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/* SPDX-License-Identifier: Apache-2.0
* Copyright(c) 2022 Cisco Systems, Inc.
* Copyright (c) 2022 Intel and/or its affiliates.
*/
#include <vlib/vlib.h>
#include <vlib/pci/pci.h>
#include <vlib/dma/dma.h>
#include <vppinfra/heap.h>
#include <vppinfra/atomics.h>
#include <vnet/plugin/plugin.h>
#include <vpp/app/version.h>
#include <dma_intel/dsa_intel.h>
extern vlib_node_registration_t intel_dsa_node;
VLIB_REGISTER_LOG_CLASS (intel_dsa_log, static) = {
.class_name = "intel_dsa",
.subclass_name = "dsa",
};
static void
intel_dsa_channel_lock (intel_dsa_channel_t *ch)
{
u8 expected = 0;
if (ch->n_threads < 2)
return;
/* channel is used by multiple threads so we need to lock it */
while (!__atomic_compare_exchange_n (&ch->lock, &expected,
/* desired */ 1, /* weak */ 0,
__ATOMIC_ACQUIRE, __ATOMIC_RELAXED))
{
while (__atomic_load_n (&ch->lock, __ATOMIC_RELAXED))
CLIB_PAUSE ();
expected = 0;
}
}
static void
intel_dsa_channel_unlock (intel_dsa_channel_t *ch)
{
if (ch->n_threads < 2)
return;
__atomic_store_n (&ch->lock, 0, __ATOMIC_RELEASE);
}
static vlib_dma_batch_t *
intel_dsa_batch_new (vlib_main_t *vm, struct vlib_dma_config_data *cd)
{
intel_dsa_main_t *idm = &intel_dsa_main;
intel_dsa_config_t *idc;
intel_dsa_batch_t *b;
idc = vec_elt_at_index (idm->dsa_config_heap,
cd->private_data + vm->thread_index);
if (vec_len (idc->freelist) > 0)
b = vec_pop (idc->freelist);
else
{
clib_spinlock_lock (&idm->lock);
b = vlib_physmem_alloc (vm, idc->alloc_size);
clib_spinlock_unlock (&idm->lock);
/* if no free space in physmem, force quit */
ASSERT (b != NULL);
*b = idc->batch_template;
b->max_transfers = idc->max_transfers;
u32 def_flags = (INTEL_DSA_OP_MEMMOVE << INTEL_DSA_OP_SHIFT) |
INTEL_DSA_FLAG_CACHE_CONTROL;
if (b->ch->block_on_fault)
def_flags |= INTEL_DSA_FLAG_BLOCK_ON_FAULT;
for (int i = 0; i < idc->max_transfers; i++)
{
intel_dsa_desc_t *dsa_desc = b->descs + i;
dsa_desc->op_flags = def_flags;
}
}
return &b->batch;
}
#if defined(__x86_64__) || defined(i386)
static_always_inline void
__movdir64b (volatile void *dst, const void *src)
{
asm volatile(".byte 0x66, 0x0f, 0x38, 0xf8, 0x02"
:
: "a"(dst), "d"(src)
: "memory");
}
#endif
static_always_inline void
intel_dsa_batch_fallback (vlib_main_t *vm, intel_dsa_batch_t *b,
intel_dsa_channel_t *ch)
{
for (u16 i = 0; i < b->batch.n_enq; i++)
{
intel_dsa_desc_t *desc = &b->descs[i];
clib_memcpy_fast (desc->dst, desc->src, desc->size);
}
b->status = INTEL_DSA_STATUS_CPU_SUCCESS;
ch->submitted++;
return;
}
int
intel_dsa_batch_submit (vlib_main_t *vm, struct vlib_dma_batch *vb)
{
intel_dsa_main_t *idm = &intel_dsa_main;
intel_dsa_batch_t *b = (intel_dsa_batch_t *) vb;
intel_dsa_channel_t *ch = b->ch;
if (PREDICT_FALSE (vb->n_enq == 0))
{
vec_add1 (idm->dsa_config_heap[b->config_heap_index].freelist, b);
