/****************************************************************/ /* */ /* config.c */ /* DOS-C */ /* */ /* config.sys Processing Functions */ /* */ /* Copyright (c) 1996 */ /* Pasquale J. Villani */ /* All Rights Reserved */ /* */ /* This file is part of DOS-C. */ /* */ /* DOS-C is free software; you can redistribute it and/or */ /* modify it under the terms of the GNU General Public License */ /* as published by the Free Software Foundation; either version */ /* 2, or (at your option) any later version. */ /* */ /* DOS-C is distributed in the hope that it will be useful, but */ /* WITHOUT ANY WARRANTY; without even the implied warranty of */ /* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See */ /* the GNU General Public License for more details. */ /* */ /* You should have received a copy of the GNU General Public */ /* License along with DOS-C; see the file COPYING. If not, */ /* write to the Free Software Foundation, 675 Mass Ave, */ /* Cambridge, MA 02139, USA. */ /****************************************************************/ #include "init-mod.h" #include "portab.h" #include "globals.h" #include "nls.h" #ifdef VERSION_STRINGS static BYTE *RcsId = "$Id$"; #endif /* * $Log$ * Revision 1.7 2000/08/07 03:03:12 jimtabor * Fix problem with devicehigh * * Revision 1.6 2000/08/06 05:50:17 jimtabor * Add new files and update cvs with patches and changes * * Revision 1.5 2000/06/21 18:16:46 jimtabor * Add UMB code, patch, and code fixes * * Revision 1.4 2000/05/26 19:25:19 jimtabor * Read History file for Change info * * Revision 1.3 2000/05/25 20:56:21 jimtabor * Fixed project history * * Revision 1.2 2000/05/08 04:29:59 jimtabor * Update CVS to 2020 * * Revision 1.1.1.1 2000/05/06 19:34:53 jhall1 * The FreeDOS Kernel. A DOS kernel that aims to be 100% compatible with * MS-DOS. Distributed under the GNU GPL. * * Revision 1.15 2000/03/31 05:40:09 jtabor * Added Eric W. Biederman Patches * * Revision 1.14 2000/03/17 22:59:04 kernel * Steffen Kaiser's NLS changes * * Revision 1.13 2000/03/09 06:07:10 kernel * 2017f updates by James Tabor * * Revision 1.12 1999/09/23 04:40:46 jprice * *** empty log message *** * * Revision 1.10 1999/08/25 03:18:07 jprice * ror4 patches to allow TC 2.01 compile. * * Revision 1.9 1999/05/03 06:25:45 jprice * Patches from ror4 and many changed of signed to unsigned variables. * * Revision 1.8 1999/04/16 21:43:40 jprice * ror4 multi-sector IO * * Revision 1.7 1999/04/16 12:21:21 jprice * Steffen c-break handler changes * * Revision 1.6 1999/04/16 00:53:32 jprice * Optimized FAT handling * * Revision 1.5 1999/04/12 03:21:17 jprice * more ror4 patches. Changes for multi-block IO * * Revision 1.4 1999/04/11 04:33:38 jprice * ror4 patches * * Revision 1.2 1999/04/04 22:57:47 jprice * no message * * Revision 1.1.1.1 1999/03/29 15:40:46 jprice * New version without IPL.SYS * * Revision 1.6 1999/03/23 23:38:15 jprice * Now checks for a reads fdconfig.sys file, if exists * * Revision 1.5 1999/02/08 05:55:57 jprice * Added Pat's 1937 kernel patches * * Revision 1.4 1999/02/01 01:48:41 jprice * Clean up; Now you can use hex numbers in config.sys. added config.sys screen function to change screen mode (28 or 43/50 lines) * * Revision 1.3 1999/01/30 08:28:11 jprice * Clean up; Fixed bug with set attribute function. * * Revision 1.2 1999/01/22 04:13:25 jprice * Formating * * Revision 1.1.1.1 1999/01/20 05:51:01 jprice * Imported sources * * * Rev 1.6 22 Jan 1998 4:09:24 patv * Fixed pointer problems affecting SDA * * Rev 1.5 04 Jan 1998 23:15:18 patv * Changed Log for strip utility * * Rev 1.4 04 Jan 1998 17:26:14 patv * Corrected subdirectory bug * * Rev 1.3 16 Jan 1997 12:46:50 patv * pre-Release 0.92 feature additions * * Rev 1.1 29 May 1996 21:03:44 patv * bug fixes for v0.91a * * Rev 1.0 19 Feb 1996 3:22:16 patv * Added NLS, int2f and config.sys processing */ #ifdef __TURBOC__ void __int__(int); /* TC 2.01 requires this. :( -- ror4 */ #endif #ifdef KDB #include #define KernelAlloc(x) adjust_far((void far *)malloc((unsigned long)(x))) #endif BYTE FAR *lpBase; BYTE FAR *upBase; static BYTE FAR *lpOldLast; static BYTE FAR *upOldLast; static COUNT nCfgLine; static COUNT nPass; static COUNT UmbState; static BYTE szLine[256]; static BYTE szBuf[256]; int singleStep = 0; INIT VOID zumcb_init(mcb FAR * mcbp, UWORD size); INIT VOID mumcb_init(mcb FAR * mcbp, UWORD size); INIT VOID Buffers(BYTE * pLine); INIT VOID sysScreenMode(BYTE * pLine); INIT VOID sysVersion(BYTE * pLine); INIT VOID Break(BYTE * pLine); INIT VOID Device(BYTE * pLine); INIT VOID DeviceHigh(BYTE * pLine); INIT VOID Files(BYTE * pLine); INIT VOID Fcbs(BYTE * pLine); INIT VOID Lastdrive(BYTE * pLine); INIT VOID LoadDevice(BYTE * pLine, COUNT top, COUNT mode); INIT VOID Dosmem(BYTE * pLine); INIT VOID Country(BYTE * pLine); INIT VOID InitPgm(BYTE * pLine); INIT VOID Switchar(BYTE * pLine); INIT VOID CfgFailure(BYTE * pLine); INIT VOID Stacks(BYTE * pLine); INIT BYTE *GetNumArg(BYTE * pLine, COUNT * pnArg); INIT BYTE *GetStringArg(BYTE * pLine, BYTE * pszString); INIT struct dhdr FAR *linkdev(struct dhdr FAR * dhp); INIT UWORD initdev(struct dhdr FAR * dhp, BYTE FAR * cmdTail); INIT int SkipLine(char *pLine); INIT static VOID FAR *AlignParagraph(VOID FAR * lpPtr); #ifndef I86 #define AlignParagraph(x) (x) #endif #define EOF 0x1a INIT struct table *LookUp(struct table *p, BYTE * token); struct table { BYTE *entry; BYTE pass; VOID(*func) (BYTE * pLine); }; static struct table commands[] = { {"break", 1, Break}, {"buffers", 1, Buffers}, {"command", 1, InitPgm}, {"country", 1, Country}, {"device", 2, Device}, {"devicehigh", 2, DeviceHigh}, {"dos", 2, Dosmem}, {"fcbs", 1, Fcbs}, {"files", 1, Files}, {"lastdrive", 1, Lastdrive}, /* rem is never executed by locking out pass */ {"rem", 0, CfgFailure}, {"shell", 1, InitPgm}, {"stacks", 1, Stacks}, {"switchar", 1, Switchar}, {"screen", 1, sysScreenMode}, /* JPP */ {"version", 1, sysVersion}, /* JPP */ /* default action */ {"", -1, CfgFailure} }; #ifndef KDB