rtio.h

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/*
 * Copyright (c) 2022 Intel Corporation
 *
 * SPDX-License-Identifier: Apache-2.0
 */
 
#ifndef ZEPHYR_INCLUDE_RTIO_RTIO_H_
#define ZEPHYR_INCLUDE_RTIO_RTIO_H_
 
#include <string.h>
 
#include <zephyr/app_memory/app_memdomain.h>
#include <zephyr/device.h>
#include <zephyr/kernel.h>
#include <zephyr/rtio/rtio_mpsc.h>
#include <zephyr/sys/__assert.h>
#include <zephyr/sys/atomic.h>
#include <zephyr/sys/mem_blocks.h>
#include <zephyr/sys/util.h>
#include <zephyr/sys/iterable_sections.h>
 
#ifdef __cplusplus
extern "C" {
#endif
 
 
#define RTIO_PRIO_LOW 0U
 
#define RTIO_PRIO_NORM 127U
 
#define RTIO_PRIO_HIGH 255U
 
#define RTIO_SQE_CHAINED BIT(0)
 
#define RTIO_SQE_TRANSACTION BIT(1)
 
 
#define RTIO_SQE_MEMPOOL_BUFFER BIT(2)
 
#define RTIO_SQE_CANCELED BIT(3)
 
#define RTIO_SQE_MULTISHOT BIT(4)
 
#define RTIO_SQE_NO_RESPONSE BIT(5)
 
#define RTIO_CQE_FLAG_MEMPOOL_BUFFER BIT(0)
 
#define RTIO_CQE_FLAG_GET(flags) FIELD_GET(GENMASK(7, 0), (flags))
 
#define RTIO_CQE_FLAG_MEMPOOL_GET_BLK_IDX(flags) FIELD_GET(GENMASK(19, 8), (flags))
 
#define RTIO_CQE_FLAG_MEMPOOL_GET_BLK_CNT(flags) FIELD_GET(GENMASK(31, 20), (flags))
 
#define RTIO_CQE_FLAG_PREP_MEMPOOL(blk_idx, blk_cnt)                                               \
        (FIELD_PREP(GENMASK(7, 0), RTIO_CQE_FLAG_MEMPOOL_BUFFER) |                                 \
         FIELD_PREP(GENMASK(19, 8), blk_idx) | FIELD_PREP(GENMASK(31, 20), blk_cnt))
 
#define RTIO_IODEV_I2C_STOP BIT(1)
 
#define RTIO_IODEV_I2C_RESTART BIT(2)
 
#define RTIO_IODEV_I2C_10_BITS BIT(3)
 
struct rtio;
struct rtio_cqe;
struct rtio_sqe;
struct rtio_sqe_pool;
struct rtio_cqe_pool;
struct rtio_iodev;
struct rtio_iodev_sqe;
typedef void (*rtio_callback_t)(struct rtio *r, const struct rtio_sqe *sqe, void *arg0);
 
struct rtio_sqe {
        uint8_t op; 
        uint8_t prio; 
        uint16_t flags; 
        uint16_t iodev_flags; 
        uint16_t _resv0;
 
        const struct rtio_iodev *iodev; 
        void *userdata;
 
        union {
 
                struct {
                        uint32_t buf_len; 
                        uint8_t *buf; 
                };
 
                struct {
                        uint8_t tiny_buf_len; 
                        uint8_t tiny_buf[7]; 
                };
 
                struct {
                        rtio_callback_t callback;
                        void *arg0; 
                };
 
                struct {
                        uint32_t txrx_buf_len;
                        uint8_t *tx_buf;
                        uint8_t *rx_buf;
                };
 
                uint32_t i2c_config;
        };
};
 
/* Ensure the rtio_sqe never grows beyond a common cacheline size of 64 bytes */
BUILD_ASSERT(sizeof(struct rtio_sqe) <= 64);
struct rtio_cqe {
        struct rtio_mpsc_node q;
 
        int32_t result; 
        void *userdata; 
        uint32_t flags; 
};
 
struct rtio_sqe_pool {
        struct rtio_mpsc free_q;
        const uint16_t pool_size;
        uint16_t pool_free;
        struct rtio_iodev_sqe *pool;
};
 
struct rtio_cqe_pool {
        struct rtio_mpsc free_q;
        const uint16_t pool_size;
        uint16_t pool_free;
        struct rtio_cqe *pool;
};
 
struct rtio {
#ifdef CONFIG_RTIO_SUBMIT_SEM
        /* A wait semaphore which may suspend the calling thread
         * to wait for some number of completions when calling submit
         */
        struct k_sem *submit_sem;
 
        uint32_t submit_count;
#endif
 
#ifdef CONFIG_RTIO_CONSUME_SEM
        /* A wait semaphore which may suspend the calling thread
         * to wait for some number of completions while consuming
         * them from the completion queue
         */
        struct k_sem *consume_sem;
#endif
 
