/* * Copyright (c) 2016, 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 "jfr/recorder/access/jfrMemorySizer.hpp" #include "logging/log.hpp" #include "runtime/os.hpp" const julong MAX_ADJUSTED_GLOBAL_BUFFER_SIZE = 1 * M; const julong MIN_ADJUSTED_GLOBAL_BUFFER_SIZE_CUTOFF = 512 * K; const julong MIN_GLOBAL_BUFFER_SIZE = 64 * K; // implies at least 2 * MIN_GLOBAL_BUFFER SIZE const julong MIN_BUFFER_COUNT = 2; // MAX global buffer count open ended const julong DEFAULT_BUFFER_COUNT = 20; // MAX thread local buffer size == size of a single global buffer (runtime determined) // DEFAULT thread local buffer size = 2 * os page size (runtime determined) const julong MIN_THREAD_BUFFER_SIZE = 4 * K; const julong MIN_MEMORY_SIZE = 1 * M; const julong DEFAULT_MEMORY_SIZE = 10 * M; // // In pages: // // units = total_pages / per_unit_pages // static julong div_pages(julong& total_pages, julong& per_unit_pages) { assert(total_pages > 0, "invariant"); assert(per_unit_pages > 0, "invariant"); assert(total_pages >= per_unit_pages, "invariant"); const julong units = total_pages / per_unit_pages; const julong rem = total_pages % per_unit_pages; assert(units > 0, "invariant"); if (rem > 0) { total_pages -= rem % units; per_unit_pages += rem / units; } assert(per_unit_pages > 0, "invariant"); assert(total_pages % units == 0, "invariant"); assert(units * per_unit_pages == total_pages, "invariant"); assert(units == total_pages / per_unit_pages, "invariant"); return units; } static void page_size_align_up(julong& value) { static const julong alignment = os::vm_page_size() - 1; value = (value + alignment) & ~alignment; } // // In bytes: // units = total_bytes / per_unit_bytes // static julong div_total_by_per_unit(julong& total_bytes, julong& per_unit_bytes) { assert(total_bytes > 0, "invariant"); assert(per_unit_bytes > 0, "invariant"); assert(total_bytes >= per_unit_bytes, "invariant"); page_size_align_up(total_bytes); assert(total_bytes % os::vm_page_size() == 0, "invariant"); julong total_pages = total_bytes / os::vm_page_size(); page_size_align_up(per_unit_bytes); assert(per_unit_bytes % os::vm_page_size() == 0, "invariant"); julong per_unit_pages = per_unit_bytes / os::vm_page_size(); const julong units = div_pages(total_pages, per_unit_pages); assert(units > 0, "invariant"); total_bytes = total_pages * os::vm_page_size(); per_unit_bytes = per_unit_pages * os::vm_page_size(); assert(per_unit_bytes > 0, "invariant"); assert(total_bytes / per_unit_bytes == units, "invariant"); return units; } // // per_unit_bytes = total_bytes / units // static julong div_total_by_units(julong& total_bytes, julong& units) { page_size_align_up(total_bytes); assert(total_bytes % os::vm_page_size() == 0, "invariant"); julong total_pages = total_bytes / os::vm_page_size(); assert(units > 0, "invariant"); julong per_unit_pages = total_pages <= units ? 1 : total_pages / units; units = div_pages(total_pages, per_unit_pages); julong per_unit_bytes = per_unit_pages * os::vm_page_size(); assert(per_unit_bytes % os::vm_page_size() == 0, "invariant"); total_bytes = total_pages * os::vm_page_size(); assert(total_bytes % os::vm_page_size() == 0, "invariant"); assert(total_bytes % units == 0, "invariant"); assert(total_bytes / units == per_unit_bytes, "invariant"); assert(units * per_unit_bytes == total_bytes, "invariant"); return per_unit_bytes; } // // total_bytes = per_unit_bytes * units; // static julong multiply(julong& per_unit_bytes, julong& units) { page_size_align_up(per_unit_bytes); assert(per_unit_bytes % os::vm_page_size() == 0, "invariant"); assert(units > 0, "invariant"); julong total_bytes = per_unit_bytes * units; assert(total_bytes % os::vm_page_size() == 0, "invariant"); assert(total_bytes % units == 0, "invariant"); assert(total_bytes / units == per_unit_bytes, "invariant"); assert(units * per_unit_bytes == total_bytes, "invariant"); return total_bytes; } // Total_bytes is explicitly set. // // Deduce other parameters by delegating to a sizing policy template static julong adjust(JfrMemoryOptions* options) { page_size_align_up(options->memory_size); assert(options->memory_size % os::vm_page_size() == 0, "invariant"); julong total_pages = options->memory_size / os::vm_page_size(); assert(options->buffer_count > 0, "invariant"); julong per_unit_pages = total_pages / options->buffer_count; page_size_align_up(options->thread_buffer_size); assert(options->thread_buffer_size % os::vm_page_size() == 0, "invariant"); julong thread_buffer_pages = options->thread_buffer_size / os::vm_page_size(); SizingPolicy::adjust(total_pages, per_unit_pages, options->buffer_count, thread_buffer_pages, options->thread_buffer_size_configured); assert(options->buffer_count * per_unit_pages == total_pages, "invariant"); const julong per_unit_bytes = per_unit_pages * os::vm_page_size(); options->memory_size = total_pages * os::vm_page_size(); options->thread_buffer_size = thread_buffer_pages * os::vm_page_size(); assert(options->memory_size % options->buffer_count == 0, "invariant"); assert(options->memory_size / options->buffer_count == per_unit_bytes, "invariant"); assert(options->buffer_count * per_unit_bytes == options->memory_size, "invariant"); assert(per_unit_bytes >= options->thread_buffer_size, "invariant"); return per_unit_bytes; } static void align_buffer_size(julong& buffer_size_in_pages, julong max_size_pages, julong min_size_pages, bool sizeup = false) { buffer_size_in_pages = MIN2(buffer_size_in_pages, max_size_pages); buffer_size_in_pages = MAX2(buffer_size_in_pages, min_size_pages); size_t multiples = 0; if (buffer_size_in_pages < max_size_pages) { while (buffer_size_in_pages >= (min_size_pages << (multiples + (sizeup ? 0 : 1)))) { ++multiples; } buffer_size_in_pages = min_size_pages << multiples; } assert(buffer_size_in_pages >= min_size_pages && buffer_size_in_pages <= max_size_pages, "invariant"); } static void adjust_buffer_size_to_total_memory_size(julong& total_pages, julong& buffer_size_pages) { static const julong max_buffer_size_pages = MAX_ADJUSTED_GLOBAL_BUFFER_SIZE / os::vm_page_size(); // If memory size is less than DEFAULT_MEMORY_SIZE, // the adjustment algorithm can decrease the size of the global buffer // all the way down to the MIN_GLOBAL_BUFFER_SIZE (taking embedded use case in account). // If memory size is larger than DEFAULT_MEMORY_SIZE, the lowest size of // a global buffer will be the size of MIN_ADJUSTED_GLOBAL_BUFFER_SIZE_CUTOFF static const julong min_buffer_size_pages = total_pages * os::vm_page_size() < DEFAULT_MEMORY_SIZE ? MIN_GLOBAL_BUFFER_SIZE / os::vm_page_size() : MIN_ADJUSTED_GLOBAL_BUFFER_SIZE_CUTOFF / os::vm_page_size(); align_buffer_size(buffer_size_pages, max_buffer_size_pages, min_buffer_size_pages); assert(buffer_size_pages % min_buffer_size_pages == 0, "invariant"); julong remainder = total_pages % buffer_size_pages; while (remainder >= (buffer_size_pages >> 1)) { if (buffer_size_pages <= min_buffer_size_pages) { break; } buffer_size_pages >>= 1; remainder = total_pages % buffer_size_pages; } } // Sizing policy class class ScaleOutAdjuster : public AllStatic { public: static void adjust(julong& total_pages, julong& buffer_size_pages, julong& buffer_count, julong& thread_buffer_size_pages, bool is_thread_buffer_size_set) { assert(buffer_count > 0, "invariant"); adjust_buffer_size_to_total_memory_size(total_pages, buffer_size_pages); assert(buffer_size_pages * os::vm_page_size() >= MIN_GLOBAL_BUFFER_SIZE, "invariant"); assert((buffer_size_pages * os::vm_page_size()) % MIN_GLOBAL_BUFFER_SIZE == 0, "invariant"); if (is_thread_buffer_size_set) { if (thread_buffer_size_pages > buffer_size_pages) { buffer_size_pages = thread_buffer_size_pages; } } // and with this information, calculate what the new buffer count will be buffer_count = div_pages(total_pages, buffer_size_pages); } }; static void memory_and_thread_buffer_size(JfrMemoryOptions* options) { assert(options->memory_size_configured, "invariant"); assert(!options->buffer_count_configured, "invariant"); assert(!options->global_buffer_size_configured, "invariant"); // here the only thing specified is the overall total memory size // we can and will apply some sizing heuristics to derive both // the size of an individual global buffer and by implication the number of global // buffers to use. Starting values for buffer count and global_buffer_size // will be the defaults. options->global_buffer_size = adjust(options); } static void memory_size_and_buffer_count(JfrMemoryOptions* options) { assert(options->memory_size_configured, "invariant"); assert(!options->global_buffer_size_configured, "invariant"); assert(!options->thread_buffer_size_configured, "invariant"); assert(options->buffer_count_configured, "invariant"); options->global_buffer_size = div_total_by_units(options->memory_size, options->buffer_count); } static void memory_size_and_global_buffer_size(JfrMemoryOptions* options) { assert(options->memory_size_configured, "invariant"); assert(options->global_buffer_size_configured, "invariant"); assert(!options->buffer_count_configured, "invariant"); page_size_align_up(options->thread_buffer_size); options->buffer_count = div_total_by_per_unit(options->memory_size, options->global_buffer_size); if (options->thread_buffer_size > options->global_buffer_size) { options->global_buffer_size = options->thread_buffer_size; options->buffer_count = div_total_by_per_unit(options->memory_size, options->global_buffer_size); } assert(options->global_buffer_size >= options->thread_buffer_size, "invariant"); } static bool is_ambiguous(const JfrMemoryOptions* options) { assert(options->memory_size_configured, "invariant"); assert(options->global_buffer_size_configured, "invariant"); assert(options->buffer_count_configured, "invariant"); assert(options->thread_buffer_size <= options->global_buffer_size, "invariant"); // This can cause an ambiguous situation because all three parameters are explicitly set. return options->global_buffer_size * options->buffer_count != options->memory_size; } static void all_options_set(JfrMemoryOptions* options) { options->buffer_count = div_total_by_per_unit(options->memory_size, options->global_buffer_size); page_size_align_up(options->thread_buffer_size); if (options->thread_buffer_size > options->global_buffer_size) { options->global_buffer_size = options->thread_buffer_size; options->buffer_count = div_total_by_per_unit(options->memory_size, options->global_buffer_size); } assert(options->global_buffer_size >= options->thread_buffer_size, "invariant"); assert(options->memory_size / options->global_buffer_size == options->buffer_count, "invariant"); assert(options->memory_size % options->global_buffer_size == 0, "invariant"); } static void global_buffer_size(JfrMemoryOptions* options) { assert(!options->memory_size_configured, "invariant"); page_size_align_up(options->thread_buffer_size); if (options->thread_buffer_size > options->global_buffer_size) { options->global_buffer_size = options->thread_buffer_size; } options->memory_size = multiply(options->global_buffer_size, options->buffer_count); assert(options->global_buffer_size >= options->thread_buffer_size, "invariant"); } static void thread_buffer_size(JfrMemoryOptions* options) { assert(!options->global_buffer_size_configured, "invariant"); assert(options->thread_buffer_size_configured, "invariant"); page_size_align_up(options->thread_buffer_size); options->global_buffer_size = div_total_by_units(options->memory_size, options->buffer_count); if (options->thread_buffer_size > options->global_buffer_size) { options->global_buffer_size = options->thread_buffer_size; options->buffer_count = div_total_by_per_unit(options->memory_size, options->global_buffer_size); } assert(options->global_buffer_size >= options->thread_buffer_size, "invariant"); } static void default_size(const JfrMemoryOptions* options) { // no memory options explicitly set // default values already statically adjusted assert(!options->thread_buffer_size_configured, "invariant"); assert(!options->memory_size_configured, "invariant"); assert(!options->buffer_count_configured, "invarinat"); assert(!options->global_buffer_size_configured, "invariant"); } #ifdef ASSERT static void assert_post_condition(const JfrMemoryOptions* options) { assert(options->memory_size % os::vm_page_size() == 0, "invariant"); assert(options->global_buffer_size % os::vm_page_size() == 0, "invariant"); assert(options->thread_buffer_size % os::vm_page_size() == 0, "invariant"); assert(options->buffer_count > 0, "invariant"); } #endif // MEMORY SIZING ALGORITHM bool JfrMemorySizer::adjust_options(JfrMemoryOptions* options) { assert(options != NULL, "invariant"); enum MemoryOptions { MEMORY_SIZE = 1, GLOBAL_BUFFER_SIZE = 2, GLOBAL_BUFFER_COUNT = 4, THREAD_BUFFER_SIZE = 8 }; // LEGEND // // M = "memorysize" option // G = "globalbuffersize" option // C = "numglobalbuffers" option // T = "threadbuffersize" option // // The memory options comprise an n-set (a 4-set) = { M, G, C, T } // // Number of r-subsets = 5 (0, 1, 2, 3, 4) (including null set) // // Unordered selection: // // C(4, 0) = {} = NULL set = 1 // C(4, 1) = { (M), (G), (C), (T) } = 4 // C(4, 2) = { (M, G), (M, C), (M, T), (G, C), (G, T), (C, T) } = 6 // C(4, 3) = { (M, G, C), (M, G, T), (M, C, T), (G, C, T) } = 4 // C(4, 4) = { (M, G, C, T) } = 1 // // in shorter terms: P({ M, G, C, T}) = 16 // #define MG (MEMORY_SIZE | GLOBAL_BUFFER_SIZE) #define MC (MEMORY_SIZE | GLOBAL_BUFFER_COUNT) #define MT (MEMORY_SIZE | THREAD_BUFFER_SIZE) #define MGC (MG | GLOBAL_BUFFER_COUNT) #define MGT (MG | THREAD_BUFFER_SIZE) #define MCT (MC | THREAD_BUFFER_SIZE) #define MGCT (MGC | THREAD_BUFFER_SIZE) #define GC (GLOBAL_BUFFER_SIZE | GLOBAL_BUFFER_COUNT) #define GT (GLOBAL_BUFFER_SIZE | THREAD_BUFFER_SIZE) #define GCT (GC | THREAD_BUFFER_SIZE) #define CT (GLOBAL_BUFFER_COUNT | THREAD_BUFFER_SIZE) int set_of_options = 0; if (options->memory_size_configured) { set_of_options |= MEMORY_SIZE; } if (options->global_buffer_size_configured) { set_of_options |= GLOBAL_BUFFER_SIZE; } if (options->buffer_count_configured) { set_of_options |= GLOBAL_BUFFER_COUNT; } if (options->thread_buffer_size_configured) { set_of_options |= THREAD_BUFFER_SIZE; } switch (set_of_options) { case MT: case MEMORY_SIZE: memory_and_thread_buffer_size(options); break; case MC: memory_size_and_buffer_count(options); break; case MGT: assert(options->thread_buffer_size_configured, "invariant"); case MG: memory_size_and_global_buffer_size(options); break; case MGC: case MGCT: if (is_ambiguous(options)) { // Let the user resolve the ambiguity by bailing. return false; } all_options_set(options); break; case GCT: assert(options->buffer_count_configured, "invariant"); assert(options->thread_buffer_size_configured, "invariant"); case GC: assert(options->global_buffer_size_configured, "invariant"); case GT: case GLOBAL_BUFFER_COUNT: case GLOBAL_BUFFER_SIZE: global_buffer_size(options); break; case MCT: assert(options->memory_size_configured, "invariant"); case CT: assert(options->buffer_count_configured, "invariant"); case THREAD_BUFFER_SIZE: thread_buffer_size(options); break; default: default_size(options); } DEBUG_ONLY(assert_post_condition(options);) return true; }