Mercurial > hg > openjdk > jdk8u > hotspot
view src/share/vm/utilities/ostream.cpp @ 9474:782f3b88b5ba default tip
8267545: [8u] Enable Xcode 12 builds on macOS
Summary: Makefile and source code patches to enable Xcode 12 builds
Reviewed-by: simonis, andrew
Contributed-by: benty@amazon.com, hohensee@amazon.com
| author | phh |
|---|---|
| date | Wed, 09 Jun 2021 21:45:47 +0000 |
| parents | 3a3803a0c789 |
| children |
line wrap: on
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/* * Copyright (c) 1997, 2018, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code 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 * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #include "precompiled.hpp" #include "compiler/compileLog.hpp" #include "gc_implementation/shared/gcId.hpp" #include "oops/oop.inline.hpp" #include "runtime/arguments.hpp" #include "runtime/mutexLocker.hpp" #include "runtime/os.hpp" #include "runtime/vmThread.hpp" #include "utilities/defaultStream.hpp" #include "utilities/ostream.hpp" #include "utilities/top.hpp" #include "utilities/xmlstream.hpp" #ifdef TARGET_OS_FAMILY_linux # include "os_linux.inline.hpp" #endif #ifdef TARGET_OS_FAMILY_solaris # include "os_solaris.inline.hpp" #endif #ifdef TARGET_OS_FAMILY_windows # include "os_windows.inline.hpp" #endif #ifdef TARGET_OS_FAMILY_aix # include "os_aix.inline.hpp" #endif #ifdef TARGET_OS_FAMILY_bsd # include "os_bsd.inline.hpp" #endif extern "C" void jio_print(const char* s); // Declarationtion of jvm method outputStream::outputStream(int width) { _width = width; _position = 0; _newlines = 0; _precount = 0; _indentation = 0; } outputStream::outputStream(int width, bool has_time_stamps) { _width = width; _position = 0; _newlines = 0; _precount = 0; _indentation = 0; if (has_time_stamps) _stamp.update(); } void outputStream::update_position(const char* s, size_t len) { for (size_t i = 0; i < len; i++) { char ch = s[i]; if (ch == '\n') { _newlines += 1; _precount += _position + 1; _position = 0; } else if (ch == '\t') { int tw = 8 - (_position & 7); _position += tw; _precount -= tw-1; // invariant: _precount + _position == total count } else { _position += 1; } } } // Execute a vsprintf, using the given buffer if necessary. // Return a pointer to the formatted string. const char* outputStream::do_vsnprintf(char* buffer, size_t buflen, const char* format, va_list ap, bool add_cr, size_t& result_len) { assert(buflen >= 2, "buffer too small"); const char* result; if (add_cr) buflen--; if (!strchr(format, '%')) { // constant format string result = format; result_len = strlen(result); if (add_cr && result_len >= buflen) result_len = buflen-1; // truncate } else if (format[0] == '%' && format[1] == 's' && format[2] == '\0') { // trivial copy-through format string result = va_arg(ap, const char*); result_len = strlen(result); if (add_cr && result_len >= buflen) result_len = buflen-1; // truncate } else { int written = os::vsnprintf(buffer, buflen, format, ap); assert(written >= 0, "vsnprintf encoding error"); result = buffer; if ((size_t)written < buflen) { result_len = written; } else { DEBUG_ONLY(warning("increase O_BUFLEN in ostream.hpp -- output truncated");) result_len = buflen - 1; } } if (add_cr) { if (result != buffer) { memcpy(buffer, result, result_len); result = buffer; } buffer[result_len++] = '\n'; buffer[result_len] = 0; } return result; } void outputStream::print(const char* format, ...) { char buffer[O_BUFLEN]; va_list ap; va_start(ap, format); size_t len; const char* str = do_vsnprintf(buffer, O_BUFLEN, format, ap, false, len); write(str, len); va_end(ap); } void outputStream::print_cr(const char* format, ...) { char buffer[O_BUFLEN]; va_list ap; va_start(ap, format); size_t len; const char* str = do_vsnprintf(buffer, O_BUFLEN, format, ap, true, len); write(str, len); va_end(ap); } void outputStream::vprint(const char *format, va_list argptr) { char buffer[O_BUFLEN]; size_t len; const char* str = do_vsnprintf(buffer, O_BUFLEN, format, argptr, false, len); write(str, len); } void outputStream::vprint_cr(const char* format, va_list argptr) { char buffer[O_BUFLEN]; size_t len; const char* str = do_vsnprintf(buffer, O_BUFLEN, format, argptr, true, len); write(str, len); } void outputStream::fill_to(int col) { int need_fill = col - position(); sp(need_fill); } void outputStream::move_to(int col, int slop, int min_space) { if (position() >= col + slop) cr(); int need_fill = col - position(); if (need_fill < min_space) need_fill = min_space; sp(need_fill); } void outputStream::put(char ch) { assert(ch != 0, "please fix call site"); char buf[] = { ch, '\0' }; write(buf, 1); } #define SP_USE_TABS false void outputStream::sp(int count) { if (count < 0) return; if (SP_USE_TABS && count >= 8) { int target = position() + count; while (count >= 8) { this->write("\t", 1); count -= 8; } count = target - position(); } while (count > 0) { int nw = (count > 8) ? 