/* * Copyright (c) 2014-2016 Advanced Micro Devices, Inc. * Copyright (c) 2012 ARM Limited * All rights reserved * * The license below extends only to copyright in the software and shall * not be construed as granting a license to any other intellectual * property including but not limited to intellectual property relating * to a hardware implementation of the functionality of the software * licensed hereunder. You may use the software subject to the license * terms below provided that you ensure that this notice is replicated * unmodified and in its entirety in all distributions of the software, * modified or unmodified, in source code or in binary form. * * Copyright (c) 2001-2005 The Regents of The University of Michigan * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer; * redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution; * neither the name of the copyright holders nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "sim/process.hh" #include #include #include #include #include #include #include #include #include "base/intmath.hh" #include "base/loader/object_file.hh" #include "base/loader/symtab.hh" #include "base/statistics.hh" #include "cpu/thread_context.hh" #include "mem/page_table.hh" #include "mem/se_translating_port_proxy.hh" #include "params/Process.hh" #include "sim/emul_driver.hh" #include "sim/fd_array.hh" #include "sim/fd_entry.hh" #include "sim/redirect_path.hh" #include "sim/se_workload.hh" #include "sim/syscall_desc.hh" #include "sim/system.hh" namespace gem5 { namespace { typedef std::vector LoaderList; LoaderList & process_loaders() { static LoaderList loaders; return loaders; } } // anonymous namespace Process::Loader::Loader() { process_loaders().emplace_back(this); } Process * Process::tryLoaders(const ProcessParams ¶ms, loader::ObjectFile *obj_file) { for (auto &loader_it : process_loaders()) { Process *p = loader_it->load(params, obj_file); if (p) return p; } return nullptr; } static std::string normalize(const std::string& directory) { if (directory.back() != '/') return directory + '/'; return directory; } Process::Process(const ProcessParams ¶ms, EmulationPageTable *pTable, loader::ObjectFile *obj_file) : SimObject(params), system(params.system), seWorkload(dynamic_cast(system->workload)), useArchPT(params.useArchPT), kvmInSE(params.kvmInSE), useForClone(false), pTable(pTable), objFile(obj_file), argv(params.cmd), envp(params.env), executable(params.executable == "" ? params.cmd[0] : params.executable), tgtCwd(normalize(params.cwd)), hostCwd(checkPathRedirect(tgtCwd)), release(params.release), _uid(params.uid), _euid(params.euid), _gid(params.gid), _egid(params.egid), _pid(params.pid), _ppid(params.ppid), _pgid(params.pgid), drivers(params.drivers), fds(std::make_shared( params.input, params.output, params.errout)), childClearTID(0), ADD_STAT(numSyscalls, statistics::units::Count::get(), "Number of system calls") { fatal_if(!seWorkload, "Couldn't find appropriate workload object."); fatal_if(_pid >= System::maxPID, "_pid is too large: %d", _pid); auto ret_pair = system->PIDs.emplace(_pid); fatal_if(!ret_pair.second, "_pid %d is already used", _pid); /** * Linux bundles together processes into this concept called a thread * group. The thread group is responsible for recording which processes * behave as threads within a process context. The thread group leader * is the process who's tgid is equal to its pid. Other processes which * belong to the thread group, but do not lead the thread group, are * treated as child threads. These threads are created by the clone system * call with options specified to create threads (differing from the * options used to implement a fork). By default, set up the tgid/pid * with a new, equivalent value. If CLONE_THREAD is specified, patch * the tgid value with the old process' value. */ _tgid = params.pid; exitGroup = new bool(); sigchld = new bool(); image = objFile->buildImage(); if (loader::debugSymbolTable.empty()) loader::debugSymbolTable = objFile->symtab(); } void Process::clone(ThreadContext *otc, ThreadContext *ntc, Process *np, RegVal flags) { #ifndef CLONE_VM #define CLONE_VM 0 #endif #ifndef CLONE_FILES #define CLONE_FILES 0 #endif #ifndef CLONE_THREAD #define CLONE_THREAD 0 #endif #ifndef CLONE_VFORK #define CLONE_VFORK 0 #endif if (CLONE_VM & flags) { /** * Share the process memory address space between the new process * and the old process. Changes in one will be visible in the other * due to the pointer use. */ delete np->pTable; np->pTable = pTable; np->memState = memState; } else { /** * Duplicate the process memory address space. The state needs to be * copied over (rather than using pointers to share everything). */ typedef std::vector> MapVec; MapVec mappings; pTable->getMappings(&mappings); for (auto map : mappings) { Addr paddr, vaddr = map.first; bool alloc_page = !