// Copyright 2017 The Crashpad Authors // // 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 "util/linux/ptracer.h" #include #include #include #include #include #include "base/logging.h" #include "build/build_config.h" #include "util/misc/from_pointer_cast.h" #if defined(ARCH_CPU_X86_FAMILY) #include #endif namespace crashpad { namespace { #if defined(ARCH_CPU_X86_FAMILY) template bool GetRegisterSet(pid_t tid, int set, Destination* dest, bool can_log) { iovec iov; iov.iov_base = dest; iov.iov_len = sizeof(*dest); if (ptrace(PTRACE_GETREGSET, tid, reinterpret_cast(set), &iov) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } if (iov.iov_len != sizeof(*dest)) { LOG_IF(ERROR, can_log) << "Unexpected registers size " << iov.iov_len << " != " << sizeof(*dest); return false; } return true; } bool GetFloatingPointRegisters32(pid_t tid, FloatContext* context, bool can_log) { return GetRegisterSet(tid, NT_PRXFPREG, &context->f32.fxsave, can_log); } bool GetFloatingPointRegisters64(pid_t tid, FloatContext* context, bool can_log) { return GetRegisterSet(tid, NT_PRFPREG, &context->f64.fxsave, can_log); } bool GetThreadArea32(pid_t tid, const ThreadContext& context, LinuxVMAddress* address, bool can_log) { size_t index = (context.t32.xgs & 0xffff) >> 3; user_desc desc; if (ptrace( PTRACE_GET_THREAD_AREA, tid, reinterpret_cast(index), &desc) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } *address = desc.base_addr; return true; } bool GetThreadArea64(pid_t tid, const ThreadContext& context, LinuxVMAddress* address, bool can_log) { *address = context.t64.fs_base; return true; } #elif defined(ARCH_CPU_ARM_FAMILY) #if defined(ARCH_CPU_ARMEL) // PTRACE_GETREGSET, introduced in Linux 2.6.34 (2225a122ae26), requires kernel // support enabled by HAVE_ARCH_TRACEHOOK. This has been set for x86 (including // x86_64) since Linux 2.6.28 (99bbc4b1e677a), but for ARM only since // Linux 3.5.0 (0693bf68148c4). Older Linux kernels support PTRACE_GETREGS, // PTRACE_GETFPREGS, and PTRACE_GETVFPREGS instead, which don't allow checking // the size of data copied. // // Fortunately, 64-bit ARM support only appeared in Linux 3.7.0, so if // PTRACE_GETREGSET fails on ARM with EIO, indicating that the request is not // supported, the kernel must be old enough that 64-bit ARM isn’t supported // either. // // TODO(mark): Once helpers to interpret the kernel version are available, add // a DCHECK to ensure that the kernel is older than 3.5. bool GetGeneralPurposeRegistersLegacy(pid_t tid, ThreadContext* context, bool can_log) { if (ptrace(PTRACE_GETREGS, tid, nullptr, &context->t32) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } return true; } bool GetFloatingPointRegistersLegacy(pid_t tid, FloatContext* context, bool can_log) { if (ptrace(PTRACE_GETFPREGS, tid, nullptr, &context->f32.fpregs) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } context->f32.have_fpregs = true; if (ptrace(PTRACE_GETVFPREGS, tid, nullptr, &context->f32.vfp) != 0) { switch (errno) { case EINVAL: // These registers are optional on 32-bit ARM cpus break; default: PLOG_IF(ERROR, can_log) << "ptrace"; return false; } } else { context->f32.have_vfp = true; } return true; } #endif // ARCH_CPU_ARMEL // Normally, the Linux kernel will copy out register sets according to the size // of the struct that contains them. Tracing a 32-bit ARM process running in // compatibility mode on a 64-bit ARM cpu will only copy data for the number of // registers times the size of the register, which won't include any possible // trailing padding in the struct. These are the sizes of the register data, not // including any possible padding. constexpr size_t kArmVfpSize = 32 * 8 + 4; // Target is 32-bit bool GetFloatingPointRegisters32(pid_t