tools/deadlock_detector.c - platform/external/bcc - Git at Google

 /*
  * deadlock_detector.c  Detects potential deadlocks in a running process.
  *                      For Linux, uses BCC, eBPF. See .py file.
  *
  * Copyright 2017 Facebook, Inc.
  * Licensed under the Apache License, Version 2.0 (the "License")
  *
  * 1-Feb-2016   Kenny Yu   Created this.
  */

 #include <linux/sched.h>
 #include <uapi/linux/ptrace.h>

 // Maximum number of mutexes a single thread can hold at once.
 // If the number is too big, the unrolled loops wil cause the stack
 // to be too big, and the bpf verifier will fail.
 #define MAX_HELD_MUTEXES 16

 // Info about held mutexes. `mutex` will be 0 if not held.
 struct held_mutex_t {
   u64 mutex;
   u64 stack_id;
 };

 // List of mutexes that a thread is holding. Whenever we loop over this array,
 // we need to force the compiler to unroll the loop, otherwise the bcc verifier
 // will fail because the loop will create a backwards edge.
 struct thread_to_held_mutex_leaf_t {
   struct held_mutex_t held_mutexes[MAX_HELD_MUTEXES];
 };

 // Map of thread ID -> array of (mutex addresses, stack id)
 BPF_HASH(thread_to_held_mutexes, u32, struct thread_to_held_mutex_leaf_t, 2097152);

 // Key type for edges. Represents an edge from mutex1 => mutex2.
 struct edges_key_t {
   u64 mutex1;
   u64 mutex2;
 };

 // Leaf type for edges. Holds information about where each mutex was acquired.
 struct edges_leaf_t {
   u64 mutex1_stack_id;
   u64 mutex2_stack_id;
   u32 thread_pid;
   char comm[TASK_COMM_LEN];
 };

 // Represents all edges currently in the mutex wait graph.
 BPF_HASH(edges, struct edges_key_t, struct edges_leaf_t, 2097152);

 // Info about parent thread when a child thread is created.
 struct thread_created_leaf_t {
   u64 stack_id;
   u32 parent_pid;
   char comm[TASK_COMM_LEN];
 };

 // Map of child thread pid -> info about parent thread.
 BPF_HASH(thread_to_parent, u32, struct thread_created_leaf_t);

 // Stack traces when threads are created and when mutexes are locked/unlocked.
 BPF_STACK_TRACE(stack_traces, 655360);

 // The first argument to the user space function we are tracing
 // is a pointer to the mutex M held by thread T.
 //
 // For all mutexes N held by mutexes_held[T]
 //   add edge N => M (held by T)
 // mutexes_held[T].add(M)
 int trace_mutex_acquire(struct pt_regs *ctx, void *mutex_addr) {
   // Higher 32 bits is process ID, Lower 32 bits is thread ID
   u32 pid = bpf_get_current_pid_tgid();
   u64 mutex = (u64)mutex_addr;

   struct thread_to_held_mutex_leaf_t empty_leaf = {};
   struct thread_to_held_mutex_leaf_t *leaf =
       thread_to_held_mutexes.lookup_or_init(&pid, &empty_leaf);
   if (!leaf) {
     bpf_trace_printk(
         "could not add thread_to_held_mutex key, thread: %d, mutex: %p\n", pid,
         mutex);
     return 1; // Could not insert, no more memory
   }

   // Recursive mutexes lock the same mutex multiple times. We cannot tell if
   // the mutex is recursive after the mutex is already created. To avoid noisy
   // reports, disallow self edges. Do one pass to check if we are already
   // holding the mutex, and if we are, do nothing.
   #pragma unroll
   for (int i = 0; i < MAX_HELD_MUTEXES; ++i) {
     if (leaf->held_mutexes[i].mutex == mutex) {
       return 1; // Disallow self edges
     }
   }

   u64 stack_id =
       stack_traces.get_stackid(ctx, BPF_F_USER_STACK | BPF_F_REUSE_STACKID);

   int added_mutex = 0;
   #pragma unroll
   for (int i = 0; i < MAX_HELD_MUTEXES; ++i) {
     // If this is a free slot, see if we can insert.
     if (!leaf->held_mutexes[i].mutex) {
       if (!added_mutex) {
         leaf->held_mutexes[i].mutex = mutex;
         leaf->held_mutexes[i].stack_id = stack_id;
         added_mutex = 1;
       }
       continue; // Nothing to do for a free slot
     }

