE;Chipset.P2Base=0;Chipset.P2Size=0;Chipset.P2End=0; Map(0x00,0xFF); // refresh mapping return; } VOID C_Eq_Id() { // config order is HDW, RAM, CE1, CE2, NCE3 if (!Chipset.IOCfig) {Nunpack(Chipset.C,(Chipset.IOBase) ^0x00019,5);return;} if (!Chipset.P0Cfg2) {Nunpack(Chipset.C,(Chipset.P0Size*0x1000)^0xFF003,5);return;} if (!Chipset.P0Cfig) {Nunpack(Chipset.C,(Chipset.P0Base*0x1000)^0x000F4,5);return;} if (cCurrentRomType=='S') // HP48SX { if (!Chipset.P1Cfg2) {Nunpack(Chipset.C,(Chipset.P1Size*0x1000)^0xFF005,5);return;} if (!Chipset.P1Cfig) {Nunpack(Chipset.C,(Chipset.P1Base*0x1000)^0x000F6,5);return;} if (!Chipset.P2Cfg2) {Nunpack(Chipset.C,(Chipset.P2Size*0x1000)^0xFF007,5);return;} if (!Chipset.P2Cfig) {Nunpack(Chipset.C,(Chipset.P2Base*0x1000)^0x000F8,5);return;} if (!Chipset.BSCfg2) {Nunpack(Chipset.C,(Chipset.BSSize*0x1000)^0xFF001,5);return;} if (!Chipset.BSCfig) {Nunpack(Chipset.C,(Chipset.BSBase*0x1000)^0x000F2,5);return;} } else // HP48GX / HP49G { if (!Chipset.BSCfg2) {Nunpack(Chipset.C,(Chipset.BSSize*0x1000)^0xFF005,5);return;} if (!Chipset.BSCfig) {Nunpack(Chipset.C,(Chipset.BSBase*0x1000)^0x000F6,5);return;} if (!Chipset.P1Cfg2) {Nunpack(Chipset.C,(Chipset.P1Size*0x1000)^0xFF007,5);return;} if (!Chipset.P1Cfig) {Nunpack(Chipset.C,(Chipset.P1Base*0x1000)^0x000F8,5);return;} if (!Chipset.P2Cfg2) {Nunpack(Chipset.C,(Chipset.P2Size*0x1000)^0xFF001,5);return;} if (!Chipset.P2Cfig) {Nunpack(Chipset.C,(Chipset.P2Base*0x1000)^0x000F2,5);return;} } memset(Chipset.C,0,5); return; } enum MMUMAP MapData(DWORD d) // check MMU area { BYTE u = (BYTE) (d>>12); if (Chipset.IOCfig && ((d&0xFFFC0)==Chipset.IOBase)) return M_IO; if (Chipset.P0Cfig && (((u^Chipset.P0Base) & ~Chipset.P0Size) == 0)) return M_RAM; if (cCurrentRomType == 'S') { if (Chipset.P2Cfig && (((u^Chipset.P2Base) & ~Chipset.P2Size) == 0)) return M_P2; if (Chipset.P1Cfig && (((u^Chipset.P1Base) & ~Chipset.P1Size) == 0)) return M_P1; if (Chipset.BSCfig && (((u^Chipset.BSBase) & ~Chipset.BSSize) == 0)) return M_BS; } else { if (Chipset.P1Cfig && (((u^Chipset.P1Base) & ~Chipset.P1Size) == 0)) return M_P1; if (Chipset.BSCfig && (((u^Chipset.BSBase) & ~Chipset.BSSize) == 0)) return M_BS; if (Chipset.P2Cfig && (((u^Chipset.P2Base) & ~Chipset.P2Size) == 0)) return M_P2; } return M_ROM; } VOID CpuReset(VOID) // register setting after Cpu Reset { StopTimers(); // stop timer, do here because function change Chipset.t2 Chipset.pc = 0; Chipset.rstkp = 0; ZeroMemory(Chipset.rstk,sizeof(Chipset.rstk)); Chipset.HST = 0; Chipset.SoftInt = FALSE; Chipset.Shutdn = TRUE; Chipset.inte = TRUE; // enable interrupts Chipset.intk = TRUE; // INTON Chipset.intd = FALSE; // no keyboard interrupts pending Chipset.crc = 0; Chipset.Bank_FF = 0; // state of bank switcher FF Chipset.FlashRomState = 0; // WSM state of flash memory ZeroMemory(Chipset.IORam,sizeof(Chipset.IORam)); Chipset.IORam[LPE] = RST; // set ReSeT bit at hardware reset Reset(); // reset MMU Chipset.t1 = 0; // reset timer values Chipset.t2 = 0; Chipset.loffset = 0; // right margin Chipset.boffset = 0; // left margin Chipset.lcounter = 0; // number of main display lines Chipset.contrast = 0; // contrast dark UpdateContrast(Chipset.contrast); // update contrast // display update when changing to run state CommSetBaud(); // new baudrate CheckSerial(); // close serial port RomSwitch(Chipset.Bank_FF); // force new memory mapping return; } VOID Npeek(BYTE *a, DWORD d, UINT s) { enum MMUMAP eMap; DWORD u, v; UINT c; BYTE *p; do { eMap = MapData(d); // get active memory controller if (M_IO == eMap) // I/O access { v = d&0x3F; do { if (v == LPE) { // don't read LPE content with the function ReadIO() c = 1; memcpy(a, Chipset.IORam+v, c); break; } if (v >= RBR_LSB && v <= RBR_MSB) { // don't read RBR content with the function ReadIO() c = MIN(s,RBR_MSB-v+1); memcpy(a, Chipset.IORam+v, c); break; } // all others registers do { if (v < LPE) { c = MIN(s,LPE-v); break; } if (v < RBR_LSB && (v+s) > RBR_LSB) { c = MIN(s,RBR_LSB-v); break; } c = MIN(s,0x40-v); } while (0); ReadIO(a,v,c,FALSE); } while (0); } else { u = d>>12; v = d&0xFFF; c = MIN(s,0x1000-v); // Flash memory Read access if (cCurrentRomType=='X' && (Chipset.IORam[LCR] & LED) && M_P2 == eMap) { FlashRead(a, FlashROMAddr(d), c); } else { if ((p=RMap[u]) != NULL) // module mapped { memcpy(a, p+v, c); } else // open data bus { for (u=0; u>12; v = d&0xFFF; c = MIN(s,0x1000-v); // bank switcher access if (cCurrentRomType!='S' && M_BS == eMap) { if (cCurrentRomType=='G') // HP48GX { Chipset.Bank_FF = v+c; // save FF value Map(Chipset.P2Base,Chipset.P2End); } if (cCurrentRomType=='E' || cCurrentRomType=='X') // HP39/40G, HP49G { RomSwitch(v+c); } } // Flash memory Read access if (cCurrentRomType=='X' && (Chipset.IORam[LCR] & LED) && M_P2 == eMap) { DWORD dwLinAddr = FlashROMAddr(d); FlashRead(a, dwLinAddr, c); #if defined DEBUG_FLASH { TCHAR buffer[256]; DWORD j; int i; i = wsprintf(buffer,_T("%.5lx: Flash Read : %.5x (%.6x),%u = "),Chipset.pc,d,dwLinAddr,c); for (j = 0;j < c;++j,++i) { buffer[i] = a[j]; if (buffer[i] > 9) buffer[i] += _T('a') - _T('9') - 1; buffer[i] += _T('0'); } buffer[i++] = _T('\n'); buffer[i] = 0; OutputDebugString(buffer); } #endif } else { if ((p=RMap[u]) != NULL) // module mapped { memcpy(a, p+v, c); } // simulate open data bus else // open data bus { for (u=0; u>12; v = d&0xFFF; c = MIN(s,0x1000-v); // bank switcher access if (cCurrentRomType!='S' && M_BS == eMap) { BOOL bWrite = FALSE; // write enabled if (Chipset.cards_status & PORT2_WRITE) { Chipset.Bank_FF = v+c-1;// save FF value bWrite = TRUE; // bank switched } else // write disabled, so latch last read cycle { if ((v & 1) != 0) // low address odd { Chipset.Bank_FF = v;// save FF value bWrite = TRUE; // bank switched } if (((v+c) & 1) != 0) // high address odd { Chipset.Bank_FF = v+c-1;// save FF value bWrite = TRUE; // bank switched } } if (bWrite) // write cycle? { // HP48GX if (cCurrentRomType=='G') Map(Chipset.P2Base,Chipset.P2End); // HP39/40G, HP49G if (cCurrentRomType=='E' || cCurrentRomType=='X') RomSwitch(Chipset.Bank_FF); } } // Flash memory Write access if (cCurrentRomType=='X' && (Chipset.IORam[LCR] & LED) && M_P2 == eMap) { DWORD dwLinAddr = FlashROMAddr(d); FlashWrite(a, dwLinAddr, c); #if defined DEBUG_FLASH { TCHAR buffer[256]; DWORD j; int i; i = wsprintf(buffer,_T("%.5lx: Flash Write: %.5x (%.6x),%u = "),Chipset.pc,d,dwLinAddr,c); for (j = 0;j < c;++j,++i) { buffer[i] = a[j]; if (buffer[i] > 9) buffer[i] += _T('a') - _T('9') - 1; buffer[i] += _T('0'); } buffer[i++] = _T('\n'); buffer[i] = 0; OutputDebugString(buffer); } #endif } else { if ((p=WMap[u]) != NULL) memcpy(p+v, a, c); } } if (!bGrayscale) UpdateDisplay(d, c); // update display a+=c; d=(d+c)&0xFFFFF; } while (s-=c); return; } DWORD Read5(DWORD d) { BYTE p[5]; Npeek(p,d,5); return Npack(p,5); } BYTE Read2(DWORD d) { BYTE p[2]; Npeek(p,d,2); return (BYTE)(p[0]|(p[1]<<4)); } VOID Write5(DWORD d, DWORD n) { BYTE p[5]; Nunpack(p,n,5); Nwrite(p,d,5); return; } VOID