//===-- NativeRegisterContextDBReg_arm64.cpp ------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "NativeRegisterContextDBReg_arm64.h" #include "lldb/Utility/LLDBLog.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/RegisterValue.h" using namespace lldb_private; // E (bit 0), used to enable breakpoint/watchpoint constexpr uint32_t g_enable_bit = 1; // PAC (bits 2:1): 0b10 constexpr uint32_t g_pac_bits = (2 << 1); // Returns appropriate control register bits for the specified size static constexpr inline uint64_t GetSizeBits(int size) { // BAS (bits 12:5) hold a bit-mask of addresses to watch // e.g. 0b00000001 means 1 byte at address // 0b00000011 means 2 bytes (addr..addr+1) // ... // 0b11111111 means 8 bytes (addr..addr+7) return ((1 << size) - 1) << 5; } uint32_t NativeRegisterContextDBReg_arm64::NumSupportedHardwareBreakpoints() { Log *log = GetLog(LLDBLog::Breakpoints); llvm::Error error = ReadHardwareDebugInfo(); if (error) { LLDB_LOG_ERROR(log, std::move(error), "failed to read debug registers: {0}"); return 0; } return m_max_hbp_supported; } uint32_t NativeRegisterContextDBReg_arm64::SetHardwareBreakpoint(lldb::addr_t addr, size_t size) { Log *log = GetLog(LLDBLog::Breakpoints); LLDB_LOG(log, "addr: {0:x}, size: {1:x}", addr, size); // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) { LLDB_LOG_ERROR( log, std::move(error), "unable to set breakpoint: failed to read debug registers: {0}"); return LLDB_INVALID_INDEX32; } uint32_t control_value = 0, bp_index = 0; // Check if size has a valid hardware breakpoint length. if (size != 4) return LLDB_INVALID_INDEX32; // Invalid size for a AArch64 hardware // breakpoint // Check 4-byte alignment for hardware breakpoint target address. if (addr & 0x03) return LLDB_INVALID_INDEX32; // Invalid address, should be 4-byte aligned. // Setup control value control_value = g_enable_bit | g_pac_bits | GetSizeBits(size); // Iterate over stored breakpoints and find a free bp_index bp_index = LLDB_INVALID_INDEX32; for (uint32_t i = 0; i < m_max_hbp_supported; i++) { if (!BreakpointIsEnabled(i)) bp_index = i; // Mark last free slot else if (m_hbp_regs[i].address == addr) return LLDB_INVALID_INDEX32; // We do not support duplicate breakpoints. } if (bp_index == LLDB_INVALID_INDEX32) return LLDB_INVALID_INDEX32; // Update breakpoint in local cache m_hbp_regs[bp_index].real_addr = addr; m_hbp_regs[bp_index].address = addr; m_hbp_regs[bp_index].control = control_value; // PTRACE call to set corresponding hardware breakpoint register. error = WriteHardwareDebugRegs(eDREGTypeBREAK); if (error) { m_hbp_regs[bp_index].address = 0; m_hbp_regs[bp_index].control &= ~1; LLDB_LOG_ERROR( log, std::move(error), "unable to set breakpoint: failed to write debug registers: {0}"); return LLDB_INVALID_INDEX32; } return bp_index; } bool NativeRegisterContextDBReg_arm64::ClearHardwareBreakpoint( uint32_t hw_idx) { Log *log = GetLog(LLDBLog::Breakpoints); LLDB_LOG(log, "hw_idx: {0}", hw_idx); // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) { LLDB_LOG_ERROR( log, std::move(error), "unable to clear breakpoint: failed to read debug registers: {0}"); return false; } if (hw_idx >= m_max_hbp_supported) return false; // Create a backup we can revert to in case of failure. lldb::addr_t tempAddr = m_hbp_regs[hw_idx].address; uint32_t tempControl = m_hbp_regs[hw_idx].control; m_hbp_regs[hw_idx].control &= ~g_enable_bit; m_hbp_regs[hw_idx].address = 0; // PTRACE call to clear corresponding hardware breakpoint register. error = WriteHardwareDebugRegs(eDREGTypeBREAK); if (error) { m_hbp_regs[hw_idx].control = tempControl; m_hbp_regs[hw_idx].address = tempAddr; LLDB_LOG_ERROR( log, std::move(error), "unable to clear breakpoint: failed to write debug registers: {0}"); return false; } return true; } Status NativeRegisterContextDBReg_arm64::GetHardwareBreakHitIndex( uint32_t &bp_index, lldb::addr_t trap_addr) { Log *log = GetLog(LLDBLog::Breakpoints); LLDB_LOGF(log, "NativeRegisterContextDBReg_arm64::%s()", __FUNCTION__); lldb::addr_t