INIT BYTE FAR *KernelAlloc(WORD nBytes); INIT BYTE FAR *KernelAllocDma(WORD); #endif BYTE *pLineStart; /* Do first time initialization. Store last so that we can reset it */ /* later. */ INIT void PreConfig(void) { /* Set pass number */ nPass = 0; VgaSet = 0; UmbState = 0; /* Initialize the base memory pointers */ lpOldLast = lpBase = AlignParagraph((BYTE FAR *) & last); #ifdef DEBUG printf("SDA located at 0x%04x:0x%04x\n", FP_SEG(internal_data), FP_OFF(internal_data)); #endif /* Begin by initializing our system buffers */ dma_scratch = (BYTE FAR *) KernelAllocDma(BUFFERSIZE); #ifdef DEBUG printf("Preliminary DMA scratchpad allocated at 0x%04x:0x%04x\n", FP_SEG(dma_scratch), FP_OFF(dma_scratch)); #endif buffers = (struct buffer FAR *) KernelAlloc(Config.cfgBuffers * sizeof(struct buffer)); #ifdef DEBUG printf("Preliminary %d buffers allocated at 0x%04x:0x%04x\n", Config.cfgBuffers, FP_SEG(buffers), FP_OFF(buffers)); #endif /* Initialize the file table */ f_nodes = (struct f_node FAR *) KernelAlloc(Config.cfgFiles * sizeof(struct f_node)); /* sfthead = (sfttbl FAR *)&basesft; */ /* FCBp = (sfttbl FAR *)&FcbSft; */ FCBp = (sfttbl FAR *) KernelAlloc(sizeof(sftheader) + Config.cfgFiles * sizeof(sft)); sfthead = (sfttbl FAR *) KernelAlloc(sizeof(sftheader) + Config.cfgFiles * sizeof(sft)); CDSp = (cdstbl FAR *) KernelAlloc(0x58 * (lastdrive)); #ifdef DEBUG printf("Preliminary f_node allocated at 0x%04x:0x%04x\n", FP_SEG(f_nodes), FP_OFF(f_nodes)); printf("Preliminary FCB table allocated at 0x%04x:0x%04x\n", FP_SEG(FCBp), FP_OFF(FCBp)); printf("Preliminary sft table allocated at 0x%04x:0x%04x\n", FP_SEG(sfthead), FP_OFF(sfthead)); printf("Preliminary CDS table allocated at 0x%04x:0x%04x\n", FP_SEG(CDSp), FP_OFF(CDSp)); #endif /* Done. Now initialize the MCB structure */ /* This next line is 8086 and 80x86 real mode specific */ #ifdef DEBUG printf("Preliminary allocation completed: top at 0x%04x:0x%04x\n", FP_SEG(lpBase), FP_OFF(lpBase)); #endif #ifdef KDB lpBase = malloc(4096); first_mcb = FP_SEG(lpBase) + ((FP_OFF(lpBase) + 0x0f) >> 4); #else first_mcb = FP_SEG(lpBase) + ((FP_OFF(lpBase) + 0x0f) >> 4); #endif /* We expect ram_top as Kbytes, so convert to paragraphs */ mcb_init((mcb FAR *) (MK_FP(first_mcb, 0)), (ram_top << 6) - first_mcb - 1); nPass = 1; } /* Do second pass initialization. */ /* Also, run config.sys to load drivers. */ INIT void PostConfig(void) { /* Set pass number */ nPass = 2; /* compute lastdrive ... */ lastdrive = Config.cfgLastdrive; if (lastdrive < nblkdev ) lastdrive = nblkdev ; /* Initialize the base memory pointers from last time. */ lpBase = AlignParagraph(lpOldLast); /* Begin by initializing our system buffers */ dma_scratch = (BYTE FAR *) KernelAllocDma(BUFFERSIZE); #ifdef DEBUG printf("DMA scratchpad allocated at 0x%04x:0x%04x\n", FP_SEG(dma_scratch), FP_OFF(dma_scratch)); #endif buffers = (struct buffer FAR *) KernelAlloc(Config.cfgBuffers * sizeof(struct buffer)); #ifdef DEBUG printf("%d buffers allocated at 