Write2(DWORD d, BYTE n) { BYTE p[2]; Nunpack(p,n,2); Nwrite(p,d,2); return; } VOID IOBit(DWORD d, BYTE b, BOOL s) // set/clear bit in I/O section { EnterCriticalSection(&csIOLock); { if (s) Chipset.IORam[d] |= b; // set bit else Chipset.IORam[d] &= ~b; // clear bit } LeaveCriticalSection(&csIOLock); } static DWORD ReadT2Acc(VOID) { static DWORD dwCyc = 0; // CPU cycle counter at last timer2 read access DWORD dwCycDif; // CPU cycles since last call dwCycDif = (DWORD) (Chipset.cycles & 0xFFFFFFFF) - dwCyc; dwCyc = (DWORD) (Chipset.cycles & 0xFFFFFFFF); // maybe CPU speed measurement, slow down the next 10 CPU opcodes if (dwCycDif < 150) { InitAdjustSpeed(); // init variables if necessary EnterCriticalSection(&csSlowLock); { nOpcSlow = 10; // slow down next 10 opcodes } LeaveCriticalSection(&csSlowLock); } return ReadT2(); } VOID ReadIO(BYTE *a, DWORD d, DWORD s, BOOL bUpdate) { BOOL bNINT,bNINT2; BOOL bLBI,bVLBI; BYTE c = 0xFF; // LINECOUNT not initialized BOOL rbr_acc = FALSE; // flag to receive data #if defined DEBUG_IO { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: IO read : %02x,%u\n"),Chipset.pc,d,s); OutputDebugString(buffer); } #endif do { switch (d) { case 0x00: *a = (Chipset.IORam[d]&DON)|Chipset.boffset; break; case 0x01: *a = Chipset.contrast&0xF; break; case 0x02: *a = Chipset.contrast>>4; break; case 0x03: *a = 0; case 0x04: *a = (Chipset.crc )&0xF; break; case 0x05: *a = (Chipset.crc>> 4)&0xF; break; case 0x06: *a = (Chipset.crc>> 8)&0xF; break; case 0x07: *a = (Chipset.crc>>12)&0xF; break; case 0x08: // LPD // LB2 and LB1 not emulated, must be 0 _ASSERT((Chipset.IORam[LPD] & (LB2 | LB1)) == 0); GetBatteryState(&bLBI,&bVLBI); // get battery state // check if battery states enabled bLBI = bLBI && ((Chipset.IORam[LPE] & ELBI) != 0); bVLBI = bVLBI && ((Chipset.IORam[LPE] & EVLBI) != 0); // set IO bits IOBit(LPD,LB0,bLBI); IOBit(LPD,VLBI,bVLBI); IOBit(SRQ1,VSRQ,bVLBI); *a = Chipset.IORam[d]; break; case 0x09: // LPE *a = Chipset.IORam[d]; if (bUpdate) { Chipset.IORam[d] &= ~RST; // clear RST bit after reading } break; case 0x0A: *a = 0; break; // case 0x0B: *a = Chipset.IORam[d]; break; // case 0x0C: *a = Chipset.IORam[d]; break; case 0x0D: // BAUD *a = Chipset.IORam[d] & 0x7; #if defined DEBUG_SERIAL // return BAUD value if (bUpdate) { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: BAUD Read: %x\n"),Chipset.pc,*a); OutputDebugString(buffer); } #endif *a |= UckBit(*a); // add UCK bit to BAUD rate register break; case 0x0E: // SMP is !NINT and SWINT is always 0 // clear SMP and SWINT bit Chipset.IORam[d] &= (ECDT | RCDT); // SMP is !NINT if ((Chipset.IORam[SRQ2] & NINT) == 0) Chipset.IORam[d] |= SMP; *a = Chipset.IORam[d]; break; case 0x0F: // card detection disabled if ((Chipset.IORam[CARDCTL] & ECDT) == 0) { *a = 0; // no cards } else { // on a HP30/40G and HP49G Chipset.cards_status bust always be 0xF _ASSERT((cCurrentRomType!='E' && cCurrentRomType!='X') || Chipset.cards_status == 0xF); *a = Chipset.cards_status; } break; case 0x10: // IO CONTROL *a = Chipset.IORam[d]; // return IO CONTROL value #if defined DEBUG_SERIAL if (bUpdate) { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: IOC Read: %x\n"),Chipset.pc,*a); OutputDebugString(buffer); } #endif break; case 0x11: // RCS *a = Chipset.IORam[d] | RX; // return RCS value #if defined DEBUG_SERIAL if (bUpdate) { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: RCS Read: %x\n"),Chipset.pc,*a); OutputDebugString(buffer); } #endif