* BSD LICENSE
*
* Copyright (c) 2016 Freescale Semiconductor, Inc. All rights reserved.
- * Copyright (c) 2016 NXP. All rights reserved.
+ * Copyright 2016 NXP.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
#ifndef _DPAA2_HW_PVT_H_
#define _DPAA2_HW_PVT_H_
+#include <rte_eventdev.h>
+
#include <mc/fsl_mc_sys.h>
#include <fsl_qbman_portal.h>
#define lower_32_bits(x) ((uint32_t)(x))
#define upper_32_bits(x) ((uint32_t)(((x) >> 16) >> 16))
+#define SVR_LS1080A 0x87030000
+#define SVR_LS2080A 0x87010000
+#define SVR_LS2088A 0x87090000
+#define SVR_LX2160A 0x87360000
+
#ifndef ETH_VLAN_HLEN
#define ETH_VLAN_HLEN 4 /** < Vlan Header Length */
#endif
#define MAX_BPID 256
#define DPAA2_MBUF_HW_ANNOTATION 64
-#define DPAA2_FD_PTA_SIZE 64
+#define DPAA2_FD_PTA_SIZE 0
#if (DPAA2_MBUF_HW_ANNOTATION + DPAA2_FD_PTA_SIZE) > RTE_PKTMBUF_HEADROOM
#error "Annotation requirement is more than RTE_PKTMBUF_HEADROOM"
#define DPAA2_HW_BUF_RESERVE 0
#define DPAA2_PACKET_LAYOUT_ALIGN 64 /*changing from 256 */
+#define DPAA2_DPCI_MAX_QUEUES 2
+
struct dpaa2_dpio_dev {
TAILQ_ENTRY(dpaa2_dpio_dev) next;
/**< Pointer to Next device instance */
uintptr_t qbman_portal_ci_paddr;
/**< Physical address of Cache Inhibit Area */
uintptr_t ci_size; /**< Size of the CI region */
- int32_t vfio_fd; /**< File descriptor received via VFIO */
+ struct rte_intr_handle intr_handle; /* Interrupt related info */
+ int32_t epoll_fd; /**< File descriptor created for interrupt polling */
int32_t hw_id; /**< An unique ID of this DPIO device instance */
+ uint64_t dqrr_held;
+ uint8_t dqrr_size;
};
struct dpaa2_dpbp_dev {
struct queue_storage_info_t {
struct qbman_result *dq_storage[NUM_DQS_PER_QUEUE];
+ struct qbman_result *active_dqs;
+ int active_dpio_id;
+ int toggle;
};
+typedef void (dpaa2_queue_cb_dqrr_t)(struct qbman_swp *swp,
+ const struct qbman_fd *fd,
+ const struct qbman_result *dq,
+ struct rte_event *ev);
+
struct dpaa2_queue {
struct rte_mempool *mb_pool; /**< mbuf pool to populate RX ring. */
void *dev;
uint64_t rx_pkts;
uint64_t tx_pkts;
uint64_t err_pkts;
- struct queue_storage_info_t *q_storage;
+ union {
+ struct queue_storage_info_t *q_storage;
+ struct qbman_result *cscn;
+ };
+ dpaa2_queue_cb_dqrr_t *cb;
+};
+
+struct swp_active_dqs {
+ struct qbman_result *global_active_dqs;
+ uint64_t reserved[7];
+};
+
+#define NUM_MAX_SWP 64
+
+extern struct swp_active_dqs rte_global_active_dqs_list[NUM_MAX_SWP];
+
+struct dpaa2_dpci_dev {
+ TAILQ_ENTRY(dpaa2_dpci_dev) next;
+ /**< Pointer to Next device instance */
+ struct fsl_mc_io dpci; /** handle to DPCI portal object */
+ uint16_t token;
+ rte_atomic16_t in_use;
+ uint32_t dpci_id; /*HW ID for DPCI object */
+ struct dpaa2_queue queue[DPAA2_DPCI_MAX_QUEUES];
};
/*! Global MCP list */
uint32_t reserved[3]; /* Not used currently */
};
+struct qbman_sge {
+ uint32_t addr_lo;
+ uint32_t addr_hi;
+ uint32_t length;
+ uint32_t fin_bpid_offset;
+};
+
+/* There are three types of frames: Single, Scatter Gather and Frame Lists */
+enum qbman_fd_format {
+ qbman_fd_single = 0,
+ qbman_fd_list,
+ qbman_fd_sg
+};
/*Macros to define operations on FD*/
#define DPAA2_SET_FD_ADDR(fd, addr) do { \