     // Add edges from held mutex => current mutex
     struct edges_key_t edge_key = {};
     edge_key.mutex1 = leaf->held_mutexes[i].mutex;
     edge_key.mutex2 = mutex;

     struct edges_leaf_t edge_leaf = {};
     edge_leaf.mutex1_stack_id = leaf->held_mutexes[i].stack_id;
     edge_leaf.mutex2_stack_id = stack_id;
     edge_leaf.thread_pid = pid;
     bpf_get_current_comm(&edge_leaf.comm, sizeof(edge_leaf.comm));

     // Returns non-zero on error
     int result = edges.update(&edge_key, &edge_leaf);
     if (result) {
       bpf_trace_printk("could not add edge key %p, %p, error: %d\n",
                        edge_key.mutex1, edge_key.mutex2, result);
       continue; // Could not insert, no more memory
     }
   }

   // There were no free slots for this mutex.
   if (!added_mutex) {
     bpf_trace_printk("could not add mutex %p, added_mutex: %d\n", mutex,
                      added_mutex);
     return 1;
   }
   return 0;
 }

 // The first argument to the user space function we are tracing
 // is a pointer to the mutex M held by thread T.
 //
 // mutexes_held[T].remove(M)
 int trace_mutex_release(struct pt_regs *ctx, void *mutex_addr) {
   // Higher 32 bits is process ID, Lower 32 bits is thread ID
   u32 pid = bpf_get_current_pid_tgid();
   u64 mutex = (u64)mutex_addr;

   struct thread_to_held_mutex_leaf_t *leaf =
       thread_to_held_mutexes.lookup(&pid);
   if (!leaf) {
     // If the leaf does not exist for the pid, then it means we either missed
     // the acquire event, or we had no more memory and could not add it.
     bpf_trace_printk(
         "could not find thread_to_held_mutex, thread: %d, mutex: %p\n", pid,
         mutex);
     return 1;
   }

   // For older kernels without "Bpf: allow access into map value arrays"
   // (https://lkml.org/lkml/2016/8/30/287) the bpf verifier will fail with an
   // invalid memory access on `leaf->held_mutexes[i]` below. On newer kernels,
   // we can avoid making this extra copy in `value` and use `leaf` directly.
   struct thread_to_held_mutex_leaf_t value = {};
   bpf_probe_read(&value, sizeof(struct thread_to_held_mutex_leaf_t), leaf);

   #pragma unroll
   for (int i = 0; i < MAX_HELD_MUTEXES; ++i) {
     // Find the current mutex (if it exists), and clear it.
     // Note: Can't use `leaf->` in this if condition, see comment above.
     if (value.held_mutexes[i].mutex == mutex) {
       leaf->held_mutexes[i].mutex = 0;
       leaf->held_mutexes[i].stack_id = 0;
     }
   }

   return 0;
 }

 // Trace return from clone() syscall in the child thread (return value > 0).
 int trace_clone(struct pt_regs *ctx, unsigned long flags, void *child_stack,
                 void *ptid, void *ctid, struct pt_regs *regs) {
   u32 child_pid = PT_REGS_RC(ctx);
   if (child_pid <= 0) {
     return 1;
   }

   struct thread_created_leaf_t thread_created_leaf = {};
   thread_created_leaf.parent_pid = bpf_get_current_pid_tgid();
   thread_created_leaf.stack_id =
       stack_traces.get_stackid(ctx, BPF_F_USER_STACK | BPF_F_REUSE_STACKID);
   bpf_get_current_comm(&thread_created_leaf.comm,
                        sizeof(thread_created_leaf.comm));

   struct thread_created_leaf_t *insert_result =
       thread_to_parent.lookup_or_init(&child_pid, &thread_created_leaf);
   if (!insert_result) {
     bpf_trace_printk(
         "could not add thread_created_key, child: %d, parent: %d\n", child_pid,
         thread_created_leaf.parent_pid);
     return 1; // Could not insert, no more memory
   }
   return 0;
 }
	/*
	* deadlock_detector.c Detects potential deadlocks in a running process.
	* For Linux, uses BCC, eBPF. See .py file.
	*
	* Copyright 2017 Facebook, Inc.
	* Licensed under the Apache License, Version 2.0 (the "License")
	*
	* 1-Feb-2016 Kenny Yu Created this.
	*/

