/************************************************************************** MISC Support Routines **************************************************************************/ #include "etherboot.h" #ifdef CONSOLE_BTEXT #include #endif #ifdef CONSOLE_PC_KBD #include #endif /************************************************************************** IPCHKSUM - Checksum IP Header **************************************************************************/ uint16_t ipchksum(const void *data, unsigned long length) { unsigned long sum; unsigned long i; const uint8_t *ptr; /* In the most straight forward way possible, * compute an ip style checksum. */ sum = 0; ptr = data; for(i = 0; i < length; i++) { unsigned long value; value = ptr[i]; if (i & 1) { value <<= 8; } /* Add the new value */ sum += value; /* Wrap around the carry */ if (sum > 0xFFFF) { sum = (sum + (sum >> 16)) & 0xFFFF; } } return (~cpu_to_le16(sum)) & 0xFFFF; } uint16_t add_ipchksums(unsigned long offset, uint16_t sum, uint16_t new) { unsigned long checksum; sum = ~sum & 0xFFFF; new = ~new & 0xFFFF; if (offset & 1) { /* byte swap the sum if it came from an odd offset * since the computation is endian independant this * works. */ new = bswap_16(new); } checksum = sum + new; if (checksum > 0xFFFF) { checksum -= 0xFFFF; } return (~checksum) & 0xFFFF; } /************************************************************************** RANDOM - compute a random number between 0 and 2147483647L or 2147483562? **************************************************************************/ int32_t random(void) { static int32_t seed = 0; int32_t q; if (!seed) /* Initialize linear congruential generator */ seed = currticks() + *(int32_t *)&arptable[ARP_CLIENT].node + ((int16_t *)arptable[ARP_CLIENT].node)[2]; /* simplified version of the LCG given in Bruce Schneier's "Applied Cryptography" */ q = seed/53668; if ((seed = 40014*(seed-53668*q) - 12211*q) < 0) seed += 2147483563L; return seed; } /************************************************************************** POLL INTERRUPTIONS **************************************************************************/ void poll_interruptions(void) { int ch; if ( ! as_main_program ) return; /* If an interruption has occured restart etherboot */ if (iskey() && (ch = getchar(), (ch == K_ESC) || (ch == K_EOF) || (ch == K_INTR))) { int state = (ch != K_INTR)? -1 : -3; longjmp(restart_etherboot, state); } } /************************************************************************** SLEEP **************************************************************************/ void sleep(int secs) { unsigned long tmo; for (tmo = currticks()+secs*TICKS_PER_SEC; currticks() < tmo; ) { poll_interruptions(); } } /************************************************************************** INTERRUPTIBLE SLEEP **************************************************************************/ void interruptible_sleep(int secs) { printf("\n"); return sleep(secs); } /************************************************************************** TWIDDLE **************************************************************************/ void twiddle(void) { #ifdef BAR_PROGRESS static int count=0; static const char tiddles[]="-\\|/"; static unsigned long lastticks = 0; unsigned long ticks; #endif if ( ! as_main_program ) return; #ifdef BAR_PROGRESS /* Limit the maximum rate at which characters are printed */ ticks = currticks(); if ((lastticks + (TICKS_PER_SEC/18)) > ticks) return; lastticks = ticks; putchar(tiddles[(count++)&3]); putchar('\b'); #else putchar('.'); #endif /* BAR_PROGRESS */ } /************************************************************************** STRCASECMP (not entirely correct, but this will do for our purposes) **************************************************************************/ int strcasecmp(const char *a, const char *b) { while (*a && *b && (*a & ~0x20) == (*b & ~0x20)) {a++; b++; } return((*a & ~0x20) - (*b & ~0x20)); } /************************************************************************** INET_ATON - Convert an ascii x.x.x.x to binary form **************************************************************************/ int inet_aton(const char *start, in_addr *i) { const char *p = start; const char *digits_start; unsigned long ip = 0; unsigned long val; int j; for(j = 0; j <= 3; j++) { digits_start = p; val = strtoul(p, &p, 10); if ((p == digits_start) || (val > 255)) return 0; if ( ( j < 3 ) && ( *(p++) != '.' ) ) return 0; ip = (ip << 8) | val; } i->s_addr = htonl(ip); return p - start; } unsigned long strtoul(const char *p, const char **endp, int base) { unsigned long ret = 0; if (base != 10) return 0; while((*p >= '0') && (*p <= '9')) { ret = ret*10 + (*p - '0'); p++; } if (endp) *endp = p; return(ret); } #define K_RDWR 0x60 /* keyboard data & cmds (read/write) */ #define K_STATUS 0x64 /* keyboard status */ #define K_CMD 0x64 /* keybd ctlr command (write-only) */ #define K_OBUF_FUL 0x01 /* output buffer full */ #define K_IBUF_FUL 0x02 /* input buffer full */ #define KC_CMD_WIN 0xd0 /* read output port */ #define KC_CMD_WOUT 0xd1 /* write output port */ #define KB_SET_A20 0xdf /* enable A20, enable output buffer full interrupt enable data line disable clock line */ #define KB_UNSET_A20 0xdd /* enable A20, enable output buffer full interrupt enable data line disable clock line */ enum { Disable_A20 = 0x2400, Enable_A20 = 0x2401, Query_A20_Status = 0x2402, Query_A20_Support = 0x2403 }; #if defined(PCBIOS) && !defined(IBM_L40) static void empty_8042(void) { unsigned long time; char st; time = currticks() + TICKS_PER_SEC; /* max wait of 1 second */ while ((((st = inb(K_CMD)) & K_OBUF_FUL) || (st & K_IBUF_FUL)) && currticks() < time) inb(K_RDWR); } #endif /* IBM_L40 */ #if defined(PCBIOS) /* * Gate A20 for high memory */ void gateA20_set(void) { #warning "gateA20_set should test to see if it is already set" if (int15(Enable_A20) == 0) { return; } #ifdef IBM_L40 outb(0x2, 0x92); #else /* IBM_L40 */ empty_8042(); outb(KC_CMD_WOUT, K_CMD); empty_8042(); outb(KB_SET_A20, K_RDWR); empty_8042(); #endif /* IBM_L40 */ } #endif int last_putchar; // From filo void putchar(int c) { c &= 0xff; last_putchar = c; if (c == '\n') putchar('\r'); #ifdef CONSOLE_FIRMWARE console_putc(c); #endif #ifdef CONSOLE_DIRECT_VGA vga_putc(c); #endif #ifdef CONSOLE_BTEXT btext_putc(c); #endif #ifdef CONSOLE_SERIAL serial_putc(c); #endif } /************************************************************************** GETCHAR - Read the next character from input device WITHOUT ECHO **************************************************************************/ int getchar(void) { int c = 256; do { #if defined(PCBIOS) && defined(POWERSAVE) /* Doze for a while (until the next interrupt). This works * fine, because the keyboard is interrupt-driven, and the * timer interrupt (approx. every 50msec) takes care of the * serial port, which is read by polling. This reduces the * power dissipation of a modern CPU considerably, and also * makes Etherboot waiting for user interaction waste a lot * less CPU time in a VMware session. */ cpu_nap(); #endif /* POWERSAVE */ #ifdef CONSOLE_FIRMWARE if (console_ischar()) c = console_getc(); #endif #ifdef CONSOLE_SERIAL if (serial_ischar()) c = serial_getc(); #endif #ifdef CONSOLE_PC_KBD if (kbd_ischar()) c = kbd_getc(); #endif } while (c==256); if (c == '\r') c = '\n'; return c; } int iskey(void) { #ifdef CONSOLE_FIRMWARE if (console_ischar()) return 1; #endif #ifdef CONSOLE_SERIAL if (serial_ischar()) return 1; #endif #ifdef CONSOLE_PC_KBD if (kbd_ischar()) return 1; #endif return 0; } #if DEBUG_UTILS void pause ( void ) { printf ( "\nPress a key" ); getchar(); printf ( "\r \r" ); } void more ( void ) { printf ( "---more---" ); getchar(); printf ( "\r \r" ); } /* Produce a paged hex dump of the specified data and length */ void hex_dump ( const char *data, const unsigned int len ) { unsigned int index; for ( index = 0; index < len; index++ ) { if ( ( index % 16 ) == 0 ) { printf ( "\n" ); } if ( ( index % 368 ) == 352 ) { more(); } if ( ( index % 16 ) == 0 ) { printf ( "%X [%X] : %hX :", data + index, virt_to_phys ( data + index ), index ); } printf ( " %hhX", data[index] ); } printf ( "\n" ); } #define GUARD_SYMBOL ( ( 'M' << 24 ) | ( 'I' << 16 ) | ( 'N' << 8 ) | 'E' ) /* Fill a region with guard markers. We use a 4-byte pattern to make * it less likely that check_region will find spurious 1-byte regions * of non-corruption. */ void guard_region ( void *region, size_t len ) { uint32_t offset = 0; len &= ~0x03; for ( offset = 0; offset < len ; offset += 4 ) { *((uint32_t *)(region + offset)) = GUARD_SYMBOL; } } /* Check a region that has been guarded with guard_region() for * corruption. */ int check_region ( void *region, size_t len ) { uint8_t corrupted = 0; uint8_t in_corruption = 0; uint32_t offset = 0; uint32_t test = 0; len &= ~0x03; for ( offset = 0; offset < len ; offset += 4 ) { test = *((uint32_t *)(region + offset)) = GUARD_SYMBOL; if ( ( in_corruption == 0 ) && ( test != GUARD_SYMBOL ) ) { /* Start of corruption */ if ( corrupted == 0 ) { corrupted = 1; printf ( "Region %#x-%#x (physical %#x-%#x) " "corrupted\n", region, region + len, virt_to_phys ( region ), virt_to_phys ( region + len ) ); } in_corruption = 1; printf ( "--- offset %#x ", offset ); } else if ( ( in_corruption != 0 ) && ( test == GUARD_SYMBOL ) ) { /* End of corruption */ in_corruption = 0; printf ( "to offset %#x", offset ); } } if ( in_corruption != 0 ) { printf ( "to offset %#x (end of region)\n", len-1 ); } return corrupted; } #endif /* DEBUG_UTILS */ /* * Local variables: * c-basic-offset: 8 * End: */