// Raw screen writing and debug output code. // // Copyright (C) 2008-2013 Kevin O'Connor // // This file may be distributed under the terms of the GNU LGPLv3 license. #include // va_list #include "farptr.h" // GET_VAR #include "bregs.h" // struct bregs #include "config.h" // CONFIG_* #include "biosvar.h" // GET_GLOBAL #include "hw/pci.h" // pci_bdf_to_bus #include "hw/pcidevice.h" // pci_device #include "hw/serialio.h" // serial_debug_putc #include "malloc.h" // malloc_tmp #include "output.h" // dprintf #include "stacks.h" // call16_int #include "string.h" // memset #include "util.h" // ScreenAndDebug struct putcinfo { void (*func)(struct putcinfo *info, char c); }; /**************************************************************** * Debug output ****************************************************************/ void debug_banner(void) { dprintf(1, "SeaBIOS (version %s)\n", VERSION); dprintf(1, "BUILD: %s\n", BUILDINFO); } // Write a character to debug port(s). static void debug_putc(struct putcinfo *action, char c) { if (! CONFIG_DEBUG_LEVEL) return; qemu_debug_putc(c); if (!MODESEGMENT) coreboot_debug_putc(c); serial_debug_putc(c); } // Flush any pending output to debug port(s). static void debug_flush(void) { serial_debug_flush(); } // In segmented mode just need a dummy variable (debug_putc is always // used anyway), and in 32bit flat mode need a pointer to the 32bit // instance of debug_putc(). #if MODE16 static struct putcinfo debuginfo VAR16; #elif MODESEGMENT static struct putcinfo debuginfo VAR32SEG; #else static struct putcinfo debuginfo = { debug_putc }; #endif /**************************************************************** * Screen writing ****************************************************************/ // Show a character on the screen. static void screenc(char c) { if (!MODESEGMENT && GET_IVT(0x10).segoff == FUNC16(entry_10).segoff) // No need to thunk to 16bit mode if vgabios is not present return; struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; br.ah = 0x0e; br.al = c; br.bl = 0x07; call16_int(0x10, &br); } // Handle a character from a printf request. static void screen_putc(struct putcinfo *action, char c) { if (ScreenAndDebug) debug_putc(&debuginfo, c); if (c == '\n') screenc('\r'); screenc(c); } static struct putcinfo screeninfo = { screen_putc }; /**************************************************************** * Xprintf code ****************************************************************/ // Output a character. static void putc(struct putcinfo *action, char c) { if (MODESEGMENT) { // Only debugging output supported in segmented mode. debug_putc(action, c); return; } void (*func)(struct putcinfo *info, char c) = GET_GLOBAL(action->func); func(action, c); } // Ouptut a string. static void puts(struct putcinfo *action, const char *s) { if (!MODESEGMENT && !s) s = "(NULL)"; for (; *s; s++) putc(action, *s); } // Output a string that is in the CS segment. static void puts_cs(struct putcinfo *action, const char *s) { char *vs = (char*)s; for (;; vs++) { char c = GET_GLOBAL(*vs); if (!c) break; putc(action, c); } } // Output an unsigned integer. static void putuint(struct putcinfo *action, u32 val) { char buf[12]; char *d = &buf[sizeof(buf) - 1]; *d-- = '\0'; for (;;) { *d = (val % 10) + '0'; val /= 10; if (!val) break; d--; } puts(action, d); } // Output a single digit hex character. static inline void putsinglehex(struct putcinfo *action, u32 val, int uc) { if (val <= 9) val = '0' + val; else if (uc) val = 'A' + val - 10; else val = 'a' + val - 10; putc(action, val); } // Output an integer in hexadecimal with a specified width. static void puthex(struct putcinfo *action, u32 val, int width, int uc) { switch (width) { default: putsinglehex(action, (val >> 28) & 0xf, uc); case 7: putsinglehex(action, (val >> 24) & 0xf, uc); case 6: putsinglehex(action, (val >> 20) & 0xf, uc); case 5: putsinglehex(action, (val >> 16) & 0xf, uc); case 4: putsinglehex(action, (val >> 12) & 0xf, uc); case 3: putsinglehex(action, (val >> 8) & 0xf, uc); case 2: putsinglehex(action, (val >> 4) & 0xf, uc); case 1: putsinglehex(action, (val >> 0) & 0xf, uc); } } // Output an integer in hexadecimal with a minimum width. static void putprettyhex(struct putcinfo *action, u32 val, int width, char padchar, int uc) { u32 tmp = val; int count = 1; while (tmp >>= 4) count++; width -= count; while (width-- > 0) putc(action, padchar); puthex(action, val, count, uc); } // Output 'struct pci_device' BDF as %02x:%02x.