突然想到让deepseek来解释一下递归

密银

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$ J- t1 r. p  Q9 I8 t解释的不错

递归是一种通过将问题分解为更小的同类子问题来解决问题的方法。它的核心思想是：**函数直接或间接地调用自身**，直到满足终止条件。
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关键要素
1. **基线条件（Base Case）**
   - 递归终止的条件，防止无限循环
   - 例如：计算阶乘时 n == 0 或 n == 1 时返回 1

, u+ R# c4 C. s. a. L+ R$ Y& L2. **递归条件（Recursive Case）**
3 k8 m2 A+ [( d# a6 x7 L9 F7 Q   - 将原问题分解为更小的子问题
   - 例如：n! = n × (n-1)!
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经典示例：计算阶乘
python
) d& |# A# ~  z' K/ odef factorial(n):
- l! ]( ?1 ^8 }) B2 g8 ]  @    if n == 0:        # 基线条件
        return 1
    else:             # 递归条件
' N/ y# m$ c; Q4 }6 W) }# T4 {8 ~        return n * factorial(n-1)
# H- W7 h. d) b/ b3 s; P- J4 x执行过程（以计算 3! 为例）：
factorial(3)
3 * factorial(2)
3 * (2 * factorial(1))
/ r0 z4 }, g+ j6 q3 * (2 * (1 * factorial(0)))
5 L( i# ?0 }% }  G3 * (2 * (1 * 1)) = 6
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递归思维要点
6 |& |; k0 b( T# ?" o1. **信任递归**：假设子问题已经解决，专注当前层逻辑
1 I- S' F  y* N* ^* h/ g$ k2. **栈结构**：每次调用都会创建新的栈帧（内存空间）
3. **递推过程**：不断向下分解问题（递）
4. **回溯过程**：组合子问题结果返回（归）

6 v8 p3 J& m* p1 @8 E 注意事项
必须要有终止条件
递归深度过大可能导致栈溢出（Python默认递归深度约1000层）
( h; U8 }) x# o3 c6 u某些问题用递归更直观（如树遍历），但效率可能不如迭代
" G6 j" R& K% I+ U/ l尾递归优化可以提升效率（但Python不支持）

递归 vs 迭代
7 |/ @- l; ~( {: X$ k1 n  K' h$ @* V|          | 递归                          | 迭代               |
, U7 d- Z5 B- }( n$ q1 {, z0 j|----------|-----------------------------|------------------|
0 z' o$ E- N7 ~9 r" e7 D3 z6 L1 g| 实现方式    | 函数自调用                        | 循环结构            |
| 内存消耗    | 需要维护调用栈（可能溢出）               | 通常更节省内存         |
* w3 f! e, w7 @- x7 p/ I| 代码可读性  | 对符合递归思维的问题更直观                | 线性流程更直接         |
# {5 B0 ~* {# [0 k8 y6 |. z2 u+ t| 适用场景    | 树结构、分治算法、回溯问题等               | 简单重复操作          |
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经典递归应用场景
1. 文件系统遍历（目录树结构）
2. 快速排序/归并排序算法
2 L6 }5 _% s+ U# }$ _0 @3. 汉诺塔问题
1 F& ~  q2 g+ L  \- I4. 二叉树遍历（前序/中序/后序）
  [! ~+ W, ?# U1 f0 r5 c5. 生成所有可能的组合（回溯算法）
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/ A# y( k, T2 I; \* _试着用递归思维想象：你站在一面镜子前，镜子里有无数个逐渐变小的你在照镜子，这就是递归的直观体现。但记住每个"分身"最终都要有结束的时刻，这就是基线条件的重要性。

testjhy

挺好，递归思维要点与我能够回忆起来我当时写递归程序的思路很一致，，或者被它唤醒，
我推理机的核心算法应该是二叉树遍历的变种。
另外知识系统的推理机搜索深度(递归深度)并不长，没有超过10层的，如果输入变量多的话，搜索宽度很大，但对那时的286-386DOS系统，计算压力也不算大。

nanimarcus

Recursion in programming is a technique where a function calls itself in order to solve a problem. It is a powerful concept that allows you to break down complex problems into smaller, more manageable subproblems. Here's a detailed explanation:
8 B5 h) J8 |6 T, I# s9 e- g9 |: V! dKey Idea of Recursion

A recursive function solves a problem by:
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' {# ?) b; V  s" J    Breaking the problem into smaller instances of the same problem.

. Q' e0 @4 C+ ]: j3 N( K% I! ?. i    Solving the smallest instance directly (base case).
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- J/ A( m& p+ U    Combining the results of smaller instances to solve the larger problem.
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Components of a Recursive Function

    Base Case:

        This is the simplest, smallest instance of the problem that can be solved directly without further recursion.

2 P" @; U) z. }1 f% N2 G        It acts as the stopping condition to prevent infinite recursion.

        Example: In calculating the factorial of a number, the base case is factorial(0) = 1.