tid, FloatContext* context, bool can_log) { context->f32.have_fpregs = false; context->f32.have_vfp = false; iovec iov; iov.iov_base = &context->f32.fpregs; iov.iov_len = sizeof(context->f32.fpregs); if (ptrace( PTRACE_GETREGSET, tid, reinterpret_cast(NT_PRFPREG), &iov) != 0) { switch (errno) { #if defined(ARCH_CPU_ARMEL) case EIO: return GetFloatingPointRegistersLegacy(tid, context, can_log); #endif // ARCH_CPU_ARMEL case EINVAL: // A 32-bit process running on a 64-bit CPU doesn't have this register // set. It should have a VFP register set instead. break; default: PLOG_IF(ERROR, can_log) << "ptrace"; return false; } } else { if (iov.iov_len != sizeof(context->f32.fpregs)) { LOG_IF(ERROR, can_log) << "Unexpected registers size " << iov.iov_len << " != " << sizeof(context->f32.fpregs); return false; } context->f32.have_fpregs = true; } iov.iov_base = &context->f32.vfp; iov.iov_len = sizeof(context->f32.vfp); if (ptrace( PTRACE_GETREGSET, tid, reinterpret_cast(NT_ARM_VFP), &iov) != 0) { switch (errno) { case EINVAL: // VFP may not be present on 32-bit ARM cpus. break; default: PLOG_IF(ERROR, can_log) << "ptrace"; return false; } } else { if (iov.iov_len != kArmVfpSize && iov.iov_len != sizeof(context->f32.vfp)) { LOG_IF(ERROR, can_log) << "Unexpected registers size " << iov.iov_len << " != " << sizeof(context->f32.vfp); return false; } context->f32.have_vfp = true; } if (!(context->f32.have_fpregs || context->f32.have_vfp)) { LOG_IF(ERROR, can_log) << "Unable to collect registers"; return false; } return true; } bool GetFloatingPointRegisters64(pid_t tid, FloatContext* context, bool can_log) { iovec iov; iov.iov_base = context; iov.iov_len = sizeof(*context); if (ptrace( PTRACE_GETREGSET, tid, reinterpret_cast(NT_PRFPREG), &iov) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } if (iov.iov_len != sizeof(context->f64)) { LOG_IF(ERROR, can_log) << "Unexpected registers size " << iov.iov_len << " != " << sizeof(context->f64); return false; } return true; } bool GetThreadArea32(pid_t tid, const ThreadContext& context, LinuxVMAddress* address, bool can_log) { #if defined(ARCH_CPU_ARMEL) void* result; if (ptrace(PTRACE_GET_THREAD_AREA, tid, nullptr, &result) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } *address = FromPointerCast(result); return true; #else // TODO(jperaza): it doesn't look like there is a way for a 64-bit ARM process // to get the thread area for a 32-bit ARM process with ptrace. LOG_IF(WARNING, can_log) << "64-bit ARM cannot trace TLS area for a 32-bit process"; return false; #endif // ARCH_CPU_ARMEL } bool GetThreadArea64(pid_t tid, const ThreadContext& context, LinuxVMAddress* address, bool can_log) { iovec iov; iov.iov_base = address; iov.iov_len = sizeof(*address); if (ptrace( PTRACE_GETREGSET, tid, reinterpret_cast(NT_ARM_TLS), &iov) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } if (iov.iov_len != 8) { LOG_IF(ERROR, can_log) << "address size mismatch"; return false; } return true; } #elif defined(ARCH_CPU_MIPS_FAMILY) // PTRACE_GETREGSET, introduced in Linux 2.6.34 (2225a122ae26), requires kernel // support enabled by HAVE_ARCH_TRACEHOOK. This has been set for x86 (including // x86_64) since Linux 2.6.28 (99bbc4b1e677a), but for MIPS only since // Linux 3.13 (c0ff3c53d4f99). Older Linux kernels support PTRACE_GETREGS, // and PTRACE_GETFPREGS instead, which don't allow checking the size of data // copied. Also, PTRACE_GETREGS assumes register size of 64 bits even for 32 bit // MIPS CPU (contrary to PTRACE_GETREGSET behavior), so we need buffer // structure here. bool GetGeneralPurposeRegistersLegacy(pid_t tid, ThreadContext* context, bool can_log) { ThreadContext context_buffer; if (ptrace(PTRACE_GETREGS, tid, nullptr, &context_buffer.t64) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } // Bitness of target process can't be determined through ptrace here, so we // assume target process has the same as current process, making cross-bit // ptrace unsupported on MIPS for kernels older than 3.13 #if defined(ARCH_CPU_MIPSEL) #define THREAD_CONTEXT_FIELD t32 #elif defined(ARCH_CPU_MIPS64EL) #define THREAD_CONTEXT_FIELD t64 #endif for (size_t reg = 0; reg < 32; ++reg) { context->THREAD_CONTEXT_FIELD.regs[reg] = context_buffer.t64.regs[reg]; } context->THREAD_CONTEXT_FIELD.lo = context_buffer.t64.lo; context->THREAD_CONTEXT_FIELD.hi = context_buffer.t64.hi; context->THREAD_CONTEXT_FIELD.cp0_epc = context_buffer.t64.cp0_epc; context->THREAD_CONTEXT_FIELD.cp0_badvaddr = context_buffer.t64.cp0_badvaddr; context->THREAD_CONTEXT_FIELD.cp0_status = context_buffer.t64.cp0_status; context->THREAD_CONTEXT_FIELD.cp0_cause = context_buffer.t64.cp0_cause; #undef THREAD_CONTEXT_FIELD return true; } bool GetFloatingPointRegistersLegacy(pid_t tid, FloatContext* context, bool can_log) { if (ptrace(PTRACE_GETFPREGS, tid, nullptr, &context->f32.fpregs) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } return true; } bool GetFloatingPointRegisters32(pid_t tid, FloatContext* context, bool can_log) { iovec iov; iov.iov_base = &context->f32.fpregs; iov.iov_len = sizeof(context->f32.fpregs); if (ptrace(PTRACE_GETFPREGS, tid, nullptr, &context->f32.fpregs) != 0) { switch (errno) { case EINVAL: // fp may not be present break; case EIO: return GetFloatingPointRegistersLegacy(tid, context, can_log); default: PLOG_IF(ERROR, can_log) << "ptrace"; return false; } } return true; } bool GetFloatingPointRegisters64(pid_t tid, FloatContext* context, bool can_log) { iovec iov; iov.iov_base = &context->f64.fpregs; iov.iov_len = sizeof(context->f64.fpregs); if (ptrace(PTRACE_GETFPREGS, tid, nullptr, &context->f64.fpregs) != 0) { switch (errno) { case EINVAL: // fp may not be present break; case EIO: return GetFloatingPointRegistersLegacy(tid, context, can_log); default: PLOG_IF(ERROR, can_log) << "ptrace"; return false; } } return true; } bool GetThreadArea32(pid_t tid, const ThreadContext& context, LinuxVMAddress* address, bool can_log) { #if defined(ARCH_CPU_MIPSEL) void* result; if (ptrace(PTRACE_GET_THREAD_AREA, tid, nullptr, &result) != 0) { PLOG_IF(ERROR, can_log) << "ptrace"; return false; } *address = FromPointerCast(result); return true; #else return false; #endif } bool GetThreadArea64(pid_t tid, const ThreadContext& context, LinuxVMAddress* address, bool can_log) { void* result; #if defined(ARCH_CPU_MIPSEL) if (ptrace(PTRACE_GET_THREAD_AREA_3264, tid, nullptr, &result) != 0) { #else if (ptrace(PTRACE_GET_THREAD_AREA, tid, nullptr, &result) != 0) { #endif PLOG_IF(ERROR, can_log) << "ptrace"; return false; } *address = FromPointerCast(result); return true; } #else #error Port. #endif // ARCH_CPU_X86_FAMILY size_t GetGeneralPurposeRegistersAndLength(pid_t tid, ThreadContext* context, bool can_log) { iovec iov; iov.iov_base = context; iov.iov_len = sizeof(*context); if (ptrace( PTRACE_GETREGSET, tid, reinterpret_cast(NT_PRSTATUS), &iov) != 0) { switch (errno) { #if defined(ARCH_CPU_ARMEL) || defined(ARCH_CPU_MIPS_FAMILY) case EIO: return GetGeneralPurposeRegistersLegacy(tid, context, can_log) ? sizeof(context->t32) : 0; #endif // ARCH_CPU_ARMEL default: PLOG_IF(ERROR, can_log) << "ptrace"; return 0; } } return iov.iov_len; } bool GetGeneralPurposeRegisters32(pid_t tid, ThreadContext* context, bool can_log) { size_t length = GetGeneralPurposeRegistersAndLength(tid, context, can_log); if (length != sizeof(context->t32)) { LOG_IF(ERROR, can_log) << "Unexpected registers size " << length << " != " << sizeof(context->t32); return