break; case 0x12: // TCS *a = Chipset.IORam[d]; // return TCS value if ((*a & TBF)) // Transmit buffer full { // the G-series XModem implementation has a timeout loop counter // waiting for transmit buffer empty, so on fast hosts with // CPU running with max. speed we may get a timeout overflow // -> to avoid this slow down CPU speed on transmit buffer full InitAdjustSpeed(); // init variables if necessary EnterCriticalSection(&csSlowLock); { nOpcSlow = 10; // slow down next 10 opcodes } LeaveCriticalSection(&csSlowLock); } #if defined DEBUG_SERIAL if (bUpdate) { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: TCS Read: %x\n"),Chipset.pc,*a); OutputDebugString(buffer); } #endif break; case 0x13: // CRER *a = 0; break; case 0x14: // RBR LSB case 0x15: // RBR MSB if (bUpdate) { *a = Chipset.IORam[d]; // return RBR value if (d==0x15) // reading RBR MSB { Chipset.IORam[RCS] &= ~RBF; // clear Receive Buffer Full flag } UpdateUSRQ(); // update USRQ rbr_acc = TRUE; // search for new RBR value #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: RBR %s Read: %x\n"),Chipset.pc,(d==0x14) ? "LSB" : "MSB",*a); OutputDebugString(buffer); } #endif } else { *a = Chipset.IORam[d]; // return RBR value UpdateUSRQ(); // update USRQ } break; // case 0x16: *a = Chipset.IORam[d]; break; // TBR LSB // case 0x17: *a = Chipset.IORam[d]; break; // TBR MSB case 0x19: // SREQ? MSB UpdateKdnBit(); // update KDN bit bNINT2 = Chipset.IORam[SRQ1] == 0 && (Chipset.IORam[SRQ2] & LSRQ) == 0; bNINT = (Chipset.IORam[SRQ2] & NINT) != 0; // card detection off and timer running if ((Chipset.IORam[CARDCTL] & ECDT) == 0 && (Chipset.IORam[TIMER2_CTRL] & RUN) != 0) { // state of CDT2 bNINT2 = bNINT2 && (Chipset.cards_status & (P2W|P2C)) != P2C; // state of CDT1 bNINT = bNINT && (Chipset.cards_status & (P1W|P1C)) != P1C; } IOBit(SRQ2,NINT2,bNINT2); IOBit(SRQ2,NINT,bNINT); // no break! case 0x18: // SREQ? LSB *a = Chipset.IORam[d]; // return SREQ value #if defined DEBUG_SERIAL if (bUpdate) { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: SEQ %s Read: %x\n"),Chipset.pc,(d==0x18) ? "LSB" : "MSB",*a); OutputDebugString(buffer); } #endif break; case 0x1A: // IR CONTROL if (cCurrentRomType=='E') // HP39/40G { Chipset.IORam[d] = (nCurrentClass != 40) ? (Chipset.IORam[d] & ~IRI) // HP39G : (Chipset.IORam[d] | IRI); // HP40G } *a = Chipset.IORam[d]; // return IR CONTROL value #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: IRC Read: %x\n"),Chipset.pc,*a); OutputDebugString(buffer); } #endif break; case 0x1B: *a = 0; break; case 0x1C: // LED CONTROL // put LBF and LBZ always to zero to indicate a free REDEYE buffer and formatter *a = (Chipset.IORam[d] & (LED|ELBE)); break; case 0x1D: // LED BUFFER *a = (Chipset.IORam[d] & LBO); break; // case 0x1E: *a = Chipset.IORam[d]; break; // case 0x1F: *a = Chipset.IORam[d]; break; case 0x20: *a = 3; break; case 0x21: *a = 3; break; case 0x22: *a = 3; break; case 0x23: *a = 3; break; case 0x24: *a = 3; break; case 0x25: *a = 3; break; case 0x26: *a = 3; break; case 0x27: *a = 3; break; case 0x28: // LINECOUNT LSB case 0x29: // LINECOUNT MSB + DA19 M32 if (Chipset.IORam[0x00]&DON) // display on { if (c == 0xFF) // no actual line information { c = GetLineCounter(); // get LCD update line // save line information in IO registers Chipset.IORam[0x28] = c & 0xF; Chipset.IORam[0x29] = (Chipset.IORam[0x29] & (DA19|M32)) | (c >> 4); } } *a = Chipset.IORam[d]; if (d==0x29) // address 0x29 is mirrored to 0x2A-0x2D { Chipset.IORam[0x2A] = *a; Chipset.IORam[0x2B] = *a; Chipset.IORam[0x2C] = *a; Chipset.IORam[0x2D] = *a; } break; // case 0x2A: *a = 0; break; // case 0x2B: *a = 0; break; // case 0x2C: *a = 0; break; // case 0x2D: *a = 0; break; case 0x2E: ReadT1(); // dummy read for update timer1 control register *a = Chipset.IORam[d]; break; case 0x2F: ReadT2(); // dummy read for update timer2 control register *a = Chipset.IORam[d]; break; case 0x30: *a = 3; break; case 0x31: *a = 3; break; case 0x32: *a = 3; break; case 0x33: *a = 3; break; case 0x34: *a = 3; break; case 0x35: *a = 0; break; case 0x36: *a = 0; break; case 0x37: *a = ReadT1(); break; case 0x38: Nunpack(a, ReadT2Acc() , s); return; case 0x39: Nunpack(a, ReadT2Acc()>> 4, s); return; case 0x3A: Nunpack(a, ReadT2Acc()>> 8, s); return; case 0x3B: Nunpack(a, ReadT2Acc()>>12, s); return; case 0x3C: Nunpack(a, ReadT2Acc()>>16, s); return; case 0x3D: Nunpack(a, ReadT2Acc()>>20, s); return; case 0x3E: Nunpack(a, ReadT2Acc()>>24, s); return; case 0x3F: Nunpack(a, ReadT2Acc()>>28, s); return; default: *a = Chipset.IORam[d]; } d++; a++; } while (--s); if (rbr_acc) CommReceive(); // look for new character return; } VOID WriteIO(BYTE *a, DWORD d, DWORD s) { DWORD b; BYTE c; BOOL tbr_acc = FALSE; // flag to transmit data BOOL bDISPADDR = FALSE; // flag addr 0x120-0x124 changed BOOL bLINEOFFS = FALSE; // flag addr 0x125-0x127 changed BOOL bMENUADDR = FALSE; // flag addr 0x130-0x134 changed DWORD dwAnnunciator = 0; // no annunciator write #if defined DEBUG_IO { TCHAR buffer[256]; DWORD j; int i; i = wsprintf(buffer,_T("%.5lx: IO write: %02x,%u = "),Chipset.pc,d,s); for (j = 0;j < s;++j,++i) { buffer[i] = a[j]; if (buffer[i] > 9) buffer[i] += _T('a') - _T('9') - 1; buffer[i] += _T('0'); } buffer[i++] = _T('\n'); buffer[i] = 0; OutputDebugString(buffer); } #endif do { c = *a; switch (d) { // 00100 = NS:DISPIO // 00100 @ Display bit offset and DON [DON OFF2 OFF1 OFF0] // 00100 @ 3 nibs for display offset (scrolling), DON=Display ON case 0x00: if ((c^Chipset.IORam[d])&DON) // DON bit changed { disp |= (DISP_POINTER | DISP_MAIN | DISP_MENUE); // adjust VBL counter start/stop values if ((c & DON) != 0) // set display on { Chipset.IORam[d] |= DON; // for StartDisplay(); UpdateContrast(Chipset.contrast); StartDisplay((BYTE) Chipset.lcounter); // start display update } else // display is off { Chipset.IORam[d] &= ~DON; UpdateContrast(Chipset.contrast); StopDisplay(); // stop display update } } // OFF bits changed if ((c^Chipset.IORam[d]) & (OFF2 | OFF1 | OFF0)) { Chipset.boffset = c & (OFF2 | OFF1 | OFF0); disp |= (DISP_POINTER | DISP_MAIN); } Chipset.IORam[d] = c; break; // 00101 = NS:CONTRLSB // 00101 @ Contrast Control [CON3 CON2 CON1 CON0] // 00101 @ Higher value = darker screen case 0x01: if (c!=Chipset.IORam[d]) { Chipset.IORam[d]=c; Chipset.contrast = (Chipset.contrast&0x10)|c; UpdateContrast(Chipset.contrast); disp |= (DISP_MAIN | DISP_MENUE); } break; // 00102 = NS:DISPTEST // 00102 @ Display test [VDIG LID TRIM CON4] [LRT LRTD LRTC BIN] // 00102 @ Normally zeros case 0x02: if (c!