fd->simple.addr_lo = lower_32_bits((uint64_t)(addr)); \
} while (0)
#define DPAA2_SET_FD_LEN(fd, length) (fd)->simple.len = length
#define DPAA2_SET_FD_BPID(fd, bpid) ((fd)->simple.bpid_offset |= bpid)
+#define DPAA2_SET_FD_IVP(fd) ((fd->simple.bpid_offset |= 0x00004000))
#define DPAA2_SET_FD_OFFSET(fd, offset) \
((fd->simple.bpid_offset |= (uint32_t)(offset) << 16))
+#define DPAA2_SET_FD_INTERNAL_JD(fd, len) fd->simple.frc = (0x80000000 | (len))
+#define DPAA2_SET_FD_FRC(fd, frc) fd->simple.frc = frc
#define DPAA2_RESET_FD_CTRL(fd) (fd)->simple.ctrl = 0
#define DPAA2_SET_FD_ASAL(fd, asal) ((fd)->simple.ctrl |= (asal << 16))
fd->simple.flc_lo = lower_32_bits((uint64_t)(addr)); \
fd->simple.flc_hi = upper_32_bits((uint64_t)(addr)); \
} while (0)
+#define DPAA2_SET_FLE_INTERNAL_JD(fle, len) (fle->frc = (0x80000000 | (len)))
+#define DPAA2_GET_FLE_ADDR(fle) \
+ (uint64_t)((((uint64_t)(fle->addr_hi)) << 32) + fle->addr_lo)
+#define DPAA2_SET_FLE_ADDR(fle, addr) do { \
+ fle->addr_lo = lower_32_bits((uint64_t)addr); \
+ fle->addr_hi = upper_32_bits((uint64_t)addr); \
+} while (0)
+#define DPAA2_GET_FLE_CTXT(fle) \
+ (uint64_t)((((uint64_t)((fle)->reserved[1])) << 32) + \
+ (fle)->reserved[0])
+#define DPAA2_FLE_SAVE_CTXT(fle, addr) do { \
+ fle->reserved[0] = lower_32_bits((uint64_t)addr); \
+ fle->reserved[1] = upper_32_bits((uint64_t)addr); \
+} while (0)
+#define DPAA2_SET_FLE_OFFSET(fle, offset) \
+ ((fle)->fin_bpid_offset |= (uint32_t)(offset) << 16)
+#define DPAA2_SET_FLE_BPID(fle, bpid) ((fle)->fin_bpid_offset |= (uint64_t)bpid)
+#define DPAA2_GET_FLE_BPID(fle) ((fle)->fin_bpid_offset & 0x000000ff)
+#define DPAA2_SET_FLE_FIN(fle) (fle->fin_bpid_offset |= (uint64_t)1 << 31)
+#define DPAA2_SET_FLE_IVP(fle) (((fle)->fin_bpid_offset |= 0x00004000))
+#define DPAA2_SET_FD_COMPOUND_FMT(fd) \
+ (fd->simple.bpid_offset |= (uint32_t)1 << 28)
#define DPAA2_GET_FD_ADDR(fd) \
((uint64_t)((((uint64_t)((fd)->simple.addr_hi)) << 32) + (fd)->simple.addr_lo))
#define DPAA2_GET_FD_LEN(fd) ((fd)->simple.len)
#define DPAA2_GET_FD_BPID(fd) (((fd)->simple.bpid_offset & 0x00003FFF))
+#define DPAA2_GET_FD_IVP(fd) ((fd->simple.bpid_offset & 0x00004000) >> 14)
#define DPAA2_GET_FD_OFFSET(fd) (((fd)->simple.bpid_offset & 0x0FFF0000) >> 16)
+#define DPAA2_GET_FLE_OFFSET(fle) (((fle)->fin_bpid_offset & 0x0FFF0000) >> 16)
+#define DPAA2_SET_FLE_SG_EXT(fle) (fle->fin_bpid_offset |= (uint64_t)1 << 29)
+#define DPAA2_IS_SET_FLE_SG_EXT(fle) \
+ ((fle->fin_bpid_offset & ((uint64_t)1 << 29)) ? 1 : 0)
+
#define DPAA2_INLINE_MBUF_FROM_BUF(buf, meta_data_size) \
((struct rte_mbuf *)((uint64_t)(buf) - (meta_data_size)))
#define DPAA2_ASAL_VAL (DPAA2_MBUF_HW_ANNOTATION / 64)
+#define DPAA2_FD_SET_FORMAT(fd, format) do { \
+ (fd)->simple.bpid_offset &= 0xCFFFFFFF; \
+ (fd)->simple.bpid_offset |= (uint32_t)format << 28; \
+} while (0)
+#define DPAA2_FD_GET_FORMAT(fd) (((fd)->simple.bpid_offset >> 28) & 0x3)
+
+#define DPAA2_SG_SET_FINAL(sg, fin) do { \
+ (sg)->fin_bpid_offset &= 0x7FFFFFFF; \
+ (sg)->fin_bpid_offset |= (uint32_t)fin << 31; \
+} while (0)
+#define DPAA2_SG_IS_FINAL(sg) (!!((sg)->fin_bpid_offset >> 31))
