| Message ID | 20240425022117.4035031-5-hao.xiang@linux.dev (mailing list archive) |
|---|---|
| State | New, archived |
| Headers | show |
| Series | Use Intel DSA accelerator to offload zero page checking in multifd live migration. | expand |
Hao Xiang <hao.xiang@linux.dev> writes: > * Use a safe thread queue for DSA task enqueue/dequeue. > * Implement DSA task submission. > * Implement DSA batch task submission. > > Signed-off-by: Hao Xiang <hao.xiang@linux.dev> > --- > include/qemu/dsa.h | 28 +++++++ > util/dsa.c | 201 +++++++++++++++++++++++++++++++++++++++++++++ > 2 files changed, 229 insertions(+) > > diff --git a/include/qemu/dsa.h b/include/qemu/dsa.h > index f15c05ee85..37cae8d9d2 100644 > --- a/include/qemu/dsa.h > +++ b/include/qemu/dsa.h > @@ -13,6 +13,34 @@ > #include <linux/idxd.h> > #include "x86intrin.h" > > +typedef enum DsaTaskType { > + DSA_TASK = 0, > + DSA_BATCH_TASK > +} DsaTaskType; > + > +typedef enum DsaTaskStatus { > + DSA_TASK_READY = 0, > + DSA_TASK_PROCESSING, > + DSA_TASK_COMPLETION > +} DsaTaskStatus; > + > +typedef void (*dsa_completion_fn)(void *); > + > +typedef struct dsa_batch_task { > + struct dsa_hw_desc batch_descriptor; > + struct dsa_hw_desc *descriptors; > + struct dsa_completion_record batch_completion __attribute__((aligned(32))); > + struct dsa_completion_record *completions; > + struct dsa_device_group *group; > + struct dsa_device *device; > + dsa_completion_fn completion_callback; > + QemuSemaphore sem_task_complete; > + DsaTaskType task_type; > + DsaTaskStatus status; > + int batch_size; > + QSIMPLEQ_ENTRY(dsa_batch_task) entry; > +} dsa_batch_task; > + > /** > * @brief Initializes DSA devices. > * > diff --git a/util/dsa.c b/util/dsa.c > index 05bbf8e31a..75739a1af6 100644 > --- a/util/dsa.c > +++ b/util/dsa.c > @@ -244,6 +244,205 @@ dsa_device_group_get_next_device(struct dsa_device_group *group) > return &group->dsa_devices[current]; > } > > +/** > + * @brief Empties out the DSA task queue. > + * > + * @param group A pointer to the DSA device group. > + */ > +static void > +dsa_empty_task_queue(struct dsa_device_group *group) > +{ > + qemu_mutex_lock(&group->task_queue_lock); > + dsa_task_queue *task_queue = &group->task_queue; > + while (!QSIMPLEQ_EMPTY(task_queue)) { > + QSIMPLEQ_REMOVE_HEAD(task_queue, entry); > + } > + qemu_mutex_unlock(&group->task_queue_lock); > +} > + > +/** > + * @brief Adds a task to the DSA task queue. > + * > + * @param group A pointer to the DSA device group. > + * @param context A pointer to the DSA task to enqueue. This is wrong^ > + * > + * @return int Zero if successful, otherwise a proper error code. > + */ > +static int > +dsa_task_enqueue(struct dsa_device_group *group, > + struct dsa_batch_task *task) > +{ > + dsa_task_queue *task_queue = &group->task_queue; > + QemuMutex *task_queue_lock = &group->task_queue_lock; > + QemuCond *task_queue_cond = &group->task_queue_cond; It's more idiomatic to not hold any of these in a variable, just access them directly. > + > + bool notify = false; > + > + qemu_mutex_lock(task_queue_lock); > + > + if (!group->running) { > + error_report("DSA: Tried to queue task to stopped device queue."); > + qemu_mutex_unlock(task_queue_lock); > + return -1; > + } > + > + /* The queue is empty. This enqueue operation is a 0->1 transition. */ > + if (QSIMPLEQ_EMPTY(task_queue)) { > + notify = true; > + } > + > + QSIMPLEQ_INSERT_TAIL(task_queue, task, entry); > + > + /* We need to notify the waiter for 0->1 transitions. */ > + if (notify) { > + qemu_cond_signal(task_queue_cond); > + } > + > + qemu_mutex_unlock(task_queue_lock); > + > + return 0; > +} > + > +/** > + * @brief Takes a DSA task out of the task queue. > + * > + * @param group A pointer to the DSA device group. > + * @return dsa_batch_task* The DSA task being dequeued. > + */ > +__attribute__((unused)) > +static struct dsa_batch_task * > +dsa_task_dequeue(struct dsa_device_group *group) > +{ > + struct dsa_batch_task *task = NULL; > + dsa_task_queue *task_queue = &group->task_queue; > + QemuMutex *task_queue_lock = &group->task_queue_lock; > + QemuCond *task_queue_cond = &group->task_queue_cond; Same here. > + > + qemu_mutex_lock(task_queue_lock); > + > + while (true) { > + if (!group->running) { > + goto exit; > + } > + task = QSIMPLEQ_FIRST(task_queue); > + if (task != NULL) { > + break; > + } > + qemu_cond_wait(task_queue_cond, task_queue_lock); > + } > + > + QSIMPLEQ_REMOVE_HEAD(task_queue, entry); > + > +exit: > + qemu_mutex_unlock(task_queue_lock); > + return task; > +} > + > +/** > + * @brief Submits a DSA work item to the device work queue. > + * > + * @param wq A pointer to the DSA work queue's device memory. > + * @param descriptor A pointer to the DSA work item descriptor. > + * > + * @return Zero if successful, non-zero otherwise. > + */ > +static int > +submit_wi_int(void *wq, struct dsa_hw_desc *descriptor) > +{ > + uint64_t retry = 0; > + > + _mm_sfence(); > + > + while (true) { > + if (_enqcmd(wq, descriptor) == 0) { > + break; > + } > + retry++; > + if (retry > max_retry_count) { > + error_report("Submit work retry %lu times.", retry); > + return -1; > + } > + } > + > + return 0; > +} > + > +/** > + * @brief Synchronously submits a DSA work item to the > + * device work queue. > + * > + * @param wq A pointer to the DSA worjk queue's device memory. s/worjk/work/ > + * @param descriptor A pointer to the DSA work item descriptor. > + * > + * @return int Zero if successful, non-zero otherwise. > + */ > +__attribute__((unused)) > +static int > +submit_wi(void *wq, struct dsa_hw_desc *descriptor) > +{ > + return submit_wi_int(wq, descriptor); > +} > + > +/** > + * @brief Asynchronously submits a DSA work item to the > + * device work queue. > + * > + * @param task A pointer to the buffer zero task. > + * > + * @return int Zero if successful, non-zero otherwise. > + */ > +__attribute__((unused)) > +static int > +submit_wi_async(struct dsa_batch_task *task) > +{ > + struct dsa_device_group *device_group = task->group; > + struct dsa_device *device_instance = task->device; > + int ret; > + > + assert(task->task_type == DSA_TASK); > + > + task->status = DSA_TASK_PROCESSING; > + > + ret = submit_wi_int(device_instance->work_queue, > + &task->descriptors[0]); > + if (ret != 0) { > + return ret; > + } > + > + return dsa_task_enqueue(device_group, task); > +} > + > +/** > + * @brief Asynchronously submits a DSA batch work item to the > + * device work queue. > + * > + * @param dsa_batch_task A pointer to the batch buffer zero task. s/buffer zero // > + * > + * @return int Zero if successful, non-zero otherwise. > + */ > +__attribute__((unused)) > +static int > +submit_batch_wi_async(struct dsa_batch_task *batch_task) > +{ > + struct dsa_device_group *device_group = batch_task->group; > + struct dsa_device *device_instance = batch_task->device; > + int ret; > + > + assert(batch_task->task_type == DSA_BATCH_TASK); > + assert(batch_task->batch_descriptor.desc_count <= batch_task->batch_size); > + assert(batch_task->status == DSA_TASK_READY); > + > + batch_task->status = DSA_TASK_PROCESSING; > + > + ret = submit_wi_int(device_instance->work_queue, > + &batch_task->batch_descriptor); > + if (ret != 0) { > + return ret; > + } > + > + return dsa_task_enqueue(device_group, batch_task); > +} > + > /** > * @brief Check if DSA is running. > * > @@ -300,6 +499,8 @@ void dsa_stop(void) > if (!group->running) { > return; > } > + > + dsa_empty_task_queue(group); > } > > /**