0x%04x:0x%04x\n", Config.cfgBuffers, FP_SEG(buffers), FP_OFF(buffers)); #endif /* Initialize the file table */ f_nodes = (struct f_node FAR *) KernelAlloc(Config.cfgFiles * sizeof(struct f_node)); /* sfthead = (sfttbl FAR *)&basesft; */ /* FCBp = (sfttbl FAR *)&FcbSft; */ FCBp = (sfttbl FAR *) KernelAlloc(sizeof(sftheader) + Config.cfgFiles * sizeof(sft)); sfthead = (sfttbl FAR *) KernelAlloc(sizeof(sftheader) + Config.cfgFiles * sizeof(sft)); CDSp = (cdstbl FAR *) KernelAlloc(0x58 * (lastdrive)); #ifdef DEBUG printf("f_node allocated at 0x%04x:0x%04x\n", FP_SEG(f_nodes), FP_OFF(f_nodes)); printf("FCB table allocated at 0x%04x:0x%04x\n", FP_SEG(FCBp), FP_OFF(FCBp)); printf("sft table allocated at 0x%04x:0x%04x\n", FP_SEG(sfthead), FP_OFF(sfthead)); printf("CDS table allocated at 0x%04x:0x%04x\n", FP_SEG(CDSp), FP_OFF(CDSp)); #endif if (Config.cfgStacks) { VOID FAR *stackBase = KernelAlloc(Config.cfgStacks * Config.cfgStackSize); init_stacks(stackBase, Config.cfgStacks, Config.cfgStackSize); #ifdef DEBUG printf("Stacks allocated at %04x:%04x\n", FP_SEG(stackBase), FP_OFF(stackBase)); #endif } #ifdef DEBUG printf("Allocation completed: top at 0x%04x:0x%04x\n", FP_SEG(lpBase), FP_OFF(lpBase)); #endif } /* This code must be executed after device drivers has been loaded */ INIT VOID configDone(VOID) { COUNT i; if (lastdrive < nblkdev) { #ifdef DEBUG printf("lastdrive %c too small upping it to: %c\n", lastdrive + 'A', nblkdev + 'A' -1); #endif /* DEBUG */ lastdrive = nblkdev; CDSp = (cdstbl FAR *) KernelAlloc(0x58 * (lastdrive )); } first_mcb = FP_SEG(lpBase) + ((FP_OFF(lpBase) + 0x0f) >> 4); /* We expect ram_top as Kbytes, so convert to paragraphs */ mcb_init((mcb FAR *) (MK_FP(first_mcb, 0)), (ram_top << 6) - first_mcb - 1); if(UmbState == 1) { mumcb_init((mcb FAR *) (MK_FP(0x9fff, 0)), umb_start - 0x9fff - 1); /* Check if any devices were loaded in umb */ if(umb_start != FP_SEG(upBase) ){ /* make last block normal with SC for the devices */ mumcb_init((mcb FAR *) (MK_FP(uppermem_root, 0)), (FP_SEG(upBase) + ((FP_OFF(upBase) + 0x0f) >> 4)) - uppermem_root - 1); uppermem_root = FP_SEG(upBase) + ((FP_OFF(upBase) + 0x0f) >> 4); zumcb_init((mcb FAR *) (MK_FP(uppermem_root, 0)), (umb_start + UMB_top ) - uppermem_root - 1); upBase += 16; } } #ifdef DEBUG printf("UMB Allocation completed: top at 0x%04x:0x%04x\n", FP_SEG(upBase), FP_OFF(upBase)); #endif /* The standard handles should be reopened here, because we may have loaded new console or printer drivers in CONFIG.SYS */ } INIT VOID DoConfig(VOID) { COUNT nFileDesc; COUNT nRetCode; BYTE *pLine, *pTmp; BOOL bEof; /* Check to see if we have a config.sys file. If not, just */ /* exit since we don't force the user to have one. */ if ((nFileDesc = dos_open((BYTE FAR *) "fdconfig.sys", 0)) < 0) { #ifdef DEBUG printf("FDCONFIG.SYS not found\n"); #endif if ((nFileDesc = dos_open((BYTE FAR *) "config.sys", 0)) < 0) { #ifdef DEBUG printf("CONFIG.SYS not found\n"); #endif return; } #ifdef DEBUG else printf("Reading CONFIG.SYS...