=Chipset.IORam[d]) { Chipset.IORam[d]=c; Chipset.contrast = (Chipset.contrast&0x0f)|((c&1)<<4); UpdateContrast(Chipset.contrast); disp |= (DISP_MAIN | DISP_MENUE); } break; case 0x03: Chipset.IORam[d]=c; break; // 00104 = HP:CRC // 00104 @ 16 bit hardware CRC (104-107) (X^16+X^12+X^5+1) // 00104 @ crc = ( crc >> 4 ) ^ ( ( ( crc ^ nib ) & 0x000F ) * 0x1081 ); case 0x04: Chipset.crc = (Chipset.crc&0xfff0)|(c*0x0001); break; case 0x05: Chipset.crc = (Chipset.crc&0xff0f)|(c*0x0010); break; case 0x06: Chipset.crc = (Chipset.crc&0xf0ff)|(c*0x0100); break; case 0x07: Chipset.crc = (Chipset.crc&0x0fff)|(c*0x1000); break; // 00108 = NS:POWERSTATUS // 00108 @ Low power registers (108-109) // 00108 @ [LB2 LB1 LB0 VLBI] (read only) // 00108 @ LowBat(2) LowBat(1) LowBat(S) VeryLowBat case 0x08: break; // read-only // 00109 = NS:POWERCTRL // 00109 @ [ELBI EVLBI GRST RST] (read/write) case 0x09: Chipset.IORam[d]=c; if (c & RST) { CpuReset(); // emulate NRES signal disp |= (DISP_POINTER | DISP_MAIN | DISP_MENUE); dwAnnunciator = 0x3F; // update all annunciators bInterrupt = TRUE; // SHUTDN } break; // 0010A = NS:MODE // 0010A @ Mode Register (read-only) case 0x0A: break; // read-only // 0010B = HP:ANNCTRL // 0010B @ Annunciator control [LA4 LA3 LA2 LA1] = [ alarm alpha -> <- ] case 0x0B: case 0x0C: // annunciator changed dwAnnunciator |= ((Chipset.IORam[d] ^c) << ((d - 0x0B) * 4)) & 0x3F; Chipset.IORam[d] = c; break; // 0010D = NS:BAUD // 0010D @ Serial baud rate [UCK BD2 BD1 BD0] (bit 3 is read-only) // 0010D @ 3 bits = {1200 1920 2400 3840 4800 7680 9600 15360} case 0x0D: Chipset.IORam[d]=(Chipset.IORam[d]&8)|(c&7); // bit 3 is read-only CommSetBaud(); // set baudrate #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: BAUD write: %x\n"),Chipset.pc,Chipset.IORam[d]); OutputDebugString(buffer); } #endif break; // 0010E = NS:CARDCTL // 0010E @ [ECDT RCDT SMP SWINT] (read/write) // 0010E @ Enable Card Det., Run Card Det., Set Module Pulled, Software interrupt case 0x0E: if (c & SWINT) // SWINT bit set { c &= (ECDT | RCDT | SMP); // clear SWINT bit Chipset.SoftInt = TRUE; bInterrupt = TRUE; } if ((c & SMP) == 0) // SMP bit cleared { BOOL bNINT = TRUE; // ack NINT interrupt -> NINT high // card detect disabled and CDT1 low -> retrigger if ((c & ECDT) == 0 && (Chipset.IORam[TIMER2_CTRL] & RUN) != 0) bNINT = (Chipset.cards_status & (P1W|P1C)) != P1C; IOBit(SRQ2,NINT,bNINT); } // falling edge of Enable Card Detect bit and timer running if ( ((c^Chipset.IORam[d]) & ECDT) != 0 && (c & ECDT) == 0 && (Chipset.IORam[TIMER2_CTRL] & RUN) != 0) { BOOL bNINT = (Chipset.IORam[SRQ2] & NINT) != 0; // card in slot1 isn't Read Only if ((Chipset.cards_status & (P1W|P1C)) != P1C) { // use random state of NINT line bNINT = bNINT && (ReadT2() & 0x1) != 0; } IOBit(SRQ2,NINT,bNINT); Chipset.HST |= MP; // set Module Pulled // Port1 and Port2 plugged and writeable or NINT2/NINT interrupt if ( Chipset.cards_status != (P2W|P1W|P2C|P1C) || (Chipset.IORam[SRQ2] & NINT2) == 0 || (Chipset.IORam[SRQ2] & NINT ) == 0 ) { Chipset.SoftInt = TRUE; // set interrupt bInterrupt = TRUE; } } Chipset.IORam[d]=c; break; // 0010F = NS:CARDSTATUS // 0010F @ [P2W P1W P2C P1C] (read-only) Port 2 writable .. Port 1 inserted case 0x0F: break; // read-only // 00110 = HP:IOC // 00110 @ Serial I/O Control [SON ETBE ERBF ERBZ] // 00110 @ Serial On, Interrupt On Recv.Buf.Empty, Full, Buzy case 0x10: Chipset.IORam[d]=c; CheckSerial(); // handle UART on/off if ((c & SON) == 0) // SON bit cleared { Chipset.IORam[IOC] = 0; // clear IOC Chipset.IORam[RCS] = 0; // clear RCS Chipset.IORam[TCS] = 0; // clear TCS Chipset.IORam[RBR_LSB] = 0; // clear RBR Chipset.IORam[RBR_MSB] = 0; Chipset.IORam[TBR_LSB] = 0; // clear TBR Chipset.IORam[TBR_MSB] = 0; } if (UpdateUSRQ()) INTERRUPT; // update USRQ bit #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: IOC write: %x\n"),Chipset.pc,Chipset.IORam[d]); OutputDebugString(buffer); } #endif