return 0;
}
intel_dsa_channel_lock (ch);
if (ch->n_enq >= ch->size)
{
if (!b->sw_fallback)
{
intel_dsa_channel_unlock (ch);
return 0;
}
/* skip channel limitation if first pending finished */
intel_dsa_batch_t *lb = NULL;
u32 n_pendings =
vec_len (idm->dsa_threads[vm->thread_index].pending_batches);
if (n_pendings)
lb =
idm->dsa_threads[vm->thread_index].pending_batches[n_pendings - 1];
if (!lb || lb->status != INTEL_DSA_STATUS_SUCCESS)
{
intel_dsa_batch_fallback (vm, b, ch);
goto done;
}
}
b->status = INTEL_DSA_STATUS_BUSY;
if (PREDICT_FALSE (vb->n_enq == 1))
{
intel_dsa_desc_t *desc = &b->descs[0];
desc->completion = (u64) &b->completion_cl;
desc->op_flags |= INTEL_DSA_FLAG_COMPLETION_ADDR_VALID |
INTEL_DSA_FLAG_REQUEST_COMPLETION;
#if defined(__x86_64__) || defined(i386)
_mm_sfence (); /* fence before writing desc to device */
__movdir64b (ch->portal, (void *) desc);
#endif
}
else
{
intel_dsa_desc_t *batch_desc = &b->descs[b->max_transfers];
batch_desc->op_flags = (INTEL_DSA_OP_BATCH << INTEL_DSA_OP_SHIFT) |
INTEL_DSA_FLAG_COMPLETION_ADDR_VALID |
INTEL_DSA_FLAG_REQUEST_COMPLETION;
batch_desc->desc_addr = (void *) (b->descs);
batch_desc->size = vb->n_enq;
batch_desc->completion = (u64) &b->completion_cl;
#if defined(__x86_64__) || defined(i386)
_mm_sfence (); /* fence before writing desc to device */
__movdir64b (ch->portal, (void *) batch_desc);
#endif
}
ch->submitted++;
ch->n_enq++;
done:
intel_dsa_channel_unlock (ch);
vec_add1 (idm->dsa_threads[vm->thread_index].pending_batches, b);
vlib_node_set_interrupt_pending (vm, intel_dsa_node.index);
return 1;
}
static int
intel_dsa_check_channel (intel_dsa_channel_t *ch, vlib_dma_config_data_t *cd)
{
if (!ch)
{
dsa_log_error ("no available dsa channel");
return 1;
}
vlib_dma_config_t supported_cfg = {
.barrier_before_last = 1,
.sw_fallback = 1,
};
if (cd->cfg.features & ~supported_cfg.features)
{
dsa_log_error ("unsupported feature requested");
return 1;
}
if (cd->cfg.max_transfers > ch->max_transfers)
{
dsa_log_error ("transfer number (%u) too big", cd->cfg.max_transfers);
return 1;
}
if (cd->cfg.max_transfer_size > ch->max_transfer_size)
{
dsa_log_error ("transfer size (%u) too big", cd->cfg.max_transfer_size);
return 1;
}
return 0;
}
static_always_inline void
intel_dsa_alloc_dma_batch (vlib_main_t *vm, intel_dsa_config_t *idc)
{
intel_dsa_batch_t *b;
b = vlib_physmem_alloc (vm, idc->alloc_size);
/* if no free space in physmem, force quit */
ASSERT (b != NULL);
*b = idc->batch_template;
b->max_transfers = idc->max_transfers;
u32 def_flags = (INTEL_DSA_OP_MEMMOVE << INTEL_DSA_OP_SHIFT) |
INTEL_DSA_FLAG_CACHE_CONTROL;
if (b->ch->block_on_fault)
def_flags |= INTEL_DSA_FLAG_BLOCK_ON_FAULT;
for (int i = 0; i < idc->max_transfers; i++)
{
intel_dsa_desc_t *dsa_desc = b->descs + i;
dsa_desc->op_flags = def_flags;