8 : count; this->write(" ", nw); count -= nw; } } void outputStream::cr() { this->write("\n", 1); } void outputStream::stamp() { if (! _stamp.is_updated()) { _stamp.update(); // start at 0 on first call to stamp() } // outputStream::stamp() may get called by ostream_abort(), use snprintf // to avoid allocating large stack buffer in print(). char buf[40]; jio_snprintf(buf, sizeof(buf), "%.3f", _stamp.seconds()); print_raw(buf); } void outputStream::stamp(bool guard, const char* prefix, const char* suffix) { if (!guard) { return; } print_raw(prefix); stamp(); print_raw(suffix); } void outputStream::date_stamp(bool guard, const char* prefix, const char* suffix) { if (!guard) { return; } print_raw(prefix); static const char error_time[] = "yyyy-mm-ddThh:mm:ss.mmm+zzzz"; static const int buffer_length = 32; char buffer[buffer_length]; const char* iso8601_result = os::iso8601_time(buffer, buffer_length); if (iso8601_result != NULL) { print_raw(buffer); } else { print_raw(error_time); } print_raw(suffix); return; } void outputStream::gclog_stamp(const GCId& gc_id) { date_stamp(PrintGCDateStamps); stamp(PrintGCTimeStamps); if (PrintGCID) { print("#%u: ", gc_id.id()); } } outputStream& outputStream::indent() { while (_position < _indentation) sp(); return *this; } void outputStream::print_jlong(jlong value) { print(JLONG_FORMAT, value); } void outputStream::print_julong(julong value) { print(JULONG_FORMAT, value); } /** * This prints out hex data in a 'windbg' or 'xxd' form, where each line is: * <hex-address>: 8 * <hex-halfword> <ascii translation (optional)> * example: * 0000000: 7f44 4f46 0102 0102 0000 0000 0000 0000 .DOF............ * 0000010: 0000 0000 0000 0040 0000 0020 0000 0005 .......@... .... * 0000020: 0000 0000 0000 0040 0000 0000 0000 015d .......@.......] * ... * * indent is applied to each line. Ends with a CR. */ void outputStream::print_data(void* data, size_t len, bool with_ascii) { size_t limit = (len + 16) / 16 * 16; for (size_t i = 0; i < limit; ++i) { if (i % 16 == 0) { indent().print(SIZE_FORMAT_HEX_W(07) ":", i); } if (i % 2 == 0) { print(" "); } if (i < len) { print("%02x", ((unsigned char*)data)[i]); } else { print(" "); } if ((i + 1) % 16 == 0) { if (with_ascii) { print(" "); for (size_t j = 0; j < 16; ++j) { size_t idx = i + j - 15; if (idx < len) { char c = ((char*)data)[idx]; print("%c", c >= 32 && c <= 126 ? c : '.'); } } } cr(); } } } stringStream::stringStream(size_t initial_size) : outputStream() { buffer_length = initial_size; buffer = NEW_RESOURCE_ARRAY(char, buffer_length); buffer_pos = 0; buffer_fixed = false; DEBUG_ONLY(rm = Thread::current()->current_resource_mark();) } // useful for output to fixed chunks of memory, such as performance counters stringStream::stringStream(char* fixed_buffer, size_t fixed_buffer_size) : outputStream() { buffer_length = fixed_buffer_size; buffer = fixed_buffer; buffer_pos = 0; buffer_fixed = true; } void stringStream::write(const char* s, size_t len) { size_t write_len = len; // number of non-null bytes to write size_t end = buffer_pos + len + 1; // position after write and final '\0' if (end > buffer_length) { if (buffer_fixed) { // if buffer cannot resize, silently truncate end = buffer_length; write_len = end - buffer_pos - 1; // leave room for the final '\0' } else { // For small overruns, double the buffer. For larger ones, // increase to the requested size. if (end < buffer_length * 2) { end = buffer_length * 2; } char* oldbuf = buffer; assert(rm == NULL || Thread::current()->current_resource_mark() == rm, "stringStream is re-allocated with a different ResourceMark"); buffer = NEW_RESOURCE_ARRAY(char, end); if (buffer_pos > 0) { memcpy(buffer, oldbuf, buffer_pos); } buffer_length = end; } } // invariant: buffer is always null-terminated guarantee(buffer_pos + write_len + 1 <= buffer_length, "stringStream oob"); if (write_len > 0) { buffer[buffer_pos + write_len] = 0; memcpy(buffer + buffer_pos, s, write_len); buffer_pos += write_len; } // Note that the following does not depend on write_len. // This means that position and count get updated // even when overflow occurs. update_position(s, len); } char* stringStream::as_string() { char* copy = NEW_RESOURCE_ARRAY(char, buffer_pos + 1); strncpy(copy, buffer, buffer_pos); copy[buffer_pos] = 0; // terminating null return copy; } stringStream::~stringStream() {} xmlStream* xtty; outputStream* tty; outputStream* gclog_or_tty; CDS_ONLY(fileStream* classlist_file;) // Only dump the classes that can be stored into the CDS archive extern Mutex* tty_lock; #define EXTRACHARLEN 32 #define CURRENTAPPX ".current" // convert YYYY-MM-DD HH:MM:SS to YYYY-MM-DD_HH-MM-SS char* get_datetime_string(char *buf, size_t len) { os::local_time_string(buf, len); int i = (int)strlen(buf); while (i-- >= 0) { if (buf[i] == ' ') buf[i] = '_'; else if (buf[i] == ':') buf[i] = '-'; } return buf; } static const char* make_log_name_internal(const char* log_name, const char* force_directory, int pid, const char* tms) { const char* basename = log_name; char file_sep = os::file_separator()[0]; const char* cp; char pid_text[32]; for (cp = log_name; *cp != '\0'; cp++) { if (*cp == '/' || *cp == file_sep) { basename = cp + 1; } } const char* nametail = log_name; // Compute buffer length size_t buffer_length; if (force_directory != NULL) { buffer_length = strlen(force_directory) + strlen(os::file_separator()) + strlen(basename) + 1; } else { buffer_length = strlen(log_name) + 1; } const char* pts = strstr(basename, "%p"); int pid_pos = (pts == NULL) ? -1 : (pts - nametail); if (pid_pos >= 0) { jio_snprintf(pid_text, sizeof(pid_text), "pid%u", pid); buffer_length += strlen(pid_text); } pts = strstr(basename, "%t"); int tms_pos = (pts == NULL) ? -1 : (pts - nametail); if (tms_pos >= 0) { buffer_length += strlen(tms); } // File name is too long. if (buffer_length > JVM_MAXPATHLEN) { return NULL; } // Create big enough buffer. char *buf = NEW_C_HEAP_ARRAY(char, buffer_length, mtInternal); strcpy(buf, ""); if (force_directory != NULL) { strcat(buf, force_directory); strcat(buf, os::file_separator()); nametail = basename; // completely skip directory