/* $XFree86: xc/programs/Xserver/hw/xfree86/SuperProbe/Utils.c,v 3.5 1996/12/23 06:31:42 dawes Exp $ */ /* * (c) Copyright 1993,1994 by David Wexelblat * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * DAVID WEXELBLAT BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF * OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. * * Except as contained in this notice, the name of David Wexelblat shall not be * used in advertising or otherwise to promote the sale, use or other dealings * in this Software without prior written authorization from David Wexelblat. * */ /* $XConsortium: Utils.c /main/7 1996/02/21 17:13:00 kaleb $ */ #include "Probe.h" #include "AsmMacros.h" /* * Return the byte value of register 'port' */ #ifdef __STDC__ Byte inp(Word port) #else Byte inp(port) Word port; #endif { return(inb(port)); } /* * Return the word value of register 'port' */ #ifdef __STDC__ Word inpw(Word port) #else Word inpw(port) Word port; #endif { return(inw(port)); } /* * Return the long value of register 'port' */ #ifdef __STDC__ Long inpl(Word port) #else Long inpl(port) Word port; #endif { return(inl(port)); } /* * Set the byte register 'port' to 'val' */ #ifdef __STDC__ void outp(Word port, Byte val) #else void outp(port, val) Word port; Byte val; #endif { outb(port, val); } /* * Set the word register 'port' to 'val' */ #ifdef __STDC__ void outpw(Word port, Word val) #else void outpw(port, val) Word port, val; #endif { outw(port, val); } /* * Set the long register 'port' to 'val' */ #ifdef __STDC__ void outpl(Word port, Long val) #else void outpl(port, val) Word port; Long val; #endif { outl(port, val); } /* * Read byte register at 'port', index 'index' */ #ifdef __STDC__ Byte rdinx(Word port, Byte index) #else Byte rdinx(port, index) Word port; Byte index; #endif { Byte tmp; Word Port[2] = {MISC_OUT_R, 0x000}; if (port == ATR_IDX) { EnableIOPorts(1, Port); Port[1] = (inp(MISC_OUT_R) & 0x01) ? 0x3DA : 0x3BA; EnableIOPorts(2, Port); tmp = inp(Port[1]); /* Reset Attribute Reg flip-flop */ DisableIOPorts(2, Port); } outb(port, index); return(inb(port+1)); } /* * Set the byte register 'port', index 'index' to 'val' */ #ifdef __STDC__ void wrinx(Word port, Byte index, Byte val) #else void wrinx(port, index, val) Word port; Byte index; Byte val; #endif { Byte tmp; Word Port[2] = {MISC_OUT_R, 0x000}; if (port == ATR_REG_W) { EnableIOPorts(1, Port); Port[1] = (inp(MISC_OUT_R) & 0x01) ? 0x3DA : 0x3BA; EnableIOPorts(2, Port); tmp = inp(Port[1]); DisableIOPorts(2, Port); outp(port, index); outp(port, val); } else { outb(port, index); outb(port+1, val); } } /* * Set the word register 'port', index 'index' to 'val' */ #ifdef __STDC__ void wrinx2(Word port, Byte index, Word val) #else void wrinx2(port, index, val) Word port; Byte index; Word val; #endif { wrinx(port, index, (val) & 0xFF); wrinx(port, index+1, (val >> 8) & 0xFF); } /* * Set the longword register 'port', index 'index' to 'val' (3 bytes, actually) */ #ifdef __STDC__ void wrinx3(Word port, Byte index, Long val) #else void wrinx3(port, index, val) Word port; Byte index; Long val; #endif { wrinx(port, index, (val) & 0xFF); wrinx(port, index+1, (val >> 8) & 0xFF); wrinx(port, index+2, (val >> 16) & 0xFF); } /* * Set the word register 'port', index 'index' to 'val' (Motorola (big-endian) * byte order) */ #ifdef __STDC__ void wrinx2m(Word port, Byte index, Word val) #else void wrinx2m(port, index, val) Word port; Byte index; Word val; #endif { wrinx(port, index, (val >> 8) & 0xFF); wrinx(port, index+1, (val) & 0xFF); } /* * Set the longword register 'port', index 'index' to 'val' (3 bytes, actually) * (Motorola (big-endian) byte order) */ #ifdef __STDC__ void wrinx3m(Word port, Byte index, Long val) #else void wrinx3m(port, index, val) Word port; Byte index; Long val; #endif { wrinx(port, index, (val >> 16) & 0xFF); wrinx(port, index+1, (val >> 8) & 0xFF); wrinx(port, index+2, (val) & 0xFF); } /* * In byte register 'port', index 'index', set the bit that are 1 in 'mask' * to the value of the corresponding bits in 'mask' */ #ifdef __STDC__ void modinx(Word port, Byte index, Byte mask, Byte newval) #else void modinx(port, index, mask, newval) Word port; Byte index; Byte mask; Byte newval; #endif { Byte tmp; tmp = (rdinx(port, index) & ~mask) | (newval & mask); wrinx(port, index, tmp); } /* * In register 