突然想到让deepseek来解释一下递归

密银

' e) ?% H/ D; f% D' q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。

关键要素
- H9 R/ e/ R! K1 D0 l$ {! q/ L1. **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
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2. **递归条件（Recursive Case）**
   - 将原问题分解为更小的子问题
   - 例如：n! = n × (n-1)!

7 Y" a# K  U. r( K, z" R 经典示例：计算阶乘
python
def factorial(n):
    if n == 0:        # 基线条件
5 ^5 U" |& Q9 b% E& @        return 1
    else:             # 递归条件
+ ~; O- Q5 }8 f- f6 C& A        return n * factorial(n-1)
执行过程（以计算 3! 为例）：
2 S+ g- N7 j' D! e( pfactorial(3)
* @" E# \$ C) n1 t2 |+ T  ~3 * factorial(2)
- v" d+ c3 F) X3 * (2 * factorial(1))
1 R4 W; \$ u- W* u5 I3 * (2 * (1 * factorial(0)))
3 * (2 * (1 * 1)) = 6

递归思维要点
, y/ `. G7 W* V5 l  g, z" `1. **信任递归**：假设子问题已经解决，专注当前层逻辑
0 d: D3 _) M/ t$ P. A; T2. **栈结构**：每次调用都会创建新的栈帧（内存空间）
: ?+ T# Z8 J, B1 `8 y- S1 Y3. **递推过程**：不断向下分解问题（递）
; u$ r  Z0 m& w, ^- L) I9 {4. **回溯过程**：组合子问题结果返回（归）
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4 k7 V  n$ C0 Q6 v/ C; P& r( n 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）
某些问题用递归更直观（如树遍历），但效率可能不如迭代
. W2 g$ Y2 G) B  O尾递归优化可以提升效率（但Python不支持）

递归 vs 迭代
|          | 递归                          | 迭代               |
1 o6 b' U  [, W$ h+ Z- ~3 V|----------|-----------------------------|------------------|
0 K3 a6 ^( E1 N, T| 实现方式    | 函数自调用                        | 循环结构            |
% v9 H" d% T0 h+ p8 O| 内存消耗    | 需要维护调用栈（可能溢出）               | 通常更节省内存         |
" M) m/ d( m6 s8 c) R| 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         |
) ~1 F+ b$ ^, j3 q7 ^| 适用场景    | 树结构、分治算法、回溯问题等               | 简单重复操作          |

2 I5 w9 X3 I- d5 U, S& U: V 经典递归应用场景
" \  Z9 t' f# H7 m1. 文件系统遍历（目录树结构）
6 l% ]8 @5 i0 K: n2. 快速排序/归并排序算法
; O! C+ C8 p3 H, i! s0 S4 W3. 汉诺塔问题
4. 二叉树遍历（前序/中序/后序）
- u( t: h$ |, |7 Q- B% ?5. 生成所有可能的组合（回溯算法）

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:
Key Idea of Recursion
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& y3 K# c# I1 P$ X& Y% xA recursive function solves a problem by:
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4 y4 i! B8 R- ?1 X) _5 h3 l9 p% I    Breaking the problem into smaller instances of the same problem.

/ H* |, B1 d0 z# |# |  N    Solving the smallest instance directly (base case).

9 {/ T. A9 Y4 m6 H    Combining the results of smaller instances to solve the larger problem.
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Components of a Recursive Function

: h" a+ N2 [: y    Base Case:
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1 l4 @" e9 V* Q$ C+ D        This is the simplest, smallest instance of the problem that can be solved directly without further recursion.
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) T* r) u; }' n% f+ Q/ d$ p, N$ W        It acts as the stopping condition to prevent infinite recursion.

, F! ~5 v4 b, p$ Y9 |& E        Example: In calculating the factorial of a number, the base case is factorial(0) = 1.
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) X- `" M8 D% w, C* r1 C    Recursive Case:
$ R& l9 }- F# D
* x: C' |1 k$ M2 L        This is where the function calls itself with a smaller or simpler version of the problem.