break_addr; for (bp_index = 0; bp_index < m_max_hbp_supported; ++bp_index) { break_addr = m_hbp_regs[bp_index].address; if (BreakpointIsEnabled(bp_index) && trap_addr == break_addr) { m_hbp_regs[bp_index].hit_addr = trap_addr; return Status(); } } bp_index = LLDB_INVALID_INDEX32; return Status(); } Status NativeRegisterContextDBReg_arm64::ClearAllHardwareBreakpoints() { Log *log = GetLog(LLDBLog::Breakpoints); LLDB_LOGF(log, "NativeRegisterContextDBReg_arm64::%s()", __FUNCTION__); // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) return Status(std::move(error)); for (uint32_t i = 0; i < m_max_hbp_supported; i++) { if (BreakpointIsEnabled(i)) { // Create a backup we can revert to in case of failure. lldb::addr_t tempAddr = m_hbp_regs[i].address; uint32_t tempControl = m_hbp_regs[i].control; // Clear watchpoints in local cache m_hbp_regs[i].control &= ~g_enable_bit; m_hbp_regs[i].address = 0; // Ptrace call to update hardware debug registers error = WriteHardwareDebugRegs(eDREGTypeBREAK); if (error) { m_hbp_regs[i].control = tempControl; m_hbp_regs[i].address = tempAddr; return Status(std::move(error)); } } } return Status(); } bool NativeRegisterContextDBReg_arm64::BreakpointIsEnabled(uint32_t bp_index) { if ((m_hbp_regs[bp_index].control & g_enable_bit) != 0) return true; else return false; } uint32_t NativeRegisterContextDBReg_arm64::NumSupportedHardwareWatchpoints() { Log *log = GetLog(LLDBLog::Watchpoints); llvm::Error error = ReadHardwareDebugInfo(); if (error) { LLDB_LOG_ERROR(log, std::move(error), "failed to read debug registers: {0}"); return 0; } return m_max_hwp_supported; } uint32_t NativeRegisterContextDBReg_arm64::SetHardwareWatchpoint( lldb::addr_t addr, size_t size, uint32_t watch_flags) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "addr: {0:x}, size: {1:x} watch_flags: {2:x}", addr, size, watch_flags); // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) { LLDB_LOG_ERROR( log, std::move(error), "unable to set watchpoint: failed to read debug registers: {0}"); return LLDB_INVALID_INDEX32; } uint32_t control_value = 0, wp_index = 0; lldb::addr_t real_addr = addr; // Check if we are setting watchpoint other than read/write/access Also // update watchpoint flag to match AArch64 write-read bit configuration. switch (watch_flags) { case 1: watch_flags = 2; break; case 2: watch_flags = 1; break; case 3: break; default: return LLDB_INVALID_INDEX32; } // Check if size has a valid hardware watchpoint length. if (size != 1 && size != 2 && size != 4 && size != 8) return LLDB_INVALID_INDEX32; // Check 8-byte alignment for hardware watchpoint target address. Below is a // hack to recalculate address and size in order to make sure we can watch // non 8-byte aligned addresses as well. if (addr & 0x07) { uint8_t watch_mask = (addr & 0x07) + size; if (watch_mask > 0x08) return LLDB_INVALID_INDEX32; else if (watch_mask <= 0x02) size = 2; else if (watch_mask <= 0x04) size = 4; else size = 8; addr = addr & (~0x07); } // Setup control value control_value = g_enable_bit | g_pac_bits | GetSizeBits(size); control_value |= watch_flags << 3; // Iterate over stored watchpoints and find a free wp_index wp_index = LLDB_INVALID_INDEX32; for (uint32_t i = 0; i < m_max_hwp_supported; i++) { if (!WatchpointIsEnabled(i)) wp_index = i; // Mark last free slot else if (m_hwp_regs[i].address == addr) { return LLDB_INVALID_INDEX32; // We do not support duplicate watchpoints. } } if (wp_index == LLDB_INVALID_INDEX32) return LLDB_INVALID_INDEX32; // Update watchpoint in local cache m_hwp_regs[wp_index].real_addr = real_addr; m_hwp_regs[wp_index].address = addr; m_hwp_regs[wp_index].control = control_value; // PTRACE call to set corresponding watchpoint register. error = WriteHardwareDebugRegs(eDREGTypeWATCH); if (error) { m_hwp_regs[wp_index].address = 0; m_hwp_regs[wp_index].control &= ~g_enable_bit; LLDB_LOG_ERROR( log, std::move(error), "unable to set