prefix } // who is first, %p or %t? int first = -1, second = -1; const char *p1st = NULL; const char *p2nd = NULL; if (pid_pos >= 0 && tms_pos >= 0) { // contains both %p and %t if (pid_pos < tms_pos) { // case foo%pbar%tmonkey.log first = pid_pos; p1st = pid_text; second = tms_pos; p2nd = tms; } else { // case foo%tbar%pmonkey.log first = tms_pos; p1st = tms; second = pid_pos; p2nd = pid_text; } } else if (pid_pos >= 0) { // contains %p only first = pid_pos; p1st = pid_text; } else if (tms_pos >= 0) { // contains %t only first = tms_pos; p1st = tms; } int buf_pos = (int)strlen(buf); const char* tail = nametail; if (first >= 0) { tail = nametail + first + 2; strncpy(&buf[buf_pos], nametail, first); strcpy(&buf[buf_pos + first], p1st); buf_pos = (int)strlen(buf); if (second >= 0) { strncpy(&buf[buf_pos], tail, second - first - 2); strcpy(&buf[buf_pos + second - first - 2], p2nd); tail = nametail + second + 2; } } strcat(buf, tail); // append rest of name, or all of name return buf; } // log_name comes from -XX:LogFile=log_name, -Xloggc:log_name or // -XX:DumpLoadedClassList=<file_name> // in log_name, %p => pid1234 and // %t => YYYY-MM-DD_HH-MM-SS static const char* make_log_name(const char* log_name, const char* force_directory) { char timestr[32]; get_datetime_string(timestr, sizeof(timestr)); return make_log_name_internal(log_name, force_directory, os::current_process_id(), timestr); } #ifndef PRODUCT void test_loggc_filename() { int pid; char tms[32]; char i_result[JVM_MAXPATHLEN]; const char* o_result; get_datetime_string(tms, sizeof(tms)); pid = os::current_process_id(); // test.log jio_snprintf(i_result, JVM_MAXPATHLEN, "test.log", tms); o_result = make_log_name_internal("test.log", NULL, pid, tms); assert(strcmp(i_result, o_result) == 0, "failed on testing make_log_name(\"test.log\", NULL)"); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); // test-%t-%p.log jio_snprintf(i_result, JVM_MAXPATHLEN, "test-%s-pid%u.log", tms, pid); o_result = make_log_name_internal("test-%t-%p.log", NULL, pid, tms); assert(strcmp(i_result, o_result) == 0, "failed on testing make_log_name(\"test-%%t-%%p.log\", NULL)"); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); // test-%t%p.log jio_snprintf(i_result, JVM_MAXPATHLEN, "test-%spid%u.log", tms, pid); o_result = make_log_name_internal("test-%t%p.log", NULL, pid, tms); assert(strcmp(i_result, o_result) == 0, "failed on testing make_log_name(\"test-%%t%%p.log\", NULL)"); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); // %p%t.log jio_snprintf(i_result, JVM_MAXPATHLEN, "pid%u%s.log", pid, tms); o_result = make_log_name_internal("%p%t.log", NULL, pid, tms); assert(strcmp(i_result, o_result) == 0, "failed on testing make_log_name(\"%%p%%t.log\", NULL)"); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); // %p-test.log jio_snprintf(i_result, JVM_MAXPATHLEN, "pid%u-test.log", pid); o_result = make_log_name_internal("%p-test.log", NULL, pid, tms); assert(strcmp(i_result, o_result) == 0, "failed on testing make_log_name(\"%%p-test.log\", NULL)"); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); // %t.log jio_snprintf(i_result, JVM_MAXPATHLEN, "%s.log", tms); o_result = make_log_name_internal("%t.log", NULL, pid, tms); assert(strcmp(i_result, o_result) == 0, "failed on testing make_log_name(\"%%t.log\", NULL)"); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); { // longest filename char longest_name[JVM_MAXPATHLEN]; memset(longest_name, 'a', sizeof(longest_name)); longest_name[JVM_MAXPATHLEN - 1] = '\0'; o_result = make_log_name_internal((const char*)&longest_name, NULL, pid, tms); assert(strcmp(longest_name, o_result) == 0, err_msg("longest name does not match. expected '%s' but got '%s'", longest_name, o_result)); FREE_C_HEAP_ARRAY(char, o_result, mtInternal); } { // too long file name char too_long_name[JVM_MAXPATHLEN + 100]; int too_long_length = sizeof(too_long_name); memset(too_long_name, 'a', too_long_length); too_long_name[too_long_length - 1] = '\0'; o_result = make_log_name_internal((const char*)&too_long_name, NULL, pid, tms); assert(o_result == NULL, err_msg("Too long file name should return NULL, but got '%s'", o_result)); } { // too long with timestamp char longest_name[JVM_MAXPATHLEN]; memset(longest_name, 'a', JVM_MAXPATHLEN); longest_name[JVM_MAXPATHLEN - 3] = '%'; longest_name[JVM_MAXPATHLEN - 2] = 't'; longest_name[JVM_MAXPATHLEN - 1] = '\0'; o_result = make_log_name_internal((const char*)&longest_name, NULL, pid, tms); assert(o_result == NULL, err_msg("Too long file name after timestamp expansion should return NULL, but got '%s'", o_result)); } { // too long with pid char longest_name[JVM_MAXPATHLEN]; memset(longest_name, 'a', JVM_MAXPATHLEN); longest_name[JVM_MAXPATHLEN - 3] = '%'; longest_name[JVM_MAXPATHLEN - 2] = 'p'; longest_name[JVM_MAXPATHLEN - 1] = '\0'; o_result = make_log_name_internal((const char*)&longest_name, NULL, pid, tms); assert(o_result == NULL, err_msg("Too long file name after pid expansion should return NULL, but got '%s'", o_result)); } } ////////////////////////////////////////////////////////////////////////////// // Test os::vsnprintf and friends. void check_snprintf_result(int expected, size_t limit, int actual, bool expect_count) { if (expect_count || ((size_t)expected < limit)) { assert(expected == actual, "snprintf result not expected value"); } else { // Make this check more permissive for jdk8u, don't assert that actual == 0. // e.g. jio_vsnprintf_wrapper and jio_snprintf return -1 when expected >= limit if (expected >= (int) limit) { assert(actual == -1, "snprintf result should be -1 for expected >= limit"); } else { assert(actual > 0, "snprintf result should be >0 for expected < limit"); } } } // PrintFn is expected to be int (*)(char*, size_t, const char*, ...). // But jio_snprintf is a C-linkage function with that signature, which // has a different type on some platforms (like Solaris). template<typename PrintFn> void test_snprintf(PrintFn pf, bool expect_count) { const char expected[] = "abcdefghijklmnopqrstuvwxyz"; const int expected_len = sizeof(expected) - 1; const size_t padding_size = 10; char buffer[2 * (sizeof(expected) + padding_size)]; char check_buffer[sizeof(buffer)]; const char check_char = '1'; // Something not in expected. memset(check_buffer, check_char, sizeof(check_buffer)); const size_t sizes_to_test[] = { sizeof(buffer) - padding_size, // Fits, with plenty of space to spare. sizeof(buffer)/2, // Fits, with space to spare. sizeof(buffer)/4, // Doesn't fit. sizeof(expected) + padding_size + 1, // Fits, with a little room to spare sizeof(expected) + padding_size, // Fits exactly. sizeof(expected) + padding_size - 1, // Doesn't quite fit. 2, // One char + terminating NUL. 1, // Only space for terminating NUL. 0 }; // No space at all. for (unsigned i = 0; i < ARRAY_SIZE(sizes_to_test); ++i) { memset(buffer, check_char, sizeof(buffer)); // To catch stray writes. size_t test_size = sizes_to_test[i]; ResourceMark rm; stringStream s; s.print("test_size: " SIZE_FORMAT, test_size); size_t prefix_size = padding_size; guarantee(test_size <= (sizeof(buffer) - prefix_size), "invariant"); size_t write_size = MIN2(sizeof(expected), test_size); size_t suffix_size = sizeof(buffer) - prefix_size - write_size; char* write_start = buffer + prefix_size; char* write_end = write_start + write_size; int result = pf(write_start, test_size, "%s", expected); check_snprintf_result(expected_len, test_size, result, expect_count); // Verify expected output. if (test_size > 0) { assert(0 == strncmp(write_start, expected, write_size - 1), "strncmp failure"); // Verify terminating NUL of output. assert('\0' == write_start[write_size - 1], "null terminator failure"); } else { guarantee(test_size == 0, "invariant"); guarantee(write_size == 0, "invariant"); guarantee(prefix_size + suffix_size == sizeof(buffer), "invariant"); guarantee(write_start == write_end, "invariant"); } // Verify no scribbling on prefix or suffix. assert(0 == strncmp(buffer, check_buffer, prefix_size), "prefix scribble"); assert(0 == strncmp(write_end, check_buffer, suffix_size), "suffix scribble"); } // Special case of 0-length buffer with empty (except for terminator) output. check_snprintf_result(0, 0, pf(NULL, 0, "%s", ""), expect_count); check_snprintf_result(0, 0, pf(NULL, 0, ""), expect_count); } // This is probably equivalent to os::snprintf, but we're being // explicit about what we're testing here. static int vsnprintf_wrapper(char* buf, size_t len, const char* fmt, ...) { va_list args; va_start(args, fmt); PRAGMA_DIAG_PUSH PRAGMA_FORMAT_NONLITERAL_IGNORED_INTERNAL int result = os::vsnprintf(buf, len, fmt, args); PRAGMA_DIAG_POP va_end(args); return result; } // These are declared in jvm.h; test here, with related functions. extern "C" { int jio_vsnprintf(char*, size_t, const char*, va_list); int jio_snprintf(char*, size_t, const char*, ...); } // This is probably equivalent to jio_snprintf, but we're being // explicit about what we're testing here. static int jio_vsnprintf_wrapper(char* buf, size_t len, const char* fmt, ...) { va_list args; va_start(args, fmt); int result = jio_vsnprintf(buf, len, fmt, args); va_end(args); return result; } void test_snprintf() { test_snprintf(vsnprintf_wrapper, true); test_snprintf(os::snprintf, true); test_snprintf(jio_vsnprintf_wrapper, false); // jio_vsnprintf returns -1 on error including exceeding buffer size test_snprintf(jio_snprintf, false); // jio_snprintf calls jio_vsnprintf } #endif // PRODUCT fileStream::fileStream(const char* file_name) { _file = fopen(file_name, "w"); if (_file != NULL) { _need_close = true; } else { warning("Cannot open file %s due to %s\n", file_name, strerror(errno)); _need_close = false; } } fileStream::fileStream(const char* file_name, const char* opentype) { _file = fopen(file_name, opentype); if (_file != NULL) { _need_close = true; } else { warning("Cannot open file %s due to %s\n", file_name, strerror(errno)); _need_close = false; } } void fileStream::write(const char* s, size_t len) { if (_file != NULL) { // Make an unused local variable to avoid warning from gcc 4.x compiler. size_t count = fwrite(s, 1, len, _file); } update_position(s, len); } long fileStream::fileSize() { long size = -1; if (_file != NULL) { long pos = ::ftell(_file); if (::fseek(_file, 0, SEEK_END) == 0) { size = ::ftell(_file); } ::fseek(_file, pos, SEEK_SET); } return size; } char* fileStream::readln(char *data, int count ) { char * ret = ::fgets(data, count, _file); //Get rid of annoying \n char data[::strlen(data)-1] = '\0'; return ret; } fileStream::~fileStream() { if (_file != NULL) { if (_need_close) fclose(_file); _file = NULL; } } void fileStream::flush() { fflush(_file); } fdStream::fdStream(const char* file_name) { _fd = open(file_name, O_WRONLY | O_CREAT | O_TRUNC, 0666); _need_close = true; } fdStream::~fdStream() { if (_fd != -1) { if (_need_close) close(_fd); _fd = -1; } } void fdStream::write(const char* s, size_t len) { if (_fd != -1) { // Make an unused local variable to avoid warning from gcc 