// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package runtime import ( "runtime/internal/atomic" "runtime/internal/sys" "unsafe" ) // The compiler knows that a print of a value of this type // should use printhex instead of printuint (decimal). type hex uint64 func bytes(s string) (ret []byte) { rp := (*slice)(unsafe.Pointer(&ret)) sp := stringStructOf(&s) rp.array = sp.str rp.len = sp.len rp.cap = sp.len return } var ( // printBacklog is a circular buffer of messages written with the builtin // print* functions, for use in postmortem analysis of core dumps. printBacklog [512]byte printBacklogIndex int ) // recordForPanic maintains a circular buffer of messages written by the // runtime leading up to a process crash, allowing the messages to be // extracted from a core dump. // // The text written during a process crash (following "panic" or "fatal // error") is not saved, since the goroutine stacks will generally be readable // from the runtime datastructures in the core file. func recordForPanic(b []byte) { printlock() if atomic.Load(&panicking) == 0 { // Not actively crashing: maintain circular buffer of print output. for i := 0; i < len(b); { n := copy(printBacklog[printBacklogIndex:], b[i:]) i += n printBacklogIndex += n printBacklogIndex %= len(printBacklog) } } printunlock() } var debuglock mutex // The compiler emits calls to printlock and printunlock around // the multiple calls that implement a single Go print or println // statement. Some of the print helpers (printslice, for example) // call print recursively. There is also the problem of a crash // happening during the print routines and needing to acquire // the print lock to print information about the crash. // For both these reasons, let a thread acquire the printlock 'recursively'. func printlock() { mp := getg().m mp.locks++ // do not reschedule between printlock++ and lock(&debuglock). mp.printlock++ if mp.printlock == 1 { lock(&debuglock) } mp.locks-- // now we know debuglock is held and holding up mp.locks for us. } func printunlock() { mp := getg().m mp.printlock-- if mp.printlock == 0 { unlock(&debuglock) } } // write to goroutine-local buffer if diverting output, // or else standard error. func gwrite(b []byte) { if len(b) == 0 { return } recordForPanic(b) gp := getg() if gp == nil || gp.writebuf == nil { writeErr(b) return } n := copy(gp.writebuf[len(gp.writebuf):cap(gp.writebuf)], b) gp.writebuf = gp.writebuf[:len(gp.writebuf)+n] } func printsp() { printstring(" ") } func printnl() { printstring("\n") } func printbool(v bool) { if v { printstring("true") } else { printstring("false") } } func printfloat(v float64) { switch { case v != v: printstring("NaN") return case v+v == v && v > 0: printstring("+Inf") return case v+v == v && v < 0: printstring("-Inf") return } const n = 7 // digits printed var buf [n + 7]byte buf[0] = '+' e := 0 // exp if v == 0 { if 1/v < 0 { buf[0] = '-' } } else { if v < 0 { v = -v buf[0] = '-' } // normalize for v >= 10 { e++ v /= 10 } for v < 1 { e-- v *= 10 } // round h := 5.0 for i := 0; i < n; i++ { h /= 10 } v += h if v >= 10 { e++ v /= 10 } } // format +d.dddd+edd for i := 0; i < n; i++ { s := int(v) buf[i+2] = byte(s + '0') v -= float64(s) v *= 10 } buf[1] = buf[2] buf[2] = '.' buf[n+2] = 'e' buf[n+3] = '+' if e < 0 { e = -e buf[n+3] = '-' } buf[n+4] = byte(e/100) + '0' buf[n+5] = byte(e/10)%10 + '0' buf[n+6] = byte(e%10) + '0' gwrite(buf[:]) } func printcomplex(c complex128) { print("(", real(c), imag(c), "i)") } func printuint(v uint64) { var buf [100]byte i := len(buf) for i--; i > 0; i-- { buf[i] = byte(v%10 + '0') if v < 10 { break } v /= 10 } gwrite(buf[i:]) } func printint(v int64) { if v < 0 { printstring("-") v = -v } printuint(uint64(v)) } func printhex(v uint64) { const dig = "0123456789abcdef" var buf [100]byte i := len(buf) for i--; i > 0; i-- { buf[i] = dig[v%16] if v < 16 { break } v /= 16 } i-- buf[i] = 'x' i-- buf[i] = '0' gwrite(buf[i:]) } func printpointer(p unsafe.Pointer) { printhex(uint64(uintptr(p))) } func printstring(s string) { gwrite(bytes(s)) } func printslice(s []byte) { sp := (*slice)(unsafe.Pointer(&s)) print("[", len(s), "/", cap(s), "]") printpointer(sp.array) } func printeface(e eface) { print("(", e._type, ",", e.data, ")") } func printiface(i iface) { print("(", i.tab, ",", i.data, ")") } // hexdumpWords prints a word-oriented hex dump of [p, end). // // If mark != nil, it will be called with each printed word's address // and should return a character mark to appear just before that // word's value. It can return 0 to indicate no mark. func hexdumpWords(p, end uintptr, mark func(uintptr) byte) { p1 := func(x uintptr) { var buf [2 * sys.PtrSize]byte for i := len(buf) - 1; i >= 0; i-- { if x&0xF < 10 { buf[i] = byte(x&0xF) + '0' } else { buf[i] = byte(x&0xF) - 10 + 'a' } x >>= 4 } gwrite(buf[:]) } printlock() var markbuf [1]byte markbuf[0] = ' ' for i := uintptr(0); p+i < end; i += sys.PtrSize { if i%16 == 0 { if i != 0 { println() } p1(p + i) print(": ") } if mark != nil { markbuf[0] = mark(p + i) if markbuf[0] == 0 { markbuf[0] = ' ' } } gwrite(markbuf[:]) val := *(*uintptr)(unsafe.Pointer(p + i)) p1(val) print(" ") // Can we symbolize val? fn := findfunc(val) if fn.valid() { print("<", funcname(fn), "+", val-fn.entry, "> ") } } println() printunlock() }