: I# g# t, I3 v7 s$ V        Example: For factorial, the recursive case is factorial(n) = n * factorial(n-1).
5 `5 s, ~9 V3 A7 A
! V0 t3 {7 S$ @" l" eExample: Factorial Calculation
% z- M! I- M: n& D6 @
0 o) E9 e' Z/ \  L, @% z1 Y$ VThe 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:
& V' d" j$ F0 r
    Base case: 0! = 1
1 S& v7 p; J3 R9 B
9 y: M& M; a: {( E    Recursive case: n! = n * (n-1)!
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Here’s how it looks in code (Python):
python
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( J8 m4 e5 [% ?! r6 _4 U- p4 odef factorial(n):
2 {1 D/ R) E$ R! P. i& D" p' Q  i    # Base case
    if n == 0:
. ~1 v% L+ [% M, a        return 1
    # Recursive case
2 B' ?6 K3 |; ~- b# Z! l    else:
        return n * factorial(n - 1)
3 i9 W; T0 `; V9 |' U; i" A6 \9 S; T! b# |% g
' X  O. v% m( O2 U# Example usage
# g# X2 C7 s: T. u( I) |4 zprint(factorial(5))  # Output: 120

  M- |# X* _8 j4 hHow Recursion Works
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0 a9 c' E# e  N3 g: ]    The function keeps calling itself with smaller inputs until it reaches the base case.

    Once the base case is reached, the function starts returning values back up the call stack.
+ u( N' K, w) d) I/ ]9 ?) T/ l; n
8 B* j4 w/ n7 Q/ O8 }* P. M    These returned values are combined to produce the final result.
  {; p6 u- w/ w2 p7 J5 d9 K
For factorial(5):
$ @' w2 f- L# }+ S: b

+ @: P$ ^  ~" G; L" y, ofactorial(5) = 5 * factorial(4)
& y. H$ q) u& m  Q0 T/ mfactorial(4) = 4 * factorial(3)
) {. `* Q4 _% P& e% v" c6 jfactorial(3) = 3 * factorial(2)
) m2 O2 E- ^8 b/ U' a4 ^# C* ?factorial(2) = 2 * factorial(1)
factorial(1) = 1 * factorial(0)
factorial(0) = 1  # Base case

Then, the results are combined:


- ?5 i# @/ _. n5 }/ R% N5 o* n8 pfactorial(1) = 1 * 1 = 1
4 }9 Z$ |' L3 hfactorial(2) = 2 * 1 = 2
factorial(3) = 3 * 2 = 6
factorial(4) = 4 * 6 = 24
factorial(5) = 5 * 24 = 120
9 v) ^7 E) z6 V5 ^/ r
Advantages of Recursion

    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).

7 n" L- D3 [; j: a* G    Readability: Recursive code can be more readable and concise compared to iterative solutions.

Disadvantages 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.
3 h6 X# p8 O$ \5 Y. t* a- t
    Inefficiency: Some problems can be solved more efficiently using iteration (e.g., Fibonacci sequence without memoization).
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5 E" p9 |6 r  }, H9 y/ _4 VWhen to Use Recursion
( E! K- z5 y% F1 ?8 \  |. I8 N
    Problems that can be broken down into smaller, similar subproblems (e.g., tree traversals, sorting algorithms like quicksort and mergesort).

    Problems with a clear base case and recursive case.

Example: Fibonacci Sequence

The Fibonacci sequence is another classic example of recursion. Each number is the sum of the two preceding ones:
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' K3 ^" k8 C! S- a  R; Q+ z    Base case: fib(0) = 0, fib(1) = 1
" v! W. f$ K+ Z& Z3 H+ p. a5 t
+ c. X" z4 h- V7 d$ A4 o    Recursive case: fib(n) = fib(n-1) + fib(n-2)

python
' d6 R/ @% |2 D) N6 s

9 ~+ X! A5 S  C% F8 y+ q5 cdef fibonacci(n):
/ J. H4 z. j( ]3 w- G: Q    # Base cases
    if n == 0:
        return 0
    elif n == 1:
; P0 p: Y0 e3 @& k; _) _        return 1
    # Recursive case
9 w8 o  @& }1 ^, ~2 t8 y    else:
) u- l  k" l9 k: \        return fibonacci(n - 1) + fibonacci(n - 2)

# Example usage
print(fibonacci(6))  # Output: 8
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Tail Recursion

3 [& C! o0 Q5 J7 {) R+ Q3 m- V- fTail 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).
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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。