(np->pTable->translate(vaddr, paddr)); np->replicatePage(vaddr, paddr, otc, ntc, alloc_page); } *np->memState = *memState; } if (CLONE_FILES & flags) { /** * The parent and child file descriptors are shared because the * two FDArray pointers are pointing to the same FDArray. Opening * and closing file descriptors will be visible to both processes. */ np->fds = fds; } else { /** * Copy the file descriptors from the old process into the new * child process. The file descriptors entry can be opened and * closed independently of the other process being considered. The * host file descriptors are also dup'd so that the flags for the * host file descriptor is independent of the other process. */ std::shared_ptr nfds = np->fds; for (int tgt_fd = 0; tgt_fd < fds->getSize(); tgt_fd++) { std::shared_ptr this_fde = (*fds)[tgt_fd]; if (!this_fde) { nfds->setFDEntry(tgt_fd, nullptr); continue; } nfds->setFDEntry(tgt_fd, this_fde->clone()); auto this_hbfd = std::dynamic_pointer_cast(this_fde); if (!this_hbfd) continue; int this_sim_fd = this_hbfd->getSimFD(); if (this_sim_fd <= 2) continue; int np_sim_fd = dup(this_sim_fd); assert(np_sim_fd != -1); auto nhbfd = std::dynamic_pointer_cast((*nfds)[tgt_fd]); nhbfd->setSimFD(np_sim_fd); } } if (CLONE_THREAD & flags) { np->_tgid = _tgid; delete np->exitGroup; np->exitGroup = exitGroup; } if (CLONE_VFORK & flags) { np->vforkContexts.push_back(otc->contextId()); } np->argv.insert(np->argv.end(), argv.begin(), argv.end()); np->envp.insert(np->envp.end(), envp.begin(), envp.end()); } void Process::revokeThreadContext(int context_id) { std::vector::iterator it; for (it = contextIds.begin(); it != contextIds.end(); it++) { if (*it == context_id) { contextIds.erase(it); return; } } warn("Unable to find thread context to revoke"); } void Process::init() { // Patch the ld_bias for dynamic executables. updateBias(); if (objFile->getInterpreter()) interpImage = objFile->getInterpreter()->buildImage(); } void Process::initState() { if (contextIds.empty()) fatal("Process %s is not associated with any HW contexts!\n", name()); // first thread context for this process... initialize & enable ThreadContext *tc = system->threads[contextIds[0]]; // mark this context as active so it will start ticking. tc->activate(); pTable->initState(); initVirtMem.reset(new SETranslatingPortProxy( tc, SETranslatingPortProxy::Always)); // load object file into target memory image.write(*initVirtMem); interpImage.write(*initVirtMem); } DrainState Process::drain() { fds->updateFileOffsets(); return DrainState::Drained; } void Process::allocateMem(Addr vaddr, int64_t size, bool clobber) { const auto page_size = pTable->pageSize(); const Addr page_addr = roundDown(vaddr, page_size); // Check if the page has been mapped by other cores if not to clobber. // When running multithreaded programs in SE-mode with DerivO3CPU model, // there are cases where two or more cores have page faults on the same // page in nearby ticks. When the cores try to handle the faults at the // commit stage (also in nearby ticks/cycles), the first core will ask for // a physical page frame to map with the virtual page. Other cores can // return if the page has been mapped and `!clobber`. if (!clobber) { const EmulationPageTable::Entry *pte = pTable->lookup(page_addr); if (pte) { warn("Process::allocateMem: addr %#x already mapped\n", vaddr); return; } } const int npages = divCeil(size, page_size); const Addr paddr = seWorkload->allocPhysPages(npages); const Addr pages_size = npages * page_size; pTable->map(page_addr, paddr, pages_size, clobber ? EmulationPageTable::Clobber : EmulationPageTable::MappingFlags(0)); } void Process::replicatePage(Addr vaddr, Addr new_paddr, ThreadContext *old_tc, ThreadContext *new_tc, bool allocate_page) { if (allocate_page) new_paddr = seWorkload->allocPhysPages(1); // Read from old physical page. uint8_t buf_p[pTable->pageSize()]; SETranslatingPortProxy(old_tc).readBlob(vaddr, buf_p, sizeof(buf_p)); // Create new mapping in process address space by clobbering existing // mapping (if any existed) and then write to the new physical page. bool clobber = true; pTable->map(vaddr, new_paddr, sizeof(buf_p), clobber); SETranslatingPortProxy(new_tc).writeBlob(vaddr, buf_p, sizeof(buf_p)); } bool Process::fixupFault(Addr vaddr) { return memState->fixupFault(vaddr); } void Process::serialize(CheckpointOut &cp) const { memState->serialize(cp); pTable->serialize(cp); fds->serialize(cp); /** * Checkpoints