        /* Total number of completions */
        atomic_t cq_count;
 
        /* Number of completions that were unable to be submitted with results
         * due to the cq spsc being full
         */
        atomic_t xcqcnt;
 
        /* Submission queue object pool with free list */
        struct rtio_sqe_pool *sqe_pool;
 
        /* Complete queue object pool with free list */
        struct rtio_cqe_pool *cqe_pool;
 
#ifdef CONFIG_RTIO_SYS_MEM_BLOCKS
        /* Mem block pool */
        struct sys_mem_blocks *block_pool;
#endif
 
        /* Submission queue */
        struct rtio_mpsc sq;
 
        /* Completion queue */
        struct rtio_mpsc cq;
};
 
extern struct k_mem_partition rtio_partition;
 
static inline size_t rtio_mempool_block_size(const struct rtio *r)
{
#ifndef CONFIG_RTIO_SYS_MEM_BLOCKS
        ARG_UNUSED(r);
        return 0;
#else
        if (r == NULL || r->block_pool == NULL) {
                return 0;
        }
        return BIT(r->block_pool->info.blk_sz_shift);
#endif
}
 
#ifdef CONFIG_RTIO_SYS_MEM_BLOCKS
static inline uint16_t __rtio_compute_mempool_block_index(const struct rtio *r, const void *ptr)
{
        uintptr_t addr = (uintptr_t)ptr;
        struct sys_mem_blocks *mem_pool = r->block_pool;
        uint32_t block_size = rtio_mempool_block_size(r);
 
        uintptr_t buff = (uintptr_t)mem_pool->buffer;
        uint32_t buff_size = mem_pool->info.num_blocks * block_size;
 
        if (addr < buff || addr >= buff + buff_size) {
                return UINT16_MAX;
        }
        return (addr - buff) / block_size;
}
#endif
 
struct rtio_iodev_sqe {
        struct rtio_sqe sqe;
        struct rtio_mpsc_node q;
        struct rtio_iodev_sqe *next;
        struct rtio *r;
};
 
struct rtio_iodev_api {
        void (*submit)(struct rtio_iodev_sqe *iodev_sqe);
};
 
struct rtio_iodev {
        /* Function pointer table */
        const struct rtio_iodev_api *api;
 
        /* Queue of RTIO contexts with requests */
        struct rtio_mpsc iodev_sq;
 
        /* Data associated with this iodev */
        void *data;
};
 
#define RTIO_OP_NOP 0
 
#define RTIO_OP_RX (RTIO_OP_NOP+1)
 
#define RTIO_OP_TX (RTIO_OP_RX+1)
 
#define RTIO_OP_TINY_TX (RTIO_OP_TX+1)
 
#define RTIO_OP_CALLBACK (RTIO_OP_TINY_TX+1)
 
#define RTIO_OP_TXRX (RTIO_OP_CALLBACK+1)
 
#define RTIO_OP_I2C_RECOVER (RTIO_OP_TXRX+1)
 
#define RTIO_OP_I2C_CONFIGURE (RTIO_OP_I2C_RECOVER+1)
 
static inline void rtio_sqe_prep_nop(struct rtio_sqe *sqe,
                                const struct rtio_iodev *iodev,
                                void *userdata)
{
        memset(sqe, 0, sizeof(struct rtio_sqe));
        sqe->op = RTIO_OP_NOP;
        sqe->iodev = iodev;
        sqe->userdata = userdata;
}
 
static inline void rtio_sqe_prep_read(struct rtio_sqe *sqe,
                                      const struct rtio_iodev *iodev,
                                      int8_t prio,
                                      uint8_t *buf,
                                      uint32_t len,
                                      void *userdata)
{
        memset(sqe, 0, sizeof(struct rtio_sqe));
        sqe->op = RTIO_OP_RX;
        sqe->prio = prio;
        sqe->iodev = iodev;
        sqe->buf_len = len;
        sqe->buf = buf;
        sqe->userdata = userdata;
}
 