    Recursive Case:

: {0 T$ N% i% a$ _  }. m        This is where the function calls itself with a smaller or simpler version of the problem.

/ A7 e# I- T/ c' a& K; V        Example: For factorial, the recursive case is factorial(n) = n * factorial(n-1).
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Example: Factorial Calculation

& ]" {0 S7 n6 R  ^: l4 H( ~( cThe factorial of a number n (denoted as n!) is the product of all positive integers less than or equal to n. It can be defined recursively as:
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4 s5 B) d" O( c" k    Base case: 0! = 1
5 I/ `9 G0 U% {* d" r
, f) N* x/ I4 I+ c% h    Recursive case: n! = n * (n-1)!
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Here’s how it looks in code (Python):
% [5 Z7 I9 ]& r. Epython
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$ e- F% n( ]# j  t+ @7 ]5 @def factorial(n):
    # Base case
; d% y- T0 I$ D    if n == 0:
/ F, P& I" b8 r# F        return 1
    # Recursive case
    else:
& d5 ]+ P* b+ D7 R- P" S        return n * factorial(n - 1)

. g0 I6 g, e9 t+ T! N# Example usage
print(factorial(5))  # Output: 120

$ L0 `0 ?7 w# f, h* UHow Recursion Works

) W0 x1 n8 h# p# @0 x# U    The function keeps calling itself with smaller inputs until it reaches the base case.
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    Once the base case is reached, the function starts returning values back up the call stack.
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    These returned values are combined to produce the final result.

For factorial(5):


factorial(5) = 5 * factorial(4)
factorial(4) = 4 * factorial(3)
factorial(3) = 3 * factorial(2)
' ?- g* \$ e4 t# Sfactorial(2) = 2 * factorial(1)
factorial(1) = 1 * factorial(0)
' G' @' n) ?$ w# r( bfactorial(0) = 1  # Base case

Then, the results are combined:
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factorial(1) = 1 * 1 = 1
. {; b# q; P, y# d0 B+ v2 Lfactorial(2) = 2 * 1 = 2
% ~# ?1 l" }& |( P: q* Qfactorial(3) = 3 * 2 = 6
: z; b' B* Q, R7 Nfactorial(4) = 4 * 6 = 24
factorial(5) = 5 * 24 = 120

Advantages of Recursion
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' G! ^' [4 {( I% e6 e- N    Simplicity: Recursive solutions are often more intuitive and easier to write for problems that have a natural recursive structure (e.g., tree traversals, divide-and-conquer algorithms).
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# G) R4 ~- o) c6 K9 h; M    Readability: Recursive code can be more readable and concise compared to iterative solutions.
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; }( t- i4 g3 {0 SDisadvantages of Recursion

    Performance Overhead: Each recursive call adds a new layer to the call stack, which can lead to high memory usage and potential stack overflow for deep recursion.
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  W) l' y/ R+ O    Inefficiency: Some problems can be solved more efficiently using iteration (e.g., Fibonacci sequence without memoization).

When to Use Recursion
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& t1 Y( O- q( U! S# a& S    Problems that can be broken down into smaller, similar subproblems (e.g., tree traversals, sorting algorithms like quicksort and mergesort).

7 a1 V' Q6 o+ H7 i# O    Problems with a clear base case and recursive case.

, c! a$ T) Z0 E' J' }/ j+ IExample: Fibonacci Sequence

The Fibonacci sequence is another classic example of recursion. Each number is the sum of the two preceding ones:

# O% c1 {9 w- ?* v  U9 `    Base case: fib(0) = 0, fib(1) = 1

    Recursive case: fib(n) = fib(n-1) + fib(n-2)
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python


8 W$ M, P; v; t: B- u! Z( Pdef fibonacci(n):
; ?8 R; v4 R4 @0 |. s0 S% d    # Base cases
+ g. x  N- s; A5 v' Z0 l1 W& n    if n == 0:
/ A" `% L. T7 o5 z4 O2 f        return 0
    elif n == 1:
4 c9 j3 X6 w2 N        return 1
- `7 _: i4 G; ^0 p  z- ^    # Recursive case
    else:
+ `* B4 }( R% f: J! m$ w, }, T- F        return fibonacci(n - 1) + fibonacci(n - 2)
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# Example usage
print(fibonacci(6))  # Output: 8

Tail Recursion

Tail recursion is a special case of recursion where the recursive call is the last operation in the function. Some programming languages optimize tail-recursive functions to avoid stack overflow, but not all languages (e.g., Python does not optimize tail recursion).

In summary, recursion is a fundamental concept in programming that allows you to solve problems by breaking them into smaller, self-similar subproblems. It’s important to define a base case to avoid infinite recursion and to understand the trade-offs between recursion and iteration.

nanimarcus

我还让Deepseek 给我讲讲Linux Kernel Driver 现在的开发流程，让一个老同志复习复习，快忘光了。