/* * Copyright (c) 2016-2022 Apple Inc. All rights reserved. * * @APPLE_OSREFERENCE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. The rights granted to you under the License * may not be used to create, or enable the creation or redistribution of, * unlawful or unlicensed copies of an Apple operating system, or to * circumvent, violate, or enable the circumvention or violation of, any * terms of an Apple operating system software license agreement. * * Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_OSREFERENCE_LICENSE_HEADER_END@ */ #include #include static errno_t kern_pbufpool_alloc_common(const kern_pbufpool_t, const uint32_t, kern_packet_t *, uint32_t); static errno_t kern_pbufpool_alloc_batch_common(const kern_pbufpool_t, const uint32_t, kern_packet_t *, uint32_t *, alloc_cb_func_t, const void *, uint32_t); #define KBI_INVALID_CB_PAIRS(cb1, cb2) \ (!(init->kbi_##cb1 == NULL && init->kbi_##cb2 == NULL) && \ ((init->kbi_##cb1 == NULL) ^ (init->kbi_##cb2 == NULL))) errno_t kern_pbufpool_create(const struct kern_pbufpool_init *init, kern_pbufpool_t *ppp, struct kern_pbufpool_memory_info *pp_info) { /* XXX: woodford_s - find a way to get 'srp' off the kernel stack */ struct skmem_region_params srp[SKMEM_REGIONS]; struct kern_pbufpool *pp = NULL; nexus_meta_type_t md_type; nexus_meta_subtype_t md_subtype; uint32_t buf_cnt; uint16_t max_frags; uint32_t ppcreatef = PPCREATEF_EXTERNAL; uint32_t pkt_cnt; uint32_t pp_region_flags = 0; int err = 0; bool kernel_only; bool tx_pool = true; if (ppp == NULL || init == NULL || init->kbi_version != KERN_PBUFPOOL_CURRENT_VERSION || init->kbi_packets == 0 || (init->kbi_buflets != 0 && init->kbi_buflets < init->kbi_packets && !(init->kbi_flags & KBIF_BUFFER_ON_DEMAND)) || init->kbi_bufsize == 0 || init->kbi_max_frags == 0 || ((init->kbi_flags & KBIF_QUANTUM) && (init->kbi_flags & KBIF_BUFFER_ON_DEMAND)) || KBI_INVALID_CB_PAIRS(buf_seg_ctor, buf_seg_dtor)) { err = EINVAL; goto done; } *ppp = NULL; md_type = ((init->kbi_flags & KBIF_QUANTUM) ? NEXUS_META_TYPE_QUANTUM : NEXUS_META_TYPE_PACKET); /* * If packet, we assume this is for a driver handling raw frames. * This also implies that at present, we do not create mirrored * regions for user space to conserve memory (since those regions * aren't going to be used anyway.) * * XXX: adi@apple.com - to allow for "direct" channels from * user process to driver, we will need to revisit this. */ md_subtype = ((md_type == NEXUS_META_TYPE_QUANTUM) ? NEXUS_META_SUBTYPE_PAYLOAD : NEXUS_META_SUBTYPE_RAW); kernel_only = (md_type == NEXUS_META_TYPE_PACKET) && #if (DEVELOPMENT || DEBUG) !skywalk_netif_direct_enabled() && #endif /* (DEVELOPMENT || DEBUG) */ ((init->kbi_flags & KBIF_USER_ACCESS) == 0); VERIFY((init->kbi_max_frags != 0) && (init->kbi_max_frags <= UINT16_MAX)); max_frags = (uint16_t)init->kbi_max_frags; if (md_type == NEXUS_META_TYPE_QUANTUM && max_frags > 1) { err = EINVAL; goto done; } if ((max_frags > 1) && !(init->kbi_flags & KBIF_BUFFER_ON_DEMAND)) { err = EINVAL; goto done; } bzero(&srp, sizeof(srp)); for (int i = 0; i < SKMEM_REGIONS; i++) { srp[i] = *skmem_get_default(i); } switch (init->kbi_flags & (KBIF_IODIR_IN | KBIF_IODIR_OUT)) { case KBIF_IODIR_IN: pp_region_flags |= PP_REGION_CONFIG_BUF_IODIR_IN; tx_pool = false; break; case KBIF_IODIR_OUT: pp_region_flags |= PP_REGION_CONFIG_BUF_IODIR_OUT; break; case (KBIF_IODIR_IN | KBIF_IODIR_OUT): default: pp_region_flags |= PP_REGION_CONFIG_BUF_IODIR_BIDIR; break; } if (init->kbi_flags & KBIF_BUFFER_ON_DEMAND) { pp_region_flags |= PP_REGION_CONFIG_BUFLET; } if (kernel_only) { pp_region_flags |= PP_REGION_CONFIG_KERNEL_ONLY; } if (init->kbi_flags & KBIF_KERNEL_READONLY) { pp_region_flags |= PP_REGION_CONFIG_BUF_KREADONLY; } if (init->kbi_flags & KBIF_THREADSAFE) { pp_region_flags |= PP_REGION_CONFIG_BUF_THREADSAFE; } /* * Enable magazine layer for metadata. */ if (!