llvm-project/lldb/source/Breakpoint/Watchpoint.cpp

Ignoring revisions in .git-blame-ignore-revs. Click here to bypass and see the normal blame view.

390 lines
13 KiB
C++
Raw Normal View History

//===-- Watchpoint.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 "lldb/Breakpoint/Watchpoint.h"
#include "lldb/Breakpoint/StoppointCallbackContext.h"
#include "lldb/Core/Value.h"
#include "lldb/Core/ValueObject.h"
#include "lldb/Core/ValueObjectMemory.h"
This patch makes Clang-independent base classes for all the expression types that lldb currently vends. Before we had: ClangFunction ClangUtilityFunction ClangUserExpression and code all over in lldb that explicitly made Clang-based expressions. This patch adds an Expression base class, and three pure virtual implementations for the Expression kinds: FunctionCaller UtilityFunction UserExpression You can request one of these expression types from the Target using the Get<ExpressionType>ForLanguage. The Target will then consult all the registered TypeSystem plugins, and if the type system that matches the language can make an expression of that kind, it will do so and return it. Because all of the real expression types need to communicate with their ExpressionParser in a uniform way, I also added a ExpressionTypeSystemHelper class that expressions generically can vend, and a ClangExpressionHelper that encapsulates the operations that the ClangExpressionParser needs to perform on the ClangExpression types. Then each of the Clang* expression kinds constructs the appropriate helper to do what it needs. The patch also fixes a wart in the UtilityFunction that to use it you had to create a parallel FunctionCaller to actually call the function made by the UtilityFunction. Now the UtilityFunction can be asked to vend a FunctionCaller that will run its function. This cleaned up a lot of boiler plate code using UtilityFunctions. Note, in this patch all the expression types explicitly depend on the LLVM JIT and IR, and all the common JIT running code is in the FunctionCaller etc base classes. At some point we could also abstract that dependency but I don't see us adding another back end in the near term, so I'll leave that exercise till it is actually necessary. llvm-svn: 247720
2015-09-16 05:13:50 +08:00
#include "lldb/Expression/UserExpression.h"
#include "lldb/Symbol/TypeSystem.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/Target.h"
#include "lldb/Target/ThreadSpec.h"
#include "lldb/Utility/Log.h"
#include "lldb/Utility/Stream.h"
using namespace lldb;
using namespace lldb_private;
Watchpoint::Watchpoint(Target &target, lldb::addr_t addr, uint32_t size,
const CompilerType *type, bool hardware)
: StoppointSite(0, addr, size, hardware), m_target(target),
m_enabled(false), m_is_hardware(hardware), m_is_watch_variable(false),
m_is_ephemeral(false), m_disabled_count(0), m_watch_read(0),
m_watch_write(0), m_watch_was_read(0), m_watch_was_written(0),
m_ignore_count(0), m_false_alarms(0), m_decl_str(), m_watch_spec_str(),
m_type(), m_error(), m_options(), m_being_created(true) {
if (type && type->IsValid())
m_type = *type;
else {
// If we don't have a known type, then we force it to unsigned int of the
// right size.
auto type_system_or_err =
target.GetScratchTypeSystemForLanguage(eLanguageTypeC);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(
lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_WATCHPOINTS),
std::move(err), "Failed to set type.");
} else {
m_type = type_system_or_err->GetBuiltinTypeForEncodingAndBitSize(
eEncodingUint, 8 * size);
}
}
// Set the initial value of the watched variable:
if (m_target.GetProcessSP()) {
ExecutionContext exe_ctx;
m_target.GetProcessSP()->CalculateExecutionContext(exe_ctx);
CaptureWatchedValue(exe_ctx);
}
m_being_created = false;
}
Watchpoint::~Watchpoint() = default;
// This function is used when "baton" doesn't need to be freed
void Watchpoint::SetCallback(WatchpointHitCallback callback, void *baton,
bool is_synchronous) {
// The default "Baton" class will keep a copy of "baton" and won't free or
// delete it when it goes goes out of scope.
m_options.SetCallback(callback, std::make_shared<UntypedBaton>(baton),
is_synchronous);
SendWatchpointChangedEvent(eWatchpointEventTypeCommandChanged);
}
// This function is used when a baton needs to be freed and therefore is
// contained in a "Baton" subclass.