break; // 00111 = HP:RCS // 00111 Serial Receive Control/Status [RX RER RBZ RBF] (bit 3 is read-only) case 0x11: if (Chipset.IORam[IOC] & SON) { EnterCriticalSection(&csIOLock); { // critical section because of RER access Chipset.IORam[d]=(Chipset.IORam[d]&8)|(c&7); } LeaveCriticalSection(&csIOLock); #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: RCS write: %x\n"),Chipset.pc,Chipset.IORam[d]); OutputDebugString(buffer); } #endif } break; // 00112 = HP:TCS // 00112 @ Serial Transmit Control/Status [BRK LPB TBZ TBF] case 0x12: if (Chipset.IORam[IOC] & SON) { Chipset.IORam[d]=c; CommTxBRK(); // update BRK condition #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: TCS write: %x\n"),Chipset.pc,Chipset.IORam[d]); OutputDebugString(buffer); } #endif } break; // 00113 = HP:CRER // 00113 @ Serial Clear RER (writing anything clears RER bit) case 0x13: IOBit(RCS,RER,FALSE); #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: CRER write: %x\n"),Chipset.pc,Chipset.IORam[d]); OutputDebugString(buffer); } #endif break; // 00114 = HP:RBR // 00114 @ Serial Receive Buffer Register (Reading clears RBF bit) case 0x14: break; // read-only case 0x15: break; // read-only // 00116 = HP:TBR // 00116 @ Serial Transmit Buffer Register (Writing sets TBF bit) case 0x16: case 0x17: if (Chipset.IORam[IOC] & SON) { Chipset.IORam[d]=c; tbr_acc = TRUE; // new TBR value #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: TBR %s write: %x\n"),Chipset.pc,(d==0x16) ? "LSB" : "MSB",*a); OutputDebugString(buffer); } #endif } break; // 00118 = NS:SRR // 00118 @ Service Request Register (read-only) // 00118 @ [ISRQ TSRQ USRQ VSRQ] [KDN NINT2 NINT LSRQ] case 0x18: break; // read-only case 0x19: break; // read-only // 0011A = HP:IRC // 0011A @ IR Control Register [IRI EIRU EIRI IRE] (bit 3 is read-only) // 0011A @ IR Input, Enable IR UART mode, Enable IR Interrupt, IR Event case 0x1A: // EIRU bit changed if (((c^Chipset.IORam[d]) & EIRU) != 0) { // save new value for COM open Chipset.IORam[d]=(Chipset.IORam[d]&8)|(c&7); // reopen COM port with new setting CommOpen(szSerialWire,szSerialIr); } Chipset.IORam[d]=(Chipset.IORam[d]&8)|(c&7); #if defined DEBUG_SERIAL { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: IRC write: %x\n"),Chipset.pc,Chipset.IORam[d]); OutputDebugString(buffer); } #endif break; // 0011B = NS:BASENIBOFF // 0011B @ Used as addressto get BASENIB from 11F to the 5th nibble case 0x1B: break; // 0011C = NS:LCR // 0011C @ Led Control Register [LED ELBE LBZ LBF] (Setting LED is draining) case 0x1C: // HP49G new mapping on LED bit change if (cCurrentRomType=='X' && ((c^Chipset.IORam[d])&LED)) { Chipset.IORam[d]=c; // save new value for mapping Map(Chipset.P2Base,Chipset.P2End); // new ROM mapping #if defined DEBUG_FLASH { TCHAR buffer[256]; wsprintf(buffer,_T("%.5lx: NCE3: R%cM\n"),Chipset.pc,(c&LED) ? 'O' : 'A'); OutputDebugString(buffer); } #endif } if ((c^Chipset.IORam[d])&ELBE) // ELBE bit changed { // Led Service ReQuest on Led Buffer Empty enabled BOOL bLSRQ = (c & (ELBE | LBF)) == ELBE; IOBit(SRQ2,LSRQ,bLSRQ); // update LSRQ bit if (bLSRQ) // interrupt on Led Buffer Empty enabled { Chipset.SoftInt = TRUE; bInterrupt = TRUE; } } Chipset.IORam[d]=c; break; // 0011D = NS:LBR // 0011D @ Led Buffer Register [0 0 0 LBO] (bits 1-3 read zero) case 0x1D: IrPrinter((BYTE)(c&LBO)); Chipset.IORam[d]=c&LBO; break; // 0011E = NS:SCRATCHPAD // 0011E @ Scratch pad case 0x1E: Chipset.IORam[d]=c; break; // 0011F = NS:BASENIB // 0011F @ 7 or 8 