linux_dsm_epyc7002/drivers/dma/ti/k3-udma.c

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dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2019 Texas Instruments Incorporated - http://www.ti.com
* Author: Peter Ujfalusi <peter.ujfalusi@ti.com>
*/
#include <linux/kernel.h>
#include <linux/delay.h>
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
#include <linux/dmaengine.h>
#include <linux/dma-mapping.h>
#include <linux/dmapool.h>
#include <linux/err.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/list.h>
#include <linux/platform_device.h>
#include <linux/slab.h>
#include <linux/spinlock.h>
#include <linux/of.h>
#include <linux/of_dma.h>
#include <linux/of_device.h>
#include <linux/of_irq.h>
#include <linux/workqueue.h>
#include <linux/completion.h>
#include <linux/soc/ti/k3-ringacc.h>
#include <linux/soc/ti/ti_sci_protocol.h>
#include <linux/soc/ti/ti_sci_inta_msi.h>
#include <linux/dma/ti-cppi5.h>
#include "../virt-dma.h"
#include "k3-udma.h"
#include "k3-psil-priv.h"
struct udma_static_tr {
u8 elsize; /* RPSTR0 */
u16 elcnt; /* RPSTR0 */
u16 bstcnt; /* RPSTR1 */
};
#define K3_UDMA_MAX_RFLOWS 1024
#define K3_UDMA_DEFAULT_RING_SIZE 16
/* How SRC/DST tag should be updated by UDMA in the descriptor's Word 3 */
#define UDMA_RFLOW_SRCTAG_NONE 0
#define UDMA_RFLOW_SRCTAG_CFG_TAG 1
#define UDMA_RFLOW_SRCTAG_FLOW_ID 2
#define UDMA_RFLOW_SRCTAG_SRC_TAG 4
#define UDMA_RFLOW_DSTTAG_NONE 0
#define UDMA_RFLOW_DSTTAG_CFG_TAG 1
#define UDMA_RFLOW_DSTTAG_FLOW_ID 2
#define UDMA_RFLOW_DSTTAG_DST_TAG_LO 4
#define UDMA_RFLOW_DSTTAG_DST_TAG_HI 5
struct udma_chan;
enum udma_mmr {
MMR_GCFG = 0,
MMR_RCHANRT,
MMR_TCHANRT,
MMR_LAST,
};
static const char * const mmr_names[] = { "gcfg", "rchanrt", "tchanrt" };
struct udma_tchan {
void __iomem *reg_rt;
int id;
struct k3_ring *t_ring; /* Transmit ring */
struct k3_ring *tc_ring; /* Transmit Completion ring */
};
struct udma_rflow {
int id;
struct k3_ring *fd_ring; /* Free Descriptor ring */
struct k3_ring *r_ring; /* Receive ring */
};
struct udma_rchan {
void __iomem *reg_rt;
int id;
};
#define UDMA_FLAG_PDMA_ACC32 BIT(0)
#define UDMA_FLAG_PDMA_BURST BIT(1)
struct udma_match_data {
u32 psil_base;
bool enable_memcpy_support;
u32 flags;
u32 statictr_z_mask;
u32 rchan_oes_offset;
u8 tpl_levels;
u32 level_start_idx[];
};
struct udma_hwdesc {
size_t cppi5_desc_size;
void *cppi5_desc_vaddr;
dma_addr_t cppi5_desc_paddr;
/* TR descriptor internal pointers */
void *tr_req_base;
struct cppi5_tr_resp_t *tr_resp_base;
};
struct udma_rx_flush {
struct udma_hwdesc hwdescs[2];
size_t buffer_size;
void *buffer_vaddr;
dma_addr_t buffer_paddr;
};
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
struct udma_dev {
struct dma_device ddev;
struct device *dev;
void __iomem *mmrs[MMR_LAST];
const struct udma_match_data *match_data;
size_t desc_align; /* alignment to use for descriptors */
struct udma_tisci_rm tisci_rm;
struct k3_ringacc *ringacc;
struct work_struct purge_work;
struct list_head desc_to_purge;
spinlock_t lock;
struct udma_rx_flush rx_flush;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
int tchan_cnt;
int echan_cnt;
int rchan_cnt;
int rflow_cnt;
unsigned long *tchan_map;
unsigned long *rchan_map;
unsigned long *rflow_gp_map;
unsigned long *rflow_gp_map_allocated;
unsigned long *rflow_in_use;
struct udma_tchan *tchans;
struct udma_rchan *rchans;
struct udma_rflow *rflows;
struct udma_chan *channels;
u32 psil_base;
};
struct udma_desc {
struct virt_dma_desc vd;
bool terminated;
enum dma_transfer_direction dir;
struct udma_static_tr static_tr;
u32 residue;
unsigned int sglen;
unsigned int desc_idx; /* Only used for cyclic in packet mode */
unsigned int tr_idx;
u32 metadata_size;
void *metadata; /* pointer to provided metadata buffer (EPIP, PSdata) */
unsigned int hwdesc_count;
struct udma_hwdesc hwdesc[0];
};
enum udma_chan_state {
UDMA_CHAN_IS_IDLE = 0, /* not active, no teardown is in progress */
UDMA_CHAN_IS_ACTIVE, /* Normal operation */
UDMA_CHAN_IS_TERMINATING, /* channel is being terminated */
};
struct udma_tx_drain {
struct delayed_work work;
ktime_t tstamp;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
u32 residue;
};
struct udma_chan_config {
bool pkt_mode; /* TR or packet */
bool needs_epib; /* EPIB is needed for the communication or not */
u32 psd_size; /* size of Protocol Specific Data */
u32 metadata_size; /* (needs_epib ? 16:0) + psd_size */
u32 hdesc_size; /* Size of a packet descriptor in packet mode */
bool notdpkt; /* Suppress sending TDC packet */
int remote_thread_id;
u32 src_thread;
u32 dst_thread;
enum psil_endpoint_type ep_type;
bool enable_acc32;
bool enable_burst;
enum udma_tp_level channel_tpl; /* Channel Throughput Level */
enum dma_transfer_direction dir;
};
struct udma_chan {
struct virt_dma_chan vc;
struct dma_slave_config cfg;
struct udma_dev *ud;
struct udma_desc *desc;
struct udma_desc *terminated_desc;
struct udma_static_tr static_tr;
char *name;
struct udma_tchan *tchan;
struct udma_rchan *rchan;
struct udma_rflow *rflow;
bool psil_paired;
int irq_num_ring;
int irq_num_udma;
bool cyclic;
bool paused;
enum udma_chan_state state;
struct completion teardown_completed;
struct udma_tx_drain tx_drain;
u32 bcnt; /* number of bytes completed since the start of the channel */
u32 in_ring_cnt; /* number of descriptors in flight */
/* Channel configuration parameters */
struct udma_chan_config config;
/* dmapool for packet mode descriptors */
bool use_dma_pool;
struct dma_pool *hdesc_pool;
u32 id;
};
static inline struct udma_dev *to_udma_dev(struct dma_device *d)
{
return container_of(d, struct udma_dev, ddev);
}
static inline struct udma_chan *to_udma_chan(struct dma_chan *c)
{
return container_of(c, struct udma_chan, vc.chan);
}
static inline struct udma_desc *to_udma_desc(struct dma_async_tx_descriptor *t)
{
return container_of(t, struct udma_desc, vd.tx);
}
/* Generic register access functions */
static inline u32 udma_read(void __iomem *base, int reg)
{
return readl(base + reg);
}
static inline void udma_write(void __iomem *base, int reg, u32 val)
{
writel(val, base + reg);
}
static inline void udma_update_bits(void __iomem *base, int reg,
u32 mask, u32 val)
{
u32 tmp, orig;
orig = readl(base + reg);
tmp = orig & ~mask;
tmp |= (val & mask);
if (tmp != orig)
writel(tmp, base + reg);
}
/* TCHANRT */
static inline u32 udma_tchanrt_read(struct udma_tchan *tchan, int reg)
{
if (!tchan)
return 0;
return udma_read(tchan->reg_rt, reg);
}
static inline void udma_tchanrt_write(struct udma_tchan *tchan, int reg,
u32 val)
{
if (!tchan)
return;
udma_write(tchan->reg_rt, reg, val);
}
static inline void udma_tchanrt_update_bits(struct udma_tchan *tchan, int reg,
u32 mask, u32 val)
{
if (!tchan)
return;
udma_update_bits(tchan->reg_rt, reg, mask, val);
}
/* RCHANRT */
static inline u32 udma_rchanrt_read(struct udma_rchan *rchan, int reg)
{
if (!rchan)
return 0;
return udma_read(rchan->reg_rt, reg);
}
static inline void udma_rchanrt_write(struct udma_rchan *rchan, int reg,
u32 val)
{
if (!rchan)
return;
udma_write(rchan->reg_rt, reg, val);
}
static inline void udma_rchanrt_update_bits(struct udma_rchan *rchan, int reg,
u32 mask, u32 val)
{