false; } return true; } bool GetGeneralPurposeRegisters64(pid_t tid, ThreadContext* context, bool can_log) { size_t length = GetGeneralPurposeRegistersAndLength(tid, context, can_log); if (length != sizeof(context->t64)) { LOG_IF(ERROR, can_log) << "Unexpected registers size " << length << " != " << sizeof(context->t64); return false; } return true; } } // namespace Ptracer::Ptracer(bool can_log) : is_64_bit_(false), can_log_(can_log), initialized_() {} Ptracer::Ptracer(bool is_64_bit, bool can_log) : is_64_bit_(is_64_bit), can_log_(can_log), initialized_() { INITIALIZATION_STATE_SET_INITIALIZING(initialized_); INITIALIZATION_STATE_SET_VALID(initialized_); } Ptracer::~Ptracer() {} bool Ptracer::Initialize(pid_t pid) { INITIALIZATION_STATE_SET_INITIALIZING(initialized_); ThreadContext context; size_t length = GetGeneralPurposeRegistersAndLength(pid, &context, can_log_); if (length == sizeof(context.t64)) { is_64_bit_ = true; } else if (length == sizeof(context.t32)) { is_64_bit_ = false; } else { LOG_IF(ERROR, can_log_) << "Unexpected registers size " << length << " != " << sizeof(context.t64) << ", " << sizeof(context.t32); return false; } INITIALIZATION_STATE_SET_VALID(initialized_); return true; } bool Ptracer::Is64Bit() { INITIALIZATION_STATE_DCHECK_VALID(initialized_); return is_64_bit_; } bool Ptracer::GetThreadInfo(pid_t tid, ThreadInfo* info) { INITIALIZATION_STATE_DCHECK_VALID(initialized_); if (is_64_bit_) { return GetGeneralPurposeRegisters64(tid, &info->thread_context, can_log_) && GetFloatingPointRegisters64(tid, &info->float_context, can_log_) && GetThreadArea64(tid, info->thread_context, &info->thread_specific_data_address, can_log_); } return GetGeneralPurposeRegisters32(tid, &info->thread_context, can_log_) && GetFloatingPointRegisters32(tid, &info->float_context, can_log_) && GetThreadArea32(tid, info->thread_context, &info->thread_specific_data_address, can_log_); } ssize_t Ptracer::ReadUpTo(pid_t pid, LinuxVMAddress address, size_t size, char* buffer) { size_t bytes_read = 0; while (size > 0) { errno = 0; if (size >= sizeof(long)) { *reinterpret_cast(buffer) = ptrace(PTRACE_PEEKDATA, pid, address, nullptr); if (errno == EIO) { ssize_t last_bytes = ReadLastBytes(pid, address, size, buffer); return last_bytes >= 0 ? bytes_read + last_bytes : -1; } if (errno != 0) { PLOG_IF(ERROR, can_log_) << "ptrace"; return -1; } size -= sizeof(long); buffer += sizeof(long); address += sizeof(long); bytes_read += sizeof(long); } else { long word = ptrace(PTRACE_PEEKDATA, pid, address, nullptr); if (errno == 0) { memcpy(buffer, reinterpret_cast(&word), size); return bytes_read + size; } if (errno == EIO) { ssize_t last_bytes = ReadLastBytes(pid, address, size, buffer); return last_bytes >= 0 ? bytes_read + last_bytes : -1; } PLOG_IF(ERROR, can_log_); return -1; } } return bytes_read; } // Handles an EIO by reading at most size bytes from address into buffer if // address was within a word of a possible page boundary, by aligning to read // the last word of the page and extracting the desired bytes. ssize_t Ptracer::ReadLastBytes(pid_t pid, LinuxVMAddress address, size_t size, char* buffer) { LinuxVMAddress aligned = ((address + 4095) & ~4095) - sizeof(long); if (aligned >= address || aligned == address - sizeof(long)) { PLOG_IF(ERROR, can_log_) << "ptrace"; return -1; } DCHECK_GT(aligned, address - sizeof(long)); errno = 0; long word = ptrace(PTRACE_PEEKDATA, pid, aligned, nullptr); if (errno != 0) { PLOG_IF(ERROR, can_log_) << "ptrace"; return -1; } size_t bytes_read = address - aligned; size_t last_bytes = std::min(sizeof(long) - bytes_read, size); memcpy(buffer, reinterpret_cast(&word) + bytes_read, last_bytes); return last_bytes; } } // namespace crashpad