'port' sets the bits in 'mask' as in 'nvw'. Other bits are * left unchanged. */ #ifdef __STDC__ void modreg(Word port, Byte mask, Byte nvw) #else void modreg(port, mask, nvw) Word port; Byte mask; Byte nvw; #endif { Byte tmp; tmp = (inp(port) & (~mask)) | (nvw & mask); outp(port, tmp); } /* * Sets the bits in register 'port', index 'index' that are also set in 'val' */ #ifdef __STDC__ void setinx(Word port, Byte index, Byte val) #else void setinx(port, index, val) Word port; Byte index; Byte val; #endif { Byte tmp; tmp = rdinx(port, index); wrinx(port, index, tmp | val); } /* * Clears the bits in register 'port', index 'index' that are set in 'val' */ #ifdef __STDC__ void clrinx(Word port, Byte index, Byte val) #else void clrinx(port, index, val) Word port; Byte index; Byte val; #endif { Byte tmp; tmp = rdinx(port, index); wrinx(port, index, tmp & ~val); } /* * Return TRUE iff the bits in 'mask' of register 'port' are read/write. */ #ifdef __STDC__ Bool tstrg(Word port, Byte mask) #else Bool tstrg(port, mask) Word port; Byte mask; #endif { Byte old, new1, new2; old = inp(port); outp(port, (old & ~mask)); new1 = inp(port) & mask; outp(port, (old | mask)); new2 = inp(port) & mask; outp(port, old); return((new1==0) && (new2==mask)); } /* * Returns true iff the bits in 'mask' of register 'port', index 'index' * are read/write. */ #ifdef __STDC__ Bool testinx2(Word port, Byte index, Byte mask) #else Bool testinx2(port, index, mask) Word port; Byte index; Byte mask; #endif { Byte old, new1, new2; old = rdinx(port, index); wrinx(port, index, (old & ~mask)); new1 = rdinx(port, index) & mask; wrinx(port, index, (old | mask)); new2 = rdinx(port, index) & mask; wrinx(port, index, old); return((new1==0) && (new2==mask)); } /* * Returns true iff all bits of register 'port', index 'index' are read/write */ #ifdef __STDC__ Bool testinx(Word port, Byte index) #else Bool testinx(port, index) Word port; Byte index; #endif { return(testinx2(port, index, 0xFF)); } /* * Force DAC back to PEL mode */ void dactopel() { (void)inp(0x3C8); } /* * Trigger HiColor DACs to change mode. */ Byte trigdac() { (void)inp(0x3C6); (void)inp(0x3C6); (void)inp(0x3C6); return(inp(0x3C6)); } /* * Enter command mode of HiColor DACs. */ Byte dactocomm() { dactopel(); return(trigdac()); } /* * Get the HiColor DAC command register and return to PEL mode. */ Byte getdaccomm() { Byte ret; dactocomm(); ret = inp(0x3C6); dactopel(); return(ret); } /* * Wait for vertical retrace interval. */ void waitforretrace() { Word Port[2] = {MISC_OUT_R, 0x000}; EnableIOPorts(1, Port); Port[1] = (inp(MISC_OUT_R) & 0x01) ? 0x3DA : 0x3BA; EnableIOPorts(2, Port); while ((inp(Port[1]) & 0x08) != 0) { /* Idle */ } while ((inp(Port[1]) & 0x08) == 0) { /* Idle */ } DisableIOPorts(2, Port); return; } /* * Check chip descriptor against exclusion list */ Bool Excluded(ExList, Chip, Mask10) Range *ExList; Chip_Descriptor *Chip; Bool Mask10; { int i, j; Word mask = (Mask10 ? 0x3FF : 0xFFFF); if (Chip->num_ports == 0) { return(FALSE); } if (Chip->ports[0] == 0) { /* Fill in CRTC */ Chip->ports[0] = CRTC_IDX; Chip->ports[1] = CRTC_REG; } for (i=0; i < Chip->num_ports; i++) { for (j=0; ExList[j].lo != (Word)-1; j++) { if (ExList[j].hi == (Word)-1) { /* single port */ if ((Chip->ports[i] & mask) == ExList[j].lo) { return(TRUE); } } else { /* range */ if (((Chip->ports[i]&mask) >= ExList[j].lo) && ((Chip->ports[i]&mask) <= ExList[j].hi)) { return(TRUE); } } } } return(FALSE); } int StrCaseCmp(s1, s2) char *s1; char *s2; { char c1, c2; if (*s1 == 0) if (*s2 == 0) return(0); else return(1); c1 = (isupper(*s1) ? tolower(*s1) : *s1); c2 = (isupper(*s2) ? tolower(*s2) : *s2); while (c1 == c2) { if (c1 == '\0') return(0); s1++; s2++; c1 = (isupper(*s1) ? tolower(*s1) : *s1); c2 = (isupper(*s2) ? tolower(*s2) : *s2); } return(c1 - c2); } unsigned int StrToUL(str) CONST char *str; { int base = 10; CONST char *p = str; unsigned int tot = 0; if (*p == '0') { p++; if (*p == 'x') { p++; base = 16; } else { base = 8; } } while (*p) { if ((*p >= '0') && (*p <= ((base == 8)?'7':'9'))) { tot = tot * base + (*p - '0'); } else if ((base == 16) && (*p >= 'a') && (*p <= 'f')) { tot = tot * base + 10 + (*p - 'a'); } else if ((base == 16) && (*p >= 'A') && (*p <= 'F')) { tot = tot * base + 10 + (*p - 'A'); } else { return(tot); } p++; } return(tot); }