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charset="us-ascii" Content-Transfer-Encoding: quoted-printable MIME-Version: 1.0 X-MS-Exchange-CrossTenant-AuthAs: Internal X-MS-Exchange-CrossTenant-AuthSource: DM6PR11MB3530.namprd11.prod.outlook.com X-MS-Exchange-CrossTenant-Network-Message-Id: b431a3d7-1bd4-4ca3-a262-08da482f1bc2 X-MS-Exchange-CrossTenant-originalarrivaltime: 07 Jun 2022 02:40:39.2437 (UTC) X-MS-Exchange-CrossTenant-fromentityheader: Hosted X-MS-Exchange-CrossTenant-id: 46c98d88-e344-4ed4-8496-4ed7712e255d X-MS-Exchange-CrossTenant-mailboxtype: HOSTED X-MS-Exchange-CrossTenant-userprincipalname: BlROmLIR+sSTkkA4kHar/c5VinLSVmK0Ntcl55tBi/jcV8ODewckUohtHPwK8bF9ZqkD98sQXzofEI/vHtJ6NA== X-MS-Exchange-Transport-CrossTenantHeadersStamped: BYAPR11MB3670 X-OriginatorOrg: intel.com X-BeenThere: stable@dpdk.org X-Mailman-Version: 2.1.29 Precedence: list List-Id: patches for DPDK stable branches List-Unsubscribe: , List-Archive: List-Post: List-Help: List-Subscribe: , Errors-To: stable-bounces@dpdk.org > -----Original Message----- > From: Zhang, Tianfei > Sent: Monday, June 6, 2022 09:39 > To: Huang, Wei ; dev@dpdk.org; > thomas@monjalon.net; nipun.gupta@nxp.com; hemant.agrawal@nxp.com > Cc: stable@dpdk.org; Xu, Rosen ; Zhang, Qi Z > > Subject: RE: [PATCH v5 2/5] raw/afu_mf: add N3000 AFU driver >=20 >=20 >=20 > > -----Original Message----- > > From: Huang, Wei > > Sent: Friday, May 27, 2022 1:37 PM > > To: dev@dpdk.org; thomas@monjalon.net; nipun.gupta@nxp.com; > > hemant.agrawal@nxp.com > > Cc: stable@dpdk.org; Xu, Rosen ; Zhang, Tianfei > > ; Zhang, Qi Z ; Huang, > Wei > > > > Subject: [PATCH v5 2/5] raw/afu_mf: add N3000 AFU driver > > > > N3000 AFU includes NLB0 and DMA modules, NLB0 is used to test PCI bus > > and DMA is used to test local memory. > > This driver initialize the modules and report test result. > > > > Signed-off-by: Wei Huang > > --- > > drivers/raw/afu_mf/afu_mf_rawdev.c | 4 + > > drivers/raw/afu_mf/afu_mf_rawdev.h | 18 + > > drivers/raw/afu_mf/meson.build | 4 +- > > drivers/raw/afu_mf/n3000_afu.c | 2005 > > ++++++++++++++++++++++++++++++++++++ > > drivers/raw/afu_mf/n3000_afu.h | 333 ++++++ > > drivers/raw/afu_mf/rte_pmd_afu.h | 97 ++ > > 6 files changed, 2460 insertions(+), 1 deletion(-) > > create mode 100644 drivers/raw/afu_mf/n3000_afu.c > > create mode 100644 drivers/raw/afu_mf/n3000_afu.h > > create mode 100644 drivers/raw/afu_mf/rte_pmd_afu.h > > > > diff --git a/drivers/raw/afu_mf/afu_mf_rawdev.c > > b/drivers/raw/afu_mf/afu_mf_rawdev.c > > index 5be372a..7c18f3b 100644 > > --- a/drivers/raw/afu_mf/afu_mf_rawdev.c > > +++ b/drivers/raw/afu_mf/afu_mf_rawdev.c > > @@ -17,15 +17,19 @@ > > #include > > #include > > > > +#include "rte_pmd_afu.h" > > #include "afu_mf_rawdev.h" > > +#include "n3000_afu.h" > > > > #define AFU_MF_PMD_RAWDEV_NAME rawdev_afu_mf > > > > static const struct rte_afu_uuid afu_uuid_map[] =3D { > > + { N3000_AFU_UUID_L, N3000_AFU_UUID_H }, > > { 0, 0 /* sentinel */ } > > }; > > > > static struct afu_mf_drv *afu_table[] =3D { > > + &n3000_afu_drv, > > NULL > > }; > > > > diff --git a/drivers/raw/afu_mf/afu_mf_rawdev.h > > b/drivers/raw/afu_mf/afu_mf_rawdev.h > > index df6715c..5a66f6c 100644 > > --- a/drivers/raw/afu_mf/afu_mf_rawdev.h > > +++ b/drivers/raw/afu_mf/afu_mf_rawdev.h > > @@ -30,6 +30,24 @@ > > #define AFU_MF_PMD_WARN(fmt, args...) \ > > AFU_MF_PMD_LOG(WARNING, fmt, ## args) > > > > +#define CLS_TO_SIZE(n) ((n) << 6) /* get size of n cache lines */ > > +#define SIZE_TO_CLS(s) ((s) >> 6) /* convert size to number of cache > lines */ > > +#define MHZ(f) ((f) * 1000000) > > + > > +#define dsm_poll_timeout(addr, val, cond, invl, timeout) \ > > +({ \ > > + uint64_t __wait =3D 0; \ > > + uint64_t __invl =3D (invl); \ > > + uint64_t __timeout =3D (timeout); \ > > + for (; __wait <=3D __timeout; __wait +=3D __invl) { \ > > + (val) =3D *(addr); \ > > + if (cond) \ > > + break; \ > > + rte_delay_ms(__invl); \ > > + } \ > > + (cond) ? 0 : 1; \ > > +}) >=20 > Dsm means DMA? DSM means 'DMA Status Memory' >=20 > > + > > struct afu_mf_rawdev; > > > > struct afu_mf_ops { > > diff --git a/drivers/raw/afu_mf/meson.build > b/drivers/raw/afu_mf/meson.build > > index 80526a2..8a989e3 100644 > > --- a/drivers/raw/afu_mf/meson.build > > +++ b/drivers/raw/afu_mf/meson.build > > @@ -2,4 +2,6 @@ > > # Copyright 2022 Intel Corporation > > > > deps +=3D ['rawdev', 'bus_pci', 'bus_ifpga'] > > -sources =3D files('afu_mf_rawdev.c') > > +sources =3D files('afu_mf_rawdev.c', 'n3000_afu.c') > > + > > +headers =3D files('rte_pmd_afu.h') > > diff --git a/drivers/raw/afu_mf/n3000_afu.c > b/drivers/raw/afu_mf/n3000_afu.c > > new file mode 100644 > > index 0000000..19d7c54 > > --- /dev/null > > +++ b/drivers/raw/afu_mf/n3000_afu.c > > @@ -0,0 +1,2005 @@ > > +/* SPDX-License-Identifier: BSD-3-Clause > > + * Copyright(c) 2022 Intel Corporation > > + */ > > + > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > + > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > +#include > > + > > +#include "afu_mf_rawdev.h" > > +#include "n3000_afu.h" > > + > > +static int nlb_afu_config(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct rte_pmd_afu_nlb_cfg *cfg =3D NULL; > > + struct nlb_csr_cfg v; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + if (!dev->priv) > > + return -ENOENT; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + cfg =3D &priv->nlb_cfg; > > + > > + v.csr =3D 0; > > + > > + if (cfg->cont) > > + v.cont =3D 1; > > + > > + if (cfg->cache_policy =3D=3D NLB_WRPUSH_I) > > + v.wrpush_i =3D 1; > > + else > > + v.wrthru_en =3D cfg->cache_policy; > > + > > + if (cfg->cache_hint =3D=3D NLB_RDLINE_MIXED) > > + v.rdsel =3D 3; > > + else > > + v.rdsel =3D cfg->cache_hint; > > + > > + v.mode =3D cfg->mode; > > + v.chsel =3D cfg->read_vc; > > + v.wr_chsel =3D cfg->write_vc; > > + v.wrfence_chsel =3D cfg->wrfence_vc; > > + v.wrthru_en =3D cfg->cache_policy; > > + v.multicl_len =3D cfg->multi_cl - 1; > > + > > + AFU_MF_PMD_DEBUG("cfg: 0x%08x", v.csr); > > + rte_write32(v.csr, priv->nlb_ctx.addr + CSR_CFG); > > + > > + return 0; > > +} > > + > > +static void nlb_afu_report(struct afu_mf_rawdev *dev, uint32_t cl) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct rte_pmd_afu_nlb_cfg *cfg =3D NULL; > > + struct nlb_dsm_status *stat =3D NULL; > > + uint64_t ticks =3D 0; > > + double num, rd_bw, wr_bw; > > + > > + if (!dev || !dev->priv) > > + return; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + > > + cfg =3D &priv->nlb_cfg; > > + stat =3D priv->nlb_ctx.status_ptr; > > + > > + if (cfg->cont) > > + ticks =3D stat->num_clocks - stat->start_overhead; > > + else > > + ticks =3D stat->num_clocks - > > + (stat->start_overhead + stat->end_overhead); > > + > > + if (cfg->freq_mhz =3D=3D 0) > > + cfg->freq_mhz =3D 200; > > + > > + num =3D (double)stat->num_reads; > > + rd_bw =3D (num * CLS_TO_SIZE(1) * MHZ(cfg->freq_mhz)) / ticks; > > + num =3D (double)stat->num_writes; > > + wr_bw =3D (num * CLS_TO_SIZE(1) * MHZ(cfg->freq_mhz)) / ticks; > > + > > + printf("Cachelines Read_Count Write_Count Clocks@%uMHz " > > + "Rd_Bandwidth Wr_Bandwidth\n", cfg->freq_mhz); > > + printf("%10u %10u %11u %12"PRIu64" %7.3f GB/s %7.3f GB/s\n", > > + cl, stat->num_reads, stat->num_writes, ticks, > > + rd_bw / 1e9, wr_bw / 1e9); > > +} > > + > > +static int nlb_afu_test(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct nlb_afu_ctx *ctx =3D NULL; > > + struct rte_pmd_afu_nlb_cfg *cfg =3D NULL; > > + struct nlb_csr_ctl ctl; > > + uint32_t *ptr =3D NULL; > > + uint32_t i, j, cl, val =3D 0; > > + uint64_t sval =3D 0; > > + int ret =3D 0; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + if (!dev->priv) > > + return -ENOENT; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + ctx =3D &priv->nlb_ctx; > > + cfg =3D &priv->nlb_cfg; > > + > > + /* initialize registers */ > > + AFU_MF_PMD_DEBUG("dsm_addr: 0x%"PRIx64, ctx->dsm_iova); > > + rte_write64(ctx->dsm_iova, ctx->addr + CSR_AFU_DSM_BASEL); > > + > > + ctl.csr =3D 0; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + ctl.reset =3D 1; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + > > + AFU_MF_PMD_DEBUG("src_addr: 0x%"PRIx64, ctx->src_iova); > > + rte_write64(SIZE_TO_CLS(ctx->src_iova), ctx->addr + > CSR_SRC_ADDR); > > + AFU_MF_PMD_DEBUG("dst_addr: 0x%"PRIx64, ctx->dest_iova); > > + rte_write64(SIZE_TO_CLS(ctx->dest_iova), ctx->addr + > CSR_DST_ADDR); > > + > > + ret =3D nlb_afu_config(dev); > > + if (ret) > > + return ret; > > + > > + /* initialize src data */ > > + ptr =3D (uint32_t *)ctx->src_ptr; > > + j =3D CLS_TO_SIZE(cfg->end) >> 2; > > + for (i =3D 0; i < j; i++) > > + *ptr++ =3D i; > > + > > + /* start test */ > > + for (cl =3D cfg->begin; cl <=3D cfg->end; cl +=3D cfg->multi_cl) { > > + memset(ctx->dest_ptr, 0, CLS_TO_SIZE(cl)); > > + memset(ctx->dsm_ptr, 0, DSM_SIZE); > > + > > + ctl.csr =3D 0; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + ctl.reset =3D 1; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + > > + rte_write32(cl, ctx->addr + CSR_NUM_LINES); > > + > > + rte_delay_us(10); > > + > > + ctl.start =3D 1; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + > > + if (cfg->cont) { > > + rte_delay_ms(cfg->timeout * 1000); > > + ctl.force_completion =3D 1; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + ret =3D dsm_poll_timeout(&ctx->status_ptr- > > >test_complete, > > + val, (val & 0x1) =3D=3D 1, DSM_POLL_INTERVAL, > > + DSM_TIMEOUT); > > + if (ret) { > > + printf("DSM poll timeout\n"); > > + goto end; > > + } > > + } else { > > + ret =3D dsm_poll_timeout(&ctx->status_ptr- > > >test_complete, > > + val, (val & 0x1) =3D=3D 1, DSM_POLL_INTERVAL, > > + DSM_TIMEOUT); > > + if (ret) { > > + printf("DSM poll timeout\n"); > > + goto end; > > + } > > + ctl.force_completion =3D 1; > > + rte_write32(ctl.csr, ctx->addr + CSR_CTL); > > + } > > + > > + nlb_afu_report(dev, cl); > > + > > + i =3D 0; > > + while (i++ < 100) { > > + sval =3D rte_read64(ctx->addr + CSR_STATUS1); > > + if (sval =3D=3D 0) > > + break; > > + rte_delay_us(1000); > > + } > > + > > + ptr =3D (uint32_t *)ctx->dest_ptr; > > + j =3D CLS_TO_SIZE(cl) >> 2; > > + for (i =3D 0; i < j; i++) { > > + if (*ptr++ !