	#include <linux/sched.h>
	#include <uapi/linux/ptrace.h>

	// Maximum number of mutexes a single thread can hold at once.
	// If the number is too big, the unrolled loops wil cause the stack
	// to be too big, and the bpf verifier will fail.
	#define MAX_HELD_MUTEXES 16

	// Info about held mutexes. `mutex` will be 0 if not held.
	struct held_mutex_t {
	u64 mutex;
	u64 stack_id;
	};

	// List of mutexes that a thread is holding. Whenever we loop over this array,
	// we need to force the compiler to unroll the loop, otherwise the bcc verifier
	// will fail because the loop will create a backwards edge.
	struct thread_to_held_mutex_leaf_t {
	struct held_mutex_t held_mutexes[MAX_HELD_MUTEXES];
	};

	// Map of thread ID -> array of (mutex addresses, stack id)
	BPF_HASH(thread_to_held_mutexes, u32, struct thread_to_held_mutex_leaf_t, 2097152);

	// Key type for edges. Represents an edge from mutex1 => mutex2.
	struct edges_key_t {
	u64 mutex1;
	u64 mutex2;
	};

	// Leaf type for edges. Holds information about where each mutex was acquired.
	struct edges_leaf_t {
	u64 mutex1_stack_id;
	u64 mutex2_stack_id;
	u32 thread_pid;
	char comm[TASK_COMM_LEN];
	};

	// Represents all edges currently in the mutex wait graph.
	BPF_HASH(edges, struct edges_key_t, struct edges_leaf_t, 2097152);

	// Info about parent thread when a child thread is created.
	struct thread_created_leaf_t {
	u64 stack_id;
	u32 parent_pid;
	char comm[TASK_COMM_LEN];
	};

	// Map of child thread pid -> info about parent thread.
	BPF_HASH(thread_to_parent, u32, struct thread_created_leaf_t);

	// Stack traces when threads are created and when mutexes are locked/unlocked.
	BPF_STACK_TRACE(stack_traces, 655360);

	// The first argument to the user space function we are tracing
	// is a pointer to the mutex M held by thread T.
	//
	// For all mutexes N held by mutexes_held[T]
	// add edge N => M (held by T)
	// mutexes_held[T].add(M)
	int trace_mutex_acquire(struct pt_regs ctx, void mutex_addr) {
	// Higher 32 bits is process ID, Lower 32 bits is thread ID
	u32 pid = bpf_get_current_pid_tgid();
	u64 mutex = (u64)mutex_addr;

	struct thread_to_held_mutex_leaf_t empty_leaf = {};
	struct thread_to_held_mutex_leaf_t *leaf =
	thread_to_held_mutexes.lookup_or_init(&pid, &empty_leaf);
	if (!leaf) {
	bpf_trace_printk(
	"could not add thread_to_held_mutex key, thread: %d, mutex: %p\n", pid,
	mutex);
	return 1; // Could not insert, no more memory
	}

	// Recursive mutexes lock the same mutex multiple times. We cannot tell if
	// the mutex is recursive after the mutex is already created. To avoid noisy
	// reports, disallow self edges. Do one pass to check if we are already
	// holding the mutex, and if we are, do nothing.
	#pragma unroll
	for (int i = 0; i < MAX_HELD_MUTEXES; ++i) {
	if (leaf->held_mutexes[i].mutex == mutex) {
	return 1; // Disallow self edges
	}
	}

	u64 stack_id =
	stack_traces.get_stackid(ctx, BPF_F_USER_STACK \| BPF_F_REUSE_STACKID);

	int added_mutex = 0;
	#pragma unroll
	for (int i = 0; i < MAX_HELD_MUTEXES; ++i) {
	// If this is a free slot, see if we can insert.
	if (!leaf->held_mutexes[i].mutex) {
	if (!added_mutex) {
	leaf->held_mutexes[i].mutex = mutex;
	leaf->held_mutexes[i].stack_id = stack_id;
	added_mutex = 1;
	}
	continue; // Nothing to do for a free slot
	}