static inline void rtio_sqe_prep_read_with_pool(struct rtio_sqe *sqe,
                                                const struct rtio_iodev *iodev, int8_t prio,
                                                void *userdata)
{
        rtio_sqe_prep_read(sqe, iodev, prio, NULL, 0, userdata);
        sqe->flags = RTIO_SQE_MEMPOOL_BUFFER;
}
 
static inline void rtio_sqe_prep_read_multishot(struct rtio_sqe *sqe,
                                                const struct rtio_iodev *iodev, int8_t prio,
                                                void *userdata)
{
        rtio_sqe_prep_read_with_pool(sqe, iodev, prio, userdata);
        sqe->flags |= RTIO_SQE_MULTISHOT;
}
 
static inline void rtio_sqe_prep_write(struct rtio_sqe *sqe,
                                       const struct rtio_iodev *iodev,
                                       int8_t prio,
                                       uint8_t *buf,
                                       uint32_t len,
                                       void *userdata)
{
        memset(sqe, 0, sizeof(struct rtio_sqe));
        sqe->op = RTIO_OP_TX;
        sqe->prio = prio;
        sqe->iodev = iodev;
        sqe->buf_len = len;
        sqe->buf = buf;
        sqe->userdata = userdata;
}
 
static inline void rtio_sqe_prep_tiny_write(struct rtio_sqe *sqe,
                                            const struct rtio_iodev *iodev,
                                            int8_t prio,
                                            const uint8_t *tiny_write_data,
                                            uint8_t tiny_write_len,
                                            void *userdata)
{
        __ASSERT_NO_MSG(tiny_write_len <= sizeof(sqe->tiny_buf));
 
        memset(sqe, 0, sizeof(struct rtio_sqe));
        sqe->op = RTIO_OP_TINY_TX;
        sqe->prio = prio;
        sqe->iodev = iodev;
        sqe->tiny_buf_len = tiny_write_len;
        memcpy(sqe->tiny_buf, tiny_write_data, tiny_write_len);
        sqe->userdata = userdata;
}
 
static inline void rtio_sqe_prep_callback(struct rtio_sqe *sqe,
                                          rtio_callback_t callback,
                                          void *arg0,
                                          void *userdata)
{
        memset(sqe, 0, sizeof(struct rtio_sqe));
        sqe->op = RTIO_OP_CALLBACK;
        sqe->prio = 0;
        sqe->iodev = NULL;
        sqe->callback = callback;
        sqe->arg0 = arg0;
        sqe->userdata = userdata;
}
 
static inline void rtio_sqe_prep_transceive(struct rtio_sqe *sqe,
                                            const struct rtio_iodev *iodev,
                                            int8_t prio,
                                            uint8_t *tx_buf,
                                            uint8_t *rx_buf,
                                            uint32_t buf_len,
                                            void *userdata)
{
        memset(sqe, 0, sizeof(struct rtio_sqe));
        sqe->op = RTIO_OP_TXRX;
        sqe->prio = prio;
        sqe->iodev = iodev;
        sqe->txrx_buf_len = buf_len;
        sqe->tx_buf = tx_buf;
        sqe->rx_buf = rx_buf;
        sqe->userdata = userdata;
}
 
static inline struct rtio_iodev_sqe *rtio_sqe_pool_alloc(struct rtio_sqe_pool *pool)
{
        struct rtio_mpsc_node *node = rtio_mpsc_pop(&pool->free_q);
 
        if (node == NULL) {
                return NULL;
        }
 
        struct rtio_iodev_sqe *iodev_sqe = CONTAINER_OF(node, struct rtio_iodev_sqe, q);
 
        pool->pool_free--;
 
        return iodev_sqe;
}
 
static inline void rtio_sqe_pool_free(struct rtio_sqe_pool *pool, struct rtio_iodev_sqe *iodev_sqe)
{
        rtio_mpsc_push(&pool->free_q, &iodev_sqe->q);
 
        pool->pool_free++;
}
 
static inline struct rtio_cqe *rtio_cqe_pool_alloc(struct rtio_cqe_pool *pool)
{
        struct rtio_mpsc_node *node = rtio_mpsc_pop(&pool->free_q);
 
        if (node == NULL) {
                return NULL;
        }
 
        struct rtio_cqe *cqe = CONTAINER_OF(node, struct rtio_cqe, q);
 
        memset(cqe, 0, sizeof(struct rtio_cqe));
 
        pool->pool_free--;
 