\n"); #endif } #ifdef DEBUG else printf("Reading FDCONFIG.SYS...\n"); #endif /* Have one -- initialize. */ nCfgLine = 0; bEof = 0; pLine = szLine; /* Read each line into the buffer and then parse the line, */ /* do the table lookup and execute the handler for that */ /* function. */ while (!bEof) { struct table *pEntry; UWORD bytesLeft = 0; if (pLine > szLine) bytesLeft = LINESIZE - (pLine - szLine); if (bytesLeft) { fbcopy(pLine, szLine, LINESIZE - bytesLeft); pLine = szLine + bytesLeft; } /* Read a line from config */ /* Interrupt processing if read error or no bytes read */ if ((nRetCode = dos_read(nFileDesc, pLine, LINESIZE - bytesLeft)) <= 0) break; /* If the buffer was not filled completely, append a CTRL-Z character to mark where the file ends */ if (nRetCode + bytesLeft < LINESIZE) szLine[nRetCode + bytesLeft] = EOF; /* Process the buffer, line by line */ pLine = szLine; while (!bEof && *pLine != EOF) { /* Do it here in the loop. */ if(UmbState == 2){ if(!Umb_Test()){ UmbState = 1; upBase = MK_FP(umb_start , 0); uppermem_root = umb_start; /* master sig for umb region with full size */ /* umcb_init((mcb FAR *) upBase, UMB_top ); upBase += 16; */ /* reset root */ uppermem_root = FP_SEG(upBase) + ((FP_OFF(upBase) + 0x0f) >> 4); /* setup the real mcb for the devicehigh block */ zumcb_init((mcb FAR *) (MK_FP(uppermem_root, 0)), UMB_top - 1); upBase += 16; } } for (pTmp = pLine; pTmp - szLine < LINESIZE; pTmp++) { if (*pTmp == '\r' || *pTmp == EOF) break; } if (pTmp - szLine >= LINESIZE) break; if (*pTmp == EOF) bEof = TRUE; *pTmp = '\0'; pLineStart = pLine; /* Skip leading white space and get verb. */ pLine = scan(pLine, szBuf); /* Translate the verb to lower case ... */ for (pTmp = szBuf; *pTmp != '\0'; pTmp++) *pTmp = tolower(*pTmp); /* If the line was blank, skip it. Otherwise, look up */ /* the verb and execute the appropriate function. */ if (*szBuf != '\0') { pEntry = LookUp(commands, szBuf); if (pEntry->pass < 0 || pEntry->pass == nPass) { if (!singleStep || !SkipLine(pLineStart)) { skipwh(pLine); if ('=' != *pLine) CfgFailure(pLine); else (*(pEntry->func)) (++pLine); } } } skipLine:nCfgLine++; pLine += strlen(pLine) + 1; } } dos_close(nFileDesc); } INIT struct table *LookUp(struct table *p, BYTE * token) { while (*(p->entry) != '\0') { if (strcmp(p->entry, token) == 0) break; else ++p; } return p; } INIT BOOL SkipLine(char *pLine) { char kbdbuf[16]; keyboard *kp = (keyboard *) kbdbuf; char *pKbd = &kp->kb_buf[0]; kp->kb_size = 12; kp->kb_count = 0; printf("%s [Y,N]?", pLine); sti(kp); pKbd = skipwh(pKbd); if (*pKbd == 'n' || *pKbd == 'N') return TRUE; return FALSE; } INIT BYTE *GetNumArg(BYTE * pLine, COUNT * pnArg) { /* look for NUMBER */ pLine = skipwh(pLine); if (!isnum(pLine)) { CfgFailure(pLine); return (BYTE *) 0; } return GetNumber(pLine, pnArg); } INIT BYTE *GetStringArg(BYTE * pLine, BYTE * pszString) { /* look for STRING */ pLine = skipwh(pLine); /* just return whatever string is there, including null */ return