if (!rchan)
return;
udma_update_bits(rchan->reg_rt, reg, mask, val);
}
static int navss_psil_pair(struct udma_dev *ud, u32 src_thread, u32 dst_thread)
{
struct udma_tisci_rm *tisci_rm = &ud->tisci_rm;
dst_thread |= K3_PSIL_DST_THREAD_ID_OFFSET;
return tisci_rm->tisci_psil_ops->pair(tisci_rm->tisci,
tisci_rm->tisci_navss_dev_id,
src_thread, dst_thread);
}
static int navss_psil_unpair(struct udma_dev *ud, u32 src_thread,
u32 dst_thread)
{
struct udma_tisci_rm *tisci_rm = &ud->tisci_rm;
dst_thread |= K3_PSIL_DST_THREAD_ID_OFFSET;
return tisci_rm->tisci_psil_ops->unpair(tisci_rm->tisci,
tisci_rm->tisci_navss_dev_id,
src_thread, dst_thread);
}
static void udma_reset_uchan(struct udma_chan *uc)
{
memset(&uc->config, 0, sizeof(uc->config));
uc->config.remote_thread_id = -1;
uc->state = UDMA_CHAN_IS_IDLE;
}
static void udma_dump_chan_stdata(struct udma_chan *uc)
{
struct device *dev = uc->ud->dev;
u32 offset;
int i;
if (uc->config.dir == DMA_MEM_TO_DEV || uc->config.dir == DMA_MEM_TO_MEM) {
dev_dbg(dev, "TCHAN State data:\n");
for (i = 0; i < 32; i++) {
offset = UDMA_TCHAN_RT_STDATA_REG + i * 4;
dev_dbg(dev, "TRT_STDATA[%02d]: 0x%08x\n", i,
udma_tchanrt_read(uc->tchan, offset));
}
}
if (uc->config.dir == DMA_DEV_TO_MEM || uc->config.dir == DMA_MEM_TO_MEM) {
dev_dbg(dev, "RCHAN State data:\n");
for (i = 0; i < 32; i++) {
offset = UDMA_RCHAN_RT_STDATA_REG + i * 4;
dev_dbg(dev, "RRT_STDATA[%02d]: 0x%08x\n", i,
udma_rchanrt_read(uc->rchan, offset));
}
}
}
static inline dma_addr_t udma_curr_cppi5_desc_paddr(struct udma_desc *d,
int idx)
{
return d->hwdesc[idx].cppi5_desc_paddr;
}
static inline void *udma_curr_cppi5_desc_vaddr(struct udma_desc *d, int idx)
{
return d->hwdesc[idx].cppi5_desc_vaddr;
}
static struct udma_desc *udma_udma_desc_from_paddr(struct udma_chan *uc,
dma_addr_t paddr)
{
struct udma_desc *d = uc->terminated_desc;
if (d) {
dma_addr_t desc_paddr = udma_curr_cppi5_desc_paddr(d,
d->desc_idx);
if (desc_paddr != paddr)
d = NULL;
}
if (!d) {
d = uc->desc;
if (d) {
dma_addr_t desc_paddr = udma_curr_cppi5_desc_paddr(d,
d->desc_idx);
if (desc_paddr != paddr)
d = NULL;
}
}
return d;
}
static void udma_free_hwdesc(struct udma_chan *uc, struct udma_desc *d)
{
if (uc->use_dma_pool) {
int i;
for (i = 0; i < d->hwdesc_count; i++) {
if (!d->hwdesc[i].cppi5_desc_vaddr)
continue;
dma_pool_free(uc->hdesc_pool,
d->hwdesc[i].cppi5_desc_vaddr,
d->hwdesc[i].cppi5_desc_paddr);
d->hwdesc[i].cppi5_desc_vaddr = NULL;
}
} else if (d->hwdesc[0].cppi5_desc_vaddr) {
struct udma_dev *ud = uc->ud;
dma_free_coherent(ud->dev, d->hwdesc[0].cppi5_desc_size,
d->hwdesc[0].cppi5_desc_vaddr,
d->hwdesc[0].cppi5_desc_paddr);
d->hwdesc[0].cppi5_desc_vaddr = NULL;
}
}
static void udma_purge_desc_work(struct work_struct *work)
{
struct udma_dev *ud = container_of(work, typeof(*ud), purge_work);
struct virt_dma_desc *vd, *_vd;
unsigned long flags;
LIST_HEAD(head);
spin_lock_irqsave(&ud->lock, flags);
list_splice_tail_init(&ud->desc_to_purge, &head);
spin_unlock_irqrestore(&ud->lock, flags);
list_for_each_entry_safe(vd, _vd, &head, node) {
struct udma_chan *uc = to_udma_chan(vd->tx.chan);
struct udma_desc *d = to_udma_desc(&vd->tx);
udma_free_hwdesc(uc, d);
list_del(&vd->node);
kfree(d);
}
/* If more to purge, schedule the work again */
if (!list_empty(&ud->desc_to_purge))
schedule_work(&ud->purge_work);
}
static void udma_desc_free(struct virt_dma_desc *vd)
{
struct udma_dev *ud = to_udma_dev(vd->tx.chan->device);
struct udma_chan *uc = to_udma_chan(vd->tx.chan);
struct udma_desc *d = to_udma_desc(&vd->tx);
unsigned long flags;
if (uc->terminated_desc == d)
uc->terminated_desc = NULL;
if (uc->use_dma_pool) {
udma_free_hwdesc(uc, d);
kfree(d);
return;
}
spin_lock_irqsave(&ud->lock, flags);
list_add_tail(&vd->node, &ud->desc_to_purge);
spin_unlock_irqrestore(&ud->lock, flags);
schedule_work(&ud->purge_work);
}
static bool udma_is_chan_running(struct udma_chan *uc)
{
u32 trt_ctl = 0;
u32 rrt_ctl = 0;
if (uc->tchan)
trt_ctl = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_CTL_REG);
if (uc->rchan)
rrt_ctl = udma_rchanrt_read(uc->rchan, UDMA_RCHAN_RT_CTL_REG);
if (trt_ctl & UDMA_CHAN_RT_CTL_EN || rrt_ctl & UDMA_CHAN_RT_CTL_EN)
return true;
return false;
}
static bool udma_is_chan_paused(struct udma_chan *uc)
{
u32 val, pause_mask;
switch (uc->config.dir) {
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
case DMA_DEV_TO_MEM:
val = udma_rchanrt_read(uc->rchan,
UDMA_RCHAN_RT_PEER_RT_EN_REG);
pause_mask = UDMA_PEER_RT_EN_PAUSE;
break;
case DMA_MEM_TO_DEV:
val = udma_tchanrt_read(uc->tchan,
UDMA_TCHAN_RT_PEER_RT_EN_REG);
pause_mask = UDMA_PEER_RT_EN_PAUSE;
break;
case DMA_MEM_TO_MEM:
val = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_CTL_REG);
pause_mask = UDMA_CHAN_RT_CTL_PAUSE;
break;
default:
return false;
}
if (val & pause_mask)
return true;
return false;
}
static void udma_sync_for_device(struct udma_chan *uc, int idx)
{
struct udma_desc *d = uc->desc;
if (uc->cyclic && uc->config.pkt_mode) {
dma_sync_single_for_device(uc->ud->dev,
d->hwdesc[idx].cppi5_desc_paddr,
d->hwdesc[idx].cppi5_desc_size,
DMA_TO_DEVICE);
} else {
int i;
for (i = 0; i < d->hwdesc_count; i++) {
if (!d->hwdesc[i].cppi5_desc_vaddr)
continue;
dma_sync_single_for_device(uc->ud->dev,
d->hwdesc[i].cppi5_desc_paddr,
d->hwdesc[i].cppi5_desc_size,
DMA_TO_DEVICE);
}
}
}
static inline dma_addr_t udma_get_rx_flush_hwdesc_paddr(struct udma_chan *uc)
{
return uc->ud->rx_flush.hwdescs[uc->config.pkt_mode].cppi5_desc_paddr;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
static int udma_push_to_ring(struct udma_chan *uc, int idx)
{
struct udma_desc *d = uc->desc;
struct k3_ring *ring = NULL;
dma_addr_t paddr;
int ret;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
switch (uc->config.dir) {
case DMA_DEV_TO_MEM:
ring = uc->rflow->fd_ring;
break;
case DMA_MEM_TO_DEV:
case DMA_MEM_TO_MEM:
ring = uc->tchan->t_ring;
break;
default:
return -EINVAL;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
}
/* RX flush packet: idx == -1 is only passed in case of DEV_TO_MEM */
if (idx == -1) {
paddr = udma_get_rx_flush_hwdesc_paddr(uc);
} else {
paddr = udma_curr_cppi5_desc_paddr(d, idx);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
wmb(); /* Ensure that writes are not moved over this point */
udma_sync_for_device(uc, idx);
}
ret = k3_ringacc_ring_push(ring, &paddr);
if (!ret)
uc->in_ring_cnt++;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
return ret;
}
static bool udma_desc_is_rx_flush(struct udma_chan *uc, dma_addr_t addr)
{
if (uc->config.dir != DMA_DEV_TO_MEM)
return false;
if (addr == udma_get_rx_flush_hwdesc_paddr(uc))
return true;
return false;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
static int udma_pop_from_ring(struct udma_chan *uc, dma_addr_t *addr)
{
struct k3_ring *ring = NULL;
int ret = -ENOENT;
switch (uc->config.dir) {
case DMA_DEV_TO_MEM:
ring = uc->rflow->r_ring;
break;
case DMA_MEM_TO_DEV:
case DMA_MEM_TO_MEM:
ring = uc->tchan->tc_ring;
break;
default:
break;
}
if (ring && k3_ringacc_ring_get_occ(ring)) {
struct udma_desc *d = NULL;
ret = k3_ringacc_ring_pop(ring, addr);
if (ret)
return ret;
/* Teardown completion */
if (cppi5_desc_is_tdcm(*addr))