%x static void put_pci_device(struct putcinfo *action, struct pci_device *pci) { puthex(action, pci_bdf_to_bus(pci->bdf), 2, 0); putc(action, ':'); puthex(action, pci_bdf_to_dev(pci->bdf), 2, 0); putc(action, '.'); puthex(action, pci_bdf_to_fn(pci->bdf), 1, 0); } static inline int isdigit(u8 c) { return ((u8)(c - '0')) < 10; } static void bvprintf(struct putcinfo *action, const char *fmt, va_list args) { const char *s = fmt; int uc; for (;; s++) { char c = GET_GLOBAL(*(u8*)s); if (!c) break; if (c != '%') { putc(action, c); continue; } const char *n = s+1; int field_width = 0; char padchar = ' '; u8 is64 = 0; for (;;) { c = GET_GLOBAL(*(u8*)n); if (!isdigit(c)) break; if (!field_width && (c == '0')) padchar = '0'; else field_width = field_width * 10 + c - '0'; n++; } if (c == 'l') { // Ignore long format indicator n++; c = GET_GLOBAL(*(u8*)n); } if (c == 'l') { is64 = 1; n++; c = GET_GLOBAL(*(u8*)n); } s32 val; const char *sarg; switch (c) { case '%': putc(action, '%'); break; case 'd': val = va_arg(args, s32); if (is64) va_arg(args, s32); if (val < 0) { putc(action, '-'); val = -val; } putuint(action, val); break; case 'u': val = va_arg(args, s32); if (is64) va_arg(args, s32); putuint(action, val); break; case 'p': val = va_arg(args, s32); if (!MODESEGMENT && GET_GLOBAL(*(u8*)(n+1)) == 'P') { // %pP is 'struct pci_device' printer put_pci_device(action, (void*)val); n++; break; } putc(action, '0'); putc(action, 'x'); puthex(action, val, 8, 0); break; case 'X': case 'x': uc = (c == 'X'); val = va_arg(args, s32); if (is64) { u32 upper = va_arg(args, s32); if (upper) { putprettyhex(action, upper, field_width - 8, padchar, uc); puthex(action, val, 8, uc); break; } } putprettyhex(action, val, field_width, padchar, uc); break; case 'c': val = va_arg(args, int); putc(action, val); break; case '.': // Hack to support "%.s" - meaning string on stack. if (GET_GLOBAL(*(u8*)(n+1)) != 's') break; n++; sarg = va_arg(args, const char *); puts(action, sarg); break; case 's': sarg = va_arg(args, const char *); puts_cs(action, sarg); break; default: putc(action, '%'); n = s; } s = n; } } void panic(const char *fmt, ...) { if (CONFIG_DEBUG_LEVEL) { va_list args; va_start(args, fmt); bvprintf(&debuginfo, fmt, args); va_end(args); debug_flush(); } // XXX - use PANIC PORT. irq_disable(); for (;;) hlt(); } void __dprintf(const char *fmt, ...) { if (!MODESEGMENT && CONFIG_THREADS && CONFIG_DEBUG_LEVEL >= DEBUG_thread && *fmt != '\\' && *fmt != '/') { struct thread_info *cur = getCurThread(); if (cur != &MainThread) { // Show "thread id" for this debug message. debug_putc(&debuginfo, '|'); puthex(&debuginfo, (u32)cur, 8, 0); debug_putc(&debuginfo, '|'); debug_putc(&debuginfo, ' '); } } va_list args; va_start(args, fmt); bvprintf(&debuginfo, fmt, args); va_end(args); debug_flush(); } void printf(const char *fmt, ...) { ASSERT32FLAT(); va_list args; va_start(args, fmt); bvprintf(&screeninfo, fmt, args); va_end(args); if (ScreenAndDebug) debug_flush(); } /**************************************************************** * snprintf ****************************************************************/ struct snprintfinfo { struct putcinfo info; char *str, *end; }; static void putc_str(struct putcinfo *info, char c) { struct snprintfinfo *sinfo = container_of(info, struct snprintfinfo, info); if (sinfo->str >= sinfo->end) return; *sinfo->str = c; sinfo->str++; } // Build a formatted string. Note, this function returns the actual // number of bytes used (not including null) even in the overflow // case. int snprintf(char *str, size_t size, const char *fmt, ...) { ASSERT32FLAT(); if (!size) return 0; struct snprintfinfo sinfo = { { putc_str }, str, str + size }; va_list args; va_start(args, fmt); bvprintf(&sinfo.info, fmt, args); va_end(args); char *end = sinfo.str; if (end >= sinfo.end) end = sinfo.end - 1; *end = '\0'; return end - str; } // Build a formatted string - malloc'ing the memory. char * znprintf(size_t size, const char *fmt, ...) { ASSERT32FLAT(); if (!size) return NULL; char *str = malloc_tmp(size); if (!str) { warn_noalloc(); return NULL; } struct snprintfinfo sinfo = { { putc_str }, str, str + size }; va_list args; va_start(args, fmt); bvprintf(&sinfo.info, fmt, args); va_end(args); char *end = sinfo.str; if (end >= sinfo.end) end = sinfo.end - 1; *end = '\0'; return str; } /**************************************************************** * Misc helpers ****************************************************************/ void hexdump(const void *d, int len) { int count=0; while (len > 0) { if (count % 8 == 0) { putc(&debuginfo, '\n'); puthex(&debuginfo, count*4, 8, 0); putc(&debuginfo, ':'); } else { putc(&debuginfo, ' '); } puthex(&debuginfo, *(u32*)d, 8, 0); count++; len-=4; d+=4; } putc(&debuginfo, '\n'); debug_flush(); } static void dump_regs(struct bregs *regs) { if (!regs) { dprintf(1, " NULL\n"); return; } dprintf(1, " a=%08x b=%08x c=%08x d=%08x ds=%04x es=%04x ss=%04x\n" , regs->eax, regs->ebx, regs->ecx, regs->edx , regs->ds, regs->es, GET_SEG(SS)); dprintf(1, " si=%08x di=%08x bp=%08x sp=%08x cs=%04x ip=%04x f=%04x\n" , regs->esi, regs->edi, regs->ebp, (u32)®s[1] , regs->code.seg, regs->code.offset, regs->flags); } // Report entry to an Interrupt Service Routine (ISR). void __debug_isr(const char *fname) { puts_cs(&debuginfo, fname); putc(&debuginfo, '\n'); debug_flush(); } // Function called on handler startup. void __debug_enter(struct bregs *regs, const char *fname) { dprintf(1, "enter %s:\n", fname); dump_regs(regs); } // Send debugging output info. void __debug_stub(struct bregs *regs, int lineno, const char *fname) { dprintf(1, "stub %s:%d:\n", fname, lineno); dump_regs(regs); } // Report on an invalid parameter. void __warn_invalid(struct bregs *regs, int lineno, const char *fname) { if (CONFIG_DEBUG_LEVEL >= DEBUG_invalid) { dprintf(1, "invalid %s:%d:\n", fname, lineno); dump_regs(regs); } } // Report on an unimplemented feature. void __warn_unimplemented(struct bregs *regs, int lineno, const char *fname) { if (CONFIG_DEBUG_LEVEL >= DEBUG_unimplemented) { dprintf(1, "unimplemented %s:%d:\n", fname, lineno); dump_regs(regs); } } // Report a detected internal inconsistency. void __warn_internalerror(int lineno, const char *fname) { dprintf(1, "WARNING - internal error detected at %s:%d!\n" , fname, lineno); } // Report on an allocation failure. void __warn_noalloc(int lineno, const char *fname) { dprintf(1, "WARNING - Unable to allocate resource at %s:%d!\n" , fname, lineno); } // Report on a timeout exceeded. void __warn_timeout(int lineno, const char *fname) { dprintf(1, "WARNING - Timeout at %s:%d!\n", fname, lineno); } // Report a handler reporting an invalid parameter to the caller. void __set_invalid(struct bregs *regs, int lineno, const char *fname) { __warn_invalid(regs, lineno, fname); set_invalid_silent(regs); } // Report a call of an unimplemented function. void __set_unimplemented(struct bregs *regs, int lineno, const char *fname) { __warn_unimplemented(regs, lineno, fname); set_invalid_silent(regs); } // Report a handler reporting an invalid parameter code to the // caller. Note, the lineno and return code are encoded in the same // parameter as gcc does a better job of scheduling function calls // when there are 3 or less parameters. void __set_code_invalid(struct bregs *regs, u32 linecode, const char *fname) { u8 code = linecode; u32 lineno = linecode >> 8; __warn_invalid(regs, lineno, fname); set_code_invalid_silent(regs, code); } // Report a call of an unimplemented function. void __set_code_unimplemented(struct bregs *regs, u32 linecode, const char *fname) { u8 code = linecode; u32 lineno = linecode >> 8; __warn_unimplemented(regs, lineno, fname); set_code_invalid_silent(regs, code); }