llvm-project/lldb/source/Target/ThreadPlanStack.cpp

509 lines
15 KiB
C++

//===-- ThreadPlanStack.cpp -------------------------------------*- C++ -*-===//
//
// 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/Target/ThreadPlanStack.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/Target.h"
#include "lldb/Target/Thread.h"
#include "lldb/Target/ThreadPlan.h"
#include "lldb/Utility/Log.h"
using namespace lldb;
using namespace lldb_private;
static void PrintPlanElement(Stream &s, const ThreadPlanSP &plan,
lldb::DescriptionLevel desc_level,
int32_t elem_idx) {
s.IndentMore();
s.Indent();
s.Printf("Element %d: ", elem_idx);
plan->GetDescription(&s, desc_level);
s.EOL();
s.IndentLess();
}
ThreadPlanStack::ThreadPlanStack(const Thread &thread, bool make_null) {
if (make_null) {
// The ThreadPlanNull doesn't do anything to the Thread, so this is actually
// still a const operation.
m_plans.push_back(
ThreadPlanSP(new ThreadPlanNull(const_cast<Thread &>(thread))));
}
}
void ThreadPlanStack::DumpThreadPlans(Stream &s,
lldb::DescriptionLevel desc_level,
bool include_internal) const {
s.IndentMore();
PrintOneStack(s, "Active plan stack", m_plans, desc_level, include_internal);
PrintOneStack(s, "Completed plan stack", m_completed_plans, desc_level,
include_internal);
PrintOneStack(s, "Discarded plan stack", m_discarded_plans, desc_level,
include_internal);
s.IndentLess();
}
void ThreadPlanStack::PrintOneStack(Stream &s, llvm::StringRef stack_name,
const PlanStack &stack,
lldb::DescriptionLevel desc_level,
bool include_internal) const {
// If the stack is empty, just exit:
if (stack.empty())
return;
// Make sure there are public completed plans:
bool any_public = false;
if (!include_internal) {
for (auto plan : stack) {
if (!plan->GetPrivate()) {
any_public = true;
break;
}
}
}
if (include_internal || any_public) {
int print_idx = 0;
s.Indent();
s << stack_name << ":\n";
for (auto plan : stack) {
if (!include_internal && plan->GetPrivate())
continue;
PrintPlanElement(s, plan, desc_level, print_idx++);
}
}
}
size_t ThreadPlanStack::CheckpointCompletedPlans() {
m_completed_plan_checkpoint++;
m_completed_plan_store.insert(
std::make_pair(m_completed_plan_checkpoint, m_completed_plans));
return m_completed_plan_checkpoint;
}
void ThreadPlanStack::RestoreCompletedPlanCheckpoint(size_t checkpoint) {
auto result = m_completed_plan_store.find(checkpoint);
assert(result != m_completed_plan_store.end() &&
"Asked for a checkpoint that didn't exist");
m_completed_plans.swap((*result).second);
m_completed_plan_store.erase(result);
}
void ThreadPlanStack::DiscardCompletedPlanCheckpoint(size_t checkpoint) {
m_completed_plan_store.erase(checkpoint);
}
void ThreadPlanStack::ThreadDestroyed(Thread *thread) {
// Tell the plan stacks that this thread is going away:
for (ThreadPlanSP plan : m_plans)
plan->ThreadDestroyed();
for (ThreadPlanSP plan : m_discarded_plans)
plan->ThreadDestroyed();
for (ThreadPlanSP plan : m_completed_plans)
plan->ThreadDestroyed();
// Now clear the current plan stacks:
m_plans.clear();
m_discarded_plans.clear();
m_completed_plans.clear();
// Push a ThreadPlanNull on the plan stack. That way we can continue
// assuming that the plan stack is never empty, but if somebody errantly asks
// questions of a destroyed thread without checking first whether it is
// destroyed, they won't crash.