/* Only Enqueue Error responses will be
* pushed on FQID_ERR of Enqueue FQ
*/
*/
#define DPAA2_EQ_RESP_ALWAYS 1
+#ifdef RTE_LIBRTE_DPAA2_USE_PHYS_IOVA
+static void *dpaa2_mem_ptov(phys_addr_t paddr) __attribute__((unused));
+/* todo - this is costly, need to write a fast coversion routine */
+static void *dpaa2_mem_ptov(phys_addr_t paddr)
+{
+ const struct rte_memseg *memseg = rte_eal_get_physmem_layout();
+ int i;
+
+ for (i = 0; i < RTE_MAX_MEMSEG && memseg[i].addr_64 != 0; i++) {
+ if (paddr >= memseg[i].phys_addr &&
+ (char *)paddr < (char *)memseg[i].phys_addr + memseg[i].len)
+ return (void *)(memseg[i].addr_64
+ + (paddr - memseg[i].phys_addr));
+ }
+ return NULL;
+}
+
+static phys_addr_t dpaa2_mem_vtop(uint64_t vaddr) __attribute__((unused));
+static phys_addr_t dpaa2_mem_vtop(uint64_t vaddr)
+{
+ const struct rte_memseg *memseg = rte_eal_get_physmem_layout();
+ int i;
+
+ for (i = 0; i < RTE_MAX_MEMSEG && memseg[i].addr_64 != 0; i++) {
+ if (vaddr >= memseg[i].addr_64 &&
+ vaddr < memseg[i].addr_64 + memseg[i].len)
+ return memseg[i].phys_addr
+ + (vaddr - memseg[i].addr_64);
+ }
+ return (phys_addr_t)(NULL);
+}
+
+/**
+ * When we are using Physical addresses as IO Virtual Addresses,
+ * Need to call conversion routines dpaa2_mem_vtop & dpaa2_mem_ptov
+ * wherever required.
+ * These routines are called with help of below MACRO's
+ */
+
+#define DPAA2_MBUF_VADDR_TO_IOVA(mbuf) ((mbuf)->buf_physaddr)
+#define DPAA2_OP_VADDR_TO_IOVA(op) (op->phys_addr)
+
+/**
+ * macro to convert Virtual address to IOVA
+ */
+#define DPAA2_VADDR_TO_IOVA(_vaddr) dpaa2_mem_vtop((uint64_t)(_vaddr))
+
+/**
+ * macro to convert IOVA to Virtual address
+ */
+#define DPAA2_IOVA_TO_VADDR(_iova) dpaa2_mem_ptov((phys_addr_t)(_iova))
+
+/**
+ * macro to convert modify the memory containing IOVA to Virtual address
+ */
+#define DPAA2_MODIFY_IOVA_TO_VADDR(_mem, _type) \
+ {_mem = (_type)(dpaa2_mem_ptov((phys_addr_t)(_mem))); }
+
+#else /* RTE_LIBRTE_DPAA2_USE_PHYS_IOVA */
+
+#define DPAA2_MBUF_VADDR_TO_IOVA(mbuf) ((mbuf)->buf_addr)
+#define DPAA2_OP_VADDR_TO_IOVA(op) (op)
+#define DPAA2_VADDR_TO_IOVA(_vaddr) (_vaddr)
+#define DPAA2_IOVA_TO_VADDR(_iova) (_iova)
+#define DPAA2_MODIFY_IOVA_TO_VADDR(_mem, _type)
+
+#endif /* RTE_LIBRTE_DPAA2_USE_PHYS_IOVA */
+
+static inline
+int check_swp_active_dqs(uint16_t dpio_index)
+{
+ if (rte_global_active_dqs_list[dpio_index].global_active_dqs != NULL)
+ return 1;
+ return 0;
+}
+
+static inline
+void clear_swp_active_dqs(uint16_t dpio_index)
+{
+ rte_global_active_dqs_list[dpio_index].global_active_dqs = NULL;
+}
+
+static inline
+struct qbman_result *get_swp_active_dqs(uint16_t dpio_index)
+{
+ return rte_global_active_dqs_list[dpio_index].global_active_dqs;
+}
+
+static inline
+void set_swp_active_dqs(uint16_t dpio_index, struct qbman_result *dqs)
+{
+ rte_global_active_dqs_list[dpio_index].global_active_dqs = dqs;
+}
struct dpaa2_dpbp_dev *dpaa2_alloc_dpbp_dev(void);
void dpaa2_free_dpbp_dev(struct dpaa2_dpbp_dev *dpbp);
+int dpaa2_dpbp_supported(void);
+
+struct dpaa2_dpci_dev *rte_dpaa2_alloc_dpci_dev(void);
+void rte_dpaa2_free_dpci_dev(struct dpaa2_dpci_dev *dpci);
#endif