=3D i) { > > + AFU_MF_PMD_ERR("Data mismatch @ %u", > i); > > + break; > > + } > > + } > > + } > > + > > +end: > > + return ret; > > +} > > + > > +static void dma_afu_buf_free(struct dma_afu_ctx *ctx) > > +{ > > + int i =3D 0; > > + > > + if (!ctx) > > + return; > > + > > + for (i =3D 0; i < NUM_DMA_BUF; i++) { > > + rte_free(ctx->dma_buf[i]); > > + ctx->dma_buf[i] =3D NULL; > > + } > > + > > + rte_free(ctx->data_buf); > > + ctx->data_buf =3D NULL; > > + > > + rte_free(ctx->ref_buf); > > + ctx->ref_buf =3D NULL; > > +} > > + > > +static int dma_afu_buf_alloc(struct dma_afu_ctx *ctx, > > + struct rte_pmd_afu_dma_cfg *cfg) > > +{ > > + size_t page_sz =3D sysconf(_SC_PAGE_SIZE); > > + int i, ret =3D 0; > > + > > + if (!ctx || !cfg) > > + return -EINVAL; > > + > > + for (i =3D 0; i < NUM_DMA_BUF; i++) { > > + ctx->dma_buf[i] =3D (uint64_t *)rte_zmalloc(NULL, cfg->size, > > + TEST_MEM_ALIGN); > > + if (!ctx->dma_buf[i]) { > > + ret =3D -ENOMEM; > > + goto free; > > + } > > + ctx->dma_iova[i] =3D rte_malloc_virt2iova(ctx->dma_buf[i]); > > + if (ctx->dma_iova[i] =3D=3D RTE_BAD_IOVA) { > > + ret =3D -ENOMEM; > > + goto free; > > + } > > + } > > + > > + ctx->data_buf =3D rte_malloc(NULL, cfg->length, page_sz); > > + if (!ctx->data_buf) { > > + ret =3D -ENOMEM; > > + goto free; > > + } > > + > > + ctx->ref_buf =3D rte_malloc(NULL, cfg->length, page_sz); > > + if (!ctx->ref_buf) { > > + ret =3D -ENOMEM; > > + goto free; > > + } >=20 > Suppose that If ctx->ref_buf alloc fail, the dma_afu_buf_free() will work > correct? >=20 dma_afu_buf_free() can work correct in failure situation, but it's not stan= dard exception handle, I will change it. > > + > > + return 0; > > + > > +free: > > + dma_afu_buf_free(ctx); > > + return ret; > > +} > > + > > +static void dma_afu_buf_init(struct dma_afu_ctx *ctx, size_t size) > > +{ > > + int *ptr =3D NULL; > > + size_t i =3D 0; > > + size_t dword_size =3D 0; > > + > > + if (!ctx || !size) > > + return; > > + > > + ptr =3D (int *)ctx->ref_buf; > > + > > + if (ctx->pattern) { > > + memset(ptr, ctx->pattern, size); > > + } else { > > + srand(99); > > + dword_size =3D size >> 2; > > + for (i =3D 0; i < dword_size; i++) > > + *ptr++ =3D rand(); > > + } > > + rte_memcpy(ctx->data_buf, ctx->ref_buf, size); > > +} > > + > > +static int dma_afu_buf_verify(struct dma_afu_ctx *ctx, size_t size) > > +{ > > + uint8_t *src =3D NULL; > > + uint8_t *dst =3D NULL; > > + size_t i =3D 0; > > + int n =3D 0; > > + > > + if (!ctx || !size) > > + return -EINVAL; > > + > > + src =3D (uint8_t *)ctx->ref_buf; > > + dst =3D (uint8_t *)ctx->data_buf; > > + > > + if (memcmp(src, dst, size)) { > > + printf("Transfer is corrupted\n"); > > + if (ctx->verbose) { > > + for (i =3D 0; i < size; i++) { > > + if (*src !=3D *dst) { > > + if (++n >=3D ERR_CHECK_LIMIT) > > + break; > > + printf("Mismatch at 0x%zx, " > > + "Expected %02x Actual > > %02x\n", > > + i, *src, *dst); > > + } > > + src++; > > + dst++; > > + } > > + if (n < ERR_CHECK_LIMIT) { > > + printf("Found %d error bytes\n", n); > > + } else { > > + printf("......\n"); > > + printf("Found more than %d error bytes\n", > n); > > + } > > + } > > + return -1; > > + } > > + > > + printf("Transfer is verified\n"); > > + return 0; > > +} > > + > > +static void blk_write64(uint64_t *dev_addr, uint64_t *host_addr, > uint64_t > > bytes) > > +{ > > + uint64_t qwords =3D bytes / sizeof(uint64_t); > > + > > + if (!IS_ALIGNED_QWORD((uint64_t)dev_addr) || > > + !IS_ALIGNED_QWORD((uint64_t)bytes)) > > + return; > > + > > + for (; qwords > 0; qwords--, host_addr++, dev_addr++) > > + rte_write64(*host_addr, dev_addr); > > +} > > + > > +static void blk_read64(uint64_t *dev_addr, uint64_t *host_addr, uint64= _t > > bytes) > > +{ > > + uint64_t qwords =3D bytes / sizeof(uint64_t); > > + > > + if (!IS_ALIGNED_QWORD((uint64_t)dev_addr) || > > + !IS_ALIGNED_QWORD((uint64_t)bytes)) > > + return; > > + > > + for (; qwords > 0; qwords--, host_addr++, dev_addr++) > > + *host_addr =3D rte_read64(dev_addr); > > +} > > + > > +static void switch_ase_page(struct dma_afu_ctx *ctx, uint64_t addr) > > +{ > > + uint64_t requested_page =3D addr & ~DMA_ASE_WINDOW_MASK; > > + > > + if (!ctx) > > + return; > > + > > + if (requested_page !=3D ctx->cur_ase_page) { > > + rte_write64(requested_page, ctx->ase_ctrl_addr); > > + ctx->cur_ase_page =3D requested_page; > > + } > > +} > > + > > +static int ase_write_unaligned(struct dma_afu_ctx *ctx, uint64_t > dev_addr, > > + uint64_t host_addr, uint32_t count) > > +{ > > + uint64_t dev_aligned_addr =3D 0; > > + uint64_t shift =3D 0; > > + uint64_t val =3D 0; > > + uintptr_t addr =3D (uintptr_t)host_addr; /* transfer to pointer size= */ > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" --> 0x%"PRIx64" (0x%x)", > > host_addr, > > + dev_addr, count); > > + > > + if (!ctx || (count >=3D QWORD_BYTES)) > > + return -EINVAL; > > + > > + if (!count) > > + return 0; > > + > > + switch_ase_page(ctx, dev_addr); > > + > > + shift =3D dev_addr % QWORD_BYTES; > > + dev_aligned_addr =3D (dev_addr - shift) & DMA_ASE_WINDOW_MASK; > > + val =3D rte_read64(ctx->ase_data_addr + dev_aligned_addr); > > + rte_memcpy(((char *)(&val)) + shift, (void *)addr, count); > > + > > + /* write back to device */ > > + rte_write64(val, ctx->ase_data_addr + dev_aligned_addr); > > + > > + return 0; > > +} > > + > > +static int ase_write(struct dma_afu_ctx *ctx, uint64_t *dst_ptr, > > + uint64_t *src_ptr, uint64_t *count) > > +{ > > + uint64_t src =3D *src_ptr; > > + uint64_t dst =3D *dst_ptr; > > + uint64_t align_bytes =3D *count; > > + uint64_t offset =3D 0; > > + uint64_t left_in_page =3D DMA_ASE_WINDOW; > > + uint64_t size_to_copy =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" --> 0x%"PRIx64" > (0x%"PRIx64")", > > src, dst, > > + align_bytes); > > + > > + if (!ctx || !IS_ALIGNED_DWORD(dst)) > > + return -EINVAL; > > + > > + if (align_bytes < DWORD_BYTES) > > + return 0; > > + > > + if (!IS_ALIGNED_QWORD(dst)) { > > + /* Write out a single DWORD to get QWORD aligned */ > > + switch_ase_page(ctx, dst); > > + offset =3D dst & DMA_ASE_WINDOW_MASK; > > + > > + rte_write32(*(uint32_t *)(uintptr_t)src, > > + ctx->ase_data_addr + offset); > > + src +=3D DWORD_BYTES; > > + dst +=3D DWORD_BYTES; > > + align_bytes -=3D DWORD_BYTES; > > + } > > + > > + if (!align_bytes) > > + return 0; > > + > > + /* Write out blocks of 64-bit values */ > > + while (align_bytes >=3D QWORD_BYTES) { > > + left_in_page -=3D dst & DMA_ASE_WINDOW_MASK; > > + size_to_copy =3D > > + MIN(left_in_page, (align_bytes & ~(QWORD_BYTES - > > 1))); > > + if (size_to_copy < QWORD_BYTES) > > + break; > > + switch_ase_page(ctx, dst); > > + offset =3D dst & DMA_ASE_WINDOW_MASK; > > + blk_write64((uint64_t *)(ctx->ase_data_addr + offset), > > + (uint64_t *)(uintptr_t)src, size_to_copy); > > + src +=3D size_to_copy; > > + dst +=3D size_to_copy; > > + align_bytes -=3D size_to_copy; > > + } > > + > > + if (align_bytes >=3D DWORD_BYTES) { > > + /* Write out remaining DWORD */ > > + switch_ase_page(ctx, dst); > > + offset =3D dst & DMA_ASE_WINDOW_MASK; > > + rte_write32(*(uint32_t *)(uintptr_t)src, > > + ctx->ase_data_addr + offset); > > + src +=3D DWORD_BYTES; > > + dst +=3D DWORD_BYTES; > > + align_bytes -=3D DWORD_BYTES; > > + } > > + > > + *src_ptr =3D src; > > + *dst_ptr =3D dst; > > + *count =3D align_bytes; > > + > > + return 0; > > +} > > + > > +static int ase_host_to_fpga(struct dma_afu_ctx *ctx, uint64_t *dst_ptr= , > > + uint64_t *src_ptr, uint64_t count) > > +{ > > + uint64_t dst =3D *dst_ptr; > > + uint64_t src =3D *src_ptr; > > + uint64_t count_left =3D count; > > + uint64_t unaligned_size =3D 0; > > + int ret =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" --> 0x%"PRIx64" > (0x%"PRIx64")", > > src, dst, > > + count); > > + > > + /* aligns address to 8 byte using dst masking method */ > > + if (!IS_ALIGNED_DWORD(dst) && !IS_ALIGNED_QWORD(dst)) { > > + unaligned_size =3D QWORD_BYTES - (dst % QWORD_BYTES); > > + if (unaligned_size > count_left) > > + unaligned_size =3D count_left; > > + ret =3D ase_write_unaligned(ctx, dst, src, unaligned_size); > > + if (ret) > > + return ret; > > + count_left -=3D unaligned_size; > > + src +=3D unaligned_size; > > + dst +=3D unaligned_size; > > + } > > + > > + /* Handles 8/4 byte MMIO transfer */ > > + ret =3D ase_write(ctx, &dst, &src, &count_left); > > + if (ret) > > + return ret; > > + > > + /* Left over unaligned bytes transferred using dst masking method > */ > > + unaligned_size =3D QWORD_BYTES - (dst % QWORD_BYTES); > > + if (unaligned_size > count_left) > > + unaligned_size =3D