// Copyright 2017 The Crashpad Authors. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "snapshot/linux/thread_snapshot_linux.h" #include #include "base/logging.h" #include "snapshot/linux/cpu_context_linux.h" #include "util/misc/reinterpret_bytes.h" namespace crashpad { namespace internal { namespace { int ComputeThreadPriority(int static_priority, int sched_policy, int nice_value) { // Map Linux scheduling policy, static priority, and nice value into a // single int value. // // The possible policies in order of approximate priority (low to high) are // SCHED_IDLE // SCHED_BATCH // SCHED_OTHER // SCHED_RR // SCHED_FIFO // // static_priority is not used for OTHER, BATCH, or IDLE and should be 0. // For FIFO and RR, static_priority should range from 1 to 99 with 99 being // the highest priority. // // nice value ranges from -20 to 19, with -20 being highest priority enum class Policy : uint8_t { kUnknown = 0, kIdle, kBatch, kOther, kRR, kFIFO }; struct LinuxPriority { #if defined(ARCH_CPU_LITTLE_ENDIAN) // nice values affect how dynamic priorities are updated, which only // matters for threads with the same static priority. uint8_t nice_value = 0; // The scheduling policy also affects how threads with the same static // priority are ordered, but has greater impact than nice value. Policy policy = Policy::kUnknown; // The static priority is the most significant in determining overall // priority. uint8_t static_priority = 0; // Put this in the most significant byte position to prevent negative // priorities. uint8_t unused = 0; #elif defined(ARCH_CPU_BIG_ENDIAN) uint8_t unused = 0; uint8_t static_priority = 0; Policy policy = Policy::kUnknown; uint8_t nice_value = 0; #endif // ARCH_CPU_LITTLE_ENDIAN }; static_assert(sizeof(LinuxPriority) <= sizeof(int), "priority is too large"); LinuxPriority prio; // Lower nice values have higher priority, so negate them and add 20 to put // them in the range 1-40 with 40 being highest priority. if (nice_value < -20 || nice_value > 19) { LOG(WARNING) << "invalid nice value " << nice_value; prio.nice_value = 0; } else { prio.nice_value = -1 * nice_value + 20; } switch (sched_policy) { case SCHED_IDLE: prio.policy = Policy::kIdle; break; case SCHED_BATCH: prio.policy = Policy::kBatch; break; case SCHED_OTHER: prio.policy = Policy::kOther; break; case SCHED_RR: prio.policy = Policy::kRR; break; case SCHED_FIFO: prio.policy = Policy::kFIFO; break; default: prio.policy = Policy::kUnknown; LOG(WARNING) << "Unknown scheduling policy " << sched_policy; } if (static_priority < 0 || static_priority > 99) { LOG(WARNING) << "invalid static priority " << static_priority; } prio.static_priority = static_priority; int priority; if (!ReinterpretBytes(prio, &priority)) { LOG(ERROR) << "Couldn't set priority"; return -1; } return priority; } } // namespace ThreadSnapshotLinux::ThreadSnapshotLinux() : ThreadSnapshot(), context_union_(), context_(), stack_(), thread_specific_data_address_(0), thread_id_(-1), priority_(-1), initialized_() {} ThreadSnapshotLinux::~ThreadSnapshotLinux() {} bool ThreadSnapshotLinux::Initialize(ProcessReaderLinux* process_reader, const ProcessReaderLinux::Thread& thread) { INITIALIZATION_STATE_SET_INITIALIZING(initialized_); #if defined(ARCH_CPU_X86_FAMILY) if (process_reader->Is64Bit()) { context_.architecture = kCPUArchitectureX86_64; context_.x86_64 = &context_union_.x86_64; InitializeCPUContextX86_64(thread.thread_info.thread_context.t64, thread.thread_info.float_context.f64, context_.x86_64); } else { context_.architecture = kCPUArchitectureX86; context_.x86 = &context_union_.x86; InitializeCPUContextX86(thread.thread_info.thread_context.t32, thread.thread_info.float_context.f32, context_.x86); } #elif defined(ARCH_CPU_ARM_FAMILY) if (process_reader->Is64Bit()) { context_.architecture = kCPUArchitectureARM64; context_.arm64 = &context_union_.arm64; InitializeCPUContextARM64(thread.thread_info.thread_context.t64, thread.thread_info.float_context.f64, context_.arm64); } else { context_.architecture = kCPUArchitectureARM; context_.arm = &context_union_.arm; InitializeCPUContextARM(thread.thread_info.thread_context.t32, thread.thread_info.float_context.f32, context_.arm); } #elif defined(ARCH_CPU_MIPS_FAMILY) if (process_reader->Is64Bit()) { context_.architecture = kCPUArchitectureMIPS64EL; context_.mips64 = &context_union_.mips64; InitializeCPUContextMIPS( thread.thread_info.thread_context.t64, thread.thread_info.float_context.f64, context_.mips64); } else { context_.architecture = kCPUArchitectureMIPSEL; context_.mipsel = &context_union_.mipsel; InitializeCPUContextMIPS( SignalThreadContext32(thread.thread_info.thread_context.t32), thread.thread_info.float_context.f32, context_.mipsel); } #else #error Port. #endif stack_.Initialize(process_reader->Memory(), thread.stack_region_address, thread.stack_region_size); thread_specific_data_address_ = thread.thread_info.thread_specific_data_address; thread_id_ = thread.tid; priority_ = thread.have_priorities ? ComputeThreadPriority( thread.static_priority, thread.sched_policy, thread.nice_value) : -1; INITIALIZATION_STATE_SET_VALID(initialized_); return true; } const CPUContext* ThreadSnapshotLinux::Context() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return &context_; } const MemorySnapshot* ThreadSnapshotLinux::Stack() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return &stack_; } uint64_t ThreadSnapshotLinux::ThreadID() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return thread_id_; } int ThreadSnapshotLinux::SuspendCount() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return 0; } int ThreadSnapshotLinux::Priority() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return priority_; } uint64_t ThreadSnapshotLinux::ThreadSpecificDataAddress() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return thread_specific_data_address_; } std::vector ThreadSnapshotLinux::ExtraMemory() const { return std::vector(); } } // namespace internal } // namespace crashpad