}
vec_add1 (idc->freelist, b);
}
static int
intel_dsa_config_add_fn (vlib_main_t *vm, vlib_dma_config_data_t *cd)
{
intel_dsa_main_t *idm = &intel_dsa_main;
intel_dsa_config_t *idc;
u32 index, n_threads = vlib_get_n_threads ();
vec_validate (idm->dsa_config_heap_handle_by_config_index, cd->config_index);
index = heap_alloc_aligned (
idm->dsa_config_heap, n_threads, CLIB_CACHE_LINE_BYTES,
idm->dsa_config_heap_handle_by_config_index[cd->config_index]);
cd->batch_new_fn = intel_dsa_batch_new;
cd->private_data = index;
for (u32 thread = 0; thread < n_threads; thread++)
{
intel_dsa_batch_t *idb;
vlib_dma_batch_t *b;
idc = vec_elt_at_index (idm->dsa_config_heap, index + thread);
/* size of physmem allocation for this config */
idc->max_transfers = cd->cfg.max_transfers;
idc->alloc_size = sizeof (intel_dsa_batch_t) +
sizeof (intel_dsa_desc_t) * (idc->max_transfers + 1);
/* fill batch template */
idb = &idc->batch_template;
idb->ch = idm->dsa_threads[thread].ch;
if (intel_dsa_check_channel (idb->ch, cd))
return 0;
dsa_log_debug ("config %d in thread %d using channel %u/%u",
cd->config_index, thread, idb->ch->did, idb->ch->qid);
idb->config_heap_index = index + thread;
idb->config_index = cd->config_index;
idb->batch.callback_fn = cd->cfg.callback_fn;
idb->features = cd->cfg.features;
b = &idb->batch;
b->stride = sizeof (intel_dsa_desc_t);
b->src_ptr_off = STRUCT_OFFSET_OF (intel_dsa_batch_t, descs[0].src);
b->dst_ptr_off = STRUCT_OFFSET_OF (intel_dsa_batch_t, descs[0].dst);
b->size_off = STRUCT_OFFSET_OF (intel_dsa_batch_t, descs[0].size);
b->submit_fn = intel_dsa_batch_submit;
dsa_log_debug (
"config %d in thread %d stride %d src/dst/size offset %d-%d-%d",
cd->config_index, thread, b->stride, b->src_ptr_off, b->dst_ptr_off,
b->size_off);
/* allocate dma batch in advance */
for (u32 index = 0; index < cd->cfg.max_batches; index++)
intel_dsa_alloc_dma_batch (vm, idc);
}
dsa_log_info ("config %u added", cd->private_data);
return 1;
}
static void
intel_dsa_config_del_fn (vlib_main_t *vm, vlib_dma_config_data_t *cd)
{
intel_dsa_main_t *idm = &intel_dsa_main;
intel_dsa_thread_t *t =
vec_elt_at_index (idm->dsa_threads, vm->thread_index);
u32 n_pending, n_threads, config_heap_index, n = 0;
n_threads = vlib_get_n_threads ();
if (!t->pending_batches)
goto free_heap;
n_pending = vec_len (t->pending_batches);
intel_dsa_batch_t *b;
/* clean pending list and free list */
for (u32 i = 0; i < n_pending; i++)
{
b = t->pending_batches[i];
if (b->config_index == cd->config_index)
{
vec_add1 (idm->dsa_config_heap[b->config_heap_index].freelist, b);
if (b->status == INTEL_DSA_STATUS_SUCCESS ||
b->status == INTEL_DSA_STATUS_BUSY)
b->ch->n_enq--;
}
else
t->pending_batches[n++] = b;
}
vec_set_len (t->pending_batches, n);
free_heap:
for (u32 thread = 0; thread < n_threads; thread++)
