Golang is a very popular programming language that supports concurrent programming. In order to meet the requirements of concurrency security, Golang provides a lock mechanism. A lock is a synchronization mechanism that can be used to control access to shared resources. In this article, we will introduce how to implement locks using Golang.
1. Types of locks
In Golang, there are three main types of locks: mutex locks, read-write locks and condition variables.
1. Mutex lock (Mutex)
Mutex lock is the simplest and most commonly used type of lock. Its function is to allow only one thread to access shared resources at the same time. If other threads try to access the resource, they are blocked until the lock is released.
2. Read-write lock (RWMutex)
Read-write lock is another type of lock that allows multiple threads to read a shared resource at the same time, but only allows one thread to write the resource. This lock is more efficient than a mutex because it allows concurrent reads, but writes must occupy the resource exclusively.
3. Condition variable (Cond)
Condition variable is an advanced synchronization mechanism that provides a mechanism for waiting and communication between multiple threads. Condition variables have two main methods: Wait and Signal. The Wait method can make the thread go to sleep to wait for a specific condition, while the Signal method notifies the waiting thread that the condition has been met.
2. Implementation of mutex locks
Golang’s standard library provides the implementation of mutex locks. You can use the Mutex type in the sync package to implement mutex locks. The following is a sample program:
package main import ( "fmt" "sync" ) var ( count int lock sync.Mutex ) func main() { var wg sync.WaitGroup for i := 0; i < 100; i++ { wg.Add(1) go func() { lock.Lock() count++ lock.Unlock() wg.Done() }() } wg.Wait() fmt.Println(count) }
In the above code, we define a counter count and create a mutex lock. Then 100 goroutines are started, and the counter is incremented by 1 in each goroutine. Since access to count is concurrent, we need to use a mutex lock to prevent race conditions from occurring.
It is worth noting that for operations involving shared resources, the operation must be performed after acquiring the lock, and the lock must be released after the operation is completed to ensure that all operations are atomic.
3. Implementation of read-write lock
Similar to mutex locks, Golang’s standard library also provides implementation of read-write locks. You can use the RWMutex type in the sync package to implement reading. Write lock. The following is a sample program:
package main import ( "fmt" "sync" ) var ( count int rw sync.RWMutex ) func main() { var wg sync.WaitGroup for i := 0; i < 100; i++ { wg.Add(1) go func() { rw.Lock() count++ rw.Unlock() wg.Done() }() } for i := 0; i < 100; i++ { wg.Add(1) go func() { rw.RLock() fmt.Println(count) rw.RUnlock() wg.Done() }() } wg.Wait() }
In the above code, we use the RWMutex type to implement read-write locks. First, start 100 goroutines to add 1 to the counter. During this period, the counter can only be occupied by one thread. Then start 100 goroutines to read the counter value. These goroutines can read the counter value at the same time.
Compared with mutex locks, read-write locks have higher concurrency and less lock competition. If most operations are read operations, using read-write locks instead of mutex locks can improve performance.
4. Implementation of condition variables
Condition variables are an advanced synchronization mechanism that can make threads enter sleep state and wait for specific conditions to be met. Condition variables are also provided in the sync package and can be implemented using the Cond type. The following is a sample program:
package main import ( "fmt" "sync" ) var ( count int waiters int lock sync.Mutex cond *sync.Cond = sync.NewCond(&lock) ) func main() { var wg sync.WaitGroup for i := 0; i < 10; i++ { wg.Add(1) go func() { lock.Lock() for count < 5 { waiters++ cond.Wait() waiters-- } fmt.Println("Count:", count) lock.Unlock() wg.Done() }() } for i := 0; i < 5; i++ { wg.Add(1) go func() { lock.Lock() count++ if waiters > 0 { cond.Signal() } lock.Unlock() wg.Done() }() } wg.Wait() }
In the above code, we define a counter count and a count waiters of waiting threads. Then start 10 goroutines to wait for the counter to reach 5, and output the value of the counter when the counter reaches 5. Start 5 more goroutines to add 1 to the counter. When the counter reaches 5, call cond.Signal() to wake up the waiting goroutine.
It should be noted that the mutex lock must be obtained before using the condition variable, otherwise a deadlock will occur.
5. Summary
This article introduces three common lock types in Golang: mutex locks, read-write locks and condition variables. Mutex locks are the most commonly used locks to prevent multiple threads from accessing shared resources at the same time. Read-write locks allow multiple read operations, but only exclusive write operations. Condition variables are an advanced synchronization mechanism that enable threads to wait for specific conditions to be met.
When writing Golang programs, choosing the appropriate lock type is crucial to achieving concurrency safety. It is necessary to select the appropriate lock type according to the application scenario and specific needs to improve concurrency performance.
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