Hao Xiang <hao.xiang@linux.dev> writes: > * Use a safe thread queue for DSA task enqueue/dequeue. > * Implement DSA task submission. > * Implement DSA batch task submission. > > Signed-off-by: Hao Xiang <hao.xiang@linux.dev> > --- > include/qemu/dsa.h | 28 +++++++ > util/dsa.c | 201 +++++++++++++++++++++++++++++++++++++++++++++ > 2 files changed, 229 insertions(+) > > diff --git a/include/qemu/dsa.h b/include/qemu/dsa.h > index f15c05ee85..37cae8d9d2 100644 > --- a/include/qemu/dsa.h > +++ b/include/qemu/dsa.h > @@ -13,6 +13,34 @@ > #include <linux/idxd.h> > #include "x86intrin.h" > > +typedef enum DsaTaskType { > + DSA_TASK = 0, > + DSA_BATCH_TASK > +} DsaTaskType; > + > +typedef enum DsaTaskStatus { > + DSA_TASK_READY = 0, > + DSA_TASK_PROCESSING, > + DSA_TASK_COMPLETION > +} DsaTaskStatus; > + > +typedef void (*dsa_completion_fn)(void *); > + > +typedef struct dsa_batch_task { > + struct dsa_hw_desc batch_descriptor; > + struct dsa_hw_desc *descriptors; > + struct dsa_completion_record batch_completion __attribute__((aligned(32))); > + struct dsa_completion_record *completions; > + struct dsa_device_group *group; > + struct dsa_device *device; > + dsa_completion_fn completion_callback; > + QemuSemaphore sem_task_complete; > + DsaTaskType task_type; > + DsaTaskStatus status; > + int batch_size; > + QSIMPLEQ_ENTRY(dsa_batch_task) entry; > +} dsa_batch_task; > + > /** > * @brief Initializes DSA devices. > * > diff --git a/util/dsa.c b/util/dsa.c > index 05bbf8e31a..75739a1af6 100644 > --- a/util/dsa.c > +++ b/util/dsa.c > @@ -244,6 +244,205 @@ dsa_device_group_get_next_device(struct dsa_device_group *group) > return &group->dsa_devices[current]; > } > > +/** > + * @brief Empties out the DSA task queue. > + * > + * @param group A pointer to the DSA device group. > + */ > +static void > +dsa_empty_task_queue(struct dsa_device_group *group) > +{ > + qemu_mutex_lock(&group->task_queue_lock); > + dsa_task_queue *task_queue = &group->task_queue; > + while (!QSIMPLEQ_EMPTY(task_queue)) { > + QSIMPLEQ_REMOVE_HEAD(task_queue, entry); > + } > + qemu_mutex_unlock(&group->task_queue_lock); > +} > + > +/** > + * @brief Adds a task to the DSA task queue. > + * > + * @param group A pointer to the DSA device group. > + * @param context A pointer to the DSA task to enqueue. > + * > + * @return int Zero if successful, otherwise a proper error code. > + */ > +static int > +dsa_task_enqueue(struct dsa_device_group *group, > + struct dsa_batch_task *task) > +{ > + dsa_task_queue *task_queue = &group->task_queue; > + QemuMutex *task_queue_lock = &group->task_queue_lock; > + QemuCond *task_queue_cond = &group->task_queue_cond; > + > + bool notify = false; > + > + qemu_mutex_lock(task_queue_lock); > + > + if (!group->running) { > + error_report("DSA: Tried to queue task to stopped device queue."); > + qemu_mutex_unlock(task_queue_lock); > + return -1; > + } > + > + /* The queue is empty. This enqueue operation is a 0->1 transition. */ > + if (QSIMPLEQ_EMPTY(task_queue)) { > + notify = true; > + } > + > + QSIMPLEQ_INSERT_TAIL(task_queue, task, entry); > + > + /* We