return ret;
/* Check for flush descriptor */
if (udma_desc_is_rx_flush(uc, *addr))
return -ENOENT;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
d = udma_udma_desc_from_paddr(uc, *addr);
if (d)
dma_sync_single_for_cpu(uc->ud->dev, *addr,
d->hwdesc[0].cppi5_desc_size,
DMA_FROM_DEVICE);
rmb(); /* Ensure that reads are not moved before this point */
if (!ret)
uc->in_ring_cnt--;
}
return ret;
}
static void udma_reset_rings(struct udma_chan *uc)
{
struct k3_ring *ring1 = NULL;
struct k3_ring *ring2 = NULL;
switch (uc->config.dir) {
case DMA_DEV_TO_MEM:
if (uc->rchan) {
ring1 = uc->rflow->fd_ring;
ring2 = uc->rflow->r_ring;
}
break;
case DMA_MEM_TO_DEV:
case DMA_MEM_TO_MEM:
if (uc->tchan) {
ring1 = uc->tchan->t_ring;
ring2 = uc->tchan->tc_ring;
}
break;
default:
break;
}
if (ring1)
k3_ringacc_ring_reset_dma(ring1,
k3_ringacc_ring_get_occ(ring1));
if (ring2)
k3_ringacc_ring_reset(ring2);
/* make sure we are not leaking memory by stalled descriptor */
if (uc->terminated_desc) {
udma_desc_free(&uc->terminated_desc->vd);
uc->terminated_desc = NULL;
}
uc->in_ring_cnt = 0;
}
static void udma_reset_counters(struct udma_chan *uc)
{
u32 val;
if (uc->tchan) {
val = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_BCNT_REG);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_BCNT_REG, val);
val = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_SBCNT_REG);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_SBCNT_REG, val);
val = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_PCNT_REG);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_PCNT_REG, val);
val = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_PEER_BCNT_REG);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_PEER_BCNT_REG, val);
}
if (uc->rchan) {
val = udma_rchanrt_read(uc->rchan, UDMA_RCHAN_RT_BCNT_REG);
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_BCNT_REG, val);
val = udma_rchanrt_read(uc->rchan, UDMA_RCHAN_RT_SBCNT_REG);
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_SBCNT_REG, val);
val = udma_rchanrt_read(uc->rchan, UDMA_RCHAN_RT_PCNT_REG);
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_PCNT_REG, val);
val = udma_rchanrt_read(uc->rchan, UDMA_RCHAN_RT_PEER_BCNT_REG);
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_PEER_BCNT_REG, val);
}
uc->bcnt = 0;
}
static int udma_reset_chan(struct udma_chan *uc, bool hard)
{
switch (uc->config.dir) {
case DMA_DEV_TO_MEM:
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_PEER_RT_EN_REG, 0);
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_CTL_REG, 0);
break;
case DMA_MEM_TO_DEV:
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_CTL_REG, 0);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_PEER_RT_EN_REG, 0);
break;
case DMA_MEM_TO_MEM:
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_CTL_REG, 0);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_CTL_REG, 0);
break;
default:
return -EINVAL;
}
/* Reset all counters */
udma_reset_counters(uc);
/* Hard reset: re-initialize the channel to reset */
if (hard) {
struct udma_chan_config ucc_backup;
int ret;
memcpy(&ucc_backup, &uc->config, sizeof(uc->config));
uc->ud->ddev.device_free_chan_resources(&uc->vc.chan);
/* restore the channel configuration */
memcpy(&uc->config, &ucc_backup, sizeof(uc->config));
ret = uc->ud->ddev.device_alloc_chan_resources(&uc->vc.chan);
if (ret)
return ret;
/*
* Setting forced teardown after forced reset helps recovering
* the rchan.
*/
if (uc->config.dir == DMA_DEV_TO_MEM)
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN |
UDMA_CHAN_RT_CTL_TDOWN |
UDMA_CHAN_RT_CTL_FTDOWN);
}
uc->state = UDMA_CHAN_IS_IDLE;
return 0;
}
static void udma_start_desc(struct udma_chan *uc)
{
struct udma_chan_config *ucc = &uc->config;
if (ucc->pkt_mode && (uc->cyclic || ucc->dir == DMA_DEV_TO_MEM)) {
int i;
/* Push all descriptors to ring for packet mode cyclic or RX */
for (i = 0; i < uc->desc->sglen; i++)
udma_push_to_ring(uc, i);
} else {
udma_push_to_ring(uc, 0);
}
}
static bool udma_chan_needs_reconfiguration(struct udma_chan *uc)
{
/* Only PDMAs have staticTR */
if (uc->config.ep_type == PSIL_EP_NATIVE)
return false;
/* Check if the staticTR configuration has changed for TX */
if (memcmp(&uc->static_tr, &uc->desc->static_tr, sizeof(uc->static_tr)))
return true;
return false;
}
static int udma_start(struct udma_chan *uc)
{
struct virt_dma_desc *vd = vchan_next_desc(&uc->vc);
if (!vd) {
uc->desc = NULL;
return -ENOENT;
}
list_del(&vd->node);
uc->desc = to_udma_desc(&vd->tx);
/* Channel is already running and does not need reconfiguration */
if (udma_is_chan_running(uc) && !udma_chan_needs_reconfiguration(uc)) {
udma_start_desc(uc);
goto out;
}
/* Make sure that we clear the teardown bit, if it is set */
udma_reset_chan(uc, false);
/* Push descriptors before we start the channel */
udma_start_desc(uc);
switch (uc->desc->dir) {
case DMA_DEV_TO_MEM:
/* Config remote TR */
if (uc->config.ep_type == PSIL_EP_PDMA_XY) {
u32 val = PDMA_STATIC_TR_Y(uc->desc->static_tr.elcnt) |
PDMA_STATIC_TR_X(uc->desc->static_tr.elsize);
const struct udma_match_data *match_data =
uc->ud->match_data;
if (uc->config.enable_acc32)
val |= PDMA_STATIC_TR_XY_ACC32;
if (uc->config.enable_burst)
val |= PDMA_STATIC_TR_XY_BURST;
udma_rchanrt_write(uc->rchan,
UDMA_RCHAN_RT_PEER_STATIC_TR_XY_REG, val);
udma_rchanrt_write(uc->rchan,
UDMA_RCHAN_RT_PEER_STATIC_TR_Z_REG,
PDMA_STATIC_TR_Z(uc->desc->static_tr.bstcnt,
match_data->statictr_z_mask));
/* save the current staticTR configuration */
memcpy(&uc->static_tr, &uc->desc->static_tr,
sizeof(uc->static_tr));
}
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN);
/* Enable remote */
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_ENABLE);
break;
case DMA_MEM_TO_DEV:
/* Config remote TR */
if (uc->config.ep_type == PSIL_EP_PDMA_XY) {
u32 val = PDMA_STATIC_TR_Y(uc->desc->static_tr.elcnt) |
PDMA_STATIC_TR_X(uc->desc->static_tr.elsize);
if (uc->config.enable_acc32)
val |= PDMA_STATIC_TR_XY_ACC32;
if (uc->config.enable_burst)
val |= PDMA_STATIC_TR_XY_BURST;
udma_tchanrt_write(uc->tchan,
UDMA_TCHAN_RT_PEER_STATIC_TR_XY_REG, val);
/* save the current staticTR configuration */
memcpy(&uc->static_tr, &uc->desc->static_tr,
sizeof(uc->static_tr));
}
/* Enable remote */
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_ENABLE);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN);
break;
case DMA_MEM_TO_MEM:
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN);
break;
default:
return -EINVAL;
}
uc->state = UDMA_CHAN_IS_ACTIVE;
out:
return 0;
}
static int udma_stop(struct udma_chan *uc)
{
enum udma_chan_state old_state = uc->state;
uc->state = UDMA_CHAN_IS_TERMINATING;
reinit_completion(&uc->teardown_completed);
switch (uc->config.dir) {
case DMA_DEV_TO_MEM:
if (!uc->cyclic && !uc->desc)
udma_push_to_ring(uc, -1);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
udma_rchanrt_write(uc->rchan, UDMA_RCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_ENABLE |
UDMA_PEER_RT_EN_TEARDOWN);
break;
case DMA_MEM_TO_DEV:
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_ENABLE |
UDMA_PEER_RT_EN_FLUSH);
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN |
UDMA_CHAN_RT_CTL_TDOWN);
break;
case DMA_MEM_TO_MEM:
udma_tchanrt_write(uc->tchan, UDMA_TCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_EN |
UDMA_CHAN_RT_CTL_TDOWN);
break;
default:
uc->state = old_state;
complete_all(&uc->teardown_completed);
return -EINVAL;
}
return 0;
}
static void udma_cyclic_packet_elapsed(struct udma_chan *uc)
{
struct udma_desc *d = uc->desc;
struct cppi5_host_desc_t *h_desc;
h_desc = d->hwdesc[d->desc_idx].cppi5_desc_vaddr;
cppi5_hdesc_reset_to_original(h_desc);
udma_push_to_ring(uc, d->desc_idx);
d->desc_idx = (d->desc_idx + 1) % d->sglen;
}
static inline void udma_fetch_epib(struct udma_chan *uc, struct udma_desc *d)
{
struct cppi5_host_desc_t *h_desc = d->hwdesc[0].cppi5_desc_vaddr;
memcpy(d->metadata, h_desc->epib, d->metadata_size);
}
static bool udma_is_desc_really_done(struct udma_chan *uc, struct udma_desc *d)
{
u32 peer_bcnt, bcnt;
/* Only TX towards PDMA is affected */
if (uc->config.ep_type == PSIL_EP_NATIVE ||
uc->config.dir != DMA_MEM_TO_DEV)
return true;
peer_bcnt = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_PEER_BCNT_REG);
bcnt = udma_tchanrt_read(uc->tchan, UDMA_TCHAN_RT_BCNT_REG);
/* Transfer is incomplete, store current residue and time stamp */
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (peer_bcnt < bcnt) {
uc->tx_drain.residue = bcnt - peer_bcnt;
uc->tx_drain.tstamp = ktime_get();
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
return false;
}
return true;
}
static void udma_check_tx_completion(struct work_struct *work)
{
struct udma_chan *uc = container_of(work, typeof(*uc),
tx_drain.work.work);
bool desc_done = true;
u32 residue_diff;
ktime_t time_diff;
unsigned long delay;
while (1) {
if (uc->desc) {
/* Get previous residue and time stamp */
residue_diff = uc->tx_drain.residue;
time_diff = uc->tx_drain.tstamp;
/*
* Get current residue and time stamp or see if
* transfer is complete
*/
desc_done = udma_is_desc_really_done(uc, uc->desc);
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (!desc_done) {
/*
* Find the time delta and residue delta w.r.t
* previous poll
*/
time_diff = ktime_sub(uc->tx_drain.tstamp,
time_diff) + 1;
residue_diff -= uc->tx_drain.residue;
if (residue_diff) {
/*
* Try to guess when we should check
* next time by calculating rate at
* which data is being drained at the
* peer device
*/
delay = (time_diff / residue_diff) *
uc->tx_drain.residue;
} else {
/* No progress, check again in 1 second */
schedule_delayed_work(&uc->tx_drain.work, HZ);
break;
}
usleep_range(ktime_to_us(delay),
ktime_to_us(delay) + 10);
continue;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
}
if (uc->desc) {
struct udma_desc *d = uc->desc;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
uc->bcnt += d->residue;
udma_start(uc);
vchan_cookie_complete(&d->vd);
break;
}
break;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
}
}
static irqreturn_t udma_ring_irq_handler(int irq, void *data)
{
struct udma_chan *uc = data;
struct udma_desc *d;
unsigned long flags;
dma_addr_t paddr = 0;
if (udma_pop_from_ring(uc, &paddr) || !paddr)
return IRQ_HANDLED;
spin_lock_irqsave(&uc->vc.lock, flags);
/* Teardown completion message */
if (cppi5_desc_is_tdcm(paddr)) {
/* Compensate our internal pop/push counter */
uc->in_ring_cnt++;
complete_all(&uc->teardown_completed);
if (uc->terminated_desc) {
udma_desc_free(&uc->terminated_desc->vd);
uc->terminated_desc = NULL;
}
if (!uc->desc)
udma_start(uc);
goto out;
}
d = udma_udma_desc_from_paddr(uc, paddr);
if (d) {
dma_addr_t desc_paddr = udma_curr_cppi5_desc_paddr(d,
d->desc_idx);
if (desc_paddr != paddr) {
dev_err(uc->ud->dev, "not matching descriptors!\n");
goto out;
}
if (uc->cyclic) {
/* push the descriptor back to the ring */
if (d == uc->desc) {
udma_cyclic_packet_elapsed(uc);
vchan_cyclic_callback(&d->vd);
}
} else {
bool desc_done = false;
if (d == uc->desc) {
desc_done = udma_is_desc_really_done(uc, d);
if (desc_done) {
uc->bcnt += d->residue;
udma_start(uc);
} else {
schedule_delayed_work(&uc->tx_drain.work,
0);
}
}
if (desc_done)
vchan_cookie_complete(&d->vd);
}
}
out:
spin_unlock_irqrestore(&uc->vc.lock, flags);
return IRQ_HANDLED;
}
static irqreturn_t udma_udma_irq_handler(int irq, void *data)
{
struct udma_chan *uc = data;
struct udma_desc *d;
unsigned long flags;
spin_lock_irqsave(&uc->vc.lock, flags);
d = uc->desc;
if (d) {
d->tr_idx = (d->tr_idx + 1) % d->sglen;
if (uc->cyclic) {
vchan_cyclic_callback(&d->vd);
} else {
/* TODO: figure out the real amount of data */
uc->bcnt += d->residue;
udma_start(uc);
vchan_cookie_complete(&d->vd);
}
}
spin_unlock_irqrestore(&uc->vc.lock, flags);
return IRQ_HANDLED;
}
dmaengine: ti: k3-udma: Add glue layer for non DMAengine users Certain users can not use right now the DMAengine API due to missing features in the core. Prime example is Networking. These users can use the glue layer interface to avoid misuse of DMAengine API and when the core gains the needed features they can be converted to use generic API. The most prominent features the glue layer clients are depending on: - most PSI-L native peripheral use extra rflow ranges on a receive channel and depending on the peripheral's configuration packets from a single free descriptor ring is going to be received to different receive ring - it is also possible to have different free descriptor rings per rflow and an rflow can also support 4 additional free descriptor ring based on the size of the incoming packet - out of order completion of descriptors on a channel - when we have several queues to handle different priority packets the descriptors will be completed 'out-of-order' - the notion of prep_slave_sg is not matching with what the streaming type of operation is demanding for networking - Streaming type of operation - Ability to fill the free descriptor ring with descriptors in anticipation of incoming traffic and when a packet arrives UDMAP will form a packet and gives it to the client driver - the descriptors are not backed with exact size data buffers as we don't know the size of the packet we will receive, but as a generic pool of buffers to be used by the receive channel - NAPI type of operation (polling instead of interrupt driven transfer) - without this we can not sustain gigabit speeds and we need to support NAPI - not to limit this to networking, but other high performance operations Signed-off-by: Grygorii Strashko <grygorii.strashko@ti.com> Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-12-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:51 +07:00
/**
* __udma_alloc_gp_rflow_range - alloc range of GP RX flows
* @ud: UDMA device
* @from: Start the search from this flow id number
* @cnt: Number of consecutive flow ids to allocate
*
* Allocate range of RX flow ids for future use, those flows can be requested
* only using explicit flow id number. if @from is set to -1 it will try to find
* first free range. if @from is positive value it will force allocation only
* of the specified range of flows.
*
* Returns -ENOMEM if can't find free range.
* -EEXIST if requested range is busy.
* -EINVAL if wrong input values passed.
* Returns flow id on success.
