| // SPDX-License-Identifier: GPL-2.0 |
| /* |
| * A fast, small, non-recursive O(n log n) sort for the Linux kernel |
| * |
| * This performs n*log2(n) + 0.37*n + o(n) comparisons on average, |
| * and 1.5*n*log2(n) + O(n) in the (very contrived) worst case. |
| * |
| * Glibc qsort() manages n*log2(n) - 1.26*n for random inputs (1.63*n |
| * better) at the expense of stack usage and much larger code to avoid |
| * quicksort's O(n^2) worst case. |
| */ |
| |
| #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt |
| |
| #include <linux/types.h> |
| #include <linux/export.h> |
| #include <linux/sort.h> |
| |
| /** |
| * is_aligned - is this pointer & size okay for word-wide copying? |
| * @base: pointer to data |
| * @size: size of each element |
| * @align: required alignment (typically 4 or 8) |
| * |
| * Returns true if elements can be copied using word loads and stores. |
| * The size must be a multiple of the alignment, and the base address must |
| * be if we do not have CONFIG_HAVE_EFFICIENT_UNALIGNED_ACCESS. |
| * |
| * For some reason, gcc doesn't know to optimize "if (a & mask || b & mask)" |
| * to "if ((a | b) & mask)", so we do that by hand. |
| */ |
| __attribute_const__ __always_inline |
| static bool is_aligned(const void *base, size_t size, unsigned char align) |
| { |
| unsigned char lsbits = (unsigned char)size; |
| |
| (void)base; |
| #ifndef CONFIG_HAVE_EFFICIENT_UNALIGNED_ACCESS |
| lsbits |= (unsigned char)(uintptr_t)base; |
| #endif |
| return (lsbits & (align - 1)) == 0; |
| } |
| |
| /** |
| * swap_words_32 - swap two elements in 32-bit chunks |
| * @a: pointer to the first element to swap |
| * @b: pointer to the second element to swap |
| * @n: element size (must be a multiple of 4) |
| * |
| * Exchange the two objects in memory. This exploits base+index addressing, |
| * which basically all CPUs have, to minimize loop overhead computations. |
| * |
| * For some reason, on x86 gcc 7.3.0 adds a redundant test of n at the |
| * bottom of the loop, even though the zero flag is still valid from the |
| * subtract (since the intervening mov instructions don't alter the flags). |
| * Gcc 8.1.0 doesn't have that problem. |
| */ |
| static void swap_words_32(void *a, void *b, size_t n) |
| { |
| do { |
| u32 t = *(u32 *)(a + (n -= 4)); |
| *(u32 *)(a + n) = *(u32 *)(b + n); |
| *(u32 *)(b + n) = t; |
| } while (n); |
| } |
| |
| /** |
| * swap_words_64 - swap two elements in 64-bit chunks |
| * @a: pointer to the first element to swap |
| * @b: pointer to the second element to swap |
| * @n: element size (must be a multiple of 8) |
| * |
| * Exchange the two objects in memory. This exploits base+index |
| * addressing, which basically all CPUs have, to minimize loop overhead |
| * computations. |
| * |
| * We'd like to use 64-bit loads if possible. If they're not, emulating |
| * one requires base+index+4 addressing which x86 has but most other |
| * processors do not. If CONFIG_64BIT, we definitely have 64-bit loads, |
| * but it's possible to have 64-bit loads without 64-bit pointers (e.g. |
| * x32 ABI). Are there any cases the kernel needs to worry about? |
| */ |
| static void swap_words_64(void *a, void *b, size_t n) |
| { |
| do { |
| #ifdef CONFIG_64BIT |
| u64 t = *(u64 *)(a + (n -= 8)); |
| *(u64 *)(a + n) = *(u64 *)(b + n); |
| *(u64 *)(b + n) = t; |
| #else |
| /* Use two 32-bit transfers to avoid base+index+4 addressing */ |
| u32 t = *(u32 *)(a + (n -= 4)); |
| *(u32 *)(a + n) = *(u32 *)(b + n); |
| *(u32 *)(b + n) = t; |
| |
| t = *(u32 *)(a + (n -= 4)); |
| *(u32 *)(a + n) = *(u32 *)(b + n); |
| *(u32 *)(b + n) = t; |
| #endif |
| } while (n); |
| } |
| |
| /** |
| * swap_bytes - swap two elements a byte at a time |
| * @a: pointer to the first element to swap |
| * @b: pointer to the second element to swap |
| * @n: element size |
| * |
| * This is the fallback if alignment doesn't allow using larger chunks. |
| */ |
| static void swap_bytes(void *a, void *b, size_t n) |
| { |
| do { |
| char t = ((char *)a)[--n]; |
| ((char *)a)[n] = ((char *)b)[n]; |
| ((char *)b)[n] = t; |
| } while (n); |
| } |
| |
| /* |
| * The values are arbitrary as long as they can't be confused with |
| * a pointer, but small integers make for the smallest compare |
| * instructions. |
| */ |
| #define SWAP_WORDS_64 (swap_func_t)0 |
| #define SWAP_WORDS_32 (swap_func_t)1 |
| #define SWAP_BYTES (swap_func_t)2 |
| |
| /* |
| * The function pointer is last to make tail calls most efficient if the |
| * compiler decides not to inline this function. |
| */ |
| static void do_swap(void *a, void *b, size_t size, swap_func_t swap_func) |
| { |
| if (swap_func == SWAP_WORDS_64) |
| swap_words_64(a, b, size); |