scan(pLine, pszString); } INIT static VOID Buffers(BYTE * pLine) { COUNT nBuffers; /* Get the argument */ if (GetNumArg(pLine, &nBuffers) == (BYTE *) 0) return; /* Got the value, assign either default or new value */ Config.cfgBuffers = max(Config.cfgBuffers, nBuffers); } INIT static VOID sysScreenMode(BYTE * pLine) { COUNT nMode; /* Get the argument */ if (GetNumArg(pLine, &nMode) == (BYTE *) 0) return; if ((nMode != 0x11) && (nMode != 0x12) && (nMode != 0x14)) return; /* Modes 0x11 (17) 28 lines 0x12 (18) 43/50 lines 0x14 (20) 25 lines */ _AX = (0x11 << 8) + nMode; _BL = 0; __int__(0x10); } INIT static VOID sysVersion(BYTE * pLine) { COUNT major, minor; char *p; p = pLine; while (*p && *p != '.') p++; if (*p++ == '\0') return; /* Get major number */ if (GetNumArg(pLine, &major) == (BYTE *) 0) return; /* Get minor number */ if (GetNumArg(p, &minor) == (BYTE *) 0) return; printf("Changing reported version to %d.%d\n", major, minor); os_major = major; os_minor = minor; } INIT static VOID Files(BYTE * pLine) { COUNT nFiles; /* Get the argument */ if (GetNumArg(pLine, &nFiles) == (BYTE *) 0) return; /* Got the value, assign either default or new value */ Config.cfgFiles = max(Config.cfgFiles, nFiles); } INIT static VOID Lastdrive(BYTE * pLine) { /* Format: LASTDRIVE = letter */ COUNT nFiles; BYTE drv; pLine = skipwh(pLine); drv = *pLine & ~0x20; if (drv < 'A' || drv > 'Z') { CfgFailure(pLine); return; } drv -= 'A'; drv++; /* Make real number*/ Config.cfgLastdrive = max(Config.cfgLastdrive, drv); } /* UmbState of confidence, 1 is sure, 2 maybe, 4 unknown and 0 no way. */ INIT static VOID Dosmem(BYTE * pLine) { if(UmbState == 0){ uppermem_link = 0; uppermem_root = 0; GetStringArg(pLine, szBuf); UmbState = strcmp(szBuf, "UMB") ? 2 : 0; } } INIT static VOID Switchar(BYTE * pLine) { /* Format: SWITCHAR = character */ GetStringArg(pLine, szBuf); switchar = *szBuf; } INIT static VOID Fcbs(BYTE * pLine) { /* Format: FCBS = totalFcbs [,protectedFcbs] */ COUNT fcbs; if ((pLine = GetNumArg(pLine, &fcbs)) == 0) return; Config.cfgFcbs = fcbs; pLine = skipwh(pLine); if (*pLine == ',') { GetNumArg(++pLine, &fcbs); Config.cfgProtFcbs = fcbs; } if (Config.cfgProtFcbs > Config.cfgFcbs) Config.cfgProtFcbs = Config.cfgFcbs; } /* LoadCountryInfo(): * Searches a file in the COUNTRY.SYS format for an entry * matching the specified code page and country code, and loads * the corresponding information into memory. If code page is 0, * the default code page for the country will be used. * * Returns TRUE if successful, FALSE if not. */ static INIT BOOL LoadCountryInfo(char *filename, UWORD ctryCode, UWORD codePage) { /* printf("cntry: %u, CP%u, file=\"%s\"\n", ctryCode, codePage, filename); */ printf("Sorry, the COUNTRY= statement has been temporarily disabled\n"); return FALSE; } INIT static VOID Country(BYTE * pLine) { /* Format: COUNTRY = countryCode, [codePage], filename */ COUNT ctryCode; COUNT codePage; if ((pLine = GetNumArg(pLine, &ctryCode)) == 0) return; pLine = skipwh(pLine); if (*pLine == ',') { pLine = skipwh(pLine + 1); if (*pLine == ',') { codePage = NLS_DEFAULT; } else { if ((pLine = GetNumArg(pLine, &codePage)) == 0) return; } pLine = skipwh(pLine); if (*pLine == ',') { GetStringArg(++pLine, szBuf); if (LoadCountryInfo(szBuf, ctryCode, codePage)) return; } } CfgFailure(pLine); } INIT static VOID Stacks(BYTE * pLine) { COUNT stacks; /* Format: STACKS = stacks [, stackSize] */ pLine = GetNumArg(pLine, &stacks); Config.cfgStacks = stacks; pLine = skipwh(pLine); if (*pLine == ',') { GetNumArg(++pLine, &stacks); Config.cfgStackSize = stacks; } if (Config.cfgStacks) { if (Config.cfgStackSize < 32) Config.cfgStackSize = 32; if (Config.cfgStackSize > 512) Config.cfgStackSize = 512; if (Config.cfgStacks > 64) Config.cfgStacks = 64; } } INIT static VOID InitPgm(BYTE * pLine) { /* Get the string argument that represents the new init pgm */ pLine = GetStringArg(pLine, Config.cfgInit); /* Now take whatever tail is left and add it on as a single */ /* string. */ strcpy(Config.cfgInitTail, pLine); /* and add a DOS new line just to be safe */ strcat(Config.cfgInitTail, "\r\n"); } INIT static VOID Break(BYTE * pLine) { /* Format: BREAK = (ON | OFF) */ BYTE *pTmp; GetStringArg(pLine, szBuf); break_ena = strcmp(szBuf, "OFF") ? 1 : 0; } INIT static VOID DeviceHigh(BYTE * pLine) { if(UmbState == 1) { LoadDevice(pLine, UMB_top, TRUE); } else { printf("UMB's unavalable!\n"); LoadDevice(pLine, ram_top, FALSE); } } INIT static VOID Device(BYTE * pLine) { LoadDevice(pLine, ram_top, FALSE); } INIT static VOID LoadDevice(BYTE * pLine, COUNT top, COUNT mode) { VOID FAR *driver_ptr; BYTE *pTmp; exec_blk eb; struct dhdr FAR *dhp; struct dhdr FAR *next_dhp; UWORD dev_seg; if(mode) dev_seg = (((ULONG) FP_SEG(upBase) << 4) + FP_OFF(upBase) + 0xf) >> 4; else dev_seg = (((ULONG) FP_SEG(lpBase) << 4) + FP_OFF(lpBase) + 0xf) >> 4; /* Get the device driver name */ GetStringArg(pLine, szBuf); /* The driver is loaded at the top of allocated memory. */ /* The device driver is paragraph aligned. */ eb.load.reloc = eb.load.load_seg = dev_seg; dhp = MK_FP(dev_seg, 0); #ifdef DEBUG printf("Loading device driver %s at segment %04x\n", szBuf, dev_seg); #endif if (DosExec(3, &eb, szBuf) == SUCCESS) { /* Link in device driver and save nul_dev pointer to next */ next_dhp = dhp->dh_next = nul_dev.dh_next; nul_dev.dh_next = dhp; if(init_device(dhp, pLine, mode, top)){ nul_dev.dh_next = next_dhp; /* return orig pointer if error */ } } else CfgFailure(pLine); } INIT static VOID CfgFailure(BYTE * pLine) { BYTE *pTmp = pLineStart; printf("CONFIG.SYS error in line %d\n", nCfgLine); printf(">>>%s\n ", pTmp); while (++pTmp != pLine) printf(" "); printf("^\n"); } #ifndef KDB INIT static BYTE FAR *KernelAlloc(WORD nBytes) { BYTE FAR *lpAllocated; lpBase = AlignParagraph(lpBase); lpAllocated = lpBase; if (0x10000 - FP_OFF(lpBase) <= nBytes) { UWORD newOffs = (FP_OFF(lpBase) + nBytes) & 0xFFFF; UWORD newSeg = FP_SEG(lpBase) + 0x1000; lpBase = MK_FP(newSeg, newOffs); } else