*/
static int __udma_alloc_gp_rflow_range(struct udma_dev *ud, int from, int cnt)
{
int start, tmp_from;
DECLARE_BITMAP(tmp, K3_UDMA_MAX_RFLOWS);
tmp_from = from;
if (tmp_from < 0)
tmp_from = ud->rchan_cnt;
/* default flows can't be allocated and accessible only by id */
if (tmp_from < ud->rchan_cnt)
return -EINVAL;
if (tmp_from + cnt > ud->rflow_cnt)
return -EINVAL;
bitmap_or(tmp, ud->rflow_gp_map, ud->rflow_gp_map_allocated,
ud->rflow_cnt);
start = bitmap_find_next_zero_area(tmp,
ud->rflow_cnt,
tmp_from, cnt, 0);
if (start >= ud->rflow_cnt)
return -ENOMEM;
if (from >= 0 && start != from)
return -EEXIST;
bitmap_set(ud->rflow_gp_map_allocated, start, cnt);
return start;
}
static int __udma_free_gp_rflow_range(struct udma_dev *ud, int from, int cnt)
{
if (from < ud->rchan_cnt)
return -EINVAL;
if (from + cnt > ud->rflow_cnt)
return -EINVAL;
bitmap_clear(ud->rflow_gp_map_allocated, from, cnt);
return 0;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
static struct udma_rflow *__udma_get_rflow(struct udma_dev *ud, int id)
{
/*
* Attempt to request rflow by ID can be made for any rflow
* if not in use with assumption that caller knows what's doing.
* TI-SCI FW will perform additional permission check ant way, it's
* safe
*/
if (id < 0 || id >= ud->rflow_cnt)
return ERR_PTR(-ENOENT);
if (test_bit(id, ud->rflow_in_use))
return ERR_PTR(-ENOENT);
/* GP rflow has to be allocated first */
if (!test_bit(id, ud->rflow_gp_map) &&
!test_bit(id, ud->rflow_gp_map_allocated))
return ERR_PTR(-EINVAL);
dev_dbg(ud->dev, "get rflow%d\n", id);
set_bit(id, ud->rflow_in_use);
return &ud->rflows[id];
}
static void __udma_put_rflow(struct udma_dev *ud, struct udma_rflow *rflow)
{
if (!test_bit(rflow->id, ud->rflow_in_use)) {
dev_err(ud->dev, "attempt to put unused rflow%d\n", rflow->id);
return;
}
dev_dbg(ud->dev, "put rflow%d\n", rflow->id);
clear_bit(rflow->id, ud->rflow_in_use);
}
#define UDMA_RESERVE_RESOURCE(res) \
static struct udma_##res *__udma_reserve_##res(struct udma_dev *ud, \
enum udma_tp_level tpl, \
int id) \
{ \
if (id >= 0) { \
if (test_bit(id, ud->res##_map)) { \
dev_err(ud->dev, "res##%d is in use\n", id); \
return ERR_PTR(-ENOENT); \
} \
} else { \
int start; \
\
if (tpl >= ud->match_data->tpl_levels) \
tpl = ud->match_data->tpl_levels - 1; \
\
start = ud->match_data->level_start_idx[tpl]; \
\
id = find_next_zero_bit(ud->res##_map, ud->res##_cnt, \
start); \
if (id == ud->res##_cnt) { \
return ERR_PTR(-ENOENT); \
} \
} \
\
set_bit(id, ud->res##_map); \
return &ud->res##s[id]; \
}
UDMA_RESERVE_RESOURCE(tchan);
UDMA_RESERVE_RESOURCE(rchan);
static int udma_get_tchan(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
if (uc->tchan) {
dev_dbg(ud->dev, "chan%d: already have tchan%d allocated\n",
uc->id, uc->tchan->id);
return 0;
}
uc->tchan = __udma_reserve_tchan(ud, uc->config.channel_tpl, -1);
if (IS_ERR(uc->tchan))
return PTR_ERR(uc->tchan);
return 0;
}
static int udma_get_rchan(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
if (uc->rchan) {
dev_dbg(ud->dev, "chan%d: already have rchan%d allocated\n",
uc->id, uc->rchan->id);
return 0;
}
uc->rchan = __udma_reserve_rchan(ud, uc->config.channel_tpl, -1);
if (IS_ERR(uc->rchan))
return PTR_ERR(uc->rchan);
return 0;
}
static int udma_get_chan_pair(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
const struct udma_match_data *match_data = ud->match_data;
int chan_id, end;
if ((uc->tchan && uc->rchan) && uc->tchan->id == uc->rchan->id) {
dev_info(ud->dev, "chan%d: already have %d pair allocated\n",
uc->id, uc->tchan->id);
return 0;
}
if (uc->tchan) {
dev_err(ud->dev, "chan%d: already have tchan%d allocated\n",
uc->id, uc->tchan->id);
return -EBUSY;
} else if (uc->rchan) {
dev_err(ud->dev, "chan%d: already have rchan%d allocated\n",
uc->id, uc->rchan->id);
return -EBUSY;
}
/* Can be optimized, but let's have it like this for now */
end = min(ud->tchan_cnt, ud->rchan_cnt);
/* Try to use the highest TPL channel pair for MEM_TO_MEM channels */
chan_id = match_data->level_start_idx[match_data->tpl_levels - 1];
for (; chan_id < end; chan_id++) {
if (!test_bit(chan_id, ud->tchan_map) &&
!test_bit(chan_id, ud->rchan_map))
break;
}
if (chan_id == end)
return -ENOENT;
set_bit(chan_id, ud->tchan_map);
set_bit(chan_id, ud->rchan_map);
uc->tchan = &ud->tchans[chan_id];
uc->rchan = &ud->rchans[chan_id];
return 0;
}
static int udma_get_rflow(struct udma_chan *uc, int flow_id)
{
struct udma_dev *ud = uc->ud;
if (!uc->rchan) {
dev_err(ud->dev, "chan%d: does not have rchan??\n", uc->id);
return -EINVAL;
}
if (uc->rflow) {
dev_dbg(ud->dev, "chan%d: already have rflow%d allocated\n",
uc->id, uc->rflow->id);
return 0;
}
uc->rflow = __udma_get_rflow(ud, flow_id);
if (IS_ERR(uc->rflow))
return PTR_ERR(uc->rflow);
return 0;
}
static void udma_put_rchan(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
if (uc->rchan) {
dev_dbg(ud->dev, "chan%d: put rchan%d\n", uc->id,
uc->rchan->id);
clear_bit(uc->rchan->id, ud->rchan_map);
uc->rchan = NULL;
}
}
static void udma_put_tchan(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
if (uc->tchan) {
dev_dbg(ud->dev, "chan%d: put tchan%d\n", uc->id,
uc->tchan->id);
clear_bit(uc->tchan->id, ud->tchan_map);
uc->tchan = NULL;
}
}
static void udma_put_rflow(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
if (uc->rflow) {
dev_dbg(ud->dev, "chan%d: put rflow%d\n", uc->id,
uc->rflow->id);
__udma_put_rflow(ud, uc->rflow);
uc->rflow = NULL;
}
}
static void udma_free_tx_resources(struct udma_chan *uc)
{
if (!uc->tchan)
return;
k3_ringacc_ring_free(uc->tchan->t_ring);
k3_ringacc_ring_free(uc->tchan->tc_ring);
uc->tchan->t_ring = NULL;
uc->tchan->tc_ring = NULL;
udma_put_tchan(uc);
}
static int udma_alloc_tx_resources(struct udma_chan *uc)
{
struct k3_ring_cfg ring_cfg;
struct udma_dev *ud = uc->ud;
int ret;
ret = udma_get_tchan(uc);
if (ret)
return ret;
uc->tchan->t_ring = k3_ringacc_request_ring(ud->ringacc,
uc->tchan->id, 0);
if (!uc->tchan->t_ring) {
ret = -EBUSY;
goto err_tx_ring;
}
uc->tchan->tc_ring = k3_ringacc_request_ring(ud->ringacc, -1, 0);
if (!uc->tchan->tc_ring) {
ret = -EBUSY;
goto err_txc_ring;
}
memset(&ring_cfg, 0, sizeof(ring_cfg));
ring_cfg.size = K3_UDMA_DEFAULT_RING_SIZE;
ring_cfg.elm_size = K3_RINGACC_RING_ELSIZE_8;
ring_cfg.mode = K3_RINGACC_RING_MODE_MESSAGE;
ret = k3_ringacc_ring_cfg(uc->tchan->t_ring, &ring_cfg);
ret |= k3_ringacc_ring_cfg(uc->tchan->tc_ring, &ring_cfg);
if (ret)
goto err_ringcfg;
return 0;