{
config_heap_index = cd->private_data + thread;
while (vec_len (idm->dsa_config_heap[config_heap_index].freelist) > 0)
{
b = vec_pop (idm->dsa_config_heap[config_heap_index].freelist);
vlib_physmem_free (vm, b);
}
}
heap_dealloc (idm->dsa_config_heap,
idm->dsa_config_heap_handle_by_config_index[cd->config_index]);
dsa_log_debug ("config %u removed", cd->private_data);
}
static uword
intel_dsa_node_fn (vlib_main_t *vm, vlib_node_runtime_t *node,
vlib_frame_t *frame)
{
intel_dsa_main_t *idm = &intel_dsa_main;
intel_dsa_thread_t *t =
vec_elt_at_index (idm->dsa_threads, vm->thread_index);
u32 n_pending = 0, n = 0;
u8 glitch = 0;
if (!t->pending_batches)
return 0;
n_pending = vec_len (t->pending_batches);
for (u32 i = 0; i < n_pending; i++)
{
intel_dsa_batch_t *b = t->pending_batches[i];
intel_dsa_channel_t *ch = b->ch;
if ((b->status == INTEL_DSA_STATUS_SUCCESS ||
b->status == INTEL_DSA_STATUS_CPU_SUCCESS) &&
!glitch)
{
/* callback */
if (b->batch.callback_fn)
b->batch.callback_fn (vm, &b->batch);
/* restore last descriptor fields */
if (b->batch.n_enq == 1)
{
b->descs[0].completion = 0;
b->descs[0].op_flags =
(INTEL_DSA_OP_MEMMOVE << INTEL_DSA_OP_SHIFT) |
INTEL_DSA_FLAG_CACHE_CONTROL;
if (b->ch->block_on_fault)
b->descs[0].op_flags |= INTEL_DSA_FLAG_BLOCK_ON_FAULT;
}
/* add to freelist */
vec_add1 (idm->dsa_config_heap[b->config_heap_index].freelist, b);
intel_dsa_channel_lock (ch);
if (b->status == INTEL_DSA_STATUS_SUCCESS)
{
ch->n_enq--;
ch->completed++;
}
else
ch->sw_fallback++;
intel_dsa_channel_unlock (ch);
b->batch.n_enq = 0;
b->status = INTEL_DSA_STATUS_IDLE;
}
else if (b->status == INTEL_DSA_STATUS_BUSY)
{
glitch = 1 & b->barrier_before_last;
t->pending_batches[n++] = b;
}
else if (!glitch)
{
/* fallback to software if exception happened */
intel_dsa_batch_fallback (vm, b, ch);
glitch = 1 & b->barrier_before_last;
}
else
{
t->pending_batches[n++] = b;
}
}
vec_set_len (t->pending_batches, n);
if (n)
{
vlib_node_set_interrupt_pending (vm, intel_dsa_node.index);
}
return n_pending - n;
}
u8 *
format_dsa_info (u8 *s, va_list *args)
{
intel_dsa_main_t *idm = &intel_dsa_main;
vlib_main_t *vm = va_arg (*args, vlib_main_t *);
intel_dsa_channel_t *ch;
ch = idm->dsa_threads[vm->thread_index].ch;
s = format (s, "thread %d dma %u/%u request %-16lld hw %-16lld cpu %-16lld",
vm->thread_index, ch->did, ch->qid, ch->submitted, ch->completed,
ch->sw_fallback);
return s;
}
VLIB_REGISTER_NODE (intel_dsa_node) = {
.function = intel_dsa_node_fn,
.name = "intel-dsa",
.type = VLIB_NODE_TYPE_INPUT,
.state = VLIB_NODE_STATE_INTERRUPT,
.vector_size = 4,
};
vlib_dma_backend_t intel_dsa_backend = {
.name = "Intel DSA",
.config_add_fn = intel_dsa_config_add_fn,
.config_del_fn = intel_dsa_config_del_fn,
.info_fn = format_dsa_info,
};
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