        return cqe;
}
 
static inline void rtio_cqe_pool_free(struct rtio_cqe_pool *pool, struct rtio_cqe *cqe)
{
        rtio_mpsc_push(&pool->free_q, &cqe->q);
 
        pool->pool_free++;
}
 
static inline int rtio_block_pool_alloc(struct rtio *r, size_t min_sz,
                                          size_t max_sz, uint8_t **buf, uint32_t *buf_len)
{
#ifndef CONFIG_RTIO_SYS_MEM_BLOCKS
        ARG_UNUSED(r);
        ARG_UNUSED(min_sz);
        ARG_UNUSED(max_sz);
        ARG_UNUSED(buf);
        ARG_UNUSED(buf_len);
        return -ENOTSUP;
#else
        const uint32_t block_size = rtio_mempool_block_size(r);
        uint32_t bytes = max_sz;
 
        /* Not every context has a block pool and the block size may return 0 in
         * that case
         */
        if (block_size == 0) {
                return -ENOMEM;
        }
 
        do {
                size_t num_blks = DIV_ROUND_UP(bytes, block_size);
                int rc = sys_mem_blocks_alloc_contiguous(r->block_pool, num_blks, (void **)buf);
 
                if (rc == 0) {
                        *buf_len = num_blks * block_size;
                        return 0;
                }
 
                bytes -= block_size;
        } while (bytes >= min_sz);
 
        return -ENOMEM;
#endif
}
 
static inline void rtio_block_pool_free(struct rtio *r, void *buf, uint32_t buf_len)
{
#ifndef CONFIG_RTIO_SYS_MEM_BLOCKS
        ARG_UNUSED(r);
        ARG_UNUSED(buf);
        ARG_UNUSED(buf_len);
#else
        size_t num_blks = buf_len >> r->block_pool->info.blk_sz_shift;
 
        sys_mem_blocks_free_contiguous(r->block_pool, buf, num_blks);
#endif
}
 
/* Do not try and reformat the macros */
/* clang-format off */
 
#define RTIO_IODEV_DEFINE(name, iodev_api, iodev_data)          \
        STRUCT_SECTION_ITERABLE(rtio_iodev, name) = {           \
                .api = (iodev_api),                             \
                .iodev_sq = RTIO_MPSC_INIT((name.iodev_sq)),    \
                .data = (iodev_data),                           \
        }
 
#define Z_RTIO_SQE_POOL_DEFINE(name, sz)                        \
        static struct rtio_iodev_sqe CONCAT(_sqe_pool_, name)[sz];      \
        STRUCT_SECTION_ITERABLE(rtio_sqe_pool, name) = {        \
                .free_q = RTIO_MPSC_INIT((name.free_q)),        \
                .pool_size = sz,                                \
                .pool_free = sz,                                \
                .pool = CONCAT(_sqe_pool_, name),               \
        }
 
 
#define Z_RTIO_CQE_POOL_DEFINE(name, sz)                        \
        static struct rtio_cqe CONCAT(_cqe_pool_, name)[sz];    \
        STRUCT_SECTION_ITERABLE(rtio_cqe_pool, name) = {        \
                .free_q = RTIO_MPSC_INIT((name.free_q)),        \
                .pool_size = sz,                                \
                .pool_free = sz,                                \
                .pool = CONCAT(_cqe_pool_, name),               \
        }
 
#define RTIO_BMEM COND_CODE_1(CONFIG_USERSPACE, (K_APP_BMEM(rtio_partition) static), (static))
 
#define RTIO_DMEM COND_CODE_1(CONFIG_USERSPACE, (K_APP_DMEM(rtio_partition) static), (static))
 
#define Z_RTIO_BLOCK_POOL_DEFINE(name, blk_sz, blk_cnt, blk_align)                                 \
        RTIO_BMEM uint8_t __aligned(WB_UP(blk_align))                                              \
        CONCAT(_block_pool_, name)[blk_cnt*WB_UP(blk_sz)];                                         \
        _SYS_MEM_BLOCKS_DEFINE_WITH_EXT_BUF(name, WB_UP(blk_sz), blk_cnt,                          \
                                            CONCAT(_block_pool_, name), RTIO_DMEM)
 