err_ringcfg:
k3_ringacc_ring_free(uc->tchan->tc_ring);
uc->tchan->tc_ring = NULL;
err_txc_ring:
k3_ringacc_ring_free(uc->tchan->t_ring);
uc->tchan->t_ring = NULL;
err_tx_ring:
udma_put_tchan(uc);
return ret;
}
static void udma_free_rx_resources(struct udma_chan *uc)
{
if (!uc->rchan)
return;
if (uc->rflow) {
struct udma_rflow *rflow = uc->rflow;
k3_ringacc_ring_free(rflow->fd_ring);
k3_ringacc_ring_free(rflow->r_ring);
rflow->fd_ring = NULL;
rflow->r_ring = NULL;
udma_put_rflow(uc);
}
udma_put_rchan(uc);
}
static int udma_alloc_rx_resources(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
struct k3_ring_cfg ring_cfg;
struct udma_rflow *rflow;
int fd_ring_id;
int ret;
ret = udma_get_rchan(uc);
if (ret)
return ret;
/* For MEM_TO_MEM we don't need rflow or rings */
if (uc->config.dir == DMA_MEM_TO_MEM)
return 0;
ret = udma_get_rflow(uc, uc->rchan->id);
if (ret) {
ret = -EBUSY;
goto err_rflow;
}
rflow = uc->rflow;
fd_ring_id = ud->tchan_cnt + ud->echan_cnt + uc->rchan->id;
rflow->fd_ring = k3_ringacc_request_ring(ud->ringacc, fd_ring_id, 0);
if (!rflow->fd_ring) {
ret = -EBUSY;
goto err_rx_ring;
}
rflow->r_ring = k3_ringacc_request_ring(ud->ringacc, -1, 0);
if (!rflow->r_ring) {
ret = -EBUSY;
goto err_rxc_ring;
}
memset(&ring_cfg, 0, sizeof(ring_cfg));
if (uc->config.pkt_mode)
ring_cfg.size = SG_MAX_SEGMENTS;
else
ring_cfg.size = K3_UDMA_DEFAULT_RING_SIZE;
ring_cfg.elm_size = K3_RINGACC_RING_ELSIZE_8;
ring_cfg.mode = K3_RINGACC_RING_MODE_MESSAGE;
ret = k3_ringacc_ring_cfg(rflow->fd_ring, &ring_cfg);
ring_cfg.size = K3_UDMA_DEFAULT_RING_SIZE;
ret |= k3_ringacc_ring_cfg(rflow->r_ring, &ring_cfg);
if (ret)
goto err_ringcfg;
return 0;
err_ringcfg:
k3_ringacc_ring_free(rflow->r_ring);
rflow->r_ring = NULL;
err_rxc_ring:
k3_ringacc_ring_free(rflow->fd_ring);
rflow->fd_ring = NULL;
err_rx_ring:
udma_put_rflow(uc);
err_rflow:
udma_put_rchan(uc);
return ret;
}
#define TISCI_TCHAN_VALID_PARAMS ( \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_PAUSE_ON_ERR_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_TX_FILT_EINFO_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_TX_FILT_PSWORDS_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_CHAN_TYPE_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_TX_SUPR_TDPKT_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_FETCH_SIZE_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_CQ_QNUM_VALID)
#define TISCI_RCHAN_VALID_PARAMS ( \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_PAUSE_ON_ERR_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_FETCH_SIZE_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_CQ_QNUM_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_CHAN_TYPE_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_RX_IGNORE_SHORT_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_RX_IGNORE_LONG_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_RX_FLOWID_START_VALID | \
TI_SCI_MSG_VALUE_RM_UDMAP_CH_RX_FLOWID_CNT_VALID)
static int udma_tisci_m2m_channel_config(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
struct udma_tisci_rm *tisci_rm = &ud->tisci_rm;
const struct ti_sci_rm_udmap_ops *tisci_ops = tisci_rm->tisci_udmap_ops;
struct udma_tchan *tchan = uc->tchan;
struct udma_rchan *rchan = uc->rchan;
int ret = 0;
/* Non synchronized - mem to mem type of transfer */
int tc_ring = k3_ringacc_get_ring_id(tchan->tc_ring);
struct ti_sci_msg_rm_udmap_tx_ch_cfg req_tx = { 0 };
struct ti_sci_msg_rm_udmap_rx_ch_cfg req_rx = { 0 };
req_tx.valid_params = TISCI_TCHAN_VALID_PARAMS;
req_tx.nav_id = tisci_rm->tisci_dev_id;
req_tx.index = tchan->id;
req_tx.tx_chan_type = TI_SCI_RM_UDMAP_CHAN_TYPE_3RDP_BCOPY_PBRR;
req_tx.tx_fetch_size = sizeof(struct cppi5_desc_hdr_t) >> 2;
req_tx.txcq_qnum = tc_ring;
ret = tisci_ops->tx_ch_cfg(tisci_rm->tisci, &req_tx);
if (ret) {
dev_err(ud->dev, "tchan%d cfg failed %d\n", tchan->id, ret);
return ret;
}
req_rx.valid_params = TISCI_RCHAN_VALID_PARAMS;
req_rx.nav_id = tisci_rm->tisci_dev_id;
req_rx.index = rchan->id;
req_rx.rx_fetch_size = sizeof(struct cppi5_desc_hdr_t) >> 2;
req_rx.rxcq_qnum = tc_ring;
req_rx.rx_chan_type = TI_SCI_RM_UDMAP_CHAN_TYPE_3RDP_BCOPY_PBRR;
ret = tisci_ops->rx_ch_cfg(tisci_rm->tisci, &req_rx);
if (ret)
dev_err(ud->dev, "rchan%d alloc failed %d\n", rchan->id, ret);
return ret;
}
static int udma_tisci_tx_channel_config(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
struct udma_tisci_rm *tisci_rm = &ud->tisci_rm;
const struct ti_sci_rm_udmap_ops *tisci_ops = tisci_rm->tisci_udmap_ops;
struct udma_tchan *tchan = uc->tchan;
int tc_ring = k3_ringacc_get_ring_id(tchan->tc_ring);
struct ti_sci_msg_rm_udmap_tx_ch_cfg req_tx = { 0 };
u32 mode, fetch_size;
int ret = 0;
if (uc->config.pkt_mode) {
mode = TI_SCI_RM_UDMAP_CHAN_TYPE_PKT_PBRR;
fetch_size = cppi5_hdesc_calc_size(uc->config.needs_epib,
uc->config.psd_size, 0);
} else {
mode = TI_SCI_RM_UDMAP_CHAN_TYPE_3RDP_PBRR;
fetch_size = sizeof(struct cppi5_desc_hdr_t);
}
req_tx.valid_params = TISCI_TCHAN_VALID_PARAMS;
req_tx.nav_id = tisci_rm->tisci_dev_id;
req_tx.index = tchan->id;
req_tx.tx_chan_type = mode;
req_tx.tx_supr_tdpkt = uc->config.notdpkt;
req_tx.tx_fetch_size = fetch_size >> 2;
req_tx.txcq_qnum = tc_ring;
ret = tisci_ops->tx_ch_cfg(tisci_rm->tisci, &req_tx);
if (ret)
dev_err(ud->dev, "tchan%d cfg failed %d\n", tchan->id, ret);
return ret;
}
static int udma_tisci_rx_channel_config(struct udma_chan *uc)
{
struct udma_dev *ud = uc->ud;
struct udma_tisci_rm *tisci_rm = &ud->tisci_rm;
const struct ti_sci_rm_udmap_ops *tisci_ops = tisci_rm->tisci_udmap_ops;
struct udma_rchan *rchan = uc->rchan;
int fd_ring = k3_ringacc_get_ring_id(uc->rflow->fd_ring);
int rx_ring = k3_ringacc_get_ring_id(uc->rflow->r_ring);
struct ti_sci_msg_rm_udmap_rx_ch_cfg req_rx = { 0 };
struct ti_sci_msg_rm_udmap_flow_cfg flow_req = { 0 };
u32 mode, fetch_size;
int ret = 0;
if (uc->config.pkt_mode) {
mode = TI_SCI_RM_UDMAP_CHAN_TYPE_PKT_PBRR;
fetch_size = cppi5_hdesc_calc_size(uc->config.needs_epib,
uc->config.psd_size, 0);
} else {
mode = TI_SCI_RM_UDMAP_CHAN_TYPE_3RDP_PBRR;
fetch_size = sizeof(struct cppi5_desc_hdr_t);
}
req_rx.valid_params = TISCI_RCHAN_VALID_PARAMS;
req_rx.nav_id = tisci_rm->tisci_dev_id;
req_rx.index = rchan->id;
req_rx.rx_fetch_size = fetch_size >> 2;
req_rx.rxcq_qnum = rx_ring;
req_rx.rx_chan_type = mode;
ret = tisci_ops->rx_ch_cfg(tisci_rm->tisci, &req_rx);
if (ret) {
dev_err(ud->dev, "rchan%d cfg failed %d\n", rchan->id, ret);
