/* * Copyright (c) 2021 Intel Corporation * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include /* Number of bits represented by one bundle */ #define bundle_bitness(ba) (sizeof((ba)->bundles[0]) * 8) struct bundle_data { /* Start and end index of bundles */ size_t sidx, eidx; /* Offset inside start and end bundles */ size_t soff, eoff; /* Masks for start/end bundles */ uint32_t smask, emask; }; static void setup_bundle_data(sys_bitarray_t *bitarray, struct bundle_data *bd, size_t offset, size_t num_bits) { bd->sidx = offset / bundle_bitness(bitarray); bd->soff = offset % bundle_bitness(bitarray); bd->eidx = (offset + num_bits - 1) / bundle_bitness(bitarray); bd->eoff = (offset + num_bits - 1) % bundle_bitness(bitarray); bd->smask = ~(BIT(bd->soff) - 1); bd->emask = (BIT(bd->eoff) - 1) | BIT(bd->eoff); if (bd->sidx == bd->eidx) { /* The region lies within the same bundle. So combine the masks. */ bd->smask &= bd->emask; } } /* * Find out if the bits in a region is all set or all clear. * * @param[in] bitarray Bitarray struct * @param[in] offset Starting bit location * @param[in] num_bits Number of bits in the region * @param[in] match_set True if matching all set bits, * False if matching all cleared bits * @param[out] bd Data related to matching which can be * used later to find out where the region * lies in the bitarray bundles. * @param[out] mismatch Offset to the mismatched bit. * Can be NULL. * * @retval true If all bits are set or cleared * @retval false Not all bits are set or cleared */ static bool match_region(sys_bitarray_t *bitarray, size_t offset, size_t num_bits, bool match_set, struct bundle_data *bd, size_t *mismatch) { size_t idx; uint32_t bundle; uint32_t mismatch_bundle; size_t mismatch_bundle_idx; size_t mismatch_bit_off; setup_bundle_data(bitarray, bd, offset, num_bits); if (bd->sidx == bd->eidx) { bundle = bitarray->bundles[bd->sidx]; if (!match_set) { bundle = ~bundle; } if ((bundle & bd->smask) != bd->smask) { /* Not matching to mask. */ mismatch_bundle = ~bundle & bd->smask; mismatch_bundle_idx = bd->sidx; goto mismatch; } else { /* Matching to mask. */ goto out; } } /* Region lies in a number of bundles. Need to loop through them. */ /* Start of bundles */ bundle = bitarray->bundles[bd->sidx]; if (!match_set) { bundle = ~bundle; } if ((bundle & bd->smask) != bd->smask) { /* Start bundle not matching to mask. */ mismatch_bundle = ~bundle & bd->smask; mismatch_bundle_idx = bd->sidx; goto mismatch; } /* End of bundles */ bundle = bitarray->bundles[bd->eidx]; if (!match_set) { bundle = ~bundle; } if ((bundle & bd->emask) != bd->emask) { /* End bundle not matching to mask. */ mismatch_bundle = ~bundle & bd->emask; mismatch_bundle_idx = bd->eidx; goto mismatch; } /* In-between bundles */ for (idx = bd->sidx + 1; idx < bd->eidx; idx++) { /* Note that this is opposite from above so that * we are simply checking if bundle == 0. */ bundle = bitarray->bundles[idx]; if (match_set) { bundle = ~bundle; } if (bundle != 0U) { /* Bits in "between bundles" do not match */ mismatch_bundle = bundle; mismatch_bundle_idx = idx; goto mismatch; } } out: /* All bits in region matched. */ return true; mismatch: if (mismatch != NULL) { /* Must have at least 1 bit set to indicate * where the mismatch is. */ __ASSERT_NO_MSG(mismatch_bundle != 0); mismatch_bit_off = find_lsb_set(mismatch_bundle) - 1; mismatch_bit_off += mismatch_bundle_idx * bundle_bitness(bitarray); *mismatch = (uint32_t)mismatch_bit_off; } return false; } /* * Set or clear a region of bits. * * @param bitarray Bitarray struct * @param offset Starting bit location * @param num_bits Number of bits in the region * @param to_set True if to set all bits. * False if to clear all bits. * @param bd Bundle data. Can reuse the output from * match_region(). NULL if there is no * prior call to match_region(). */ static void set_region(sys_bitarray_t *bitarray, size_t offset, size_t num_bits, bool to_set, struct bundle_data *bd) { size_t idx; struct bundle_data bdata; if (bd == NULL) { bd = &bdata; setup_bundle_data(bitarray, bd, offset, num_bits); } if (bd->sidx == bd->eidx) { /* Start/end at same bundle */ if (to_set) { bitarray->bundles[bd->sidx] |= bd->smask; } else { bitarray->bundles[bd->sidx] &= ~bd->smask; } } else { /* Start/end at different bundle. * So set/clear the bits in start and end bundles * separately. For in-between bundles, * set/clear all bits. */ if (to_set) { bitarray->bundles[bd->sidx] |= bd->smask; bitarray->bundles[bd->eidx] |= bd->emask; for (idx = bd->sidx + 1; idx < bd->eidx; idx++) { bitarray->bundles[idx] = ~0U; } } else { bitarray->bundles[bd->sidx] &= ~bd->smask; bitarray->bundles[bd->eidx] &= ~bd->emask; for (idx = bd->sidx + 1; idx < bd->eidx; idx++) { bitarray->bundles[idx] = 0U; } } } } int sys_bitarray_popcount_region(sys_bitarray_t *bitarray, size_t num_bits, size_t offset, size_t *count) { k_spinlock_key_t key; size_t idx; struct bundle_data bd; int ret; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); if (num_bits == 0 || offset + num_bits > bitarray->num_bits) { ret = -EINVAL; goto out; } CHECKIF(count == NULL) { ret = -EINVAL; goto out; } setup_bundle_data(bitarray, &bd, offset, num_bits); if (bd.sidx == bd.eidx) { /* Start/end at same bundle */ *count = POPCOUNT(bitarray->bundles[bd.sidx] & bd.smask); } else { /* Start/end at different bundle. * So count the bits in start and end bundles * separately with correct mask applied. For in-between bundles, * count all bits. */ *count = 0; *count += POPCOUNT(bitarray->bundles[bd.sidx] & bd.smask); *count += POPCOUNT(bitarray->bundles[bd.eidx] & bd.emask); for (idx = bd.sidx + 1; idx < bd.eidx; idx++) { *count += POPCOUNT(bitarray->bundles[idx]); } } ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_xor(sys_bitarray_t *dst, sys_bitarray_t *other, size_t num_bits, size_t offset) { k_spinlock_key_t key_dst, key_other; int ret; size_t idx; struct bundle_data bd; __ASSERT_NO_MSG(dst != NULL); __ASSERT_NO_MSG(dst->num_bits > 0); __ASSERT_NO_MSG(other != NULL); __ASSERT_NO_MSG(other->num_bits > 0); key_dst = k_spin_lock(&dst->lock); key_other = k_spin_lock(&other->lock); if (dst->num_bits != other->num_bits) { ret = -EINVAL; goto out; } if (num_bits == 0 || offset + num_bits > dst->num_bits) { ret = -EINVAL; goto out; } setup_bundle_data(other, &bd, offset, num_bits); if (bd.sidx == bd.eidx) { /* Start/end at same bundle */ dst->bundles[bd.sidx] = ((other->bundles[bd.sidx] ^ dst->bundles[bd.sidx]) & bd.smask) | (dst->bundles[bd.sidx] & ~bd.smask); } else { /* Start/end at different bundle. * So xor the bits in start and end bundles according to their bitmasks * separately. For in-between bundles, * xor all bits. */ dst->bundles[bd.sidx] = ((other->bundles[bd.sidx] ^ dst->bundles[bd.sidx]) & bd.smask) | (dst->bundles[bd.sidx] & ~bd.smask); dst->bundles[bd.eidx] = ((other->bundles[bd.eidx] ^ dst->bundles[bd.eidx]) & bd.emask) | (dst->bundles[bd.eidx] & ~bd.emask); for (idx = bd.sidx + 1; idx < bd.eidx; idx++) { dst->bundles[idx] ^= other->bundles[idx]; } } ret = 0; out: k_spin_unlock(&other->lock, key_other); k_spin_unlock(&dst->lock, key_dst); return ret; } int sys_bitarray_set_bit(sys_bitarray_t *bitarray, size_t bit) { k_spinlock_key_t key; int ret; size_t idx, off; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); if (bit >= bitarray->num_bits) { ret = -EINVAL; goto out; } idx = bit / bundle_bitness(bitarray); off = bit % bundle_bitness(bitarray); bitarray->bundles[idx] |= BIT(off); ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_clear_bit(sys_bitarray_t *bitarray, size_t bit) { k_spinlock_key_t key; int ret; size_t idx, off; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); if (bit >= bitarray->num_bits) { ret = -EINVAL; goto out; } idx = bit / bundle_bitness(bitarray); off = bit % bundle_bitness(bitarray); bitarray->bundles[idx] &= ~BIT(off); ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_test_bit(sys_bitarray_t *bitarray, size_t bit, int *val) { k_spinlock_key_t key; int ret; size_t idx, off; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); CHECKIF(val == NULL) { ret = -EINVAL; goto out; } if (bit >= bitarray->num_bits) { ret = -EINVAL; goto out; } idx = bit / bundle_bitness(bitarray); off = bit % bundle_bitness(bitarray); if ((bitarray->bundles[idx] & BIT(off)) != 0) { *val = 1; } else { *val = 0; } ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_test_and_set_bit(sys_bitarray_t *bitarray, size_t bit, int *prev_val) { k_spinlock_key_t key; int ret; size_t idx, off; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); CHECKIF(prev_val == NULL) { ret = -EINVAL; goto out; } if (bit >= bitarray->num_bits) { ret = -EINVAL; goto out; } idx = bit / bundle_bitness(bitarray); off = bit % bundle_bitness(bitarray); if ((bitarray->bundles[idx] & BIT(off)) != 0) { *prev_val = 1; } else { *prev_val = 0; } bitarray->bundles[idx] |= BIT(off); ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_test_and_clear_bit(sys_bitarray_t *bitarray, size_t bit, int *prev_val) { k_spinlock_key_t key; int ret; size_t idx, off; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); CHECKIF(prev_val == NULL) { ret = -EINVAL; goto out; } if (bit >= bitarray->num_bits) { ret = -EINVAL; goto out; } idx = bit / bundle_bitness(bitarray); off = bit % bundle_bitness(bitarray); if ((bitarray->bundles[idx] & BIT(off)) != 0) { *prev_val = 1; } else { *prev_val = 0; } bitarray->bundles[idx] &= ~BIT(off); ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_alloc(sys_bitarray_t *bitarray, size_t num_bits, size_t *offset) { k_spinlock_key_t key; uint32_t bit_idx; int ret; struct bundle_data bd; size_t off_start, off_end; size_t mismatch; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); CHECKIF(offset == NULL) { ret = -EINVAL; goto out; } if ((num_bits == 0) || (num_bits > bitarray->num_bits)) { ret = -EINVAL; goto out; } bit_idx = 0; /* Find the first non-allocated bit by looking at bundles * instead of individual bits. * * On RISC-V 64-bit, it complains about undefined reference to `ffs`. * So don't use this on RISCV64. */ for (size_t idx = 0; idx < bitarray->num_bundles; idx++) { if (~bitarray->bundles[idx] == 0U) { /* bundle is all 1s => all allocated, skip */ bit_idx += bundle_bitness(bitarray); continue; } if (bitarray->bundles[idx] != 0U) { /* Find the first free bit in bundle if not all free */ off_start = find_lsb_set(~bitarray->bundles[idx]) - 1; bit_idx += off_start; } break; } off_end = bitarray->num_bits - num_bits; ret = -ENOSPC; while (bit_idx <= off_end) { if (match_region(bitarray, bit_idx, num_bits, false, &bd, &mismatch)) { set_region(bitarray, bit_idx, num_bits, true, &bd); *offset = bit_idx; ret = 0; break; } /* Fast-forward to the bit just after * the mismatched bit. */ bit_idx = mismatch + 1; } out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_find_nth_set(sys_bitarray_t *bitarray, size_t n, size_t num_bits, size_t offset, size_t *found_at) { k_spinlock_key_t key; size_t count, idx; uint32_t mask; struct bundle_data bd; int ret; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); if (n == 0 || num_bits == 0 || offset + num_bits > bitarray->num_bits) { ret = -EINVAL; goto out; } ret = 1; mask = 0; setup_bundle_data(bitarray, &bd, offset, num_bits); count = POPCOUNT(bitarray->bundles[bd.sidx] & bd.smask); /* If we already found more bits set than n, we found the target bundle */ if (count >= n) { idx = bd.sidx; mask = bd.smask; goto found; } /* Keep looking if there are more bundles */ if (bd.sidx != bd.eidx) { /* We are now only looking for the remaining bits */ n -= count; /* First bundle was already checked, keep looking in middle (complete) * bundles. */ for (idx = bd.sidx + 1; idx < bd.eidx; idx++) { count = POPCOUNT(bitarray->bundles[idx]); if (count >= n) { mask = ~(mask & 0); goto found; } n -= count; } /* Continue searching in last bundle */ count = POPCOUNT(bitarray->bundles[bd.eidx] & bd.emask); if (count >= n) { idx = bd.eidx; mask = bd.emask; goto found; } } goto out; found: /* The bit we are looking for must be in the current bundle idx. * Find out the exact index of the bit. */ for (int j = 0; j <= bundle_bitness(bitarray) - 1; j++) { if (bitarray->bundles[idx] & mask & BIT(j)) { if (--n <= 0) { *found_at = idx * bundle_bitness(bitarray) + j; ret = 0; break; } } } out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_free(sys_bitarray_t *bitarray, size_t num_bits, size_t offset) { k_spinlock_key_t key; int ret; size_t off_end = offset + num_bits - 1; struct bundle_data bd; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); key = k_spin_lock(&bitarray->lock); if ((num_bits == 0) || (num_bits > bitarray->num_bits) || (offset >= bitarray->num_bits) || (off_end >= bitarray->num_bits)) { ret = -EINVAL; goto out; } /* Note that we need to make sure the bits in specified region * (offset to offset + num_bits) are all allocated before we clear * them. */ if (match_region(bitarray, offset, num_bits, true, &bd, NULL)) { set_region(bitarray, offset, num_bits, false, &bd); ret = 0; } else { ret = -EFAULT; } out: k_spin_unlock(&bitarray->lock, key); return ret; } static bool is_region_set_clear(sys_bitarray_t *bitarray, size_t num_bits, size_t offset, bool to_set) { bool ret; struct bundle_data bd; size_t off_end = offset + num_bits - 1; k_spinlock_key_t key = k_spin_lock(&bitarray->lock); __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); if ((num_bits == 0) || (num_bits > bitarray->num_bits) || (offset >= bitarray->num_bits) || (off_end >= bitarray->num_bits)) { ret = false; goto out; } ret = match_region(bitarray, offset, num_bits, to_set, &bd, NULL); out: k_spin_unlock(&bitarray->lock, key); return ret; } bool sys_bitarray_is_region_set(sys_bitarray_t *bitarray, size_t num_bits, size_t offset) { return is_region_set_clear(bitarray, num_bits, offset, true); } bool sys_bitarray_is_region_cleared(sys_bitarray_t *bitarray, size_t num_bits, size_t offset) { return is_region_set_clear(bitarray, num_bits, offset, false); } static int set_clear_region(sys_bitarray_t *bitarray, size_t num_bits, size_t offset, bool to_set) { int ret; size_t off_end = offset + num_bits - 1; k_spinlock_key_t key = k_spin_lock(&bitarray->lock); __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); if ((num_bits == 0) || (num_bits > bitarray->num_bits) || (offset >= bitarray->num_bits) || (off_end >= bitarray->num_bits)) { ret = -EINVAL; goto out; } set_region(bitarray, offset, num_bits, to_set, NULL); ret = 0; out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_test_and_set_region(sys_bitarray_t *bitarray, size_t num_bits, size_t offset, bool to_set) { int ret; bool region_clear; struct bundle_data bd; __ASSERT_NO_MSG(bitarray != NULL); __ASSERT_NO_MSG(bitarray->num_bits > 0); size_t off_end = offset + num_bits - 1; k_spinlock_key_t key = k_spin_lock(&bitarray->lock); if ((num_bits == 0) || (num_bits > bitarray->num_bits) || (offset >= bitarray->num_bits) || (off_end >= bitarray->num_bits)) { ret = -EINVAL; goto out; } region_clear = match_region(bitarray, offset, num_bits, !to_set, &bd, NULL); if (region_clear) { set_region(bitarray, offset, num_bits, to_set, &bd); ret = 0; } else { ret = -EEXIST; } out: k_spin_unlock(&bitarray->lock, key); return ret; } int sys_bitarray_set_region(sys_bitarray_t *bitarray, size_t num_bits, size_t offset) { return set_clear_region(bitarray, num_bits, offset, true); } int sys_bitarray_clear_region(sys_bitarray_t *bitarray, size_t num_bits, size_t offset) { return set_clear_region(bitarray, num_bits, offset, false); }