count_left; > > + > > + ret =3D ase_write_unaligned(ctx, dst, src, unaligned_size); > > + if (ret) > > + return ret; > > + > > + count_left -=3D unaligned_size; > > + *dst_ptr =3D dst + unaligned_size; > > + *src_ptr =3D src + unaligned_size; > > + > > + return 0; > > +} > > + > > +static int ase_read_unaligned(struct dma_afu_ctx *ctx, uint64_t > dev_addr, > > + uint64_t host_addr, uint32_t count) > > +{ > > + uint64_t dev_aligned_addr =3D 0; > > + uint64_t shift =3D 0; > > + uint64_t val =3D 0; > > + uintptr_t addr =3D (uintptr_t)host_addr; /* transfer to pointer size= */ > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" <-- 0x%"PRIx64" (0x%x)", > > host_addr, > > + dev_addr, count); > > + > > + if (!ctx || (count >=3D QWORD_BYTES)) > > + return -EINVAL; > > + > > + if (!count) > > + return 0; > > + > > + switch_ase_page(ctx, dev_addr); > > + > > + shift =3D dev_addr % QWORD_BYTES; > > + dev_aligned_addr =3D (dev_addr - shift) & DMA_ASE_WINDOW_MASK; > > + val =3D rte_read64(ctx->ase_data_addr + dev_aligned_addr); > > + rte_memcpy((void *)addr, ((char *)(&val)) + shift, count); > > + > > + return 0; > > +} > > + > > +static int ase_read(struct dma_afu_ctx *ctx, uint64_t *src_ptr, > > + uint64_t *dst_ptr, uint64_t *count) > > +{ > > + uint64_t src =3D *src_ptr; > > + uint64_t dst =3D *dst_ptr; > > + uint64_t align_bytes =3D *count; > > + uint64_t offset =3D 0; > > + uint64_t left_in_page =3D DMA_ASE_WINDOW; > > + uint64_t size_to_copy =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" <-- 0x%"PRIx64" > (0x%"PRIx64")", > > dst, src, > > + align_bytes); > > + > > + if (!ctx || !IS_ALIGNED_DWORD(src)) > > + return -EINVAL; > > + > > + if (align_bytes < DWORD_BYTES) > > + return 0; > > + > > + if (!IS_ALIGNED_QWORD(src)) { > > + /* Read a single DWORD to get QWORD aligned */ > > + switch_ase_page(ctx, src); > > + offset =3D src & DMA_ASE_WINDOW_MASK; > > + *(uint32_t *)(uintptr_t)dst =3D > > + rte_read32(ctx->ase_data_addr + offset); > > + src +=3D DWORD_BYTES; > > + dst +=3D DWORD_BYTES; > > + align_bytes -=3D DWORD_BYTES; > > + } > > + > > + if (!align_bytes) > > + return 0; > > + > > + /* Read blocks of 64-bit values */ > > + while (align_bytes >=3D QWORD_BYTES) { > > + left_in_page -=3D src & DMA_ASE_WINDOW_MASK; > > + size_to_copy =3D > > + MIN(left_in_page, (align_bytes & ~(QWORD_BYTES - > > 1))); > > + if (size_to_copy < QWORD_BYTES) > > + break; > > + switch_ase_page(ctx, src); > > + offset =3D src & DMA_ASE_WINDOW_MASK; > > + blk_read64((uint64_t *)(ctx->ase_data_addr + offset), > > + (uint64_t *)(uintptr_t)dst, size_to_copy); > > + src +=3D size_to_copy; > > + dst +=3D size_to_copy; > > + align_bytes -=3D size_to_copy; > > + } > > + > > + if (align_bytes >=3D DWORD_BYTES) { > > + /* Read remaining DWORD */ > > + switch_ase_page(ctx, src); > > + offset =3D src & DMA_ASE_WINDOW_MASK; > > + *(uint32_t *)(uintptr_t)dst =3D > > + rte_read32(ctx->ase_data_addr + offset); > > + src +=3D DWORD_BYTES; > > + dst +=3D DWORD_BYTES; > > + align_bytes -=3D DWORD_BYTES; > > + } > > + > > + *src_ptr =3D src; > > + *dst_ptr =3D dst; > > + *count =3D align_bytes; > > + > > + return 0; > > +} > > + > > +static int ase_fpga_to_host(struct dma_afu_ctx *ctx, uint64_t *src_ptr= , > > + uint64_t *dst_ptr, uint64_t count) > > +{ > > + uint64_t src =3D *src_ptr; > > + uint64_t dst =3D *dst_ptr; > > + uint64_t count_left =3D count; > > + uint64_t unaligned_size =3D 0; > > + int ret =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" --> 0x%"PRIx64" > (0x%"PRIx64")", > > src, dst, > > + count); > > + > > + /* Aligns address to 8 byte using src masking method */ > > + if (!IS_ALIGNED_DWORD(src) && !IS_ALIGNED_QWORD(src)) { > > + unaligned_size =3D QWORD_BYTES - (src % QWORD_BYTES); > > + if (unaligned_size > count_left) > > + unaligned_size =3D count_left; > > + ret =3D ase_read_unaligned(ctx, src, dst, unaligned_size); > > + if (ret) > > + return ret; > > + count_left -=3D unaligned_size; > > + dst +=3D unaligned_size; > > + src +=3D unaligned_size; > > + } > > + > > + /* Handles 8/4 byte MMIO transfer */ > > + ret =3D ase_read(ctx, &src, &dst, &count_left); > > + if (ret) > > + return ret; > > + > > + /* Left over unaligned bytes transferred using src masking method */ > > + unaligned_size =3D QWORD_BYTES - (src % QWORD_BYTES); > > + if (unaligned_size > count_left) > > + unaligned_size =3D count_left; > > + > > + ret =3D ase_read_unaligned(ctx, src, dst, unaligned_size); > > + if (ret) > > + return ret; > > + > > + count_left -=3D unaligned_size; > > + *dst_ptr =3D dst + unaligned_size; > > + *src_ptr =3D src + unaligned_size; > > + > > + return 0; > > +} > > + > > +static void clear_interrupt(struct dma_afu_ctx *ctx) > > +{ > > + /* clear interrupt by writing 1 to IRQ bit in status register */ > > + msgdma_status status; > > + > > + if (!ctx) > > + return; > > + > > + status.csr =3D 0; > > + status.irq =3D 1; > > + rte_write32(status.csr, CSR_STATUS(ctx->csr_addr)); > > +} > > + > > +static int poll_interrupt(struct dma_afu_ctx *ctx) > > +{ > > + struct pollfd pfd =3D {0}; > > + uint64_t count =3D 0; > > + ssize_t bytes_read =3D 0; > > + int poll_ret =3D 0; > > + int ret =3D 0; > > + > > + if (!ctx || (ctx->event_fd < 0)) > > + return -EINVAL; > > + > > + pfd.fd =3D ctx->event_fd; > > + pfd.events =3D POLLIN; > > + poll_ret =3D poll(&pfd, 1, DMA_TIMEOUT_MSEC); > > + if (poll_ret < 0) { > > + AFU_MF_PMD_ERR("Error %s", strerror(errno)); > > + ret =3D -EFAULT; > > + goto out; > > + } else if (poll_ret =3D=3D 0) { > > + AFU_MF_PMD_ERR("Timeout"); > > + ret =3D -ETIMEDOUT; > > + } else { > > + bytes_read =3D read(pfd.fd, &count, sizeof(count)); > > + if (bytes_read > 0) { > > + if (ctx->verbose) > > + AFU_MF_PMD_DEBUG("Successful, ret %d, > cnt > > %"PRIu64, > > + poll_ret, count); > > + ret =3D 0; > > + } else { > > + AFU_MF_PMD_ERR("Failed %s", bytes_read > 0 ? > > + strerror(errno) : "zero bytes read"); > > + ret =3D -EIO; > > + } > > + } > > +out: > > + clear_interrupt(ctx); > > + return ret; > > +} > > + > > +static void send_descriptor(struct dma_afu_ctx *ctx, msgdma_ext_desc > *desc) > > +{ > > + msgdma_status status; > > + uint64_t fpga_queue_full =3D 0; > > + > > + if (!ctx) > > + return; > > + > > + if (ctx->verbose) { > > + AFU_MF_PMD_DEBUG("descriptor.rd_address =3D 0x%x%08x", > > + desc->rd_address_ext, desc->rd_address); > > + AFU_MF_PMD_DEBUG("descriptor.wr_address =3D > 0x%x%08x", > > + desc->wr_address_ext, desc->wr_address); > > + AFU_MF_PMD_DEBUG("descriptor.len =3D %u", desc->len); > > + AFU_MF_PMD_DEBUG("descriptor.wr_burst_count =3D %u", > > + desc->wr_burst_count); > > + AFU_MF_PMD_DEBUG("descriptor.rd_burst_count =3D %u", > > + desc->rd_burst_count); > > + AFU_MF_PMD_DEBUG("descriptor.wr_stride %u", desc- > > >wr_stride); > > + AFU_MF_PMD_DEBUG("descriptor.rd_stride %u", desc- > > >rd_stride); > > + } > > + > > + do { > > + status.csr =3D rte_read32(CSR_STATUS(ctx->csr_addr)); > > + if (fpga_queue_full++ > 100000000) { > > + AFU_MF_PMD_DEBUG("DMA queue full retry"); > > + fpga_queue_full =3D 0; > > + } > > + } while (status.desc_buf_full); > > + > > + blk_write64((uint64_t *)ctx->desc_addr, (uint64_t *)desc, > > + sizeof(*desc)); > > +} > > + > > +static int do_dma(struct dma_afu_ctx *ctx, uint64_t dst, uint64_t src, > > + int count, int is_last_desc, fpga_dma_type type, int intr_en) > > +{ > > + msgdma_ext_desc *desc =3D NULL; > > + int alignment_offset =3D 0; > > + int segment_size =3D 0; > > + > > + if (!ctx) > > + return -EINVAL; > > + > > + /* src, dst and count must be 64-byte aligned */ > > + if (!IS_DMA_ALIGNED(src) || !IS_DMA_ALIGNED(dst) || > > + !IS_DMA_ALIGNED(count)) > > + return -EINVAL; > > + memset(ctx->desc_buf, 0, sizeof(msgdma_ext_desc)); > > + > > + /* these fields are fixed for all DMA transfers */ > > + desc =3D ctx->desc_buf; > > + desc->seq_num =3D 0; > > + desc->wr_stride =3D 1; > > + desc->rd_stride =3D 1; > > + desc->control.go =3D 1; > > + if (intr_en) > > + desc->control.transfer_irq_en =3D 1; > > + else > > + desc->control.transfer_irq_en =3D 0; > > + > > + if (!is_last_desc) > > + desc->control.early_done_en =3D 1; > > + else > > + desc->control.early_done_en =3D 0; > > + > > + if (type =3D=3D FPGA_TO_FPGA) { > > + desc->rd_address =3D src & DMA_MASK_32_BIT; > > + desc->wr_address =3D dst & DMA_MASK_32_BIT; > > + desc->len =3D count; > > + desc->wr_burst_count =3D 4; > > + desc->rd_burst_count =3D 4; > > + desc->rd_address_ext =3D (src >> 32) & DMA_MASK_32_BIT; > > + desc->wr_address_ext =3D (dst >> 32) & DMA_MASK_32_BIT; > > + send_descriptor(ctx, desc); > > + } else { > > + /* check CCIP (host) address is aligned to 4CL (256B) */ > > + alignment_offset =3D (type =3D=3D HOST_TO_FPGA) > > + ? (src % CCIP_ALIGN_BYTES) : (dst % > > CCIP_ALIGN_BYTES); > > + /* performing a short transfer to get aligned */ > > + if (alignment_offset !