if (thread != nullptr) {
lldb::ThreadPlanSP null_plan_sp(new ThreadPlanNull(*thread));
m_plans.push_back(null_plan_sp);
}
}
void ThreadPlanStack::EnableTracer(bool value, bool single_stepping) {
for (ThreadPlanSP plan : m_plans) {
if (plan->GetThreadPlanTracer()) {
plan->GetThreadPlanTracer()->EnableTracing(value);
plan->GetThreadPlanTracer()->EnableSingleStep(single_stepping);
}
}
}
void ThreadPlanStack::SetTracer(lldb::ThreadPlanTracerSP &tracer_sp) {
for (ThreadPlanSP plan : m_plans)
plan->SetThreadPlanTracer(tracer_sp);
}
void ThreadPlanStack::PushPlan(lldb::ThreadPlanSP new_plan_sp) {
// If the thread plan doesn't already have a tracer, give it its parent's
// tracer:
// The first plan has to be a base plan:
assert((m_plans.size() > 0 || new_plan_sp->IsBasePlan()) &&
"Zeroth plan must be a base plan");
if (!new_plan_sp->GetThreadPlanTracer()) {
assert(!m_plans.empty());
new_plan_sp->SetThreadPlanTracer(m_plans.back()->GetThreadPlanTracer());
}
m_plans.push_back(new_plan_sp);
new_plan_sp->DidPush();
}
lldb::ThreadPlanSP ThreadPlanStack::PopPlan() {
assert(m_plans.size() > 1 && "Can't pop the base thread plan");
lldb::ThreadPlanSP plan_sp = std::move(m_plans.back());
m_completed_plans.push_back(plan_sp);
plan_sp->WillPop();
m_plans.pop_back();
return plan_sp;
}
lldb::ThreadPlanSP ThreadPlanStack::DiscardPlan() {
assert(m_plans.size() > 1 && "Can't discard the base thread plan");
lldb::ThreadPlanSP plan_sp = std::move(m_plans.back());
m_discarded_plans.push_back(plan_sp);
plan_sp->WillPop();
m_plans.pop_back();
return plan_sp;
}
// If the input plan is nullptr, discard all plans. Otherwise make sure this
// plan is in the stack, and if so discard up to and including it.
void ThreadPlanStack::DiscardPlansUpToPlan(ThreadPlan *up_to_plan_ptr) {
int stack_size = m_plans.size();
if (up_to_plan_ptr == nullptr) {
for (int i = stack_size - 1; i > 0; i--)
DiscardPlan();
return;
}
bool found_it = false;
for (int i = stack_size - 1; i > 0; i--) {
if (m_plans[i].get() == up_to_plan_ptr) {
found_it = true;
break;
}
}
if (found_it) {
bool last_one = false;
for (int i = stack_size - 1; i > 0 && !last_one; i--) {
if (GetCurrentPlan().get() == up_to_plan_ptr)
last_one = true;
DiscardPlan();
}
}
}
void ThreadPlanStack::DiscardAllPlans() {
int stack_size = m_plans.size();
for (int i = stack_size - 1; i > 0; i--) {
DiscardPlan();
}
return;
}
void ThreadPlanStack::DiscardConsultingMasterPlans() {
while (true) {
int master_plan_idx;
bool discard = true;
// Find the first master plan, see if it wants discarding, and if yes
// discard up to it.
for (master_plan_idx = m_plans.size() - 1; master_plan_idx >= 0;
master_plan_idx--) {
if (m_plans[master_plan_idx]->IsMasterPlan()) {
discard = m_plans[master_plan_idx]->OkayToDiscard();
break;
}
}
// If the master plan doesn't want to get discarded, then we're done.
if (!discard)
return;
// First pop all the dependent plans:
for (int i = m_plans.size() - 1; i > master_plan_idx; i--) {
DiscardPlan();
}
// Now discard the master plan itself.