for pipes, device drivers or sockets currently * do not work. Need to come back and fix them at a later date. */ warn("Checkpoints for pipes, device drivers and sockets do not work."); } void Process::unserialize(CheckpointIn &cp) { memState->unserialize(cp); pTable->unserialize(cp); fds->unserialize(cp, this); /** * Checkpoints for pipes, device drivers or sockets currently * do not work. Need to come back and fix them at a later date. */ warn("Checkpoints for pipes, device drivers and sockets do not work."); // The above returns a bool so that you could do something if you don't // find the param in the checkpoint if you wanted to, like set a default // but in this case we'll just stick with the instantiated value if not // found. } bool Process::map(Addr vaddr, Addr paddr, int64_t size, bool cacheable) { pTable->map(vaddr, paddr, size, cacheable ? EmulationPageTable::MappingFlags(0) : EmulationPageTable::Uncacheable); return true; } EmulatedDriver * Process::findDriver(std::string filename) { for (EmulatedDriver *d : drivers) { if (d->match(filename)) return d; } return nullptr; } std::string Process::checkPathRedirect(const std::string &filename) { // If the input parameter contains a relative path, convert it. // The target version of the current working directory is fine since // we immediately convert it using redirect paths into a host version. auto abs_path = absolutePath(filename, false); for (auto path : system->redirectPaths) { // Search through the redirect paths to see if a starting substring of // our path falls into any buckets which need to redirected. if (startswith(abs_path, path->appPath())) { std::string tail = abs_path.substr(path->appPath().size()); // If this path needs to be redirected, search through a list // of targets to see if we can match a valid file (or directory). for (auto host_path : path->hostPaths()) { if (access((host_path + tail).c_str(), R_OK) == 0) { // Return the valid match. return host_path + tail; } } // The path needs to be redirected, but the file or directory // does not exist on the host filesystem. Return the first // host path as a default. return path->hostPaths()[0] + tail; } } // The path does not need to be redirected. return abs_path; } void Process::updateBias() { auto *interp = objFile->getInterpreter(); if (!interp || !interp->relocatable()) return; // Determine how large the interpreters footprint will be in the process // address space. Addr interp_mapsize = roundUp(interp->mapSize(), pTable->pageSize()); // We are allocating the memory area; set the bias to the lowest address // in the allocated memory region. Addr mmap_end = memState->getMmapEnd(); Addr ld_bias = mmapGrowsDown() ? mmap_end - interp_mapsize : mmap_end; // Adjust the process mmap area to give the interpreter room; the real // execve system call would just invoke the kernel's internal mmap // functions to make these adjustments. mmap_end = mmapGrowsDown() ? ld_bias : mmap_end + interp_mapsize; memState->setMmapEnd(mmap_end); interp->updateBias(ld_bias); } loader::ObjectFile * Process::getInterpreter() { return objFile->getInterpreter(); } Addr Process::getBias() { auto *interp = getInterpreter(); return interp ? interp->bias() : objFile->bias(); } Addr Process::getStartPC() { auto *interp = getInterpreter(); return interp ? interp->entryPoint() : objFile->entryPoint(); } std::string Process::absolutePath(const std::string &filename, bool host_filesystem) { if (filename.empty() || startswith(filename, "/")) return filename; // Construct the absolute path given the current working directory for // either the host filesystem or target filesystem. The distinction only // matters if filesystem redirection is utilized in the simulation. auto path_base = std::string(); if (host_filesystem) { path_base = hostCwd; assert(!hostCwd.empty()); } else { path_base = tgtCwd; assert(!tgtCwd.empty()); } // Add a trailing '/' if the current working directory did not have one. path_base = normalize(path_base); // Append the filename onto the current working path. auto absolute_path = path_base + filename; return absolute_path; } Process * ProcessParams::create() const { // If not specified, set the executable parameter equal to the // simulated system's zeroth command line parameter const std::string &exec = (executable == "") ? cmd[0] : executable; auto *obj_file = loader::createObjectFile(exec); fatal_if(!obj_file, "Cannot load object file %s.", exec); Process *process = Process::tryLoaders(*this, obj_file); fatal_if(!process, "Unknown error creating process object."); return process; } } // namespace gem5