void Watchpoint::SetCallback(WatchpointHitCallback callback,
const BatonSP &callback_baton_sp,
bool is_synchronous) {
m_options.SetCallback(callback, callback_baton_sp, is_synchronous);
SendWatchpointChangedEvent(eWatchpointEventTypeCommandChanged);
}
void Watchpoint::ClearCallback() {
m_options.ClearCallback();
SendWatchpointChangedEvent(eWatchpointEventTypeCommandChanged);
}
void Watchpoint::SetDeclInfo(const std::string &str) { m_decl_str = str; }
std::string Watchpoint::GetWatchSpec() { return m_watch_spec_str; }
void Watchpoint::SetWatchSpec(const std::string &str) {
m_watch_spec_str = str;
}
bool Watchpoint::IsHardware() const {
lldbassert(m_is_hardware || !HardwareRequired());
return m_is_hardware;
}
bool Watchpoint::IsWatchVariable() const { return m_is_watch_variable; }
void Watchpoint::SetWatchVariable(bool val) { m_is_watch_variable = val; }
bool Watchpoint::CaptureWatchedValue(const ExecutionContext &exe_ctx) {
ConstString watch_name("$__lldb__watch_value");
m_old_value_sp = m_new_value_sp;
Address watch_address(GetLoadAddress());
if (!m_type.IsValid()) {
// Don't know how to report new & old values, since we couldn't make a
// scalar type for this watchpoint. This works around an assert in
// ValueObjectMemory::Create.
// FIXME: This should not happen, but if it does in some case we care about,
// we can go grab the value raw and print it as unsigned.
return false;
}
m_new_value_sp = ValueObjectMemory::Create(
exe_ctx.GetBestExecutionContextScope(), watch_name.GetStringRef(),
watch_address, m_type);
m_new_value_sp = m_new_value_sp->CreateConstantValue(watch_name);
return (m_new_value_sp && m_new_value_sp->GetError().Success());
}
void Watchpoint::IncrementFalseAlarmsAndReviseHitCount() {
++m_false_alarms;
if (m_false_alarms) {
if (m_hit_counter.GetValue() >= m_false_alarms) {
m_hit_counter.Decrement(m_false_alarms);
m_false_alarms = 0;
} else {
m_false_alarms -= m_hit_counter.GetValue();
m_hit_counter.Reset();
}
}
}
// RETURNS - true if we should stop at this breakpoint, false if we
// should continue.
bool Watchpoint::ShouldStop(StoppointCallbackContext *context) {
m_hit_counter.Increment();
return IsEnabled();
}
void Watchpoint::GetDescription(Stream *s, lldb::DescriptionLevel level) {
DumpWithLevel(s, level);
}
void Watchpoint::Dump(Stream *s) const {
DumpWithLevel(s, lldb::eDescriptionLevelBrief);
}
// If prefix is nullptr, we display the watch id and ignore the prefix
// altogether.
void Watchpoint::DumpSnapshots(Stream *s, const char *prefix) const {
if (!prefix) {
s->Printf("\nWatchpoint %u hit:", GetID());
prefix = "";
}
if (m_old_value_sp) {
const char *old_value_cstr = m_old_value_sp->GetValueAsCString();
if (old_value_cstr && old_value_cstr[0])
s->Printf("\n%sold value: %s", prefix, old_value_cstr);
else {
const char *old_summary_cstr = m_old_value_sp->GetSummaryAsCString();
if (old_summary_cstr && old_summary_cstr[0])
s->Printf("\n%sold value: %s", prefix, old_summary_cstr);
}
}
if (m_new_value_sp) {
const char *new_value_cstr = m_new_value_sp->GetValueAsCString();
if (new_value_cstr && new_value_cstr[0])
s->Printf("\n%snew value: %s", prefix, new_value_cstr);
else {
const char *new_summary_cstr = m_new_value_sp->GetSummaryAsCString();
if (new_summary_cstr && new_summary_cstr[0])
s->Printf("\n%snew value: %s", prefix, new_summary_cstr);
}
}
}
void Watchpoint::DumpWithLevel(Stream *s,
lldb::DescriptionLevel description_level) const {
if (s == nullptr)
return;
assert(description_level >= lldb::eDescriptionLevelBrief &&
description_level <= lldb::eDescriptionLevelVerbose);
s->Printf("Watchpoint %u: addr = 0x%8.8" PRIx64
" size = %u state = %s type = %s%s",
GetID(), GetLoadAddress(), m_byte_size,
IsEnabled() ? "enabled" : "disabled", m_watch_read ? "r" : "",
m_watch_write ? "w" : "");
if (description_level >= lldb::eDescriptionLevelFull) {
if (!m_decl_str.empty())
s->Printf("\n declare @ '%s'", m_decl_str.c_str());
if (!m_watch_spec_str.empty())
s->Printf("\n watchpoint spec = '%s'", m_watch_spec_str.c_str());
// Dump the snapshots we have taken.