watchpoint: failed to write debug registers: {0}"); return LLDB_INVALID_INDEX32; } return wp_index; } bool NativeRegisterContextDBReg_arm64::ClearHardwareWatchpoint( uint32_t wp_index) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "wp_index: {0}", wp_index); // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) { LLDB_LOG_ERROR( log, std::move(error), "unable to clear watchpoint: failed to read debug registers: {0}"); return false; } if (wp_index >= m_max_hwp_supported) return false; // Create a backup we can revert to in case of failure. lldb::addr_t tempAddr = m_hwp_regs[wp_index].address; uint32_t tempControl = m_hwp_regs[wp_index].control; // Update watchpoint in local cache m_hwp_regs[wp_index].control &= ~g_enable_bit; m_hwp_regs[wp_index].address = 0; // Ptrace call to update hardware debug registers error = WriteHardwareDebugRegs(eDREGTypeWATCH); if (error) { m_hwp_regs[wp_index].control = tempControl; m_hwp_regs[wp_index].address = tempAddr; LLDB_LOG_ERROR( log, std::move(error), "unable to clear watchpoint: failed to write debug registers: {0}"); return false; } return true; } Status NativeRegisterContextDBReg_arm64::ClearAllHardwareWatchpoints() { // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) return Status(std::move(error)); for (uint32_t i = 0; i < m_max_hwp_supported; i++) { if (WatchpointIsEnabled(i)) { // Create a backup we can revert to in case of failure. lldb::addr_t tempAddr = m_hwp_regs[i].address; uint32_t tempControl = m_hwp_regs[i].control; // Clear watchpoints in local cache m_hwp_regs[i].control &= ~g_enable_bit; m_hwp_regs[i].address = 0; // Ptrace call to update hardware debug registers error = WriteHardwareDebugRegs(eDREGTypeWATCH); if (error) { m_hwp_regs[i].control = tempControl; m_hwp_regs[i].address = tempAddr; return Status(std::move(error)); } } } return Status(); } uint32_t NativeRegisterContextDBReg_arm64::GetWatchpointSize(uint32_t wp_index) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "wp_index: {0}", wp_index); switch ((m_hwp_regs[wp_index].control >> 5) & 0xff) { case 0x01: return 1; case 0x03: return 2; case 0x0f: return 4; case 0xff: return 8; default: return 0; } } bool NativeRegisterContextDBReg_arm64::WatchpointIsEnabled(uint32_t wp_index) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "wp_index: {0}", wp_index); if ((m_hwp_regs[wp_index].control & g_enable_bit) != 0) return true; else return false; } Status NativeRegisterContextDBReg_arm64::GetWatchpointHitIndex( uint32_t &wp_index, lldb::addr_t trap_addr) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "wp_index: {0}, trap_addr: {1:x}", wp_index, trap_addr); // Read hardware breakpoint and watchpoint information. llvm::Error error = ReadHardwareDebugInfo(); if (error) return Status(std::move(error)); // Mask off ignored bits from watchpoint trap address. trap_addr = FixWatchpointHitAddress(trap_addr); uint32_t watch_size; lldb::addr_t watch_addr; for (wp_index = 0; wp_index < m_max_hwp_supported; ++wp_index) { watch_size = GetWatchpointSize(wp_index); watch_addr = m_hwp_regs[wp_index].address; if (WatchpointIsEnabled(wp_index) && trap_addr >= watch_addr && trap_addr < watch_addr + watch_size) { m_hwp_regs[wp_index].hit_addr = trap_addr; return Status(); } } wp_index = LLDB_INVALID_INDEX32; return Status(); } lldb::addr_t NativeRegisterContextDBReg_arm64::GetWatchpointAddress(uint32_t wp_index) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "wp_index: {0}", wp_index); if (wp_index >= m_max_hwp_supported) return LLDB_INVALID_ADDRESS; if (WatchpointIsEnabled(wp_index)) return m_hwp_regs[wp_index].real_addr; return LLDB_INVALID_ADDRESS; } lldb::addr_t NativeRegisterContextDBReg_arm64::GetWatchpointHitAddress(uint32_t wp_index) { Log *log = GetLog(LLDBLog::Watchpoints); LLDB_LOG(log, "wp_index: {0}", wp_index); if (wp_index >= m_max_hwp_supported) return LLDB_INVALID_ADDRESS; if (WatchpointIsEnabled(wp_index)) return m_hwp_regs[wp_index].hit_addr; return LLDB_INVALID_ADDRESS; }