(init->kbi_flags & KBIF_NO_MAGAZINES)) { pp_region_flags |= PP_REGION_CONFIG_MD_MAGAZINE_ENABLE; } pp_region_flags |= PP_REGION_CONFIG_MD_PERSISTENT; pkt_cnt = init->kbi_packets; /* * For TCP to be able to send a 4MB window worth of data, packet pool * must have at least 4MB/MTU packets. On devices which are not * memory constrained, we can increase the pool to be atleast * 4K packets. */ if (tx_pool && !SKMEM_MEM_CONSTRAINED_DEVICE() && #if (DEVELOPMENT || DEBUG) !skmem_test_enabled() && #endif /* (DEVELOPMENT || DEBUG) */ !(init->kbi_flags & KBIF_MONOLITHIC) && !(init->kbi_flags & KBIF_VIRTUAL_DEVICE) && !(init->kbi_flags & KBIF_PHYS_CONTIGUOUS) && !(init->kbi_flags & KBIF_KERNEL_READONLY) && !(init->kbi_flags & KBIF_QUANTUM)) { pkt_cnt = MAX((4 * 1024), pkt_cnt); } #if (DEVELOPMENT || DEBUG) if (sk_min_pool_size != 0) { pkt_cnt = MAX(pkt_cnt, sk_min_pool_size); } #endif /* (DEVELOPMENT || DEBUG) */ /* make sure # of buffers is >= # of packets */ buf_cnt = MAX(pkt_cnt, init->kbi_buflets); /* * Apply same logic as in nxprov_create_common(). */ if (init->kbi_flags & (KBIF_PERSISTENT | KBIF_MONOLITHIC | KBIF_INHIBIT_CACHE | KBIF_PHYS_CONTIGUOUS)) { if (init->kbi_flags & KBIF_PERSISTENT) { pp_region_flags |= PP_REGION_CONFIG_BUF_PERSISTENT; } if (init->kbi_flags & KBIF_MONOLITHIC) { pp_region_flags |= PP_REGION_CONFIG_BUF_MONOLITHIC; } if (init->kbi_flags & KBIF_INHIBIT_CACHE) { pp_region_flags |= PP_REGION_CONFIG_BUF_NOCACHE; } if (init->kbi_flags & KBIF_PHYS_CONTIGUOUS) { pp_region_flags |= PP_REGION_CONFIG_BUF_SEGPHYSCONTIG; } } /* adjust region params */ pp_regions_params_adjust(srp, md_type, md_subtype, pkt_cnt, max_frags, init->kbi_bufsize, 0, buf_cnt, init->kbi_buf_seg_size, pp_region_flags); /* * Create packet pool. */ ASSERT(ppcreatef & PPCREATEF_EXTERNAL); if (kernel_only) { ppcreatef |= PPCREATEF_KERNEL_ONLY; } if (init->kbi_flags & KBIF_BUFFER_ON_DEMAND) { ppcreatef |= PPCREATEF_ONDEMAND_BUF; } /* * Enable CPU-layer magazine resizing if this is a long-lived * pbufpool, e.g. one that's allocated by a device driver. */ if (!(init->kbi_flags & KBIF_VIRTUAL_DEVICE)) { ppcreatef |= PPCREATEF_DYNAMIC; } if ((pp = pp_create((const char *)init->kbi_name, srp, init->kbi_buf_seg_ctor, init->kbi_buf_seg_dtor, init->kbi_ctx, init->kbi_ctx_retain, init->kbi_ctx_release, ppcreatef)) == NULL) { err = ENOMEM; goto done; } *ppp = pp; if (pp_info != NULL) { err = kern_pbufpool_get_memory_info(pp, pp_info); VERIFY(err == 0); } done: if (err != 0 && pp != NULL) { /* callee drops reference */ pp_close(pp); pp = NULL; } return err; } void * kern_pbufpool_get_context(const kern_pbufpool_t pp) { void *ctx = (pp->pp_flags & PPF_EXTERNAL) ? pp->pp_ctx : NULL; if (ctx != NULL) { pp->pp_ctx_retain(ctx); } return ctx; } errno_t kern_pbufpool_get_memory_info(const kern_pbufpool_t pp, struct kern_pbufpool_memory_info *pp_info) { if (pp_info == NULL) { return EINVAL; } bzero(pp_info, sizeof(*pp_info)); if (pp->pp_flags & PPF_EXTERNAL) { pp_info->kpm_flags |= KPMF_EXTERNAL; } pp_info->kpm_packets = pp->pp_kmd_region->skr_c_obj_cnt; pp_info->kpm_max_frags = pp->pp_max_frags; pp_info->kpm_buflets = PP_BUF_REGION_DEF(pp)->skr_c_obj_cnt; pp_info->kpm_bufsize = PP_BUF_SIZE_DEF(pp); pp_info->kpm_buf_obj_size = PP_BUF_OBJ_SIZE_DEF(pp); pp_info->kpm_bufsegs = PP_BUF_REGION_DEF(pp)->skr_seg_max_cnt; pp_info->kpm_buf_seg_size = PP_BUF_REGION_DEF(pp)->skr_seg_size; return 0; } kern_segment_idx_t kern_segment_get_index(const kern_segment_t seg) { return seg->sg_index; } static errno_t kern_pbufpool_alloc_common(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *pph, uint32_t skmflag) { struct __kern_quantum *kqum; *pph = 0; if (__improbable(bufcnt > pp->pp_max_frags)) { return EINVAL; } if (__improbable((bufcnt != pp->pp_max_frags) && !PP_HAS_BUFFER_ON_DEMAND(pp))) { return EINVAL; } kqum = SK_PTR_ADDR_KQUM(pp_alloc_packet(pp, (uint16_t)bufcnt, skmflag)); if (__probable(kqum != NULL)) { *pph = SK_PTR_ENCODE(kqum, METADATA_TYPE(kqum), METADATA_SUBTYPE(kqum)); } return (kqum != NULL) ? 