#define Z_RTIO_DEFINE(name, _sqe_pool, _cqe_pool, _block_pool)                                     \
        IF_ENABLED(CONFIG_RTIO_SUBMIT_SEM,                                                         \
                   (static K_SEM_DEFINE(CONCAT(_submit_sem_, name), 0, K_SEM_MAX_LIMIT)))          \
        IF_ENABLED(CONFIG_RTIO_CONSUME_SEM,                                                        \
                   (static K_SEM_DEFINE(CONCAT(_consume_sem_, name), 0, K_SEM_MAX_LIMIT)))         \
        STRUCT_SECTION_ITERABLE(rtio, name) = {                                                    \
                IF_ENABLED(CONFIG_RTIO_SUBMIT_SEM, (.submit_sem = &CONCAT(_submit_sem_, name),))   \
                IF_ENABLED(CONFIG_RTIO_SUBMIT_SEM, (.submit_count = 0,))                           \
                IF_ENABLED(CONFIG_RTIO_CONSUME_SEM, (.consume_sem = &CONCAT(_consume_sem_, name),))\
                .cq_count = ATOMIC_INIT(0),                                                        \
                .xcqcnt = ATOMIC_INIT(0),                                                          \
                .sqe_pool = _sqe_pool,                                                             \
                .cqe_pool = _cqe_pool,                                                             \
                IF_ENABLED(CONFIG_RTIO_SYS_MEM_BLOCKS, (.block_pool = _block_pool,))               \
                .sq = RTIO_MPSC_INIT((name.sq)),                                                   \
                .cq = RTIO_MPSC_INIT((name.cq)),                                                   \
        }
 
#define RTIO_DEFINE(name, sq_sz, cq_sz)                                         \
        Z_RTIO_SQE_POOL_DEFINE(CONCAT(name, _sqe_pool), sq_sz);                 \
        Z_RTIO_CQE_POOL_DEFINE(CONCAT(name, _cqe_pool), cq_sz);                 \
        Z_RTIO_DEFINE(name, &CONCAT(name, _sqe_pool),                           \
                      &CONCAT(name, _cqe_pool), NULL)
 
/* clang-format on */
 
#define RTIO_DEFINE_WITH_MEMPOOL(name, sq_sz, cq_sz, num_blks, blk_size, balign) \
        Z_RTIO_SQE_POOL_DEFINE(name##_sqe_pool, sq_sz);         \
        Z_RTIO_CQE_POOL_DEFINE(name##_cqe_pool, cq_sz);                 \
        Z_RTIO_BLOCK_POOL_DEFINE(name##_block_pool, blk_size, num_blks, balign); \
        Z_RTIO_DEFINE(name, &name##_sqe_pool, &name##_cqe_pool, &name##_block_pool)
 
/* clang-format on */
 
static inline uint32_t rtio_sqe_acquirable(struct rtio *r)
{
        return r->sqe_pool->pool_free;
}
 
static inline struct rtio_iodev_sqe *rtio_txn_next(const struct rtio_iodev_sqe *iodev_sqe)
{
        if (iodev_sqe->sqe.flags & RTIO_SQE_TRANSACTION) {
                return iodev_sqe->next;
        } else {
                return NULL;
        }
}
 
 
static inline struct rtio_iodev_sqe *rtio_chain_next(const struct rtio_iodev_sqe *iodev_sqe)
{
        if (iodev_sqe->sqe.flags & RTIO_SQE_CHAINED) {
                return iodev_sqe->next;
        } else {
                return NULL;
        }
}
 
static inline struct rtio_iodev_sqe *rtio_iodev_sqe_next(const struct rtio_iodev_sqe *iodev_sqe)
{
        return iodev_sqe->next;
}
 
static inline struct rtio_sqe *rtio_sqe_acquire(struct rtio *r)
{
        struct rtio_iodev_sqe *iodev_sqe = rtio_sqe_pool_alloc(r->sqe_pool);
 
        if (iodev_sqe == NULL) {
                return NULL;
        }
 
        rtio_mpsc_push(&r->sq, &iodev_sqe->q);
 
        return &iodev_sqe->sqe;
}
 
static inline void rtio_sqe_drop_all(struct rtio *r)
{
        struct rtio_iodev_sqe *iodev_sqe;
        struct rtio_mpsc_node *node = rtio_mpsc_pop(&r->sq);
 
        while (node != NULL) {
                iodev_sqe = CONTAINER_OF(node, struct rtio_iodev_sqe, q);
                rtio_sqe_pool_free(r->sqe_pool, iodev_sqe);
                node = rtio_mpsc_pop(&r->sq);
        }
}
 
static inline struct rtio_cqe *rtio_cqe_acquire(struct rtio *r)
{
        struct rtio_cqe *cqe = rtio_cqe_pool_alloc(r->cqe_pool);
 
        if (cqe == NULL) {
                return NULL;
        }
 
        memset(cqe, 0, sizeof(struct rtio_cqe));
 
        return cqe;
}
 
static inline void rtio_cqe_produce(struct rtio *r, struct rtio_cqe *cqe)
{
        rtio_mpsc_push(&r->cq, &cqe->q);
}
 
static inline struct rtio_cqe *rtio_cqe_consume(struct rtio *r)
{
        struct rtio_mpsc_node *node;
        struct rtio_cqe *cqe = NULL;
 