4.x compiler. size_t count = ::write(_fd, s, (int)len); } update_position(s, len); } // dump vm version, os version, platform info, build id, // memory usage and command line flags into header void gcLogFileStream::dump_loggc_header() { if (is_open()) { print_cr("%s", Abstract_VM_Version::internal_vm_info_string()); os::print_memory_info(this); print("CommandLine flags: "); CommandLineFlags::printSetFlags(this); } } gcLogFileStream::~gcLogFileStream() { if (_file != NULL) { if (_need_close) fclose(_file); _file = NULL; } if (_file_name != NULL) { FREE_C_HEAP_ARRAY(char, _file_name, mtInternal); _file_name = NULL; } delete _file_lock; } gcLogFileStream::gcLogFileStream(const char* file_name) : _file_lock(NULL) { _cur_file_num = 0; _bytes_written = 0L; _file_name = make_log_name(file_name, NULL); if (_file_name == NULL) { warning("Cannot open file %s: file name is too long.\n", file_name); _need_close = false; UseGCLogFileRotation = false; return; } // gc log file rotation if (UseGCLogFileRotation && NumberOfGCLogFiles > 1) { char tempbuf[JVM_MAXPATHLEN]; jio_snprintf(tempbuf, sizeof(tempbuf), "%s.%d" CURRENTAPPX, _file_name, _cur_file_num); _file = fopen(tempbuf, "w"); } else { _file = fopen(_file_name, "w"); } if (_file != NULL) { _need_close = true; dump_loggc_header(); if (UseGCLogFileRotation) { _file_lock = new Mutex(Mutex::leaf, "GCLogFile"); } } else { warning("Cannot open file %s due to %s\n", _file_name, strerror(errno)); _need_close = false; } } void gcLogFileStream::write(const char* s, size_t len) { if (_file != NULL) { // we can't use Thread::current() here because thread may be NULL // in early stage(ostream_init_log) Thread* thread = ThreadLocalStorage::thread(); // avoid the mutex in the following cases // 1) ThreadLocalStorage::thread() hasn't been initialized // 2) _file_lock is not in use. // 3) current() is VMThread and its reentry flag is set if (!thread || !_file_lock || (thread->is_VM_thread() && ((VMThread* )thread)->is_gclog_reentry())) { size_t count = fwrite(s, 1, len, _file); _bytes_written += count; } else { MutexLockerEx ml(_file_lock, Mutex::_no_safepoint_check_flag); size_t count = fwrite(s, 1, len, _file); _bytes_written += count; } } update_position(s, len); } // rotate_log must be called from VMThread at a safepoint. In case need change parameters // for gc log rotation from thread other than VMThread, a sub type of VM_Operation // should be created and be submitted to VMThread's operation queue. DO NOT call this // function directly. It is safe to rotate log through VMThread because // no mutator threads run concurrently with the VMThread, and GC threads that run // concurrently with the VMThread are synchronized in write and rotate_log via _file_lock. // rotate_log can write log entries, so write supports reentry for it. void gcLogFileStream::rotate_log(bool force, outputStream* out) { #ifdef ASSERT Thread *thread = Thread::current(); assert(thread == NULL || (thread->is_VM_thread() && SafepointSynchronize::is_at_safepoint()), "Must be VMThread at safepoint"); #endif VMThread* vmthread = VMThread::vm_thread(); { // nop if _file_lock is NULL. MutexLockerEx ml(_file_lock, Mutex::_no_safepoint_check_flag); vmthread->set_gclog_reentry(true); rotate_log_impl(force, out); vmthread->set_gclog_reentry(false); } } void gcLogFileStream::rotate_log_impl(bool force, outputStream* out) { char time_msg[O_BUFLEN]; char time_str[EXTRACHARLEN]; char current_file_name[JVM_MAXPATHLEN]; char renamed_file_name[JVM_MAXPATHLEN]; if (!should_rotate(force)) { return; } if (NumberOfGCLogFiles == 1) { // rotate in same file rewind(); _bytes_written = 0L; jio_snprintf(time_msg, sizeof(time_msg), "File %s rotated at %s\n", _file_name, os::local_time_string((char *)time_str, sizeof(time_str))); write(time_msg, strlen(time_msg)); if (out != NULL) { out->print("%s", time_msg); } dump_loggc_header(); return; } #if defined(_WINDOWS) #ifndef F_OK #define F_OK 0 #endif #endif // _WINDOWS // rotate file in names extended_filename.0, extended_filename.1, ..., // extended_filename.<NumberOfGCLogFiles - 1>. Current rotation file name will // have a form of extended_filename.<i>.current where i is the current rotation // file number. After it reaches max file size, the file will be saved and renamed // with .current removed from its tail. if (_file != NULL) { jio_snprintf(renamed_file_name, JVM_MAXPATHLEN, "%s.%d", _file_name, _cur_file_num); int result = jio_snprintf(current_file_name, JVM_MAXPATHLEN, "%s.%d" CURRENTAPPX, _file_name, _cur_file_num); if (result >= JVM_MAXPATHLEN) { warning("Cannot create new log file name: %s: file name is too long.\n", current_file_name); return; } const char* msg = force ? "GC log rotation request has been received." : "GC log file has reached the maximum size."; jio_snprintf(time_msg, sizeof(time_msg), "%s %s Saved as %s\n", os::local_time_string((char *)time_str, sizeof(time_str)), msg, renamed_file_name); write(time_msg, strlen(time_msg)); if (out != NULL) { out->print("%s", time_msg); } fclose(_file); _file = NULL; bool can_rename = true; if (access(current_file_name, F_OK) != 0) { // current file does not exist? warning("No source file exists, cannot rename\n"); can_rename = false; } if (can_rename) { if (access(renamed_file_name, F_OK) == 0) { if (remove(renamed_file_name) != 0) { warning("Could not delete existing file %s\n", renamed_file_name); can_rename = false; } } else { // file does not exist, ok to rename } } if (can_rename && rename(current_file_name, renamed_file_name) != 0) { warning("Could not rename %s to %s\n", _file_name, renamed_file_name); } } _cur_file_num++; if (_cur_file_num > NumberOfGCLogFiles - 1) _cur_file_num = 0; int result = jio_snprintf(current_file_name, JVM_MAXPATHLEN, "%s.