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pigweed / pigweed / pigweed / 3bfceac6441a13bebd7c2de6017ffc5a04807e44 / . / pw_cpu_exception_cortex_m / util.cc
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// Copyright 2022 The Pigweed 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
//
// https://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 "pw_cpu_exception_cortex_m/util.h"
#include <cinttypes>
#include "pw_cpu_exception_cortex_m/cpu_state.h"
#include "pw_cpu_exception_cortex_m_private/config.h"
#include "pw_cpu_exception_cortex_m_private/cortex_m_constants.h"
#include "pw_log/log.h"
#include "pw_preprocessor/arch.h"
namespace pw::cpu_exception::cortex_m {
namespace {
[[maybe_unused]] void LogCfsrAnalysis(const uint32_t cfsr) {
if (cfsr == 0) {
return;
}
PW_LOG_INFO("Active CFSR fields:");
// Memory managment fault fields.
if (cfsr & kCfsrIaccviolMask) {
PW_LOG_ERROR(" IACCVIOL: MPU violation on instruction fetch");
}
if (cfsr & kCfsrDaccviolMask) {
PW_LOG_ERROR(" DACCVIOL: MPU violation on memory read/write");
}
if (cfsr & kCfsrMunstkerrMask) {
PW_LOG_ERROR(" MUNSTKERR: 'MPU violation on exception return");
}
if (cfsr & kCfsrMstkerrMask) {
PW_LOG_ERROR(" MSTKERR: MPU violation on exception entry");
}
if (cfsr & kCfsrMlsperrMask) {
PW_LOG_ERROR(" MLSPERR: MPU violation on lazy FPU state preservation");
}
if (cfsr & kCfsrMmarvalidMask) {
PW_LOG_ERROR(" MMARVALID: MMFAR register is valid");
}
// Bus fault fields.
if (cfsr & kCfsrIbuserrMask) {
PW_LOG_ERROR(" IBUSERR: Bus fault on instruction fetch");
}
if (cfsr & kCfsrPreciserrMask) {
PW_LOG_ERROR(" PRECISERR: Precise bus fault");
}
if (cfsr & kCfsrImpreciserrMask) {
PW_LOG_ERROR(" IMPRECISERR: Imprecise bus fault");
}
if (cfsr & kCfsrUnstkerrMask) {
PW_LOG_ERROR(" UNSTKERR: Derived bus fault on exception context save");
}
if (cfsr & kCfsrStkerrMask) {
PW_LOG_ERROR(" STKERR: Derived bus fault on exception context restore");
}
if (cfsr & kCfsrLsperrMask) {
PW_LOG_ERROR(" LSPERR: Derived bus fault on lazy FPU state preservation");
}
if (cfsr & kCfsrBfarvalidMask) {
PW_LOG_ERROR(" BFARVALID: BFAR register is valid");
}
// Usage fault fields.
if (cfsr & kCfsrUndefinstrMask) {
PW_LOG_ERROR(" UNDEFINSTR: Encountered invalid instruction");
}
if (cfsr & kCfsrInvstateMask) {
PW_LOG_ERROR(
" INVSTATE: Attempted to execute an instruction with an invalid "
"Execution Program Status Register (EPSR) value");
}
if (cfsr & kCfsrInvpcMask) {
PW_LOG_ERROR(" INVPC: Program Counter (PC) is not legal");
}
if (cfsr & kCfsrNocpMask) {
PW_LOG_ERROR(" NOCP: Coprocessor disabled or not present");
}
if (cfsr & kCfsrUnalignedMask) {
PW_LOG_ERROR(" UNALIGNED: Unaligned memory access");
}
if (cfsr & kCfsrDivbyzeroMask) {
PW_LOG_ERROR(" DIVBYZERO: Division by zero");
}
#if _PW_ARCH_ARM_V8M_MAINLINE
if (cfsr & kCfsrStkofMask) {
PW_LOG_ERROR(" STKOF: Stack overflowed");
}
#endif // _PW_ARCH_ARM_V8M_MAINLINE
}
} // namespace
void LogExceptionAnalysis(const pw_cpu_exception_State& cpu_state) {
// This provides a high-level assessment of the cause of the exception.
// These conditionals are ordered by priority to ensure the most critical
// issues are highlighted first. These are not mutually exclusive; a bus fault
// could occur during the handling of a MPU violation, causing a nested fault.
if (cpu_state.extended.hfsr & kHfsrForcedMask) {
PW_LOG_CRITICAL("Encountered a nested CPU fault (See active CFSR fields)");
}
#if _PW_ARCH_ARM_V8M_MAINLINE
if (cpu_state.extended.cfsr & kCfsrStkofMask) {
if (ProcessStackActive(cpu_state)) {
PW_LOG_CRITICAL("Encountered process stack overflow (psp)");
} else {
PW_LOG_CRITICAL("Encountered main stack overflow (msp)");
}
}
#endif // _PW_ARCH_ARM_V8M_MAINLINE
if (cpu_state.extended.cfsr & kCfsrMemFaultMask) {
if (cpu_state.extended.cfsr & kCfsrMmarvalidMask) {
PW_LOG_CRITICAL(
"Encountered Memory Protection Unit (MPU) violation at 0x%08" PRIx32,
cpu_state.extended.mmfar);
} else {
PW_LOG_CRITICAL("Encountered Memory Protection Unit (MPU) violation");
}
}
if (cpu_state.extended.cfsr & kCfsrBusFaultMask) {
if (cpu_state.extended.cfsr & kCfsrBfarvalidMask) {
PW_LOG_CRITICAL("Encountered bus fault at 0x%08" PRIx32,
cpu_state.extended.bfar);
} else {
PW_LOG_CRITICAL("Encountered bus fault");
}
}
if (cpu_state.extended.cfsr & kCfsrUsageFaultMask) {
PW_LOG_CRITICAL("Encountered usage fault (See active CFSR fields)");
}
if ((cpu_state.extended.icsr & kIcsrVectactiveMask) == kNmiIsrNum) {
PW_LOG_INFO("Encountered non-maskable interrupt (NMI)");
}
#if PW_CPU_EXCEPTION_CORTEX_M_EXTENDED_CFSR_DUMP
LogCfsrAnalysis(cpu_state.extended.cfsr);
#endif // PW_CPU_EXCEPTION_CORTEX_M_EXTENDED_CFSR_DUMP
}
ProcessorMode ActiveProcessorMode(const pw_cpu_exception_State& cpu_state) {
// See ARMv7-M Architecture Reference Manual Section B1.5.8 for the exception
// return values, in particular bits 0:3.
// Bits 0:3 of EXC_RETURN:
// 0b0001 - 0x1 Handler mode Main
// 0b1001 - 0x9 Thread mode Main
// 0b1101 - 0xD Thread mode Process
// ^
if (cpu_state.extended.exc_return & kExcReturnModeMask) {
return ProcessorMode::kThreadMode;
}
return ProcessorMode::kHandlerMode;
}
bool MainStackActive(const pw_cpu_exception_State& cpu_state) {
// See ARMv7-M Architecture Reference Manual Section B1.5.8 for the exception
// return values, in particular bits 0:3.
// Bits 0:3 of EXC_RETURN:
// 0b0001 - 0x1 Handler mode Main
// 0b1001 - 0x9 Thread mode Main
// 0b1101 - 0xD Thread mode Process
// ^
return (cpu_state.extended.exc_return & kExcReturnStackMask) == 0;
}
} // namespace pw::cpu_exception::cortex_m