| else if (swap_func == SWAP_WORDS_32) |
| swap_words_32(a, b, size); |
| else if (swap_func == SWAP_BYTES) |
| swap_bytes(a, b, size); |
| else |
| swap_func(a, b, (int)size); |
| } |
| |
| #define _CMP_WRAPPER ((cmp_r_func_t)0L) |
| |
| static int do_cmp(const void *a, const void *b, cmp_r_func_t cmp, const void *priv) |
| { |
| if (cmp == _CMP_WRAPPER) |
| return ((cmp_func_t)(priv))(a, b); |
| return cmp(a, b, priv); |
| } |
| |
| /** |
| * parent - given the offset of the child, find the offset of the parent. |
| * @i: the offset of the heap element whose parent is sought. Non-zero. |
| * @lsbit: a precomputed 1-bit mask, equal to "size & -size" |
| * @size: size of each element |
| * |
| * In terms of array indexes, the parent of element j = @i/@size is simply |
| * (j-1)/2. But when working in byte offsets, we can't use implicit |
| * truncation of integer divides. |
| * |
| * Fortunately, we only need one bit of the quotient, not the full divide. |
| * @size has a least significant bit. That bit will be clear if @i is |
| * an even multiple of @size, and set if it's an odd multiple. |
| * |
| * Logically, we're doing "if (i & lsbit) i -= size;", but since the |
| * branch is unpredictable, it's done with a bit of clever branch-free |
| * code instead. |
| */ |
| __attribute_const__ __always_inline |
| static size_t parent(size_t i, unsigned int lsbit, size_t size) |
| { |
| i -= size; |
| i -= size & -(i & lsbit); |
| return i / 2; |
| } |
| |
| /** |
| * sort_r - sort an array of elements |
| * @base: pointer to data to sort |
| * @num: number of elements |
| * @size: size of each element |
| * @cmp_func: pointer to comparison function |
| * @swap_func: pointer to swap function or NULL |
| * @priv: third argument passed to comparison function |
| * |
| * This function does a heapsort on the given array. You may provide |
| * a swap_func function if you need to do something more than a memory |
| * copy (e.g. fix up pointers or auxiliary data), but the built-in swap |
| * avoids a slow retpoline and so is significantly faster. |
| * |
| * Sorting time is O(n log n) both on average and worst-case. While |
| * quicksort is slightly faster on average, it suffers from exploitable |
| * O(n*n) worst-case behavior and extra memory requirements that make |
| * it less suitable for kernel use. |
| */ |
| void sort_r(void *base, size_t num, size_t size, |
| cmp_r_func_t cmp_func, |
| swap_func_t swap_func, |
| const void *priv) |
| { |
| /* pre-scale counters for performance */ |
| size_t n = num * size, a = (num/2) * size; |
| const unsigned int lsbit = size & -size; /* Used to find parent */ |
| |
| if (!a) /* num < 2 || size == 0 */ |
| return; |
| |
| if (!swap_func) { |
| if (is_aligned(base, size, 8)) |
| swap_func = SWAP_WORDS_64; |
| else if (is_aligned(base, size, 4)) |
| swap_func = SWAP_WORDS_32; |
| else |
| swap_func = SWAP_BYTES; |
| } |
| |
| /* |
| * Loop invariants: |
| * 1. elements [a,n) satisfy the heap property (compare greater than |
| * all of their children), |
| * 2. elements [n,num*size) are sorted, and |
| * 3. a <= b <= c <= d <= n (whenever they are valid). |
| */ |
| for (;;) { |
| size_t b, c, d; |
| |
| if (a) /* Building heap: sift down --a */ |
| a -= size; |
| else if (n -= size) /* Sorting: Extract root to --n */ |
| do_swap(base, base + n, size, swap_func); |
| else /* Sort complete */ |
| break; |
| |
| /* |
| * Sift element at "a" down into heap. This is the |
| * "bottom-up" variant, which significantly reduces |
| * calls to cmp_func(): we find the sift-down path all |
| * the way to the leaves (one compare per level), then |
| * backtrack to find where to insert the target element. |
| * |
| * Because elements tend to sift down close to the leaves, |
| * this uses fewer compares than doing two per level |
| * on the way down. (A bit more than half as many on |
| * average, 3/4 worst-case.) |
| */ |
| for (b = a; c = 2*b + size, (d = c + size) < n;) |
| b = do_cmp(base + c, base + d, cmp_func, priv) >= 0 ? c : d; |
| if (d == n) /* Special case last leaf with no sibling */ |
| b = c; |
| |
| /* Now backtrack from "b" to the correct location for "a" */ |
| while (b != a && do_cmp(base + a, base + b, cmp_func, priv) >= 0) |
| b = parent(b, lsbit, size); |
| c = b; /* Where "a" belongs */ |
| while (b != a) { /* Shift it into place */ |
| b = parent(b, lsbit, size); |
| do_swap(base + b, base + c, size, swap_func); |
| } |
| } |
| } |
| EXPORT_SYMBOL(sort_r); |
| |
| void sort(void *base, size_t num, size_t size, |
| cmp_func_t cmp_func, |
| swap_func_t swap_func) |
| { |
| return sort_r(base, num, size, _CMP_WRAPPER, swap_func, cmp_func); |
| } |
| EXPORT_SYMBOL(sort); |