#ifdef CONFIG_RTIO_CONSUME_SEM
        if (k_sem_take(r->consume_sem, K_NO_WAIT) != 0) {
                return NULL;
        }
#endif
 
        node = rtio_mpsc_pop(&r->cq);
        if (node == NULL) {
                return NULL;
        }
        cqe = CONTAINER_OF(node, struct rtio_cqe, q);
 
        return cqe;
}
 
static inline struct rtio_cqe *rtio_cqe_consume_block(struct rtio *r)
{
        struct rtio_mpsc_node *node;
        struct rtio_cqe *cqe;
 
#ifdef CONFIG_RTIO_CONSUME_SEM
        k_sem_take(r->consume_sem, K_FOREVER);
#endif
        node = rtio_mpsc_pop(&r->cq);
        while (node == NULL) {
                Z_SPIN_DELAY(1);
                node = rtio_mpsc_pop(&r->cq);
        }
        cqe = CONTAINER_OF(node, struct rtio_cqe, q);
 
        return cqe;
}
 
static inline void rtio_cqe_release(struct rtio *r, struct rtio_cqe *cqe)
{
        rtio_cqe_pool_free(r->cqe_pool, cqe);
}
 
static inline uint32_t rtio_cqe_compute_flags(struct rtio_iodev_sqe *iodev_sqe)
{
        uint32_t flags = 0;
 
#ifdef CONFIG_RTIO_SYS_MEM_BLOCKS
        if (iodev_sqe->sqe.op == RTIO_OP_RX && iodev_sqe->sqe.flags & RTIO_SQE_MEMPOOL_BUFFER) {
                struct rtio *r = iodev_sqe->r;
                struct sys_mem_blocks *mem_pool = r->block_pool;
                int blk_index = (iodev_sqe->sqe.buf - mem_pool->buffer) >>
                                mem_pool->info.blk_sz_shift;
                int blk_count = iodev_sqe->sqe.buf_len >> mem_pool->info.blk_sz_shift;
 
                flags = RTIO_CQE_FLAG_PREP_MEMPOOL(blk_index, blk_count);
        }
#else
        ARG_UNUSED(iodev_sqe);
#endif
 
        return flags;
}
 
__syscall int rtio_cqe_get_mempool_buffer(const struct rtio *r, struct rtio_cqe *cqe,
                                          uint8_t **buff, uint32_t *buff_len);
 
static inline int z_impl_rtio_cqe_get_mempool_buffer(const struct rtio *r, struct rtio_cqe *cqe,
                                                     uint8_t **buff, uint32_t *buff_len)
{
#ifdef CONFIG_RTIO_SYS_MEM_BLOCKS
        if (RTIO_CQE_FLAG_GET(cqe->flags) == RTIO_CQE_FLAG_MEMPOOL_BUFFER) {
                int blk_idx = RTIO_CQE_FLAG_MEMPOOL_GET_BLK_IDX(cqe->flags);
                int blk_count = RTIO_CQE_FLAG_MEMPOOL_GET_BLK_CNT(cqe->flags);
                uint32_t blk_size = rtio_mempool_block_size(r);
 
                *buff = r->block_pool->buffer + blk_idx * blk_size;
                *buff_len = blk_count * blk_size;
                __ASSERT_NO_MSG(*buff >= r->block_pool->buffer);
                __ASSERT_NO_MSG(*buff <
                                r->block_pool->buffer + blk_size * r->block_pool->info.num_blocks);
                return 0;
        }
        return -EINVAL;
#else
        ARG_UNUSED(r);
        ARG_UNUSED(cqe);
        ARG_UNUSED(buff);
        ARG_UNUSED(buff_len);
 
        return -ENOTSUP;
#endif
}
 
void rtio_executor_submit(struct rtio *r);
void rtio_executor_ok(struct rtio_iodev_sqe *iodev_sqe, int result);
void rtio_executor_err(struct rtio_iodev_sqe *iodev_sqe, int result);
 