// The bottom-most plan never gets discarded. "OkayToDiscard" for it
// means discard it's dependent plans, but not it...
if (master_plan_idx > 0) {
DiscardPlan();
}
}
}
lldb::ThreadPlanSP ThreadPlanStack::GetCurrentPlan() const {
assert(m_plans.size() != 0 && "There will always be a base plan.");
return m_plans.back();
}
lldb::ThreadPlanSP ThreadPlanStack::GetCompletedPlan(bool skip_private) const {
if (m_completed_plans.empty())
return {};
if (!skip_private)
return m_completed_plans.back();
for (int i = m_completed_plans.size() - 1; i >= 0; i--) {
lldb::ThreadPlanSP completed_plan_sp;
completed_plan_sp = m_completed_plans[i];
if (!completed_plan_sp->GetPrivate())
return completed_plan_sp;
}
return {};
}
lldb::ThreadPlanSP ThreadPlanStack::GetPlanByIndex(uint32_t plan_idx,
bool skip_private) const {
uint32_t idx = 0;
for (lldb::ThreadPlanSP plan_sp : m_plans) {
if (skip_private && plan_sp->GetPrivate())
continue;
if (idx == plan_idx)
return plan_sp;
idx++;
}
return {};
}
lldb::ValueObjectSP ThreadPlanStack::GetReturnValueObject() const {
if (m_completed_plans.empty())
return {};
for (int i = m_completed_plans.size() - 1; i >= 0; i--) {
lldb::ValueObjectSP return_valobj_sp;
return_valobj_sp = m_completed_plans[i]->GetReturnValueObject();
if (return_valobj_sp)
return return_valobj_sp;
}
return {};
}
lldb::ExpressionVariableSP ThreadPlanStack::GetExpressionVariable() const {
if (m_completed_plans.empty())
return {};
for (int i = m_completed_plans.size() - 1; i >= 0; i--) {
lldb::ExpressionVariableSP expression_variable_sp;
expression_variable_sp = m_completed_plans[i]->GetExpressionVariable();
if (expression_variable_sp)
return expression_variable_sp;
}
return {};
}
bool ThreadPlanStack::AnyPlans() const {
// There is always a base plan...
return m_plans.size() > 1;
}
bool ThreadPlanStack::AnyCompletedPlans() const {
return !m_completed_plans.empty();
}
bool ThreadPlanStack::AnyDiscardedPlans() const {
return !m_discarded_plans.empty();
}
bool ThreadPlanStack::IsPlanDone(ThreadPlan *in_plan) const {
for (auto plan : m_completed_plans) {
if (plan.get() == in_plan)
return true;
}
return false;
}
bool ThreadPlanStack::WasPlanDiscarded(ThreadPlan *in_plan) const {
for (auto plan : m_discarded_plans) {
if (plan.get() == in_plan)
return true;
}
return false;
}
ThreadPlan *ThreadPlanStack::GetPreviousPlan(ThreadPlan *current_plan) const {
if (current_plan == nullptr)
return nullptr;
// Look first in the completed plans, if the plan is here and there is
// a completed plan above it, return that.
int stack_size = m_completed_plans.size();
for (int i = stack_size - 1; i > 0; i--) {
if (current_plan == m_completed_plans[i].get())
return m_completed_plans[i - 1].get();
}
// If this is the first completed plan, the previous one is the
// bottom of the regular plan stack.
if (stack_size > 0 && m_completed_plans[0].get() == current_plan) {
return GetCurrentPlan().get();
}
// Otherwise look for it in the regular plans.
stack_size = m_plans.size();
for (int i = stack_size - 1; i > 0; i--) {
if (current_plan == m_plans[i].get())
return m_plans[i - 1].get();
}
return nullptr;
}
ThreadPlan *ThreadPlanStack::GetInnermostExpression() const {
int stack_size = m_plans.size();
for (int i = stack_size - 1; i > 0; i--) {
if (m_plans[i]->GetKind() == ThreadPlan::eKindCallFunction)
return m_plans[i].get();
}
return nullptr;
}
void ThreadPlanStack::WillResume() {
m_completed_plans.clear();
m_discarded_plans.clear();
}
const ThreadPlanStack::PlanStack &
ThreadPlanStack::GetStackOfKind(ThreadPlanStack::StackKind kind) const {
switch (kind) {
case ePlans:
return m_plans;
case eCompletedPlans:
return m_completed_plans;
case eDiscardedPlans:
return m_discarded_plans;
}
llvm_unreachable("Invalid StackKind value");
}
void ThreadPlanStackMap::Update(ThreadList &current_threads,
bool delete_missing,
bool check_for_new) {
// Now find all the new threads and add them to the map:
if (check_for_new) {
for (auto thread : current_threads.Threads()) {
lldb::tid_t cur_tid = thread->GetID();
if (!Find(cur_tid)) {
AddThread(*thread.get());
thread->QueueFundamentalPlan(true);
}
}
}
// If we aren't reaping missing threads at this point,
// we are done.