	// Add edges from held mutex => current mutex
	struct edges_key_t edge_key = {};
	edge_key.mutex1 = leaf->held_mutexes[i].mutex;
	edge_key.mutex2 = mutex;

	struct edges_leaf_t edge_leaf = {};
	edge_leaf.mutex1_stack_id = leaf->held_mutexes[i].stack_id;
	edge_leaf.mutex2_stack_id = stack_id;
	edge_leaf.thread_pid = pid;
	bpf_get_current_comm(&edge_leaf.comm, sizeof(edge_leaf.comm));

	// Returns non-zero on error
	int result = edges.update(&edge_key, &edge_leaf);
	if (result) {
	bpf_trace_printk("could not add edge key %p, %p, error: %d\n",
	edge_key.mutex1, edge_key.mutex2, result);
	continue; // Could not insert, no more memory
	}
	}

	// There were no free slots for this mutex.
	if (!added_mutex) {
	bpf_trace_printk("could not add mutex %p, added_mutex: %d\n", mutex,
	added_mutex);
	return 1;
	}
	return 0;
	}

	// The first argument to the user space function we are tracing
	// is a pointer to the mutex M held by thread T.
	//
	// mutexes_held[T].remove(M)
	int trace_mutex_release(struct pt_regs ctx, void mutex_addr) {
	// Higher 32 bits is process ID, Lower 32 bits is thread ID
	u32 pid = bpf_get_current_pid_tgid();
	u64 mutex = (u64)mutex_addr;

	struct thread_to_held_mutex_leaf_t *leaf =
	thread_to_held_mutexes.lookup(&pid);
	if (!leaf) {
	// If the leaf does not exist for the pid, then it means we either missed
	// the acquire event, or we had no more memory and could not add it.
	bpf_trace_printk(
	"could not find thread_to_held_mutex, thread: %d, mutex: %p\n", pid,
	mutex);
	return 1;
	}

	// For older kernels without "Bpf: allow access into map value arrays"
	// (https://lkml.org/lkml/2016/8/30/287) the bpf verifier will fail with an
	// invalid memory access on `leaf->held_mutexes[i]` below. On newer kernels,
	// we can avoid making this extra copy in `value` and use `leaf` directly.
	struct thread_to_held_mutex_leaf_t value = {};
	bpf_probe_read(&value, sizeof(struct thread_to_held_mutex_leaf_t), leaf);

	#pragma unroll
	for (int i = 0; i < MAX_HELD_MUTEXES; ++i) {
	// Find the current mutex (if it exists), and clear it.
	// Note: Can't use `leaf->` in this if condition, see comment above.
	if (value.held_mutexes[i].mutex == mutex) {
	leaf->held_mutexes[i].mutex = 0;
	leaf->held_mutexes[i].stack_id = 0;
	}
	}

	return 0;
	}

	// Trace return from clone() syscall in the child thread (return value > 0).
	int trace_clone(struct pt_regs ctx, unsigned long flags, void child_stack,
	void ptid, void ctid, struct pt_regs *regs) {
	u32 child_pid = PT_REGS_RC(ctx);
	if (child_pid <= 0) {
	return 1;
	}

	struct thread_created_leaf_t thread_created_leaf = {};
	thread_created_leaf.parent_pid = bpf_get_current_pid_tgid();
	thread_created_leaf.stack_id =
	stack_traces.get_stackid(ctx, BPF_F_USER_STACK \| BPF_F_REUSE_STACKID);
	bpf_get_current_comm(&thread_created_leaf.comm,
	sizeof(thread_created_leaf.comm));

	struct thread_created_leaf_t *insert_result =
	thread_to_parent.lookup_or_init(&child_pid, &thread_created_leaf);
	if (!insert_result) {
	bpf_trace_printk(
	"could not add thread_created_key, child: %d, parent: %d\n", child_pid,
	thread_created_leaf.parent_pid);
	return 1; // Could not insert, no more memory
	}
	return 0;
	}