static inline void rtio_iodev_sqe_ok(struct rtio_iodev_sqe *iodev_sqe, int result)
{
        rtio_executor_ok(iodev_sqe, result);
}
 
static inline void rtio_iodev_sqe_err(struct rtio_iodev_sqe *iodev_sqe, int result)
{
        rtio_executor_err(iodev_sqe, result);
}
 
static inline void rtio_iodev_cancel_all(struct rtio_iodev *iodev)
{
        /* Clear pending requests as -ENODATA */
        struct rtio_mpsc_node *node = rtio_mpsc_pop(&iodev->iodev_sq);
 
        while (node != NULL) {
                struct rtio_iodev_sqe *iodev_sqe = CONTAINER_OF(node, struct rtio_iodev_sqe, q);
 
                rtio_iodev_sqe_err(iodev_sqe, -ECANCELED);
                node = rtio_mpsc_pop(&iodev->iodev_sq);
        }
}
 
static inline void rtio_cqe_submit(struct rtio *r, int result, void *userdata, uint32_t flags)
{
        struct rtio_cqe *cqe = rtio_cqe_acquire(r);
 
        if (cqe == NULL) {
                atomic_inc(&r->xcqcnt);
        } else {
                cqe->result = result;
                cqe->userdata = userdata;
                cqe->flags = flags;
                rtio_cqe_produce(r, cqe);
        }
 
        atomic_inc(&r->cq_count);
#ifdef CONFIG_RTIO_SUBMIT_SEM
        if (r->submit_count > 0) {
                r->submit_count--;
                if (r->submit_count == 0) {
                        k_sem_give(r->submit_sem);
                }
        }
#endif
#ifdef CONFIG_RTIO_CONSUME_SEM
        k_sem_give(r->consume_sem);
#endif
}
 
#define __RTIO_MEMPOOL_GET_NUM_BLKS(num_bytes, blk_size) (((num_bytes) + (blk_size)-1) / (blk_size))
 
static inline int rtio_sqe_rx_buf(const struct rtio_iodev_sqe *iodev_sqe, uint32_t min_buf_len,
                                  uint32_t max_buf_len, uint8_t **buf, uint32_t *buf_len)
{
        struct rtio_sqe *sqe = (struct rtio_sqe *)&iodev_sqe->sqe;
 
#ifdef CONFIG_RTIO_SYS_MEM_BLOCKS
        if (sqe->op == RTIO_OP_RX && sqe->flags & RTIO_SQE_MEMPOOL_BUFFER) {
                struct rtio *r = iodev_sqe->r;
 
                if (sqe->buf != NULL) {
                        if (sqe->buf_len < min_buf_len) {
                                return -ENOMEM;
                        }
                        *buf = sqe->buf;
                        *buf_len = sqe->buf_len;
                        return 0;
                }
 
                int rc = rtio_block_pool_alloc(r, min_buf_len, max_buf_len, buf, buf_len);
                if (rc == 0) {
                        sqe->buf = *buf;
                        sqe->buf_len = *buf_len;
                        return 0;
                }
 
                return -ENOMEM;
        }
#else
        ARG_UNUSED(max_buf_len);
#endif
 
        if (sqe->buf_len < min_buf_len) {
                return -ENOMEM;
        }
 
        *buf = sqe->buf;
        *buf_len = sqe->buf_len;
        return 0;
}
 
__syscall void rtio_release_buffer(struct rtio *r, void *buff, uint32_t buff_len);
 
static inline void z_impl_rtio_release_buffer(struct rtio *r, void *buff, uint32_t buff_len)
{
#ifdef CONFIG_RTIO_SYS_MEM_BLOCKS
        if (r == NULL || buff == NULL || r->block_pool == NULL || buff_len == 0) {
                return;
        }
 
        rtio_block_pool_free(r, buff, buff_len);
#else
        ARG_UNUSED(r);
        ARG_UNUSED(buff);
        ARG_UNUSED(buff_len);
#endif
}
 
static inline void rtio_access_grant(struct rtio *r, struct k_thread *t)
{
        k_object_access_grant(r, t);
 
#ifdef CONFIG_RTIO_SUBMIT_SEM
        k_object_access_grant(r->submit_sem, t);
#endif
 
#ifdef CONFIG_RTIO_CONSUME_SEM
        k_object_access_grant(r->consume_sem, t);
#endif
}
 