0 : ENOMEM; } errno_t kern_pbufpool_alloc(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *pph) { return kern_pbufpool_alloc_common(pp, bufcnt, pph, SKMEM_SLEEP); } errno_t kern_pbufpool_alloc_nosleep(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *pph) { return kern_pbufpool_alloc_common(pp, bufcnt, pph, SKMEM_NOSLEEP); } static errno_t kern_pbufpool_alloc_batch_common(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *array, uint32_t *size, alloc_cb_func_t cb, const void *ctx, uint32_t skmflag) { if (__improbable(array == NULL || size == NULL || *size == 0 || bufcnt > pp->pp_max_frags || (cb == NULL && ctx != NULL))) { return EINVAL; } if (__improbable((bufcnt != pp->pp_max_frags) && !PP_HAS_BUFFER_ON_DEMAND(pp))) { return EINVAL; } return pp_alloc_packet_batch(pp, (uint16_t)bufcnt, array, size, TRUE, cb, ctx, skmflag); } errno_t kern_pbufpool_alloc_batch(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *array, uint32_t *size) { return kern_pbufpool_alloc_batch_common(pp, bufcnt, array, size, NULL, NULL, SKMEM_SLEEP); } errno_t kern_pbufpool_alloc_batch_callback(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *array, uint32_t *size, alloc_cb_func_t cb, const void *ctx) { return kern_pbufpool_alloc_batch_common(pp, bufcnt, array, size, cb, ctx, SKMEM_SLEEP); } errno_t kern_pbufpool_alloc_batch_nosleep(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *array, uint32_t *size) { return kern_pbufpool_alloc_batch_common(pp, bufcnt, array, size, NULL, NULL, SKMEM_NOSLEEP); } errno_t kern_pbufpool_alloc_batch_nosleep_callback(const kern_pbufpool_t pp, const uint32_t bufcnt, kern_packet_t *array, uint32_t *size, alloc_cb_func_t cb, const void *ctx) { return kern_pbufpool_alloc_batch_common(pp, bufcnt, array, size, cb, ctx, SKMEM_NOSLEEP); } void kern_pbufpool_free(const kern_pbufpool_t pp, kern_packet_t ph) { pp_free_packet(pp, SK_PTR_ADDR(ph)); } void kern_pbufpool_free_batch(const kern_pbufpool_t pp, kern_packet_t *array, uint32_t size) { if (__improbable(array == NULL || size == 0)) { return; } pp_free_packet_batch(pp, array, size); } void kern_pbufpool_free_chain(const kern_pbufpool_t pp, kern_packet_t chain) { struct __kern_packet *pkt_chain = SK_PTR_ADDR_KPKT(chain); VERIFY(pp == pkt_chain->pkt_qum.qum_pp); pp_free_packet_chain(pkt_chain, NULL); } errno_t kern_pbufpool_alloc_buffer(const kern_pbufpool_t pp, mach_vm_address_t *buf, kern_segment_t *sg, kern_obj_idx_seg_t *sg_idx) { return pp_alloc_buffer(pp, buf, sg, sg_idx, 0); } errno_t kern_pbufpool_alloc_buffer_nosleep(const kern_pbufpool_t pp, mach_vm_address_t *buf, kern_segment_t *sg, kern_obj_idx_seg_t *sg_idx) { return pp_alloc_buffer(pp, buf, sg, sg_idx, SKMEM_NOSLEEP); } void kern_pbufpool_free_buffer(const kern_pbufpool_t pp, mach_vm_address_t baddr) { pp_free_buffer(pp, baddr); } void kern_pbufpool_destroy(kern_pbufpool_t pp) { VERIFY(pp->pp_flags & PPF_EXTERNAL); pp_close(pp); } errno_t kern_pbufpool_alloc_buflet(const kern_pbufpool_t pp, kern_buflet_t *pbuf) { return pp_alloc_buflet(pp, pbuf, SKMEM_SLEEP, false); } errno_t kern_pbufpool_alloc_buflet_nosleep(const kern_pbufpool_t pp, kern_buflet_t *pbuf) { return pp_alloc_buflet(pp, pbuf, SKMEM_NOSLEEP, false); }