DumpSnapshots(s, " ");
if (GetConditionText())
s->Printf("\n condition = '%s'", GetConditionText());
m_options.GetCallbackDescription(s, description_level);
}
if (description_level >= lldb::eDescriptionLevelVerbose) {
s->Printf("\n hw_index = %i hit_count = %-4u ignore_count = %-4u",
GetHardwareIndex(), GetHitCount(), GetIgnoreCount());
}
}
bool Watchpoint::IsEnabled() const { return m_enabled; }
// Within StopInfo.cpp, we purposely turn on the ephemeral mode right before
// temporarily disable the watchpoint in order to perform possible watchpoint
// actions without triggering further watchpoint events. After the temporary
// disabled watchpoint is enabled, we then turn off the ephemeral mode.
void Watchpoint::TurnOnEphemeralMode() { m_is_ephemeral = true; }
void Watchpoint::TurnOffEphemeralMode() {
m_is_ephemeral = false;
// Leaving ephemeral mode, reset the m_disabled_count!
m_disabled_count = 0;
}
bool Watchpoint::IsDisabledDuringEphemeralMode() {
return m_disabled_count > 1 && m_is_ephemeral;
}
void Watchpoint::SetEnabled(bool enabled, bool notify) {
if (!enabled) {
if (!m_is_ephemeral)
SetHardwareIndex(LLDB_INVALID_INDEX32);
else
++m_disabled_count;
// Don't clear the snapshots for now.
// Within StopInfo.cpp, we purposely do disable/enable watchpoint while
// performing watchpoint actions.
}
bool changed = enabled != m_enabled;
m_enabled = enabled;
if (notify && !m_is_ephemeral && changed)
SendWatchpointChangedEvent(enabled ? eWatchpointEventTypeEnabled
: eWatchpointEventTypeDisabled);
}
void Watchpoint::SetWatchpointType(uint32_t type, bool notify) {
int old_watch_read = m_watch_read;
int old_watch_write = m_watch_write;
m_watch_read = (type & LLDB_WATCH_TYPE_READ) != 0;
m_watch_write = (type & LLDB_WATCH_TYPE_WRITE) != 0;
if (notify &&
(old_watch_read != m_watch_read || old_watch_write != m_watch_write))
SendWatchpointChangedEvent(eWatchpointEventTypeTypeChanged);
}
bool Watchpoint::WatchpointRead() const { return m_watch_read != 0; }
bool Watchpoint::WatchpointWrite() const { return m_watch_write != 0; }
uint32_t Watchpoint::GetIgnoreCount() const { return m_ignore_count; }
void Watchpoint::SetIgnoreCount(uint32_t n) {
bool changed = m_ignore_count != n;
m_ignore_count = n;
if (changed)
SendWatchpointChangedEvent(eWatchpointEventTypeIgnoreChanged);
}
bool Watchpoint::InvokeCallback(StoppointCallbackContext *context) {
return m_options.InvokeCallback(context, GetID());
}
void Watchpoint::SetCondition(const char *condition) {
if (condition == nullptr || condition[0] == '\0') {
if (m_condition_up)
m_condition_up.reset();
} else {
// Pass nullptr for expr_prefix (no translation-unit level definitions).