=3D 0) { > > + desc->rd_address =3D src & DMA_MASK_32_BIT; > > + desc->wr_address =3D dst & DMA_MASK_32_BIT; > > + desc->wr_burst_count =3D 1; > > + desc->rd_burst_count =3D 1; > > + desc->rd_address_ext =3D (src >> 32) & > > DMA_MASK_32_BIT; > > + desc->wr_address_ext =3D (dst >> 32) & > > DMA_MASK_32_BIT; > > + /* count isn't large enough to hit next 4CL boundary > */ > > + if ((CCIP_ALIGN_BYTES - alignment_offset) >=3D count) > { > > + segment_size =3D count; > > + count =3D 0; > > + } else { > > + segment_size =3D CCIP_ALIGN_BYTES > > + - alignment_offset; > > + src +=3D segment_size; > > + dst +=3D segment_size; > > + count -=3D segment_size; > > + desc->control.transfer_irq_en =3D 0; > > + } > > + /* post short transfer to align to a 4CL (256 byte) */ > > + desc->len =3D segment_size; > > + send_descriptor(ctx, desc); > > + } > > + /* at this point we are 4CL (256 byte) aligned */ > > + if (count >=3D CCIP_ALIGN_BYTES) { > > + desc->rd_address =3D src & DMA_MASK_32_BIT; > > + desc->wr_address =3D dst & DMA_MASK_32_BIT; > > + desc->wr_burst_count =3D 4; > > + desc->rd_burst_count =3D 4; > > + desc->rd_address_ext =3D (src >> 32) & > > DMA_MASK_32_BIT; > > + desc->wr_address_ext =3D (dst >> 32) & > > DMA_MASK_32_BIT; > > + /* buffer ends on 4CL boundary */ > > + if ((count % CCIP_ALIGN_BYTES) =3D=3D 0) { > > + segment_size =3D count; > > + count =3D 0; > > + } else { > > + segment_size =3D count > > + - (count % CCIP_ALIGN_BYTES); > > + src +=3D segment_size; > > + dst +=3D segment_size; > > + count -=3D segment_size; > > + desc->control.transfer_irq_en =3D 0; > > + } > > + desc->len =3D segment_size; > > + send_descriptor(ctx, desc); > > + } > > + /* post short transfer to handle the remainder */ > > + if (count > 0) { > > + desc->rd_address =3D src & DMA_MASK_32_BIT; > > + desc->wr_address =3D dst & DMA_MASK_32_BIT; > > + desc->len =3D count; > > + desc->wr_burst_count =3D 1; > > + desc->rd_burst_count =3D 1; > > + desc->rd_address_ext =3D (src >> 32) & > > DMA_MASK_32_BIT; > > + desc->wr_address_ext =3D (dst >> 32) & > > DMA_MASK_32_BIT; > > + if (intr_en) > > + desc->control.transfer_irq_en =3D 1; > > + send_descriptor(ctx, desc); > > + } > > + } > > + > > + return 0; > > +} > > + > > +static int issue_magic(struct dma_afu_ctx *ctx) > > +{ > > + *(ctx->magic_buf) =3D 0ULL; > > + return do_dma(ctx, DMA_WF_HOST_ADDR(ctx->magic_iova), > > + DMA_WF_MAGIC_ROM, 64, 1, FPGA_TO_HOST, 1); > > +} > > + > > +static void wait_magic(struct dma_afu_ctx *ctx) > > +{ > > + int magic_timeout =3D 0; > > + > > + if (!ctx) > > + return; > > + > > + poll_interrupt(ctx); > > + while (*(ctx->magic_buf) !=3D DMA_WF_MAGIC) { > > + if (magic_timeout++ > 1000) { > > + AFU_MF_PMD_ERR("DMA magic operation > timeout"); > > + magic_timeout =3D 0; > > + break; > > + } > > + } > > + *(ctx->magic_buf) =3D 0ULL; > > +} > > + > > +static int dma_tx_buf(struct dma_afu_ctx *ctx, uint64_t dst, uint64_t = src, > > + uint64_t chunk, int is_last_chunk, int *intr_issued) > > +{ > > + int intr_en =3D 0; > > + int ret =3D 0; > > + > > + if (!ctx || !intr_issued) > > + return -EINVAL; > > + > > + src +=3D chunk * ctx->dma_buf_size; > > + dst +=3D chunk * ctx->dma_buf_size; > > + > > + if (((chunk % HALF_DMA_BUF) =3D=3D (HALF_DMA_BUF - 1)) || > > is_last_chunk) { > > + if (*intr_issued) { > > + ret =3D poll_interrupt(ctx); > > + if (ret) > > + return ret; > > + } > > + intr_en =3D 1; > > + } > > + > > + chunk %=3D NUM_DMA_BUF; > > + rte_memcpy(ctx->dma_buf[chunk], (void *)(uintptr_t)src, > > + ctx->dma_buf_size); > > + ret =3D do_dma(ctx, dst, DMA_HOST_ADDR(ctx->dma_iova[chunk]), > > + ctx->dma_buf_size, 0, HOST_TO_FPGA, intr_en); > > + if (intr_en) > > + *intr_issued =3D 1; > > + > > + return ret; > > +} > > + > > +static int dma_host_to_fpga(struct dma_afu_ctx *ctx, uint64_t dst, > uint64_t > > src, > > + size_t count) > > +{ > > + uint64_t i =3D 0; > > + uint64_t count_left =3D count; > > + uint64_t aligned_addr =3D 0; > > + uint64_t align_bytes =3D 0; > > + uint64_t dma_chunks =3D 0; > > + uint64_t dma_tx_bytes =3D 0; > > + uint64_t offset =3D 0; > > + int issued_intr =3D 0; > > + int ret =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" ---> 0x%"PRIx64" (%zu)", src, > dst, > > + count); > > + > > + if (!ctx) > > + return -EINVAL; > > + > > + if (!IS_DMA_ALIGNED(dst)) { > > + if (count_left < DMA_ALIGN_BYTES) > > + return ase_host_to_fpga(ctx, &dst, &src, count_left); > > + > > + aligned_addr =3D ((dst / DMA_ALIGN_BYTES) + 1) > > + * DMA_ALIGN_BYTES; > > + align_bytes =3D aligned_addr - dst; > > + ret =3D ase_host_to_fpga(ctx, &dst, &src, align_bytes); > > + if (ret) > > + return ret; > > + count_left =3D count_left - align_bytes; > > + } > > + > > + if (count_left) { > > + dma_chunks =3D count_left / ctx->dma_buf_size; > > + offset =3D dma_chunks * ctx->dma_buf_size; > > + count_left -=3D offset; > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" ---> 0x%"PRIx64 > > + " (%"PRIu64"...0x%"PRIx64")", > > + src, dst, dma_chunks, count_left); > > + for (i =3D 0; i < dma_chunks; i++) { > > + ret =3D dma_tx_buf(ctx, dst, src, i, > > + i =3D=3D (dma_chunks - 1), &issued_intr); > > + if (ret) > > + return ret; > > + } > > + > > + if (issued_intr) { > > + ret =3D poll_interrupt(ctx); > > + if (ret) > > + return ret; > > + } > > + > > + if (count_left) { > > + i =3D count_left / DMA_ALIGN_BYTES; > > + if (i > 0) { > > + dma_tx_bytes =3D i * DMA_ALIGN_BYTES; > > + AFU_MF_PMD_DEBUG("left over > 0x%"PRIx64" > > to DMA", > > + dma_tx_bytes); > > + rte_memcpy(ctx->dma_buf[0], > > + (void *)(uintptr_t)(src + offset), > > + dma_tx_bytes); > > + ret =3D do_dma(ctx, dst + offset, > > + DMA_HOST_ADDR(ctx- > >dma_iova[0]), > > + dma_tx_bytes, 1, HOST_TO_FPGA, 1); > > + if (ret) > > + return ret; > > + ret =3D poll_interrupt(ctx); > > + if (ret) > > + return ret; > > + } > > + > > + count_left -=3D dma_tx_bytes; > > + if (count_left) { > > + AFU_MF_PMD_DEBUG("left over > 0x%"PRIx64" > > to ASE", > > + count_left); > > + dst +=3D offset + dma_tx_bytes; > > + src +=3D offset + dma_tx_bytes; > > + ret =3D ase_host_to_fpga(ctx, &dst, &src, > > + count_left); > > + } > > + } > > + } > > + > > + return ret; > > +} > > + > > +static int dma_rx_buf(struct dma_afu_ctx *ctx, uint64_t dst, uint64_t = src, > > + uint64_t chunk, int is_last_chunk, uint64_t *rx_count, int *wf_issued= ) > > +{ > > + uint64_t i =3D chunk % NUM_DMA_BUF; > > + uint64_t n =3D *rx_count; > > + uint64_t num_pending =3D 0; > > + int ret =3D 0; > > + > > + if (!ctx || !wf_issued) > > + return -EINVAL; > > + > > + ret =3D do_dma(ctx, DMA_HOST_ADDR(ctx->dma_iova[i]), > > + src + chunk * ctx->dma_buf_size, > > + ctx->dma_buf_size, 1, FPGA_TO_HOST, 0); > > + if (ret) > > + return ret; > > + > > + num_pending =3D chunk - n + 1; > > + if (num_pending =3D=3D HALF_DMA_BUF) { > > + ret =3D issue_magic(ctx); > > + if (ret) { > > + AFU_MF_PMD_DEBUG("Magic issue failed"); > > + return ret; > > + } > > + *wf_issued =3D 1; > > + } > > + > > + if ((num_pending > (NUM_DMA_BUF - 1)) || is_last_chunk) { > > + if (*wf_issued) { > > + wait_magic(ctx); > > + for (i =3D 0; i < HALF_DMA_BUF; i++) { > > + rte_memcpy((void *)(uintptr_t)(dst + > > + n * ctx->dma_buf_size), > > + ctx->dma_buf[n % NUM_DMA_BUF], > > + ctx->dma_buf_size); > > + n++; > > + } > > + *wf_issued =3D 0; > > + *rx_count =3D n; > > + } > > + ret =3D issue_magic(ctx); > > + if (ret) { > > + AFU_MF_PMD_DEBUG("Magic issue failed"); > > + return ret; > > + } > > + *wf_issued =3D 1; > > + } > > + > > + return ret; > > +} > > + > > +static int dma_fpga_to_host(struct dma_afu_ctx *ctx, uint64_t dst, > uint64_t > > src, > > + size_t count) > > +{ > > + uint64_t i =3D 0; > > + uint64_t count_left =3D count; > > + uint64_t aligned_addr =3D 0; > > + uint64_t align_bytes =3D 0; > > + uint64_t dma_chunks =3D 0; > > + uint64_t pending_buf =3D 0; > > + uint64_t dma_rx_bytes =3D 0; > > + uint64_t offset =3D 0; > > + int wf_issued =3D 0; > > + int ret =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" ---> 0x%"PRIx64" (%zu)", src, > dst, > > + count); > > + > > + if (!ctx) > > + return -EINVAL; > > + > > + if (!IS_DMA_ALIGNED(src)) { > > + if (count_left < DMA_ALIGN_BYTES) > > + return ase_fpga_to_host(ctx, &src, &dst, count_left); > > + > > + aligned_addr =3D ((src / DMA_ALIGN_BYTES) + 1) > > + * DMA_ALIGN_BYTES; > > + align_bytes =3D aligned_addr - src; > > + ret =3D ase_fpga_to_host(ctx, &src, &dst, align_bytes); > > + if (ret) > > + return ret; > > + count_left =3D count_left - align_bytes; > > + } > > + > > + if (count_left) { > > + dma_chunks =3D count_left / ctx->dma_buf_size; > > + offset =3D dma_chunks * ctx->dma_buf_size; > > + count_left -=3D offset; > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" ---> 0x%"PRIx64 > > + " (%"PRIu64"...0x%"PRIx64")", > > + src, dst, dma_chunks, count_left); > > + for (i =3D 0; i < dma_chunks; i++) { > > + ret =3D dma_rx_buf(ctx, dst, src, i, > > + i =3D=3D (dma_chunks - 1), > > + &pending_buf, &wf_issued); > > + if (ret) > > + return ret; > > + } > > + > > + if (wf_issued) > > + wait_magic(ctx); > > + > > + /* clear out final dma memcpy operations */ > > + while (pending_buf < dma_chunks) { > > + /* constant size transfer; no length check required */ > > + rte_memcpy((void *)(uintptr_t)(dst + > > + pending_buf * ctx->dma_buf_size), > > + ctx->dma_buf[pending_buf % > > NUM_DMA_BUF], > > + ctx->dma_buf_size); > > + pending_buf++; > > + } > > + > > + if (count_left > 0) { > > + i =3D count_left / DMA_ALIGN_BYTES; > > + if (i > 0) { > > + dma_rx_bytes =3D i * DMA_ALIGN_BYTES; > > + AFU_MF_PMD_DEBUG("left over > 0x%"PRIx64" > > to DMA", > > + dma_rx_bytes); > > + ret =3D do_dma(ctx, > > + DMA_HOST_ADDR(ctx- > >dma_iova[0]), > > + src + offset, > > + dma_rx_bytes, 1, FPGA_TO_HOST, 0); > > + if (ret) > > + return ret; > > + ret =3D issue_magic(ctx); > > + if (ret) > > + return ret; > > + wait_magic(ctx); > > + rte_memcpy((void *)(uintptr_t)(dst + offset), > > + ctx->dma_buf[0], dma_rx_bytes); > > + } > > + > > + count_left -=3D dma_rx_bytes; > > + if (count_left) { > > + AFU_MF_PMD_DEBUG("left over > 0x%"PRIx64" > > to ASE", > > + count_left); > > + dst +=3D offset + dma_rx_bytes; > > + src +=3D offset + dma_rx_bytes; > > + ret =3D ase_fpga_to_host(ctx, &src, &dst, > > + count_left); > > + } > > + } > > + } > > + > > + return ret; > > +} > > + > > +static int dma_fpga_to_fpga(struct dma_afu_ctx *ctx, uint64_t dst, > uint64_t > > src, > > + size_t count) > > +{ > > + uint64_t i =3D 0; > > + uint64_t count_left =3D count; > > + uint64_t dma_chunks =3D 0; > > + uint64_t offset =3D 0; > > + uint32_t tx_chunks =3D 0; > > + uint64_t *tmp_buf =3D NULL; > > + int ret =3D 0; > > + > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" ---> 0x%"PRIx64" (%zu)", src, > dst, > > + count); > > + > > + if (!ctx) > > + return -EINVAL; > > + > > + if (IS_DMA_ALIGNED(dst) && IS_DMA_ALIGNED(src) > > + && IS_DMA_ALIGNED(count_left)) { > > + dma_chunks =3D count_left / ctx->dma_buf_size; > > + offset =3D dma_chunks * ctx->dma_buf_size; > > + count_left -=3D offset; > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" ---> 0x%"PRIx64 > > + " (%"PRIu64"...0x%"PRIx64")", > > + src, dst, dma_chunks, count_left); > > + for (i =3D 0; i < dma_chunks; i++) { > > + ret =3D do_dma(ctx, dst + i * ctx->dma_buf_size, > > + src + i * ctx->dma_buf_size, > > + ctx->dma_buf_size, 0, FPGA_TO_FPGA, 0); > > + if (ret) > > + return ret; > > + if ((((i + 1) % NUM_DMA_BUF) =3D=3D 0) || > > + (i =3D=3D (dma_chunks - 1))) { > > + ret =3D issue_magic(ctx); > > + if (ret) > > + return ret; > > + wait_magic(ctx); > > + } > > + } > > + > > + if (count_left > 0) { > > + AFU_MF_PMD_DEBUG("left over 0x%"PRIx64" to > > DMA", count_left); > > + ret =3D do_dma(ctx, dst + offset, src + offset, > > + count_left, 1, FPGA_TO_FPGA, 0); > > + if (ret) > > + return ret; > > + ret =3D issue_magic(ctx); > > + if (ret) > > + return ret; > > + wait_magic(ctx); > > + } > > + } else { > > + if ((src < dst) && (src + count_left > dst)) { > > + AFU_MF_PMD_ERR("Overlapping: 0x%"PRIx64 > > + " -> 0x%"PRIx64" (0x%"PRIx64")", > > + src, dst, count_left); > > + return -EINVAL; > > + } > > + tx_chunks =3D count_left / ctx->dma_buf_size; > > + offset =3D tx_chunks * ctx->dma_buf_size; > > + count_left -=3D offset; > > + AFU_MF_PMD_DEBUG("0x%"PRIx64" --> 0x%"PRIx64 > > + " (%u...0x%"PRIx64")", > > + src, dst, tx_chunks, count_left); > > + tmp_buf =3D (uint64_t *)rte_malloc(NULL, ctx->dma_buf_size, > > + DMA_ALIGN_BYTES); > > + for (i =3D 0; i < tx_chunks; i++) { > > + ret =3D dma_fpga_to_host(ctx, (uint64_t)tmp_buf, > > + src + i * ctx->dma_buf_size, > > + ctx->dma_buf_size); > > + if (ret) > > + goto free_buf; > > + ret =3D dma_host_to_fpga(ctx, > > + dst + i * ctx->dma_buf_size, > > + (uint64_t)tmp_buf, ctx->dma_buf_size); > > + if (ret) > > + goto free_buf; > > + } > > + > > + if (count_left > 0) { > > + ret =3D dma_fpga_to_host(ctx, (uint64_t)tmp_buf, > > + src + offset, count_left); > > + if (ret) > > + goto free_buf; > > + ret =3D dma_host_to_fpga(ctx, dst + offset, > > + (uint64_t)tmp_buf, count_left); > > + if (ret) > > + goto free_buf; > > + } > > +free_buf: > > + rte_free(tmp_buf); > > + } > > + > > + return ret; > > +} > > + > > +static int dma_transfer_sync(struct dma_afu_ctx *ctx, uint64_t dst, > > + uint64_t src, size_t count, fpga_dma_type type) > > +{ > > + int ret =3D 0; > > + > > + if (!ctx) > > + return -EINVAL; > > + > > + if (type =3D=3D HOST_TO_FPGA) > > + ret =3D dma_host_to_fpga(ctx, dst, src, count); > > + else if (type =3D=3D FPGA_TO_HOST) > > + ret =3D dma_fpga_to_host(ctx, dst, src, count); > > + else if (type =3D=3D FPGA_TO_FPGA) > > + ret =3D dma_fpga_to_fpga(ctx, dst, src, count); > > + else > > + return -EINVAL; > > + > > + return ret; > > +} > > + > > +static double getTime(struct timespec start, struct timespec end) > > +{ > > + uint64_t diff =3D 1000000000L * (end.tv_sec - start.tv_sec) > > + + end.tv_nsec - start.tv_nsec; > > + return (double)diff / (double)1000000000L; > > +} > > + > > +#define SWEEP_ITERS 1 > > +static int sweep_test(struct dma_afu_ctx *ctx, uint32_t length, > > + uint64_t ddr_offset, uint64_t buf_offset, uint64_t size_decrement) > > +{ > > + struct timespec start, end; > > + uint64_t test_size =3D 0; > > + uint64_t *dma_buf_ptr =3D NULL; > > + double throughput, total_time =3D 0.0; > > + int i =3D 0; > > + int ret =3D 0; > > + > > + if (!ctx || !ctx->data_buf || !ctx->ref_buf) { > > + AFU_MF_PMD_ERR("Buffer for DMA test is not allocated"); > > + return -EINVAL; > > + } > > + > > + if (length < (buf_offset + size_decrement)) { > > + AFU_MF_PMD_ERR("Test length does not match unaligned > > parameter"); > > + return -EINVAL; > > + } > > + test_size =3D length - (buf_offset + size_decrement); > > + if ((ddr_offset + test_size) > ctx->mem_size) { > > + AFU_MF_PMD_ERR("Test is out of DDR memory space"); > > + return -EINVAL; > > + } > > + > > + dma_buf_ptr =3D (uint64_t *)((uint8_t *)ctx->data_buf + buf_offset); > > + printf("Sweep Host %p to FPGA 0x%"PRIx64 > > + " with 0x%"PRIx64" bytes ...\n", > > + (void *)dma_buf_ptr, ddr_offset, test_size); > > + > > + for (i =3D 0; i < SWEEP_ITERS; i++) { > > + clock_gettime(CLOCK_MONOTONIC, &start); > > + ret =3D dma_transfer_sync(ctx, ddr_offset, > > (uint64_t)dma_buf_ptr, > > + test_size, HOST_TO_FPGA); > > + clock_gettime(CLOCK_MONOTONIC, &end); > > + if (ret) { > > + AFU_MF_PMD_ERR("Failed"); > > + return ret; > > + } > > + total_time +=3D getTime(start, end); > > + } > > + throughput =3D (test_size * SWEEP_ITERS) / (total_time * 1000000); > > + printf("Measured bandwidth =3D %lf MB/s\n", throughput); > > + > > + printf("Sweep FPGA 0x%"PRIx64" to Host %p with 0x%"PRIx64" bytes > > ...\n", > > + ddr_offset, (void *)dma_buf_ptr, test_size); > > + > > + total_time =3D 0.0; > > + memset((char *)dma_buf_ptr, 0, test_size); > > + for (i =3D 0; i < SWEEP_ITERS; i++) { > > + clock_gettime(CLOCK_MONOTONIC, &start); > > + ret =3D dma_transfer_sync(ctx, (uint64_t)dma_buf_ptr, > > ddr_offset, > > + test_size, FPGA_TO_HOST); > > + clock_gettime(CLOCK_MONOTONIC, &end); > > + if (ret) { > > + AFU_MF_PMD_ERR("Failed"); > > + return ret; > > + } > > + total_time +=3D getTime(start, end); > > + } > > + throughput =3D (test_size * SWEEP_ITERS) / (total_time * 1000000); > > + printf("Measured bandwidth =3D %lf MB/s\n", throughput); > > + > > + printf("Verifying buffer ...\n"); > > + return dma_afu_buf_verify(ctx, test_size); > > +} > > + > > +static int dma_afu_test(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct dma_afu_ctx *ctx =3D NULL; > > + struct rte_pmd_afu_dma_cfg *cfg =3D NULL; > > + msgdma_ctrl ctrl; > > + uint64_t offset =3D 0; > > + uint32_t i =3D 0; > > + int ret =3D 0; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + if (!dev->priv) > > + return -ENOENT; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + cfg =3D &priv->dma_cfg; > > + if (cfg->index >=3D NUM_N3000_DMA) > > + return -EINVAL; > > + ctx =3D &priv->dma_ctx[cfg->index]; > > + > > + ctx->pattern =3D (int)cfg->pattern; > > + ctx->verbose =3D (int)cfg->verbose; > > + ctx->dma_buf_size =3D cfg->size; > > + > > + ret =3D dma_afu_buf_alloc(ctx, cfg); > > + if (ret) > > + goto free; > > + > > + printf("Initialize test buffer\n"); > > + dma_afu_buf_init(ctx, cfg->length); > > + > > + /* enable interrupt */ > > + ctrl.csr =3D 0; > > + ctrl.global_intr_en_mask =3D 1; > > + rte_write32(ctrl.csr, CSR_CONTROL(ctx->csr_addr)); > > + > > + printf("Host %p to FPGA 0x%x with 0x%x bytes\n", ctx->data_buf, > > + cfg->offset, cfg->length); > > + ret =3D dma_transfer_sync(ctx, cfg->offset, (uint64_t)ctx->data_buf, > > + cfg->length, HOST_TO_FPGA); > > + if (ret) { > > + AFU_MF_PMD_ERR("Failed to transfer data from host to > > FPGA"); > > + goto end; > > + } > > + memset(ctx->data_buf, 0, cfg->length); > > + > > + printf("FPGA 0x%x to Host %p with 0x%x bytes\n", cfg->offset, > > + ctx->data_buf, cfg->length); > > + ret =3D dma_transfer_sync(ctx, (uint64_t)ctx->data_buf, cfg->offset, > > + cfg->length, FPGA_TO_HOST); > > + if (ret) { > > + AFU_MF_PMD_ERR("Failed to transfer data from FPGA to > > host"); > > + goto end; > > + } > > + ret =3D dma_afu_buf_verify(ctx, cfg->length); > > + if (ret) > > + goto end; > > + > > + if ((cfg->offset + cfg->length * 2) <=3D ctx->mem_size) > > + offset =3D cfg->offset + cfg->length; > > + else if (cfg->offset > cfg->length) > > + offset =3D 0; > > + else > > + goto end; > > + > > + printf("FPGA 0x%x to FPGA 0x%"PRIx64" with 0x%x bytes\n", > > + cfg->offset, offset, cfg->length); > > + ret =3D dma_transfer_sync(ctx, offset, cfg->offset, cfg->length, > > + FPGA_TO_FPGA); > > + if (ret) { > > + AFU_MF_PMD_ERR("Failed to transfer data from FPGA to > > FPGA"); > > + goto end; > > + } > > + > > + printf("FPGA 0x%"PRIx64" to Host %p with 0x%x bytes\n", offset, > > + ctx->data_buf, cfg->length); > > + ret =3D dma_transfer_sync(ctx, (uint64_t)ctx->data_buf, offset, > > + cfg->length, FPGA_TO_HOST); > > + if (ret) { > > + AFU_MF_PMD_ERR("Failed to transfer data from FPGA to > > host"); > > + goto end; > > + } > > + ret =3D dma_afu_buf_verify(ctx, cfg->length); > > + if (ret) > > + goto end; > > + > > + printf("Sweep with aligned address and size\n"); > > + ret =3D sweep_test(ctx, cfg->length, cfg->offset, 0, 0); > > + if (ret) > > + goto