__syscall int rtio_sqe_cancel(struct rtio_sqe *sqe);
 
static inline int z_impl_rtio_sqe_cancel(struct rtio_sqe *sqe)
{
        struct rtio_iodev_sqe *iodev_sqe = CONTAINER_OF(sqe, struct rtio_iodev_sqe, sqe);
 
        do {
                iodev_sqe->sqe.flags |= RTIO_SQE_CANCELED;
                iodev_sqe = rtio_iodev_sqe_next(iodev_sqe);
        } while (iodev_sqe != NULL);
 
        return 0;
}
 
__syscall int rtio_sqe_copy_in_get_handles(struct rtio *r, const struct rtio_sqe *sqes,
                                           struct rtio_sqe **handle, size_t sqe_count);
 
static inline int z_impl_rtio_sqe_copy_in_get_handles(struct rtio *r, const struct rtio_sqe *sqes,
                                                      struct rtio_sqe **handle,
                                                      size_t sqe_count)
{
        struct rtio_sqe *sqe;
        uint32_t acquirable = rtio_sqe_acquirable(r);
 
        if (acquirable < sqe_count) {
                return -ENOMEM;
        }
 
        for (unsigned long i = 0; i < sqe_count; i++) {
                sqe = rtio_sqe_acquire(r);
                __ASSERT_NO_MSG(sqe != NULL);
                if (handle != NULL && i == 0) {
                        *handle = sqe;
                }
                *sqe = sqes[i];
        }
 
        return 0;
}
 
static inline int rtio_sqe_copy_in(struct rtio *r, const struct rtio_sqe *sqes, size_t sqe_count)
{
        return rtio_sqe_copy_in_get_handles(r, sqes, NULL, sqe_count);
}
 
__syscall int rtio_cqe_copy_out(struct rtio *r,
                                struct rtio_cqe *cqes,
                                size_t cqe_count,
                                k_timeout_t timeout);
static inline int z_impl_rtio_cqe_copy_out(struct rtio *r,
                                           struct rtio_cqe *cqes,
                                           size_t cqe_count,
                                           k_timeout_t timeout)
{
        size_t copied = 0;
        struct rtio_cqe *cqe;
        k_timepoint_t end = sys_timepoint_calc(timeout);
 
        do {
                cqe = K_TIMEOUT_EQ(timeout, K_FOREVER) ? rtio_cqe_consume_block(r)
                                                       : rtio_cqe_consume(r);
                if (cqe == NULL) {
#ifdef CONFIG_BOARD_NATIVE_POSIX
                        /* Native posix fakes the clock and only moves it forward when sleeping. */
                        k_sleep(K_TICKS(1));
#else
                        Z_SPIN_DELAY(1);
#endif
                        continue;
                }
                cqes[copied++] = *cqe;
                rtio_cqe_release(r, cqe);
        } while (copied < cqe_count && !sys_timepoint_expired(end));
 
        return copied;
}
 
__syscall int rtio_submit(struct rtio *r, uint32_t wait_count);
 
static inline int z_impl_rtio_submit(struct rtio *r, uint32_t wait_count)
{
        int res = 0;
 
#ifdef CONFIG_RTIO_SUBMIT_SEM
        /* TODO undefined behavior if another thread calls submit of course
         */
        if (wait_count > 0) {
                __ASSERT(!k_is_in_isr(),
                         "expected rtio submit with wait count to be called from a thread");
 
                k_sem_reset(r->submit_sem);
                r->submit_count = wait_count;
        }
#else
        uintptr_t cq_count = (uintptr_t)atomic_get(&r->cq_count) + wait_count;
#endif
 
        /* Submit the queue to the executor which consumes submissions
         * and produces completions through ISR chains or other means.
         */
        rtio_executor_submit(r);
 
 
        /* TODO could be nicer if we could suspend the thread and not
         * wake up on each completion here.
         */
#ifdef CONFIG_RTIO_SUBMIT_SEM
 
        if (wait_count > 0) {
                res = k_sem_take(r->submit_sem, K_FOREVER);
                __ASSERT(res == 0,
                         "semaphore was reset or timed out while waiting on completions!");
        }
#else
        while ((uintptr_t)atomic_get(&r->cq_count) < cq_count) {
                Z_SPIN_DELAY(10);
                k_yield();
        }
#endif
 
        return res;
}
 
#ifdef __cplusplus
}
#endif
 
#include <syscalls/rtio.h>
 
#endif /* ZEPHYR_INCLUDE_RTIO_RTIO_H_ */