if (!delete_missing)
return;
// Otherwise scan for absent TID's.
std::vector<lldb::tid_t> missing_threads;
// If we are going to delete plans from the plan stack,
// then scan for absent TID's:
for (auto thread_plans : m_plans_list) {
lldb::tid_t cur_tid = thread_plans.first;
ThreadSP thread_sp = current_threads.FindThreadByID(cur_tid);
if (!thread_sp)
missing_threads.push_back(cur_tid);
}
for (lldb::tid_t tid : missing_threads) {
RemoveTID(tid);
}
}
void ThreadPlanStackMap::DumpPlans(Stream &strm,
lldb::DescriptionLevel desc_level,
bool internal, bool condense_if_trivial,
bool skip_unreported) {
for (auto elem : m_plans_list) {
lldb::tid_t tid = elem.first;
uint32_t index_id = 0;
ThreadSP thread_sp = m_process.GetThreadList().FindThreadByID(tid);
if (skip_unreported) {
if (!thread_sp)
continue;
}
if (thread_sp)
index_id = thread_sp->GetIndexID();
if (condense_if_trivial) {
if (!elem.second.AnyPlans() && !elem.second.AnyCompletedPlans() &&
!elem.second.AnyDiscardedPlans()) {
strm.Printf("thread #%u: tid = 0x%4.4" PRIx64 "\n", index_id, tid);
strm.IndentMore();
strm.Indent();
strm.Printf("No active thread plans\n");
strm.IndentLess();
return;
}
}
strm.Indent();
strm.Printf("thread #%u: tid = 0x%4.4" PRIx64 ":\n", index_id, tid);
elem.second.DumpThreadPlans(strm, desc_level, internal);
}
}
bool ThreadPlanStackMap::DumpPlansForTID(Stream &strm, lldb::tid_t tid,
lldb::DescriptionLevel desc_level,
bool internal,
bool condense_if_trivial,
bool skip_unreported) {
uint32_t index_id = 0;
ThreadSP thread_sp = m_process.GetThreadList().FindThreadByID(tid);
if (skip_unreported) {
if (!thread_sp) {
strm.Format("Unknown TID: {0}", tid);
return false;
}
}
if (thread_sp)
index_id = thread_sp->GetIndexID();
ThreadPlanStack *stack = Find(tid);
if (!stack) {
strm.Format("Unknown TID: {0}\n", tid);
return false;
}
if (condense_if_trivial) {
if (!stack->AnyPlans() && !stack->AnyCompletedPlans() &&
!stack->AnyDiscardedPlans()) {
strm.Printf("thread #%u: tid = 0x%4.4" PRIx64 "\n", index_id, tid);
strm.IndentMore();
strm.Indent();
strm.Printf("No active thread plans\n");
strm.IndentLess();
return true;
}
}
strm.Indent();
strm.Printf("thread #%u: tid = 0x%4.4" PRIx64 ":\n", index_id, tid);
stack->DumpThreadPlans(strm, desc_level, internal);
return true;
}
bool ThreadPlanStackMap::PrunePlansForTID(lldb::tid_t tid) {
// We only remove the plans for unreported TID's.
ThreadSP thread_sp = m_process.GetThreadList().FindThreadByID(tid);
if (thread_sp)
return false;
return RemoveTID(tid);
}