return ret;
}
flow_req.valid_params =
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_EINFO_PRESENT_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_PSINFO_PRESENT_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_ERROR_HANDLING_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_DESC_TYPE_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_DEST_QNUM_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_SRC_TAG_HI_SEL_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_SRC_TAG_LO_SEL_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_DEST_TAG_HI_SEL_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_DEST_TAG_LO_SEL_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_FDQ0_SZ0_QNUM_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_FDQ1_QNUM_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_FDQ2_QNUM_VALID |
TI_SCI_MSG_VALUE_RM_UDMAP_FLOW_FDQ3_QNUM_VALID;
flow_req.nav_id = tisci_rm->tisci_dev_id;
flow_req.flow_index = rchan->id;
if (uc->config.needs_epib)
flow_req.rx_einfo_present = 1;
else
flow_req.rx_einfo_present = 0;
if (uc->config.psd_size)
flow_req.rx_psinfo_present = 1;
else
flow_req.rx_psinfo_present = 0;
flow_req.rx_error_handling = 1;
flow_req.rx_dest_qnum = rx_ring;
flow_req.rx_src_tag_hi_sel = UDMA_RFLOW_SRCTAG_NONE;
flow_req.rx_src_tag_lo_sel = UDMA_RFLOW_SRCTAG_SRC_TAG;
flow_req.rx_dest_tag_hi_sel = UDMA_RFLOW_DSTTAG_DST_TAG_HI;
flow_req.rx_dest_tag_lo_sel = UDMA_RFLOW_DSTTAG_DST_TAG_LO;
flow_req.rx_fdq0_sz0_qnum = fd_ring;
flow_req.rx_fdq1_qnum = fd_ring;
flow_req.rx_fdq2_qnum = fd_ring;
flow_req.rx_fdq3_qnum = fd_ring;
ret = tisci_ops->rx_flow_cfg(tisci_rm->tisci, &flow_req);
if (ret)
dev_err(ud->dev, "flow%d config failed: %d\n", rchan->id, ret);
return 0;
}
static int udma_alloc_chan_resources(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
struct udma_dev *ud = to_udma_dev(chan->device);
const struct udma_match_data *match_data = ud->match_data;
struct k3_ring *irq_ring;
u32 irq_udma_idx;
int ret;
if (uc->config.pkt_mode || uc->config.dir == DMA_MEM_TO_MEM) {
uc->use_dma_pool = true;
/* in case of MEM_TO_MEM we have maximum of two TRs */
if (uc->config.dir == DMA_MEM_TO_MEM) {
uc->config.hdesc_size = cppi5_trdesc_calc_size(
sizeof(struct cppi5_tr_type15_t), 2);
uc->config.pkt_mode = false;
}
}
if (uc->use_dma_pool) {
uc->hdesc_pool = dma_pool_create(uc->name, ud->ddev.dev,
uc->config.hdesc_size,
ud->desc_align,
0);
if (!uc->hdesc_pool) {
dev_err(ud->ddev.dev,
"Descriptor pool allocation failed\n");
uc->use_dma_pool = false;
return -ENOMEM;
}
}
/*
* Make sure that the completion is in a known state:
* No teardown, the channel is idle
*/
reinit_completion(&uc->teardown_completed);
complete_all(&uc->teardown_completed);
uc->state = UDMA_CHAN_IS_IDLE;
switch (uc->config.dir) {
case DMA_MEM_TO_MEM:
/* Non synchronized - mem to mem type of transfer */
dev_dbg(uc->ud->dev, "%s: chan%d as MEM-to-MEM\n", __func__,
uc->id);
ret = udma_get_chan_pair(uc);
if (ret)
return ret;
ret = udma_alloc_tx_resources(uc);
if (ret)
return ret;
ret = udma_alloc_rx_resources(uc);
if (ret) {
udma_free_tx_resources(uc);
return ret;
}
uc->config.src_thread = ud->psil_base + uc->tchan->id;
uc->config.dst_thread = (ud->psil_base + uc->rchan->id) |
K3_PSIL_DST_THREAD_ID_OFFSET;
irq_ring = uc->tchan->tc_ring;
irq_udma_idx = uc->tchan->id;
ret = udma_tisci_m2m_channel_config(uc);
break;
case DMA_MEM_TO_DEV:
/* Slave transfer synchronized - mem to dev (TX) trasnfer */
dev_dbg(uc->ud->dev, "%s: chan%d as MEM-to-DEV\n", __func__,
uc->id);
ret = udma_alloc_tx_resources(uc);
if (ret) {
uc->config.remote_thread_id = -1;
return ret;
}
uc->config.src_thread = ud->psil_base + uc->tchan->id;
uc->config.dst_thread = uc->config.remote_thread_id;
uc->config.dst_thread |= K3_PSIL_DST_THREAD_ID_OFFSET;
irq_ring = uc->tchan->tc_ring;
irq_udma_idx = uc->tchan->id;
ret = udma_tisci_tx_channel_config(uc);
break;
case DMA_DEV_TO_MEM:
/* Slave transfer synchronized - dev to mem (RX) trasnfer */
dev_dbg(uc->ud->dev, "%s: chan%d as DEV-to-MEM\n", __func__,
uc->id);
ret = udma_alloc_rx_resources(uc);
if (ret) {
uc->config.remote_thread_id = -1;
return ret;
}
uc->config.src_thread = uc->config.remote_thread_id;
uc->config.dst_thread = (ud->psil_base + uc->rchan->id) |
K3_PSIL_DST_THREAD_ID_OFFSET;
irq_ring = uc->rflow->r_ring;
irq_udma_idx = match_data->rchan_oes_offset + uc->rchan->id;
ret = udma_tisci_rx_channel_config(uc);
break;
default:
/* Can not happen */
dev_err(uc->ud->dev, "%s: chan%d invalid direction (%u)\n",
__func__, uc->id, uc->config.dir);
return -EINVAL;
}
/* check if the channel configuration was successful */
if (ret)
goto err_res_free;
if (udma_is_chan_running(uc)) {
dev_warn(ud->dev, "chan%d: is running!\n", uc->id);
udma_stop(uc);
if (udma_is_chan_running(uc)) {
dev_err(ud->dev, "chan%d: won't stop!\n", uc->id);
goto err_res_free;
}
}
/* PSI-L pairing */
ret = navss_psil_pair(ud, uc->config.src_thread, uc->config.dst_thread);
if (ret) {
dev_err(ud->dev, "PSI-L pairing failed: 0x%04x -> 0x%04x\n",
uc->config.src_thread, uc->config.dst_thread);
goto err_res_free;
}
uc->psil_paired = true;
uc->irq_num_ring = k3_ringacc_get_ring_irq_num(irq_ring);
if (uc->irq_num_ring <= 0) {
dev_err(ud->dev, "Failed to get ring irq (index: %u)\n",
k3_ringacc_get_ring_id(irq_ring));
ret = -EINVAL;
goto err_psi_free;
}
ret = request_irq(uc->irq_num_ring, udma_ring_irq_handler,
IRQF_TRIGGER_HIGH, uc->name, uc);
if (ret) {
dev_err(ud->dev, "chan%d: ring irq request failed\n", uc->id);
goto err_irq_free;
}
/* Event from UDMA (TR events) only needed for slave TR mode channels */
if (is_slave_direction(uc->config.dir) && !uc->config.pkt_mode) {
uc->irq_num_udma = ti_sci_inta_msi_get_virq(ud->dev,
irq_udma_idx);
if (uc->irq_num_udma <= 0) {
dev_err(ud->dev, "Failed to get udma irq (index: %u)\n",
irq_udma_idx);
free_irq(uc->irq_num_ring, uc);
ret = -EINVAL;
goto err_irq_free;
}
ret = request_irq(uc->irq_num_udma, udma_udma_irq_handler, 0,
uc->name, uc);
if (ret) {
dev_err(ud->dev, "chan%d: UDMA irq request failed\n",
uc->id);
free_irq(uc->irq_num_ring, uc);
goto err_irq_free;
}
} else {
uc->irq_num_udma = 0;
}
udma_reset_rings(uc);
INIT_DELAYED_WORK_ONSTACK(&uc->tx_drain.work,
udma_check_tx_completion);
return 0;
err_irq_free:
uc->irq_num_ring = 0;
uc->irq_num_udma = 0;
err_psi_free:
navss_psil_unpair(ud, uc->config.src_thread, uc->config.dst_thread);
uc->psil_paired = false;
err_res_free:
udma_free_tx_resources(uc);