end; > > + > > + if (cfg->unaligned) { > > + printf("Sweep with unaligned address and size\n"); > > + struct unaligned_set { > > + uint64_t addr_offset; > > + uint64_t size_dec; > > + } param[] =3D {{61, 5}, {3, 0}, {7, 3}, {0, 3}, {0, 61}, {0, 7}}; > > + for (i =3D 0; i < ARRAY_SIZE(param); i++) { > > + ret =3D sweep_test(ctx, cfg->length, cfg->offset, > > + param[i].addr_offset, param[i].size_dec); > > + if (ret) > > + break; > > + } > > + } > > + > > +end: > > + /* disable interrupt */ > > + ctrl.global_intr_en_mask =3D 0; > > + rte_write32(ctrl.csr, CSR_CONTROL(ctx->csr_addr)); > > + > > +free: > > + dma_afu_buf_free(ctx); > > + return ret; > > +} > > + > > +static struct rte_pci_device *n3000_afu_get_pci_dev(struct > afu_mf_rawdev > > *dev) > > +{ > > + struct rte_afu_device *afudev =3D NULL; > > + > > + if (!dev || !dev->rawdev || !dev->rawdev->device) > > + return NULL; > > + > > + afudev =3D RTE_DEV_TO_AFU(dev->rawdev->device); > > + if (!afudev->rawdev || !afudev->rawdev->device) > > + return NULL; > > + > > + return RTE_DEV_TO_PCI(afudev->rawdev->device); > > +} > > + > > +#ifdef VFIO_PRESENT > > +static int dma_afu_set_irqs(struct afu_mf_rawdev *dev, uint32_t > vec_start, > > + uint32_t count, int *efds) > > +{ > > + struct rte_pci_device *pci_dev =3D NULL; > > + struct vfio_irq_set *irq_set =3D NULL; > > + int vfio_dev_fd =3D 0; > > + size_t sz =3D 0; > > + int ret =3D 0; > > + > > + if (!dev || !efds || (count =3D=3D 0) || (count > MAX_MSIX_VEC)) > > + return -EINVAL; > > + > > + pci_dev =3D n3000_afu_get_pci_dev(dev); > > + if (!pci_dev) > > + return -ENODEV; > > + vfio_dev_fd =3D rte_intr_dev_fd_get(pci_dev->intr_handle); > > + > > + sz =3D sizeof(*irq_set) + sizeof(*efds) * count; > > + irq_set =3D rte_zmalloc(NULL, sz, 0); > > + if (!irq_set) > > + return -ENOMEM; > > + > > + irq_set->argsz =3D (uint32_t)sz; > > + irq_set->count =3D count; > > + irq_set->flags =3D VFIO_IRQ_SET_DATA_EVENTFD | > > + VFIO_IRQ_SET_ACTION_TRIGGER; > > + irq_set->index =3D VFIO_PCI_MSIX_IRQ_INDEX; > > + irq_set->start =3D vec_start; > > + > > + rte_memcpy(&irq_set->data, efds, sizeof(*efds) * count); > > + ret =3D ioctl(vfio_dev_fd, VFIO_DEVICE_SET_IRQS, irq_set); > > + if (ret) > > + AFU_MF_PMD_ERR("Error enabling MSI-X interrupts\n"); > > + > > + rte_free(irq_set); > > + return ret; > > +} > > +#endif > > + > > +static void *n3000_afu_get_port_addr(struct afu_mf_rawdev *dev) > > +{ > > + struct rte_pci_device *pci_dev =3D NULL; > > + uint8_t *addr =3D NULL; > > + uint64_t val =3D 0; > > + uint32_t bar =3D 0; > > + > > + pci_dev =3D n3000_afu_get_pci_dev(dev); > > + if (!pci_dev) > > + return NULL; > > + > > + addr =3D (uint8_t *)pci_dev->mem_resource[0].addr; > > + val =3D rte_read64(addr + PORT_ATTR_REG(dev->port)); > > + if (!PORT_IMPLEMENTED(val)) { > > + AFU_MF_PMD_INFO("FIU port %d is not implemented", > dev- > > >port); > > + return NULL; > > + } > > + > > + bar =3D PORT_BAR(val); > > + if (bar >=3D PCI_MAX_RESOURCE) { > > + AFU_MF_PMD_ERR("BAR index %u is out of limit", bar); > > + return NULL; > > + } > > + > > + addr =3D (uint8_t *)pci_dev->mem_resource[bar].addr + > > PORT_OFFSET(val); > > + return addr; > > +} > > + > > +static int n3000_afu_get_irq_capability(struct afu_mf_rawdev *dev, > > + uint32_t *vec_start, uint32_t *vec_count) > > +{ > > + uint8_t *addr =3D NULL; > > + uint64_t val =3D 0; > > + uint64_t header =3D 0; > > + uint64_t next_offset =3D 0; > > + > > + addr =3D (uint8_t *)n3000_afu_get_port_addr(dev); > > + if (!addr) > > + return -ENOENT; > > + > > + do { > > + addr +=3D next_offset; > > + header =3D rte_read64(addr); > > + if ((DFH_TYPE(header) =3D=3D DFH_TYPE_PRIVATE) && > > + (DFH_FEATURE_ID(header) =3D=3D > > PORT_FEATURE_UINT_ID)) { > > + val =3D rte_read64(addr + PORT_UINT_CAP_REG); > > + if (vec_start) > > + *vec_start =3D PORT_VEC_START(val); > > + if (vec_count) > > + *vec_count =3D PORT_VEC_COUNT(val); > > + return 0; > > + } > > + next_offset =3D DFH_NEXT_OFFSET(header); > > + if (((next_offset & 0xffff) =3D=3D 0xffff) || (next_offset =3D=3D 0)= ) > > + break; > > + } while (!DFH_EOL(header)); > > + > > + return -ENOENT; > > +} > > + > > +static int nlb_afu_ctx_release(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct nlb_afu_ctx *ctx =3D NULL; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + ctx =3D &priv->nlb_ctx; > > + > > + rte_free(ctx->dsm_ptr); > > + ctx->dsm_ptr =3D NULL; > > + ctx->status_ptr =3D NULL; > > + > > + rte_free(ctx->src_ptr); > > + ctx->src_ptr =3D NULL; > > + > > + rte_free(ctx->dest_ptr); > > + ctx->dest_ptr =3D NULL; > > + > > + return 0; > > +} > > + > > +static int nlb_afu_ctx_init(struct afu_mf_rawdev *dev, uint8_t *addr) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct nlb_afu_ctx *ctx =3D NULL; > > + int ret =3D 0; > > + > > + if (!dev || !addr) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + ctx =3D &priv->nlb_ctx; > > + ctx->addr =3D addr; > > + > > + ctx->dsm_ptr =3D (uint8_t *)rte_zmalloc(NULL, DSM_SIZE, > > TEST_MEM_ALIGN); > > + if (!ctx->dsm_ptr) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + ctx->dsm_iova =3D rte_malloc_virt2iova(ctx->dsm_ptr); > > + if (ctx->dsm_iova =3D=3D RTE_BAD_IOVA) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + > > + ctx->src_ptr =3D (uint8_t *)rte_zmalloc(NULL, NLB_BUF_SIZE, > > + TEST_MEM_ALIGN); > > + if (!ctx->src_ptr) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + ctx->src_iova =3D rte_malloc_virt2iova(ctx->src_ptr); > > + if (ctx->src_iova =3D=3D RTE_BAD_IOVA) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + > > + ctx->dest_ptr =3D (uint8_t *)rte_zmalloc(NULL, NLB_BUF_SIZE, > > + TEST_MEM_ALIGN); > > + if (!ctx->dest_ptr) { > > + ret =3D -ENOMEM; > > + goto release; > > + } >=20 > Suppose that If ctx->dest_ptr fail, the nlb_afu_ctx_release() will work > correct? >=20 > > + ctx->dest_iova =3D rte_malloc_virt2iova(ctx->dest_ptr); > > + if (ctx->dest_iova =3D=3D RTE_BAD_IOVA) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + > > + ctx->status_ptr =3D (struct nlb_dsm_status *)(ctx->dsm_ptr + > > DSM_STATUS); > > + return 0; > > + > > +release: > > + nlb_afu_ctx_release(dev); > > + return ret; > > +} > > + > > +static int dma_afu_ctx_release(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct dma_afu_ctx *ctx =3D NULL; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + ctx =3D &priv->dma_ctx[0]; > > + > > + rte_free(ctx->desc_buf); > > + ctx->desc_buf =3D NULL; > > + > > + rte_free(ctx->magic_buf); > > + ctx->magic_buf =3D NULL; > > + > > + close(ctx->event_fd); > > + return 0; > > +} > > + > > +static int dma_afu_ctx_init(struct afu_mf_rawdev *dev, int index, uint= 8_t > > *addr) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct dma_afu_ctx *ctx =3D NULL; > > + uint64_t mem_sz[] =3D {0x100000000, 0x100000000, 0x40000000, > > 0x1000000}; > > + static int efds[1] =3D {0}; > > + uint32_t vec_start =3D 0; > > + int ret =3D 0; > > + > > + if (!dev || (index < 0) || (index >=3D NUM_N3000_DMA) || !addr) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + ctx =3D &priv->dma_ctx[index]; > > + ctx->index =3D index; > > + ctx->addr =3D addr; > > + ctx->csr_addr =3D addr + DMA_CSR; > > + ctx->desc_addr =3D addr + DMA_DESC; > > + ctx->ase_ctrl_addr =3D addr + DMA_ASE_CTRL; > > + ctx->ase_data_addr =3D addr + DMA_ASE_DATA; > > + ctx->mem_size =3D mem_sz[ctx->index]; > > + ctx->cur_ase_page =3D INVALID_ASE_PAGE; > > + if (ctx->index =3D=3D 0) { > > + ret =3D n3000_afu_get_irq_capability(dev, &vec_start, NULL); > > + if (ret) > > + return ret; > > + > > + efds[0] =3D eventfd(0, EFD_NONBLOCK | EFD_CLOEXEC); > > + if (efds[0] < 0) { > > + AFU_MF_PMD_ERR("eventfd create failed"); > > + return -EBADF; > > + } > > +#ifdef VFIO_PRESENT > > + if (dma_afu_set_irqs(dev, vec_start, 1, efds)) > > + AFU_MF_PMD_ERR("DMA interrupt setup failed"); > > +#endif > > + } > > + ctx->event_fd =3D efds[0]; > > + > > + ctx->desc_buf =3D (msgdma_ext_desc *)rte_zmalloc(NULL, > > + sizeof(msgdma_ext_desc), DMA_ALIGN_BYTES); > > + if (!ctx->desc_buf) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + > > + ctx->magic_buf =3D (uint64_t *)rte_zmalloc(NULL, MAGIC_BUF_SIZE, > > + TEST_MEM_ALIGN); > > + if (!ctx->magic_buf) { > > + ret =3D -ENOMEM; > > + goto release; > > + } >=20 > Suppose that If ctx->magic_buf fail, the dma_afu_ctx_release () will work > correct? >=20 > > + ctx->magic_iova =3D rte_malloc_virt2iova(ctx->magic_buf); > > + if (ctx->magic_iova =3D=3D RTE_BAD_IOVA) { > > + ret =3D -ENOMEM; > > + goto release; > > + } > > + > > + return 0; > > + > > +release: > > + dma_afu_ctx_release(dev); > > + return ret; > > +} > > + > > +static int n3000_afu_ctx_init(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + uint8_t *addr =3D NULL; > > + uint64_t header =3D 0; > > + uint64_t uuid_hi =3D 0; > > + uint64_t uuid_lo =3D 0; > > + uint64_t next_offset =3D 0; > > + int ret =3D 0; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + addr =3D (uint8_t *)dev->addr; > > + do { > > + addr +=3D next_offset; > > + header =3D rte_read64(addr); > > + uuid_lo =3D rte_read64(addr + DFH_UUID_L_OFFSET); > > + uuid_hi =3D rte_read64(addr + DFH_UUID_H_OFFSET); > > + > > + if ((DFH_TYPE(header) =3D=3D DFH_TYPE_AFU) && > > + (uuid_lo =3D=3D N3000_NLB0_UUID_L) && > > + (uuid_hi =3D=3D N3000_NLB0_UUID_H)) { > > + AFU_MF_PMD_INFO("AFU NLB0 found @ %p", (void > > *)addr); > > + ret =3D