%d" CURRENTAPPX, _file_name, _cur_file_num); if (result >= JVM_MAXPATHLEN) { warning("Cannot create new log file name: %s: file name is too long.\n", current_file_name); return; } _file = fopen(current_file_name, "w"); if (_file != NULL) { _bytes_written = 0L; _need_close = true; // reuse current_file_name for time_msg jio_snprintf(current_file_name, JVM_MAXPATHLEN, "%s.%d", _file_name, _cur_file_num); jio_snprintf(time_msg, sizeof(time_msg), "%s GC log file created %s\n", os::local_time_string((char *)time_str, sizeof(time_str)), current_file_name); write(time_msg, strlen(time_msg)); if (out != NULL) { out->print("%s", time_msg); } dump_loggc_header(); // remove the existing file if (access(current_file_name, F_OK) == 0) { if (remove(current_file_name) != 0) { warning("Could not delete existing file %s\n", current_file_name); } } } else { warning("failed to open rotation log file %s due to %s\n" "Turned off GC log file rotation\n", _file_name, strerror(errno)); _need_close = false; FLAG_SET_DEFAULT(UseGCLogFileRotation, false); } } defaultStream* defaultStream::instance = NULL; int defaultStream::_output_fd = 1; int defaultStream::_error_fd = 2; FILE* defaultStream::_output_stream = stdout; FILE* defaultStream::_error_stream = stderr; #define LOG_MAJOR_VERSION 160 #define LOG_MINOR_VERSION 1 void defaultStream::init() { _inited = true; if (LogVMOutput || LogCompilation) { init_log(); } } bool defaultStream::has_log_file() { // lazily create log file (at startup, LogVMOutput is false even // if +LogVMOutput is used, because the flags haven't been parsed yet) // For safer printing during fatal error handling, do not init logfile // if a VM error has been reported. if (!_inited && !is_error_reported()) init(); return _log_file != NULL; } fileStream* defaultStream::open_file(const char* log_name) { const char* try_name = make_log_name(log_name, NULL); if (try_name == NULL) { warning("Cannot open file %s: file name is too long.\n", log_name); return NULL; } fileStream* file = new(ResourceObj::C_HEAP, mtInternal) fileStream(try_name); FREE_C_HEAP_ARRAY(char, try_name, mtInternal); if (file->is_open()) { return file; } // Try again to open the file in the temp directory. delete file; char warnbuf[O_BUFLEN*2]; jio_snprintf(warnbuf, sizeof(warnbuf), "Warning: Cannot open log file: %s\n", log_name); // Note: This feature is for maintainer use only. No need for L10N. jio_print(warnbuf); try_name = make_log_name(log_name, os::get_temp_directory()); if (try_name == NULL) { warning("Cannot open file %s: file name is too long for directory %s.\n", log_name, os::get_temp_directory()); return NULL; } jio_snprintf(warnbuf, sizeof(warnbuf), "Warning: Forcing option -XX:LogFile=%s\n", try_name); jio_print(warnbuf); file = new(ResourceObj::C_HEAP, mtInternal) fileStream(try_name); FREE_C_HEAP_ARRAY(char, try_name, mtInternal); if (file->is_open()) { return file; } delete file; return NULL; } void defaultStream::init_log() { // %%% Need a MutexLocker? const char* log_name = LogFile != NULL ? LogFile : "hotspot_%p.log"; fileStream* file = open_file(log_name); if (file != NULL) { _log_file = file; _outer_xmlStream = new(ResourceObj::C_HEAP, mtInternal) xmlStream(file); start_log(); } else { // and leave xtty as NULL LogVMOutput = false; DisplayVMOutput = true; LogCompilation = false; } } void defaultStream::start_log() { xmlStream*xs = _outer_xmlStream; if (this == tty) xtty = xs; // Write XML header. xs->print_cr("<?xml version='1.0' encoding='UTF-8'?>"); // (For now, don't bother to issue a DTD for this private format.) jlong time_ms = os::javaTimeMillis() - tty->time_stamp().milliseconds(); // %%% Should be: jlong time_ms = os::start_time_milliseconds(), if // we ever get round to introduce that method on the os class xs->head("hotspot_log version='%d %d'" " process='%d' time_ms='" INT64_FORMAT "'", LOG_MAJOR_VERSION, LOG_MINOR_VERSION, os::current_process_id(), (int64_t)time_ms); // Write VM version header immediately. xs->head("vm_version"); xs->head("name"); xs->text("%s", VM_Version::vm_name()); xs->cr(); xs->tail("name"); xs->head("release"); xs->text("%s", VM_Version::vm_release()); xs->cr(); xs->tail("release"); xs->head("info"); xs->text("%s", VM_Version::internal_vm_info_string()); xs->cr(); xs->tail("info"); xs->tail("vm_version"); // Record information about the command-line invocation. xs->head("vm_arguments"); // Cf. Arguments::print_on() if (Arguments::num_jvm_flags() > 0) { xs->head("flags"); Arguments::print_jvm_flags_on(xs->text()); xs->tail("flags"); } if (Arguments::num_jvm_args() > 0) { xs->head("args"); Arguments::print_jvm_args_on(xs->text()); xs->tail("args"); } if (Arguments::java_command() != NULL) { xs->head("command"); xs->text()->print_cr("%s", Arguments::java_command()); xs->tail("command"); } if (Arguments::sun_java_launcher() != NULL) { xs->head("launcher"); xs->text()->print_cr("%s", Arguments::sun_java_launcher()); xs->tail("launcher"); } if (Arguments::system_properties() != NULL) { xs->head("properties"); // Print it as a java-style property list. // System properties don't generally contain newlines, so don't bother with unparsing. for (SystemProperty* p = Arguments::system_properties(); p != NULL; p = p->next()) { xs->text()->print_cr("%s=%s", p->key(), p->value()); } xs->tail("properties"); } xs->tail("vm_arguments"); // tty output per se is grouped under the <tty>...