for base memory case 0x1F: Chipset.IORam[d]=c; break; // 00120 = NS:DISPADDR // 00120 @ Display Start Address (write only) // 00120 @ bit 0 is ignored (display must start on byte boundary) case 0x20: case 0x21: case 0x22: case 0x23: case 0x24: Chipset.IORam[d]=c; bDISPADDR = TRUE; // addr 0x120-0x124 changed break; // 00125 = NS:LINEOFFS // 00125 @ Display Line offset (write only) (no of bytes skipped after each line) // 00125 @ MSG sign extended case 0x25: case 0x26: case 0x27: Chipset.IORam[d]=c; bLINEOFFS = TRUE; // addr 0x125-0x127 changed break; // 00128 = NS:LINECOUNT // 00128 @ Display Line Counter and miscellaneous (28-29) // 00128 @ [LC3 LC2 LC1 LC0] [DA19 M32 LC5 LC4] // 00128 @ Line counter 6 bits -> max = 2^6-1 = 63 = disp height // 00128 @ Normally has 55 -> Menu starts at display row 56 case 0x28: // LSB of LINECOUNT changed if (c != (BYTE) (Chipset.lcounter & 0xf)) { Chipset.lcounter = (Chipset.lcounter & ~0xF) | c; disp |= (DISP_POINTER | DISP_MAIN | DISP_MENUE); } break; case 0x29: // MSB of LINECOUNT changed b = (c & 0x3) << 4; // upper two bits if (b != (Chipset.lcounter & 0x30)) { Chipset.lcounter = (Chipset.lcounter & ~0x30) | b; disp |= (DISP_POINTER | DISP_MAIN | DISP_MENUE); } if ((c^Chipset.IORam[d])&DA19) // DA19 changed { Chipset.IORam[d]^=DA19; // save new DA19 Map(0x00,0xFF); // new ROM mapping } break; case 0x2A: break; case 0x2B: break; case 0x2C: break; case 0x2D: break; // 0012E = NS:TIMER1CTRL // 0012E @ TIMER1 Control [SRQ WKE INT XTRA] case 0x2E: Chipset.IORam[d]=c; // don't clear XTRA bit ReadT1(); // dummy read for checking control bits break; // 0012F = NS:TIMER2CTRL // 0012F @ TIMER2 Control [SRQ WKE INT RUN] case 0x2F: Chipset.IORam[d]=c; ReadT2(); // dummy read for checking control bits if (c&1) StartTimers(); else StopTimers(); dwAnnunciator = 0x3F; // update all annunciators break; // 00130 = NS:MENUADDR // 00130 @ Display Secondary Start Address (write only) (30-34) // 00130 @ Menu Display Address, no line offsets case 0x30: case 0x31: case 0x32: case 0x33: case 0x34: Chipset.IORam[d]=c; bMENUADDR = TRUE; // addr 0x130-0x134 changed break; case 0x35: break; case 0x36: break; // 00137 = HP:TIMER1 // 00137 @ Decremented 16 times/s case 0x37: SetT1(c); // set new value break; // 00138 = HP:TIMER2 // 00138 @ hardware timer (38-3F), decremented 8192 times/s // nothing - fall through to default default: Chipset.IORam[d]=c; // write data if (d >= TIMER2) // timer2 update { Nunpack(Chipset.IORam+TIMER2,ReadT2(),8); memcpy(Chipset.IORam+d,a,s); SetT2(Npack(Chipset.IORam+TIMER2,8)); goto finish; } } a++; d++; } while (--s); finish: if (bDISPADDR) // 0x120-0x124 changed { b = Npack(Chipset.IORam+DISP1CTL,5)&0xFFFFE; if (b != Chipset.start1) { Chipset.start1 = b; disp |= (DISP_POINTER | DISP_MAIN); } } if (bLINEOFFS) // addr 0x125-0x127 changed { signed short lo = (signed short)Npack(Chipset.IORam+LINENIBS,3); if (lo&0x800) lo-=0x1000; if (lo != Chipset.loffset) { Chipset.loffset = lo; disp |= (DISP_POINTER | DISP_MAIN); } } if (bMENUADDR) // addr 0x130-0x134 changed { b = Npack(Chipset.IORam+DISP2CTL,5)&0xFFFFE; if (b != Chipset.start2) { Chipset.start2 = b; disp |= (DISP_POINTER | DISP_MENUE); } } if (tbr_acc) // addr 0x116-0x117 changed { IOBit(TCS,TBF,TRUE); // set transmit buffer full bit CommTransmit(); // transmit char } if (disp & DISP_POINTER) { disp &= ~DISP_POINTER; // display pointer updated UpdateDisplayPointers(); } if (dwAnnunciator) { UpdateAnnunciators(dwAnnunciator); } return; }