nlb_afu_ctx_init(dev, addr); > > + if (ret) > > + return ret; > > + } else if ((DFH_TYPE(header) =3D=3D DFH_TYPE_BBB) && > > + (uuid_lo =3D=3D N3000_DMA_UUID_L) && > > + (uuid_hi =3D=3D N3000_DMA_UUID_H) && > > + (priv->num_dma < NUM_N3000_DMA)) { > > + AFU_MF_PMD_INFO("AFU DMA%d found @ %p", > > + priv->num_dma, (void *)addr); > > + ret =3D dma_afu_ctx_init(dev, priv->num_dma, addr); > > + if (ret) > > + return ret; > > + priv->num_dma++; > > + } else { > > + AFU_MF_PMD_DEBUG("DFH: type %"PRIu64 > > + ", uuid %016"PRIx64"%016"PRIx64, > > + DFH_TYPE(header), uuid_hi, uuid_lo); > > + } > > + > > + next_offset =3D DFH_NEXT_OFFSET(header); > > + if (((next_offset & 0xffff) =3D=3D 0xffff) || (next_offset =3D=3D 0)= ) > > + break; > > + } while (!DFH_EOL(header)); > > + > > + return 0; > > +} > > + > > +static int n3000_afu_init(struct afu_mf_rawdev *dev) > > +{ > > + if (!dev) > > + return -EINVAL; > > + > > + if (!dev->priv) { > > + dev->priv =3D rte_zmalloc(NULL, sizeof(struct n3000_afu_priv), > 0); > > + if (!dev->priv) > > + return -ENOMEM; > > + } > > + > > + return n3000_afu_ctx_init(dev); > > +} > > + > > +static int n3000_afu_config(struct afu_mf_rawdev *dev, void *config, > > + size_t config_size) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + struct rte_pmd_afu_n3000_cfg *cfg =3D NULL; > > + int i =3D 0; > > + uint64_t top =3D 0; > > + > > + if (!dev || !config || !config_size) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + if (config_size !=3D sizeof(struct rte_pmd_afu_n3000_cfg)) > > + return -EINVAL; > > + > > + cfg =3D (struct rte_pmd_afu_n3000_cfg *)config; > > + if (cfg->type =3D=3D RTE_PMD_AFU_N3000_NLB) { > > + if (cfg->nlb_cfg.mode !=3D NLB_MODE_LPBK) > > + return -EINVAL; > > + if ((cfg->nlb_cfg.read_vc > NLB_VC_RANDOM) || > > + (cfg->nlb_cfg.write_vc > NLB_VC_RANDOM)) > > + return -EINVAL; > > + if (cfg->nlb_cfg.wrfence_vc > NLB_VC_VH1) > > + return -EINVAL; > > + if (cfg->nlb_cfg.cache_hint > NLB_RDLINE_MIXED) > > + return -EINVAL; > > + if (cfg->nlb_cfg.cache_policy > NLB_WRPUSH_I) > > + return -EINVAL; > > + if ((cfg->nlb_cfg.multi_cl !=3D 1) && > > + (cfg->nlb_cfg.multi_cl !=3D 2) && > > + (cfg->nlb_cfg.multi_cl !=3D 4)) > > + return -EINVAL; > > + if ((cfg->nlb_cfg.begin < MIN_CACHE_LINES) || > > + (cfg->nlb_cfg.begin > MAX_CACHE_LINES)) > > + return -EINVAL; > > + if ((cfg->nlb_cfg.end < cfg->nlb_cfg.begin) || > > + (cfg->nlb_cfg.end > MAX_CACHE_LINES)) > > + return -EINVAL; > > + rte_memcpy(&priv->nlb_cfg, &cfg->nlb_cfg, > > + sizeof(struct rte_pmd_afu_nlb_cfg)); > > + } else if (cfg->type =3D=3D RTE_PMD_AFU_N3000_DMA) { > > + if (cfg->dma_cfg.index >=3D NUM_N3000_DMA) > > + return -EINVAL; > > + i =3D cfg->dma_cfg.index; > > + if (cfg->dma_cfg.length > priv->dma_ctx[i].mem_size) > > + return -EINVAL; > > + if (cfg->dma_cfg.offset >=3D priv->dma_ctx[i].mem_size) > > + return -EINVAL; > > + top =3D cfg->dma_cfg.length + cfg->dma_cfg.offset; > > + if ((top =3D=3D 0) || (top > priv->dma_ctx[i].mem_size)) > > + return -EINVAL; > > + if (i =3D=3D 3) { /* QDR connected to DMA3 */ > > + if (cfg->dma_cfg.length & 0x3f) { > > + cfg->dma_cfg.length &=3D ~0x3f; > > + AFU_MF_PMD_INFO("Round size to %x for > > QDR", > > + cfg->dma_cfg.length); > > + } > > + } > > + rte_memcpy(&priv->dma_cfg, &cfg->dma_cfg, > > + sizeof(struct rte_pmd_afu_dma_cfg)); > > + } else { > > + AFU_MF_PMD_ERR("Invalid type of N3000 AFU"); > > + return -EINVAL; > > + } > > + > > + priv->cfg_type =3D cfg->type; > > + return 0; > > +} > > + > > +static int n3000_afu_test(struct afu_mf_rawdev *dev) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + int ret =3D 0; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + if (!dev->priv) > > + return -ENOENT; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + > > + if (priv->cfg_type =3D=3D RTE_PMD_AFU_N3000_NLB) { > > + AFU_MF_PMD_INFO("Test NLB"); > > + ret =3D nlb_afu_test(dev); > > + } else if (priv->cfg_type =3D=3D RTE_PMD_AFU_N3000_DMA) { > > + AFU_MF_PMD_INFO("Test DMA%u", priv->dma_cfg.index); > > + ret =3D dma_afu_test(dev); > > + } else { > > + AFU_MF_PMD_ERR("Please configure AFU before test"); > > + ret =3D -EINVAL; > > + } > > + > > + return ret; > > +} > > + > > +static int n3000_afu_close(struct afu_mf_rawdev *dev) > > +{ > > + if (!dev) > > + return -EINVAL; > > + > > + nlb_afu_ctx_release(dev); > > + dma_afu_ctx_release(dev); > > + > > + rte_free(dev->priv); > > + dev->priv =3D NULL; > > + > > + return 0; > > +} > > + > > +static int n3000_afu_dump(struct afu_mf_rawdev *dev, FILE *f) > > +{ > > + struct n3000_afu_priv *priv =3D NULL; > > + > > + if (!dev) > > + return -EINVAL; > > + > > + priv =3D (struct n3000_afu_priv *)dev->priv; > > + if (!priv) > > + return -ENOENT; > > + > > + if (!f) > > + f =3D stdout; > > + > > + if (priv->cfg_type =3D=3D RTE_PMD_AFU_N3000_NLB) { > > + struct nlb_afu_ctx *ctx =3D &priv->nlb_ctx; > > + fprintf(f, "addr:\t\t%p\n", (void *)ctx->addr); > > + fprintf(f, "dsm_ptr:\t%p\n", (void *)ctx->dsm_ptr); > > + fprintf(f, "dsm_iova:\t0x%"PRIx64"\n", ctx->dsm_iova); > > + fprintf(f, "src_ptr:\t%p\n", (void *)ctx->src_ptr); > > + fprintf(f, "src_iova:\t0x%"PRIx64"\n", ctx->src_iova); > > + fprintf(f, "dest_ptr:\t%p\n", (void *)ctx->dest_ptr); > > + fprintf(f, "dest_iova:\t0x%"PRIx64"\n", ctx->dest_iova); > > + fprintf(f, "status_ptr:\t%p\n", (void *)ctx->status_ptr); > > + } else if (priv->cfg_type =3D=3D RTE_PMD_AFU_N3000_DMA) { > > + struct dma_afu_ctx *ctx =3D &priv->dma_ctx[priv- > > >dma_cfg.index]; > > + fprintf(f, "index:\t\t%d\n", ctx->index); > > + fprintf(f, "addr:\t\t%p\n", (void *)ctx->addr); > > + fprintf(f, "csr_addr:\t%p\n", (void *)ctx->csr_addr); > > + fprintf(f, "desc_addr:\t%p\n", (void *)ctx->desc_addr); > > + fprintf(f, "ase_ctrl_addr:\t%p\n", (void *)ctx->ase_ctrl_addr); > > + fprintf(f, "ase_data_addr:\t%p\n", (void *)ctx- > >ase_data_addr); > > + fprintf(f, "desc_buf:\t%p\n", (void *)ctx->desc_buf); > > + fprintf(f, "magic_buf:\t%p\n", (void *)ctx->magic_buf); > > + fprintf(f, "magic_iova:\t0x%"PRIx64"\n", ctx->magic_iova); > > + } else { > > + return -EINVAL; > > + } > > + > > + return 0; > > +} > > + > > +static int n3000_afu_reset(struct afu_mf_rawdev *dev) > > +{ > > + uint8_t *addr =3D NULL; > > + uint64_t val =3D 0; > > + > > + addr =3D (uint8_t *)n3000_afu_get_port_addr(dev); > > + if (!addr) > > + return -ENOENT; > > + > > + val =3D rte_read64(addr + PORT_CTRL_REG); > > + val |=3D PORT_SOFT_RESET; > > + rte_write64(val, addr + PORT_CTRL_REG); > > + rte_delay_us(100); > > + val &=3D ~PORT_SOFT_RESET; > > + rte_write64(val, addr + PORT_CTRL_REG); > > + > > + return 0; > > +} > > + > > +static struct afu_mf_ops n3000_afu_ops =3D { > > + .init =3D n3000_afu_init, > > + .config =3D n3000_afu_config, > > + .start =3D NULL, > > + .stop =3D NULL, > > + .test =3D n3000_afu_test, > > + .close =3D n3000_afu_close, > > + .dump =3D n3000_afu_dump, > > + .reset =3D n3000_afu_reset > > +}; > > + > > +struct afu_mf_drv n3000_afu_drv =3D { > > + .uuid =3D { N3000_AFU_UUID_L, N3000_AFU_UUID_H }, > > + .ops =3D &n3000_afu_ops > > +}; > > diff --git a/drivers/raw/afu_mf/n3000_afu.h > b/drivers/raw/afu_mf/n3000_afu.h > > new file mode 100644 > > index 0000000..4c740da > > --- /dev/null > > +++ b/drivers/raw/afu_mf/n3000_afu.h > > @@ -0,0 +1,333 @@ > > +/* SPDX-License-Identifier: BSD-3-Clause > > + * Copyright(c) 2022 Intel Corporation > > + */ > > + > > +#ifndef _N3000_AFU_H_ > > +#define _N3000_AFU_H_ > > + > > +#include "afu_mf_rawdev.h" > > +#include "rte_pmd_afu.h" > > + > > +#define N3000_AFU_UUID_L 0xc000c9660d824272 > > +#define N3000_AFU_UUID_H 0x9aeffe5f84570612 > > +#define N3000_NLB0_UUID_L 0xf89e433683f9040b > > +#define N3000_NLB0_UUID_H 0xd8424dc4a4a3c413 > > +#define N3000_DMA_UUID_L 0xa9149a35bace01ea > > +#define N3000_DMA_UUID_H 0xef82def7f6ec40fc > > + > > +extern struct afu_mf_drv n3000_afu_drv; > > + > > +#define NUM_N3000_DMA 4 > > +#define MAX_MSIX_VEC 7 > > + > > +/* N3000 DFL definition */ > > +#define DFH_UUID_L_OFFSET 8 > > +#define DFH_UUID_H_OFFSET 16 > > +#define DFH_TYPE(hdr) (((hdr) >> 60) & 0xf) > > +#define DFH_TYPE_AFU 1 > > +#define DFH_TYPE_BBB 2 > > +#define DFH_TYPE_PRIVATE 3 > > +#define DFH_EOL(hdr) (((hdr) >> 40) & 0x1) > > +#define DFH_NEXT_OFFSET(hdr) (((hdr) >> 16) & 0xffffff) > > +#define DFH_FEATURE_ID(hdr) ((hdr) & 0xfff) > > +#define PORT_ATTR_REG(n) (((n) << 3) + 0x38) > > +#define PORT_IMPLEMENTED(attr) (((attr) >> 60) & 0x1) > > +#define PORT_BAR(attr) (((attr) >> 32) & 0x7) > > +#define PORT_OFFSET(attr) ((attr) & 0xffffff) > > +#define PORT_FEATURE_UINT_ID 0x12 > > +#define PORT_UINT_CAP_REG 0x8 > > +#define PORT_VEC_START(cap) (((cap) >> 12) & 0xfff) > > +#define PORT_VEC_COUNT(cap) ((cap) >> 12 & 0xfff) > > +#define PORT_CTRL_REG 0x38 > > +#define PORT_SOFT_RESET (0x1 << 0) > > + > > +/* NLB registers definition */ > > +#define CSR_SCRATCHPAD0 0x100 > > +#define CSR_SCRATCHPAD1 0x108 > > +#define CSR_AFU_DSM_BASEL 0x110 > > +#define CSR_AFU_DSM_BASEH 0x114 > > +#define CSR_SRC_ADDR 0x120 > > +#define CSR_DST_ADDR 0x128 > > +#define CSR_NUM_LINES 0x130 > > +#define CSR_CTL 0x138 > > +#define CSR_CFG 0x140 > > +#define CSR_INACT_THRESH 0x148 > > +#define CSR_INTERRUPT0 0x150 > > +#define CSR_SWTEST_MSG 0x158 > > +#define CSR_STATUS0 0x160 > > +#define CSR_STATUS1 0x168 > > +#define CSR_ERROR 0x170 > > +#define CSR_STRIDE 0x178 > > +#define CSR_HE_INFO0 0x180 > > + > > +#define