Status error;
m_condition_up.reset(m_target.GetUserExpressionForLanguage(
condition, llvm::StringRef(), lldb::eLanguageTypeUnknown,
UserExpression::eResultTypeAny, EvaluateExpressionOptions(), nullptr,
error));
This patch makes Clang-independent base classes for all the expression types that lldb currently vends. Before we had: ClangFunction ClangUtilityFunction ClangUserExpression and code all over in lldb that explicitly made Clang-based expressions. This patch adds an Expression base class, and three pure virtual implementations for the Expression kinds: FunctionCaller UtilityFunction UserExpression You can request one of these expression types from the Target using the Get<ExpressionType>ForLanguage. The Target will then consult all the registered TypeSystem plugins, and if the type system that matches the language can make an expression of that kind, it will do so and return it. Because all of the real expression types need to communicate with their ExpressionParser in a uniform way, I also added a ExpressionTypeSystemHelper class that expressions generically can vend, and a ClangExpressionHelper that encapsulates the operations that the ClangExpressionParser needs to perform on the ClangExpression types. Then each of the Clang* expression kinds constructs the appropriate helper to do what it needs. The patch also fixes a wart in the UtilityFunction that to use it you had to create a parallel FunctionCaller to actually call the function made by the UtilityFunction. Now the UtilityFunction can be asked to vend a FunctionCaller that will run its function. This cleaned up a lot of boiler plate code using UtilityFunctions. Note, in this patch all the expression types explicitly depend on the LLVM JIT and IR, and all the common JIT running code is in the FunctionCaller etc base classes. At some point we could also abstract that dependency but I don't see us adding another back end in the near term, so I'll leave that exercise till it is actually necessary. llvm-svn: 247720
2015-09-16 05:13:50 +08:00
if (error.Fail()) {
// FIXME: Log something...
m_condition_up.reset();
}
}
SendWatchpointChangedEvent(eWatchpointEventTypeConditionChanged);
}
const char *Watchpoint::GetConditionText() const {
if (m_condition_up)
return m_condition_up->GetUserText();
else
return nullptr;
}
void Watchpoint::SendWatchpointChangedEvent(
lldb::WatchpointEventType eventKind) {
if (!m_being_created &&
GetTarget().EventTypeHasListeners(
Target::eBroadcastBitWatchpointChanged)) {
WatchpointEventData *data =
new Watchpoint::WatchpointEventData(eventKind, shared_from_this());
GetTarget().BroadcastEvent(Target::eBroadcastBitWatchpointChanged, data);
}
}
void Watchpoint::SendWatchpointChangedEvent(WatchpointEventData *data) {
if (data == nullptr)
return;
if (!m_being_created &&
GetTarget().EventTypeHasListeners(Target::eBroadcastBitWatchpointChanged))
GetTarget().BroadcastEvent(Target::eBroadcastBitWatchpointChanged, data);
else
delete data;
}
Watchpoint::WatchpointEventData::WatchpointEventData(
WatchpointEventType sub_type, const WatchpointSP &new_watchpoint_sp)
: EventData(), m_watchpoint_event(sub_type),
m_new_watchpoint_sp(new_watchpoint_sp) {}
Watchpoint::WatchpointEventData::~WatchpointEventData() = default;
ConstString Watchpoint::WatchpointEventData::GetFlavorString() {
static ConstString g_flavor("Watchpoint::WatchpointEventData");
return g_flavor;
}
ConstString Watchpoint::WatchpointEventData::GetFlavor() const {
return WatchpointEventData::GetFlavorString();
}
WatchpointSP &Watchpoint::WatchpointEventData::GetWatchpoint() {
return m_new_watchpoint_sp;
}
WatchpointEventType
Watchpoint::WatchpointEventData::GetWatchpointEventType() const {
return m_watchpoint_event;
}
void Watchpoint::WatchpointEventData::Dump(Stream *s) const {}
const Watchpoint::WatchpointEventData *
Watchpoint::WatchpointEventData::GetEventDataFromEvent(const Event *event) {
if (event) {
const EventData *event_data = event->GetData();
if (event_data &&
event_data->GetFlavor() == WatchpointEventData::GetFlavorString())
return static_cast<const WatchpointEventData *>(event->GetData());
}
return nullptr;
}
WatchpointEventType
Watchpoint::WatchpointEventData::GetWatchpointEventTypeFromEvent(
const EventSP &event_sp) {
const WatchpointEventData *data = GetEventDataFromEvent(event_sp.get());
if (data == nullptr)
return eWatchpointEventTypeInvalidType;
else
return data->GetWatchpointEventType();
}
WatchpointSP Watchpoint::WatchpointEventData::GetWatchpointFromEvent(
const EventSP &event_sp) {
WatchpointSP wp_sp;
const WatchpointEventData *data = GetEventDataFromEvent(event_sp.get());
if (data)
wp_sp = data->m_new_watchpoint_sp;
return wp_sp;
}