need to notify the waiter for 0->1 transitions. */ > + if (notify) { > + qemu_cond_signal(task_queue_cond); > + } > + > + qemu_mutex_unlock(task_queue_lock); > + > + return 0; > +} > + > +/** > + * @brief Takes a DSA task out of the task queue. > + * > + * @param group A pointer to the DSA device group. > + * @return dsa_batch_task* The DSA task being dequeued. > + */ > +__attribute__((unused)) > +static struct dsa_batch_task * > +dsa_task_dequeue(struct dsa_device_group *group) > +{ > + struct dsa_batch_task *task = NULL; > + dsa_task_queue *task_queue = &group->task_queue; > + QemuMutex *task_queue_lock = &group->task_queue_lock; > + QemuCond *task_queue_cond = &group->task_queue_cond; > + > + qemu_mutex_lock(task_queue_lock); > + > + while (true) { > + if (!group->running) { > + goto exit; > + } > + task = QSIMPLEQ_FIRST(task_queue); > + if (task != NULL) { > + break; > + } > + qemu_cond_wait(task_queue_cond, task_queue_lock); > + } > + > + QSIMPLEQ_REMOVE_HEAD(task_queue, entry); > + > +exit: > + qemu_mutex_unlock(task_queue_lock); > + return task; > +} > + > +/** > + * @brief Submits a DSA work item to the device work queue. > + * > + * @param wq A pointer to the DSA work queue's device memory. > + * @param descriptor A pointer to the DSA work item descriptor. > + * > + * @return Zero if successful, non-zero otherwise. > + */ > +static int > +submit_wi_int(void *wq, struct dsa_hw_desc *descriptor) > +{ > + uint64_t retry = 0; > + > + _mm_sfence(); > + > + while (true) { > + if (_enqcmd(wq, descriptor) == 0) { > + break; > + } > + retry++; > + if (retry > max_retry_count) { You missed my comment in v2 that max_retry_count is UINT64_MAX. > + error_report("Submit work retry %lu times.", retry); > + return -1; > + } > + } > + > + return 0; > +} > + > +/** > + * @brief Synchronously submits a DSA work item to the > + * device work queue. > + * > + * @param wq A pointer to the DSA worjk queue's device memory. > + * @param descriptor A pointer to the DSA work item descriptor. > + * > + * @return int Zero if successful, non-zero otherwise. > + */ > +__attribute__((unused)) > +static int > +submit_wi(void *wq, struct dsa_hw_desc *descriptor) > +{ > + return submit_wi_int(wq, descriptor); > +} > + > +/** > + * @brief Asynchronously submits a DSA work item to the > + * device work queue. > + * > + * @param task A pointer to the buffer zero task. > + * > + * @return int Zero if successful, non-zero otherwise. > + */ > +__attribute__((unused)) > +static int > +submit_wi_async(struct dsa_batch_task *task) > +{ > + struct dsa_device_group *device_group = task->group; > + struct dsa_device *device_instance = task->device; > + int ret; > + > + assert(task->task_type == DSA_TASK); > + > + task->status = DSA_TASK_PROCESSING; > + > + ret = submit_wi_int(device_instance->work_queue, > + &task->descriptors[0]); > + if (ret != 0) { > + return ret; > + } > + > + return dsa_task_enqueue(device_group, task); > +} > + > +/** > + * @brief Asynchronously submits a DSA batch work item to the > + * device work queue. > + * > + * @param dsa_batch_task A pointer to the batch buffer zero task. > + * > + * @return int Zero if successful, non-zero otherwise. > + */ > +__attribute__((unused)) > +static int > +submit_batch_wi_async(struct dsa_batch_task *batch_task) > +{ > + struct dsa_device_group *device_group = batch_task->group; > + struct dsa_device *device_instance = batch_task->device; > + int ret; > + > + assert(batch_task->task_type == DSA_BATCH_TASK); > + assert(batch_task->batch_descriptor.desc_count <= batch_task->batch_size); > + assert(batch_task->status == DSA_TASK_READY); > + > + batch_task->status = DSA_TASK_PROCESSING; > + > + ret = submit_wi_int(device_instance->work_queue, > + &batch_task->batch_descriptor); > + if (ret != 0) { > + return ret; > + } > + > + return dsa_task_enqueue(device_group, batch_task); > +} > + > /** > * @brief Check if DSA is running. > * > @@ -300,6 +499,8 @@ void dsa_stop(void) > if (!group->running) { > return; > } > + > + dsa_empty_task_queue(group); > } > > /**
diff --git a/include/qemu/dsa.h b/include/qemu/dsa.h index f15c05ee85..37cae8d9d2 100644 --- a/include/qemu/dsa.h +++ b/include/qemu/dsa.h @@ -13,6 +13,34 @@ #include <linux/idxd.h> #include "x86intrin.h" +typedef enum DsaTaskType { + DSA_TASK = 0, + DSA_BATCH_TASK +} DsaTaskType; + +typedef enum DsaTaskStatus { + DSA_TASK_READY = 0, + DSA_TASK_PROCESSING, + DSA_TASK_COMPLETION +} DsaTaskStatus; + +typedef void (*dsa_completion_fn)(void *); + +typedef struct dsa_batch_task { + struct dsa_hw_desc batch_descriptor; + struct dsa_hw_desc *descriptors; + struct dsa_completion_record batch_completion __attribute__((aligned(32))); + struct dsa_completion_record *completions; + struct dsa_device_group *group; + struct dsa_device *device; + dsa_completion_fn completion_callback; + QemuSemaphore sem_task_complete; + DsaTaskType task_type; + DsaTaskStatus status; + int batch_size; + QSIMPLEQ_ENTRY(dsa_batch_task) entry; +} dsa_batch_task; + /** * @brief Initializes DSA devices. * diff --git a/util/dsa.c b/util/dsa.c index 05bbf8e31a..75739a1af6 100644 --- a/util/dsa.c +++ b/util/dsa.c @@ -244,6 +244,205 @@ dsa_device_group_get_next_device(struct dsa_device_group *group) return &group->dsa_devices[current]; } +/** + * @brief Empties out the DSA task queue. + * + * @param group A pointer to the DSA device group. + */ +static void +dsa_empty_task_queue(struct dsa_device_group *group) +{ + qemu_mutex_lock(&group->task_queue_lock); + dsa_task_queue *task_queue = &group->task_queue; + while (!QSIMPLEQ_EMPTY(task_queue)) { + QSIMPLEQ_REMOVE_HEAD(task_queue, entry); + } + qemu_mutex_unlock(&group->task_queue_lock); +} + +/** + * @brief Adds a task to the DSA task queue. + * + * @param group A pointer to the DSA device group. + * @param context A pointer to the DSA task to enqueue. + * + * @return int Zero if successful, otherwise a proper error code. + */ +static int +dsa_task_enqueue(struct dsa_device_group *group, + struct dsa_batch_task *task) +{ + dsa_task_queue *task_queue = &group->task_queue; + QemuMutex *task_queue_lock = &group->task_queue_lock; + QemuCond *task_queue_cond = &group->task_queue_cond; + + bool notify = false; + + qemu_mutex_lock(task_queue_lock); + + if (!group->running) { + error_report("DSA: Tried to queue task to stopped device queue."); + qemu_mutex_unlock(task_queue_lock); + return -1; + } + + /* The queue is empty. This enqueue operation is a 0->1 transition. */ + if (QSIMPLEQ_EMPTY(task_queue)) { + notify = true; + } + + QSIMPLEQ_INSERT_TAIL(task_queue, task, entry); + + /* We need to notify the waiter for 0->1 transitions. */ + if (notify) { + qemu_cond_signal(task_queue_cond); + } + + qemu_mutex_unlock(task_queue_lock); + + return 0; +} + +/** + * @brief Takes a DSA task out of the task queue. + * + * @param group A pointer to the DSA device group. + * @return dsa_batch_task* The DSA task being dequeued. + */ +__attribute__((unused)) +static struct dsa_batch_task * +dsa_task_dequeue(struct dsa_device_group *group) +{ + struct dsa_batch_task *task = NULL; + dsa_task_queue *task_queue = &group->task_queue; + QemuMutex *task_queue_lock = &group->task_queue_lock; + QemuCond *task_queue_cond = &group->task_queue_cond; + + qemu_mutex_lock(task_queue_lock); + + while (true) { + if (!group->running) { + goto exit; + } + task = QSIMPLEQ_FIRST(task_queue); + if (task != NULL) { + break; + } + qemu_cond_wait(task_queue_cond, task_queue_lock); + } + + QSIMPLEQ_REMOVE_HEAD(task_queue, entry); + +exit: + qemu_mutex_unlock(task_queue_lock); + return task; +} + +/** + * @brief Submits a DSA work item to the device work queue. + * + * @param wq A pointer to the DSA work queue's device memory. + * @param descriptor A pointer to the DSA work item descriptor. + * + * @return Zero if successful, non-zero otherwise. + */ +static int +submit_wi_int(void *wq, struct dsa_hw_desc *descriptor) +{ + uint64_t retry = 0; + + _mm_sfence(); + + while (true) { + if (_enqcmd(wq, descriptor) == 0) { + break; + } + retry++; + if (retry > max_retry_count) { + error_report("Submit work retry %lu times.", retry); + return -1; + } + } + + return 0; +} + +/** + * @brief Synchronously submits a DSA work item to the + * device work queue. + * + * @param wq A pointer to the DSA worjk queue's device memory. + * @param descriptor A pointer to the DSA work item descriptor. + * + * @return int Zero if successful, non-zero otherwise. + */ +__attribute__((unused)) +static int +submit_wi(void *wq, struct dsa_hw_desc *descriptor) +{ + return submit_wi_int(wq, descriptor); +} + +/** + * @brief Asynchronously submits a DSA work item to the + * device work queue. + * + * @param task A pointer to the buffer zero task. + * + * @return int Zero if successful, non-zero otherwise. + */ +__attribute__((unused)) +static int +submit_wi_async(struct dsa_batch_task *task) +{ + struct dsa_device_group *device_group = task->group; + struct dsa_device *device_instance = task->device; + int ret; + + assert(task->task_type == DSA_TASK); + + task->status = DSA_TASK_PROCESSING; + + ret = submit_wi_int(device_instance->work_queue, + &task->descriptors[0]); + if (ret != 0) { + return ret; + } + + return dsa_task_enqueue(device_group, task); +} + +/** + * @brief Asynchronously submits a DSA batch work item to the + * device work queue. + * + * @param dsa_batch_task A pointer to the batch buffer zero task. + * + * @return int Zero if successful, non-zero otherwise. + */ +__attribute__((unused)) +static int +submit_batch_wi_async(struct dsa_batch_task *batch_task) +{ + struct dsa_device_group *device_group = batch_task->group; + struct dsa_device *device_instance = batch_task->device; + int ret; + + assert(batch_task->task_type == DSA_BATCH_TASK); + assert(batch_task->batch_descriptor.desc_count <= batch_task->batch_size); + assert(batch_task->status == DSA_TASK_READY); + + batch_task->status = DSA_TASK_PROCESSING; + + ret = submit_wi_int(device_instance->work_queue, + &batch_task->batch_descriptor); + if (ret != 0) { + return ret; + } + + return dsa_task_enqueue(device_group, batch_task); +} + /** * @brief Check if DSA is running. * @@ -300,6 +499,8 @@ void dsa_stop(void) if (!group->running) { return; } + + dsa_empty_task_queue(group); } /**
* Use a safe thread queue for DSA task enqueue/dequeue. * Implement DSA task submission. * Implement DSA batch task submission. Signed-off-by: Hao Xiang <hao.xiang@linux.dev> --- include/qemu/dsa.h | 28 +++++++ util/dsa.c | 201 +++++++++++++++++++++++++++++++++++++++++++++ 2 files changed, 229 insertions(+)