DSM_SIZE 0x200000 > > +#define DSM_STATUS 0x40 > > +#define DSM_POLL_INTERVAL 5 /* ms */ > > +#define DSM_TIMEOUT 1000 /* ms */ > > + > > +#define NLB_BUF_SIZE 0x400000 > > +#define TEST_MEM_ALIGN 1024 > > + > > +struct nlb_csr_ctl { > > + union { > > + uint32_t csr; > > + struct { > > + uint32_t reset:1; > > + uint32_t start:1; > > + uint32_t force_completion:1; > > + uint32_t reserved:29; > > + }; > > + }; > > +}; > > + > > +struct nlb_csr_cfg { > > + union { > > + uint32_t csr; > > + struct { > > + uint32_t wrthru_en:1; > > + uint32_t cont:1; > > + uint32_t mode:3; > > + uint32_t multicl_len:2; > > + uint32_t rsvd1:1; > > + uint32_t delay_en:1; > > + uint32_t rdsel:2; > > + uint32_t rsvd2:1; > > + uint32_t chsel:3; > > + uint32_t rsvd3:1; > > + uint32_t wrpush_i:1; > > + uint32_t wr_chsel:3; > > + uint32_t rsvd4:3; > > + uint32_t test_cfg:5; > > + uint32_t interrupt_on_error:1; > > + uint32_t interrupt_testmode:1; > > + uint32_t wrfence_chsel:2; > > + }; > > + }; > > +}; > > + > > +struct nlb_status0 { > > + union { > > + uint64_t csr; > > + struct { > > + uint32_t num_writes; > > + uint32_t num_reads; > > + }; > > + }; > > +}; > > + > > +struct nlb_status1 { > > + union { > > + uint64_t csr; > > + struct { > > + uint32_t num_pend_writes; > > + uint32_t num_pend_reads; > > + }; > > + }; > > +}; > > + > > +struct nlb_dsm_status { > > + uint32_t test_complete; > > + uint32_t test_error; > > + uint64_t num_clocks; > > + uint32_t num_reads; > > + uint32_t num_writes; > > + uint32_t start_overhead; > > + uint32_t end_overhead; > > +}; > > + > > +/* DMA registers definition */ > > +#define DMA_CSR 0x40 > > +#define DMA_DESC 0x60 > > +#define DMA_ASE_CTRL 0x200 > > +#define DMA_ASE_DATA 0x1000 > > + > > +#define DMA_ASE_WINDOW 4096 > > +#define DMA_ASE_WINDOW_MASK ((uint64_t)(DMA_ASE_WINDOW - > 1)) > > +#define INVALID_ASE_PAGE 0xffffffffffffffffULL > > + > > +#define DMA_WF_MAGIC 0x5772745F53796E63ULL > > +#define DMA_WF_MAGIC_ROM 0x1000000000000 > > +#define DMA_HOST_ADDR(addr) ((addr) | 0x2000000000000) > > +#define DMA_WF_HOST_ADDR(addr) ((addr) | 0x3000000000000) > > + > > +#define NUM_DMA_BUF 8 > > +#define HALF_DMA_BUF (NUM_DMA_BUF / 2) > > + > > +#define DMA_MASK_32_BIT 0xFFFFFFFF > > + > > +#define DMA_CSR_BUSY 0x1 > > +#define DMA_DESC_BUFFER_EMPTY 0x2 > > +#define DMA_DESC_BUFFER_FULL 0x4 > > + > > +#define DWORD_BYTES 4 > > +#define IS_ALIGNED_DWORD(addr) (((addr) % DWORD_BYTES) =3D=3D 0) > > + > > +#define QWORD_BYTES 8 > > +#define IS_ALIGNED_QWORD(addr) (((addr) % QWORD_BYTES) =3D=3D 0) > > + > > +#define DMA_ALIGN_BYTES 64 > > +#define IS_DMA_ALIGNED(addr) (((addr) % DMA_ALIGN_BYTES) =3D=3D 0) > > + > > +#define CCIP_ALIGN_BYTES (DMA_ALIGN_BYTES << 2) > > + > > +#define DMA_TIMEOUT_MSEC 5000 > > + > > +#define MAGIC_BUF_SIZE 64 > > +#define ERR_CHECK_LIMIT 64 > > + > > +#ifndef MIN > > +#define MIN(a, b) ((a) < (b) ? (a) : (b)) > > +#endif > > + > > +#ifndef ARRAY_SIZE > > +#define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0])) > > +#endif > > + > > +typedef enum { > > + HOST_TO_FPGA =3D 0, > > + FPGA_TO_HOST, > > + FPGA_TO_FPGA, > > + FPGA_MAX_TRANSFER_TYPE, > > +} fpga_dma_type; > > + > > +typedef union { > > + uint32_t csr; > > + struct { > > + uint32_t tx_channel:8; > > + uint32_t generate_sop:1; > > + uint32_t generate_eop:1; > > + uint32_t park_reads:1; > > + uint32_t park_writes:1; > > + uint32_t end_on_eop:1; > > + uint32_t reserved_1:1; > > + uint32_t transfer_irq_en:1; > > + uint32_t early_term_irq_en:1; > > + uint32_t trans_error_irq_en:8; > > + uint32_t early_done_en:1; > > + uint32_t reserved_2:6; > > + uint32_t go:1; > > + }; > > +} msgdma_desc_ctrl; > > + > > +typedef struct __rte_packed { > > + uint32_t rd_address; > > + uint32_t wr_address; > > + uint32_t len; > > + uint16_t seq_num; > > + uint8_t rd_burst_count; > > + uint8_t wr_burst_count; > > + uint16_t rd_stride; > > + uint16_t wr_stride; > > + uint32_t rd_address_ext; > > + uint32_t wr_address_ext; > > + msgdma_desc_ctrl control; > > +} msgdma_ext_desc; > > + > > +typedef union { > > + uint32_t csr; > > + struct { > > + uint32_t busy:1; > > + uint32_t desc_buf_empty:1; > > + uint32_t desc_buf_full:1; > > + uint32_t rsp_buf_empty:1; > > + uint32_t rsp_buf_full:1; > > + uint32_t stopped:1; > > + uint32_t resetting:1; > > + uint32_t stopped_on_error:1; > > + uint32_t stopped_on_early_term:1; > > + uint32_t irq:1; > > + uint32_t reserved:22; > > + }; > > +} msgdma_status; > > + > > +typedef union { > > + uint32_t csr; > > + struct { > > + uint32_t stop_dispatcher:1; > > + uint32_t reset_dispatcher:1; > > + uint32_t stop_on_error:1; > > + uint32_t stopped_on_early_term:1; > > + uint32_t global_intr_en_mask:1; > > + uint32_t stop_descriptors:1; > > + uint32_t reserved:22; > > + }; > > +} msgdma_ctrl; > > + > > +typedef union { > > + uint32_t csr; > > + struct { > > + uint32_t rd_fill_level:16; > > + uint32_t wr_fill_level:16; > > + }; > > +} msgdma_fill_level; > > + > > +typedef union { > > + uint32_t csr; > > + struct { > > + uint32_t rsp_fill_level:16; > > + uint32_t reserved:16; > > + }; > > +} msgdma_rsp_level; > > + > > +typedef union { > > + uint32_t csr; > > + struct { > > + uint32_t rd_seq_num:16; > > + uint32_t wr_seq_num:16; > > + }; > > +} msgdma_seq_num; > > + > > +typedef struct __rte_packed { > > + msgdma_status status; > > + msgdma_ctrl ctrl; > > + msgdma_fill_level fill_level; > > + msgdma_rsp_level rsp; > > + msgdma_seq_num seq_num; > > +} msgdma_csr; > > + > > +#define CSR_STATUS(csr) (&(((msgdma_csr *)(csr))->status)) > > +#define CSR_CONTROL(csr) (&(((msgdma_csr *)(csr))->ctrl)) > > + > > +struct nlb_afu_ctx { > > + uint8_t *addr; > > + uint8_t *dsm_ptr; > > + uint64_t dsm_iova; > > + uint8_t *src_ptr; > > + uint64_t src_iova; > > + uint8_t *dest_ptr; > > + uint64_t dest_iova; > > + struct nlb_dsm_status *status_ptr; > > +}; > > + > > +struct dma_afu_ctx { > > + int index; > > + uint8_t *addr; > > + uint8_t *csr_addr; > > + uint8_t *desc_addr; > > + uint8_t *ase_ctrl_addr; > > + uint8_t *ase_data_addr; > > + uint64_t mem_size; > > + uint64_t cur_ase_page; > > + int event_fd; > > + int verbose; > > + int pattern; > > + void *data_buf; > > + void *ref_buf; > > + msgdma_ext_desc *desc_buf; > > + uint64_t *magic_buf; > > + uint64_t magic_iova; > > + uint32_t dma_buf_size; > > + uint64_t *dma_buf[NUM_DMA_BUF]; > > + uint64_t dma_iova[NUM_DMA_BUF]; > > +}; > > + > > +struct n3000_afu_priv { > > + struct rte_pmd_afu_nlb_cfg nlb_cfg; > > + struct rte_pmd_afu_dma_cfg dma_cfg; > > + struct nlb_afu_ctx nlb_ctx; > > + struct dma_afu_ctx dma_ctx[NUM_N3000_DMA]; > > + int num_dma; > > + int cfg_type; > > +}; > > + > > +#endif /* _N3000_AFU_H_ */ > > diff --git a/drivers/raw/afu_mf/rte_pmd_afu.h > > b/drivers/raw/afu_mf/rte_pmd_afu.h > > new file mode 100644 > > index 0000000..f14a053 > > --- /dev/null > > +++ b/drivers/raw/afu_mf/rte_pmd_afu.h > > @@ -0,0 +1,97 @@ > > +/* SPDX-License-Identifier: BSD-3-Clause > > + * Copyright 2022 Intel Corporation > > + */ > > + > > +#ifndef __RTE_PMD_AFU_H__ > > +#define __RTE_PMD_AFU_H__ > > + > > +/** > > + * @file rte_pmd_afu.h > > + * > > + * AFU PMD specific definitions. > > + * > > + * @b EXPERIMENTAL: this API may change, or be removed, without prior > > notice > > + * > > + */ > > + > > +#ifdef __cplusplus > > +extern "C" { > > +#endif > > + > > +#include > > + > > +#define RTE_PMD_AFU_N3000_NLB 1 > > +#define RTE_PMD_AFU_N3000_DMA 2 > > + > > +#define NLB_MODE_LPBK 0 > > +#define NLB_MODE_READ 1 > > +#define NLB_MODE_WRITE 2 > > +#define NLB_MODE_TRPUT 3 > > + > > +#define NLB_VC_AUTO 0 > > +#define NLB_VC_VL0 1 > > +#define NLB_VC_VH0 2 > > +#define NLB_VC_VH1 3 > > +#define NLB_VC_RANDOM 4 > > + > > +#define NLB_WRLINE_M 0 > > +#define NLB_WRLINE_I 1 > > +#define NLB_WRPUSH_I 2 > > + > > +#define NLB_RDLINE_S 0 > > +#define NLB_RDLINE_I 1 > > +#define NLB_RDLINE_MIXED 2 > > + > > +#define MIN_CACHE_LINES 1 > > +#define MAX_CACHE_LINES 1024 > > + > > +#define MIN_DMA_BUF_SIZE 64 > > +#define MAX_DMA_BUF_SIZE (1023 * 1024) > > + > > +/** > > + * NLB AFU configuration data structure. > > + */ > > +struct rte_pmd_afu_nlb_cfg { > > + uint32_t mode; > > + uint32_t begin; > > + uint32_t end; > > + uint32_t multi_cl; > > + uint32_t cont; > > + uint32_t timeout; > > + uint32_t cache_policy; > > + uint32_t cache_hint; > > + uint32_t read_vc; > > + uint32_t write_vc; > > + uint32_t wrfence_vc; > > + uint32_t freq_mhz; > > +}; > > + > > +/** > > + * DMA AFU configuration data structure. > > + */ > > +struct rte_pmd_afu_dma_cfg { > > + uint32_t index; /* index of DMA controller */ > > + uint32_t length; /* total length of data to DMA */ > > + uint32_t offset; /* address offset of target memory */ > > + uint32_t size; /* size of transfer buffer */ > > + uint32_t pattern; /* data pattern to fill in test buffer */ > > + uint32_t unaligned; /* use unaligned address or length in sweep test > */ > > + uint32_t verbose; /* enable verbose error information in test */ > > +}; > > + > > +/** > > + * N3000 AFU configuration data structure. > > + */ > > +struct rte_pmd_afu_n3000_cfg { > > + int type; /* RTE_PMD_AFU_N3000_NLB or > > RTE_PMD_AFU_N3000_DMA */ > > + union { > > + struct rte_pmd_afu_nlb_cfg nlb_cfg; > > + struct rte_pmd_afu_dma_cfg dma_cfg; > > + }; > > +}; > > + > > +#ifdef __cplusplus > > +} > > +#endif > > + > > +#endif /* __RTE_PMD_AFU_H__ */ > > -- > > 1.8.3.1