</tty> element. xs->head("tty"); // All further non-markup text gets copied to the tty: xs->_text = this; // requires friend declaration! } // finish_log() is called during normal VM shutdown. finish_log_on_error() is // called by ostream_abort() after a fatal error. // void defaultStream::finish_log() { xmlStream* xs = _outer_xmlStream; xs->done("tty"); // Other log forks are appended here, at the End of Time: CompileLog::finish_log(xs->out()); // write compile logging, if any, now xs->done("hotspot_log"); xs->flush(); fileStream* file = _log_file; _log_file = NULL; delete _outer_xmlStream; _outer_xmlStream = NULL; file->flush(); delete file; } void defaultStream::finish_log_on_error(char *buf, int buflen) { xmlStream* xs = _outer_xmlStream; if (xs && xs->out()) { xs->done_raw("tty"); // Other log forks are appended here, at the End of Time: CompileLog::finish_log_on_error(xs->out(), buf, buflen); // write compile logging, if any, now xs->done_raw("hotspot_log"); xs->flush(); fileStream* file = _log_file; _log_file = NULL; _outer_xmlStream = NULL; if (file) { file->flush(); // Can't delete or close the file because delete and fclose aren't // async-safe. We are about to die, so leave it to the kernel. // delete file; } } } intx defaultStream::hold(intx writer_id) { bool has_log = has_log_file(); // check before locking if (// impossible, but who knows? writer_id == NO_WRITER || // bootstrap problem tty_lock == NULL || // can't grab a lock or call Thread::current() if TLS isn't initialized ThreadLocalStorage::thread() == NULL || // developer hook !SerializeVMOutput || // VM already unhealthy is_error_reported() || // safepoint == global lock (for VM only) (SafepointSynchronize::is_synchronizing() && Thread::current()->is_VM_thread()) ) { // do not attempt to lock unless we know the thread and the VM is healthy return NO_WRITER; } if (_writer == writer_id) { // already held, no need to re-grab the lock return NO_WRITER; } tty_lock->lock_without_safepoint_check(); // got the lock if (writer_id != _last_writer) { if (has_log) { _log_file->bol(); // output a hint where this output is coming from: _log_file->print_cr("<writer thread='" UINTX_FORMAT "'/>", writer_id); } _last_writer = writer_id; } _writer = writer_id; return writer_id; } void defaultStream::release(intx holder) { if (holder == NO_WRITER) { // nothing to release: either a recursive lock, or we scribbled (too bad) return; } if (_writer != holder) { return; // already unlocked, perhaps via break_tty_lock_for_safepoint } _writer = NO_WRITER; tty_lock->unlock(); } // Yuck: jio_print does not accept char*/len. static void call_jio_print(const char* s, size_t len) { char buffer[O_BUFLEN+100]; if (len > sizeof(buffer)-1) { warning("increase O_BUFLEN in ostream.cpp -- output truncated"); len = sizeof(buffer)-1; } strncpy(buffer, s, len); buffer[len] = '\0'; jio_print(buffer); } void defaultStream::write(const char* s, size_t len) { intx thread_id = os::current_thread_id(); intx holder = hold(thread_id); if (DisplayVMOutput && (_outer_xmlStream == NULL || !_outer_xmlStream->inside_attrs())) { // print to output stream. It can be redirected by a vfprintf hook if (s[len] == '\0') { jio_print(s); } else { call_jio_print(s, len); } } // print to log file if (has_log_file()) { int nl0 = _newlines; xmlTextStream::write(s, len); // flush the log file too, if there were any newlines if (nl0 != _newlines){ flush(); } } else { update_position(s, len); } release(holder); } intx ttyLocker::hold_tty() { if (defaultStream::instance == NULL) return defaultStream::NO_WRITER; intx thread_id = os::current_thread_id(); return defaultStream::instance->hold(thread_id); } void ttyLocker::release_tty(intx holder) { if (holder == defaultStream::NO_WRITER) return; defaultStream::instance->release(holder); } bool ttyLocker::release_tty_if_locked() { intx thread_id = os::current_thread_id(); if (defaultStream::instance->writer() == thread_id) { // release the lock and return true so callers know if was // previously held. release_tty(thread_id); return true; } return false; } void ttyLocker::break_tty_lock_for_safepoint(intx holder) { if (defaultStream::instance != NULL && defaultStream::instance->writer() == holder) { if (xtty != NULL) { xtty->print_cr("<!-- safepoint while printing -->"); } defaultStream::instance->release(holder); } // (else there was no lock to break) } void ostream_init() { if (defaultStream::instance == NULL) { defaultStream::instance = new(ResourceObj::C_HEAP, mtInternal) defaultStream(); tty = defaultStream::instance; // We want to ensure that time stamps in GC logs consider time 0 // the time when the JVM is initialized, not the first time we ask // for a time stamp. So, here, we explicitly update the time stamp // of tty. tty->time_stamp().update_to(1); } } void ostream_init_log() { // For -Xloggc:<file> option - called in runtime/thread.cpp // Note : this must be called AFTER ostream_init() gclog_or_tty = tty; // default to tty if (Arguments::gc_log_filename() != NULL) { fileStream * gclog = new(ResourceObj::C_HEAP, mtInternal) gcLogFileStream(Arguments::gc_log_filename()); if (gclog->is_open()) { // now we update the time stamp of the GC log to be synced up // with tty. gclog->time_stamp().update_to(tty->time_stamp().ticks()); } gclog_or_tty = gclog; } #if INCLUDE_CDS // For -XX:DumpLoadedClassList=<file> option if (DumpLoadedClassList != NULL) { const char* list_name = make_log_name(DumpLoadedClassList, NULL); classlist_file = new(ResourceObj::C_HEAP, mtInternal) fileStream(list_name); FREE_C_HEAP_ARRAY(char, list_name, mtInternal); } #endif // If we haven't lazily initialized the logfile yet, do it now, // to avoid the possibility of lazy initialization during a VM // crash, which can affect the stability of the fatal error handler. defaultStream::instance->has_log_file(); } // ostream_exit() is called during normal VM exit to finish log files, flush // output and free resource. void ostream_exit() { static bool ostream_exit_called = false; if (ostream_exit_called) return; ostream_exit_called = true; #if INCLUDE_CDS if (classlist_file != NULL) { delete classlist_file; } #endif if (gclog_or_tty != tty) { delete gclog_or_tty; } { // we temporaly disable PrintMallocFree here // as otherwise it'll lead to using of almost deleted // tty or defaultStream::instance in logging facility // of HeapFree(), see 6391258 DEBUG_ONLY(FlagSetting fs(PrintMallocFree, false);) if (tty != defaultStream::instance) { delete tty; } if (defaultStream::instance != NULL) { delete defaultStream::instance; } } tty = NULL; xtty = NULL; gclog_or_tty = NULL; defaultStream::instance = NULL; } // ostream_abort() is called by os::abort() when VM is about to die. void ostream_abort() { // Here we can't delete gclog_or_tty and tty, just flush their output if (gclog_or_tty) gclog_or_tty->flush(); if (tty) tty->flush(); if (defaultStream::instance != NULL) { static char buf[4096]; defaultStream::instance->finish_log_on_error(buf, sizeof(buf)); } } staticBufferStream::staticBufferStream(char* buffer, size_t buflen, outputStream *outer_stream) { _buffer = buffer; _buflen = buflen; _outer_stream = outer_stream; // compile task prints time stamp relative to VM start _stamp.update_to(1); } void staticBufferStream::write(const char* c, size_t len) { _outer_stream->print_raw(c, (int)len); } void staticBufferStream::flush() { _outer_stream->flush(); } void staticBufferStream::print(const char* format, ...) { va_list ap; va_start(ap, format); size_t len; const char* str = do_vsnprintf(_buffer, _buflen, format, ap, false, len); write(str, len); va_end(ap); } void staticBufferStream::print_cr(const char* format, ...) { va_list ap; va_start(ap, format); size_t len; const char* str = do_vsnprintf(_buffer, _buflen, format, ap, true, len); write(str, len); va_end(ap); } void staticBufferStream::vprint(const char *format, va_list argptr) { size_t len; const char* str = do_vsnprintf(_buffer, _buflen, format, argptr, false, len); write(str, len); } void staticBufferStream::vprint_cr(const char* format, va_list argptr) { size_t len; const char* str = do_vsnprintf(_buffer, _buflen, format, argptr, true, len); write(str, len); } bufferedStream::bufferedStream(size_t initial_size, size_t bufmax) : outputStream() { buffer_length = initial_size; buffer = NEW_C_HEAP_ARRAY(char, buffer_length, mtInternal); buffer_pos = 0; buffer_fixed = false; buffer_max = bufmax; } bufferedStream::bufferedStream(char* fixed_buffer, size_t fixed_buffer_size, size_t bufmax) : outputStream() { buffer_length = fixed_buffer_size; buffer = fixed_buffer; buffer_pos = 0; buffer_fixed = true; buffer_max = bufmax; } void bufferedStream::write(const char* s, size_t len) { if(buffer_pos + len > buffer_max) { flush(); } size_t end = buffer_pos + len; if (end >= buffer_length) { if (buffer_fixed) { // if buffer cannot resize, silently truncate len = buffer_length - buffer_pos - 1; } else { // For small overruns, double the buffer. For larger ones, // increase to the requested size. if (end < buffer_length * 2) { end = buffer_length * 2; } buffer = REALLOC_C_HEAP_ARRAY(char, buffer, end, mtInternal); buffer_length = end; } } memcpy(buffer + buffer_pos, s, len); buffer_pos += len; update_position(s, len); } char* bufferedStream::as_string() { char* copy = NEW_RESOURCE_ARRAY(char, buffer_pos+1); strncpy(copy, buffer, buffer_pos); copy[buffer_pos] = 0; // terminating null return copy; } bufferedStream::~bufferedStream() { if (!buffer_fixed) { FREE_C_HEAP_ARRAY(char, buffer, mtInternal); } } #ifndef PRODUCT #if defined(SOLARIS) || defined(LINUX) || defined(AIX) || defined(_ALLBSD_SOURCE) #include <sys/types.h> #include <sys/socket.h> #include <netinet/in.h> #include <arpa/inet.h> #endif // Network access networkStream::networkStream() : bufferedStream(1024*10, 1024*10) { _socket = -1; int result = os::socket(AF_INET, SOCK_STREAM, 0); if (result <= 0) { assert(false, "Socket could not be created!"); } else { _socket = result; } } int networkStream::read(char *buf, size_t len) { return os::recv(_socket, buf, (int)len, 0); } void networkStream::flush() { if (size() != 0) { int result = os::raw_send(_socket, (char *)base(), size(), 0); assert(result != -1, "connection error"); assert(result == (int)size(), "didn't send enough data"); } reset(); } networkStream::~networkStream() { close(); } void networkStream::close() { if (_socket != -1) { flush(); os::socket_close(_socket); _socket = -1; } } bool networkStream::connect(const char *ip, short port) { struct sockaddr_in server; server.sin_family = AF_INET; server.sin_port = htons(port); server.sin_addr.s_addr = inet_addr(ip); if (server.sin_addr.s_addr == (uint32_t)-1) { struct hostent* host = os::get_host_by_name((char*)ip); if (host != NULL) { memcpy(&server.sin_addr, host->h_addr_list[0], host->h_length); } else { return false; } } int result = os::connect(_socket, (struct sockaddr*)&server, sizeof(struct sockaddr_in)); return (result >= 0); } #endif