lpBase += nBytes; return lpAllocated; } #endif #ifdef I86 INIT static BYTE FAR *KernelAllocDma(WORD bytes) { BYTE FAR *allocated; lpBase = AlignParagraph(lpBase); if ((FP_SEG(lpBase) & 0x0fff) + (bytes >> 4) > 0x1000) lpBase = MK_FP((FP_SEG(lpBase) + 0x0fff) & 0xf000, 0); allocated = lpBase; lpBase += bytes; return allocated; } INIT static VOID FAR *AlignParagraph(VOID FAR * lpPtr) { ULONG lTemp; UWORD uSegVal; /* First, convert the segmented pointer to linear address */ lTemp = FP_SEG(lpPtr); lTemp = (lTemp << 4) + FP_OFF(lpPtr); /* Next, round up the linear address to a paragraph boundary. */ lTemp += 0x0f; lTemp &= 0xfffffff0l; /* Break it into segments. */ uSegVal = (UWORD) (lTemp >> 4); /* and return an adddress adjusted to the nearest paragraph */ /* boundary. */ return MK_FP(uSegVal, 0); } #endif INIT BYTE * skipwh(BYTE * s) { while (*s && (*s == 0x0d || *s == 0x0a || *s == ' ' || *s == '\t')) ++s; return s; } INIT BYTE * scan(BYTE * s, BYTE * d) { s = skipwh(s); while (*s && !(*s == 0x0d || *s == 0x0a || *s == ' ' || *s == '\t' || *s == '=')) *d++ = *s++; *d = '\0'; return s; } INIT BYTE *scan_seperator(BYTE * s, BYTE * d) { s = skipwh(s); if (*s) *d++ = *s++; *d = '\0'; return s; } INIT BOOL isnum(BYTE * pLine) { return (*pLine >= '0' && *pLine <= '9'); } /* JPP - changed so will accept hex number. */ INIT BYTE *GetNumber(REG BYTE * pszString, REG COUNT * pnNum) { BYTE Base = 10; *pnNum = 0; while (isnum(pszString) || toupper(*pszString) == 'X') { if (toupper(*pszString) == 'X') { Base = 16; pszString++; } else *pnNum = *pnNum * Base + (*pszString++ - '0'); } return pszString; } /* Yet another change for true portability (WDL) */ INIT COUNT tolower(COUNT c) { if (c >= 'A' && c <= 'Z') return (c + ('a' - 'A')); else return c; } /* Yet another change for true portability (PJV) */ INIT COUNT toupper(COUNT c) { if (c >= 'a' && c <= 'z') return (c - ('a' - 'A')); else return c; } /* The following code is 8086 dependant */ #ifdef KERNEL INIT VOID mcb_init(mcb FAR * mcbp, UWORD size) { COUNT i; mcbp->m_type = MCB_LAST; mcbp->m_psp = FREE_PSP; /* if(UmbState == 1)*/ mcbp->m_size = (size - 1); /* mcbp->m_size = size; */ for (i = 0; i < 8; i++) mcbp->m_name[i] = '\0'; mem_access_mode = FIRST_FIT; } /* master umb sig */ INIT VOID umcb_init(mcb FAR * mcbp, UWORD size) { COUNT i; static char name[8] = "UMB "; mcbp->m_type = MCB_LAST; mcbp->m_psp = (UWORD) FP_SEG( mcbp ); mcbp->m_psp++; mcbp->m_size = size; for (i = 0; i < 8; i++) mcbp->m_name[i] = name[i]; } INIT VOID zumcb_init(mcb FAR * mcbp, UWORD size) { COUNT i; mcbp->m_type = MCB_LAST; mcbp->m_psp = FREE_PSP; mcbp->m_size = size; for (i = 0; i < 8; i++) mcbp->m_name[i] = '\0'; } INIT VOID mumcb_init(mcb FAR * mcbp, UWORD size) { COUNT i; static char name[8] = "SC\0\0\0\0\0\0"; mcbp->m_type = MCB_NORMAL; mcbp->m_psp = 8; mcbp->m_size = size; for (i = 0; i < 8; i++) mcbp->m_name[i] = name[i]; } #endif INIT VOID strcat(REG BYTE * d, REG BYTE * s) { while (*d != 0) ++d; strcpy(d, s); }