udma_free_rx_resources(uc);
udma_reset_uchan(uc);
if (uc->use_dma_pool) {
dma_pool_destroy(uc->hdesc_pool);
uc->use_dma_pool = false;
}
return ret;
}
static int udma_slave_config(struct dma_chan *chan,
struct dma_slave_config *cfg)
{
struct udma_chan *uc = to_udma_chan(chan);
memcpy(&uc->cfg, cfg, sizeof(uc->cfg));
return 0;
}
static struct udma_desc *udma_alloc_tr_desc(struct udma_chan *uc,
size_t tr_size, int tr_count,
enum dma_transfer_direction dir)
{
struct udma_hwdesc *hwdesc;
struct cppi5_desc_hdr_t *tr_desc;
struct udma_desc *d;
u32 reload_count = 0;
u32 ring_id;
switch (tr_size) {
case 16:
case 32:
case 64:
case 128:
break;
default:
dev_err(uc->ud->dev, "Unsupported TR size of %zu\n", tr_size);
return NULL;
}
/* We have only one descriptor containing multiple TRs */
d = kzalloc(sizeof(*d) + sizeof(d->hwdesc[0]), GFP_NOWAIT);
if (!d)
return NULL;
d->sglen = tr_count;
d->hwdesc_count = 1;
hwdesc = &d->hwdesc[0];
/* Allocate memory for DMA ring descriptor */
if (uc->use_dma_pool) {
hwdesc->cppi5_desc_size = uc->config.hdesc_size;
hwdesc->cppi5_desc_vaddr = dma_pool_zalloc(uc->hdesc_pool,
GFP_NOWAIT,
&hwdesc->cppi5_desc_paddr);
} else {
hwdesc->cppi5_desc_size = cppi5_trdesc_calc_size(tr_size,
tr_count);
hwdesc->cppi5_desc_size = ALIGN(hwdesc->cppi5_desc_size,
uc->ud->desc_align);
hwdesc->cppi5_desc_vaddr = dma_alloc_coherent(uc->ud->dev,
hwdesc->cppi5_desc_size,
&hwdesc->cppi5_desc_paddr,
GFP_NOWAIT);
}
if (!hwdesc->cppi5_desc_vaddr) {
kfree(d);
return NULL;
}
/* Start of the TR req records */
hwdesc->tr_req_base = hwdesc->cppi5_desc_vaddr + tr_size;
/* Start address of the TR response array */
hwdesc->tr_resp_base = hwdesc->tr_req_base + tr_size * tr_count;
tr_desc = hwdesc->cppi5_desc_vaddr;
if (uc->cyclic)
reload_count = CPPI5_INFO0_TRDESC_RLDCNT_INFINITE;
if (dir == DMA_DEV_TO_MEM)
ring_id = k3_ringacc_get_ring_id(uc->rflow->r_ring);
else
ring_id = k3_ringacc_get_ring_id(uc->tchan->tc_ring);
cppi5_trdesc_init(tr_desc, tr_count, tr_size, 0, reload_count);
cppi5_desc_set_pktids(tr_desc, uc->id,
CPPI5_INFO1_DESC_FLOWID_DEFAULT);
cppi5_desc_set_retpolicy(tr_desc, 0, ring_id);
return d;
}
/**
* udma_get_tr_counters - calculate TR counters for a given length
* @len: Length of the trasnfer
* @align_to: Preferred alignment
* @tr0_cnt0: First TR icnt0
* @tr0_cnt1: First TR icnt1
* @tr1_cnt0: Second (if used) TR icnt0
*
* For len < SZ_64K only one TR is enough, tr1_cnt0 is not updated
* For len >= SZ_64K two TRs are used in a simple way:
* First TR: SZ_64K-alignment blocks (tr0_cnt0, tr0_cnt1)
* Second TR: the remaining length (tr1_cnt0)
*
* Returns the number of TRs the length needs (1 or 2)
* -EINVAL if the length can not be supported
*/
static int udma_get_tr_counters(size_t len, unsigned long align_to,
u16 *tr0_cnt0, u16 *tr0_cnt1, u16 *tr1_cnt0)
{
if (len < SZ_64K) {
*tr0_cnt0 = len;
*tr0_cnt1 = 1;
return 1;
}
if (align_to > 3)
align_to = 3;
realign:
*tr0_cnt0 = SZ_64K - BIT(align_to);
if (len / *tr0_cnt0 >= SZ_64K) {
if (align_to) {
align_to--;
goto realign;
}
return -EINVAL;
}
*tr0_cnt1 = len / *tr0_cnt0;
*tr1_cnt0 = len % *tr0_cnt0;
return 2;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
static struct udma_desc *
udma_prep_slave_sg_tr(struct udma_chan *uc, struct scatterlist *sgl,
unsigned int sglen, enum dma_transfer_direction dir,
unsigned long tx_flags, void *context)
{
struct scatterlist *sgent;
struct udma_desc *d;
struct cppi5_tr_type1_t *tr_req = NULL;
u16 tr0_cnt0, tr0_cnt1, tr1_cnt0;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
unsigned int i;
size_t tr_size;
int num_tr = 0;
int tr_idx = 0;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (!is_slave_direction(dir)) {
dev_err(uc->ud->dev, "Only slave cyclic is supported\n");
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
return NULL;
}
/* estimate the number of TRs we will need */
for_each_sg(sgl, sgent, sglen, i) {
if (sg_dma_len(sgent) < SZ_64K)
num_tr++;
else
num_tr += 2;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
/* Now allocate and setup the descriptor. */
tr_size = sizeof(struct cppi5_tr_type1_t);
d = udma_alloc_tr_desc(uc, tr_size, num_tr, dir);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (!d)
return NULL;
d->sglen = sglen;
tr_req = d->hwdesc[0].tr_req_base;
for_each_sg(sgl, sgent, sglen, i) {
dma_addr_t sg_addr = sg_dma_address(sgent);
num_tr = udma_get_tr_counters(sg_dma_len(sgent), __ffs(sg_addr),
&tr0_cnt0, &tr0_cnt1, &tr1_cnt0);
if (num_tr < 0) {
dev_err(uc->ud->dev, "size %u is not supported\n",
sg_dma_len(sgent));
udma_free_hwdesc(uc, d);
kfree(d);
return NULL;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
cppi5_tr_init(&tr_req[i].flags, CPPI5_TR_TYPE1, false, false,
CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
cppi5_tr_csf_set(&tr_req[i].flags, CPPI5_TR_CSF_SUPR_EVT);
tr_req[tr_idx].addr = sg_addr;
tr_req[tr_idx].icnt0 = tr0_cnt0;
tr_req[tr_idx].icnt1 = tr0_cnt1;
tr_req[tr_idx].dim1 = tr0_cnt0;
tr_idx++;
if (num_tr == 2) {
cppi5_tr_init(&tr_req[tr_idx].flags, CPPI5_TR_TYPE1,
false, false,
CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
cppi5_tr_csf_set(&tr_req[tr_idx].flags,
CPPI5_TR_CSF_SUPR_EVT);
tr_req[tr_idx].addr = sg_addr + tr0_cnt1 * tr0_cnt0;
tr_req[tr_idx].icnt0 = tr1_cnt0;
tr_req[tr_idx].icnt1 = 1;
tr_req[tr_idx].dim1 = tr1_cnt0;
tr_idx++;
}
d->residue += sg_dma_len(sgent);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
}
cppi5_tr_csf_set(&tr_req[tr_idx - 1].flags, CPPI5_TR_CSF_EOP);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
return d;
}
static int udma_configure_statictr(struct udma_chan *uc, struct udma_desc *d,
enum dma_slave_buswidth dev_width,
u16 elcnt)
{
if (uc->config.ep_type != PSIL_EP_PDMA_XY)
return 0;
/* Bus width translates to the element size (ES) */
switch (dev_width) {
case DMA_SLAVE_BUSWIDTH_1_BYTE:
d->static_tr.elsize = 0;
break;
case DMA_SLAVE_BUSWIDTH_2_BYTES:
d->static_tr.elsize = 1;
break;
case DMA_SLAVE_BUSWIDTH_3_BYTES:
d->static_tr.elsize = 2;
break;
case DMA_SLAVE_BUSWIDTH_4_BYTES:
d->static_tr.elsize = 3;
break;
case DMA_SLAVE_BUSWIDTH_8_BYTES:
d->static_tr.elsize = 4;
break;
default: /* not reached */
return -EINVAL;
}
d->static_tr.elcnt = elcnt;
/*
* PDMA must to close the packet when the channel is in packet mode.
* For TR mode when the channel is not cyclic we also need PDMA to close
* the packet otherwise the transfer will stall because PDMA holds on
* the data it has received from the peripheral.
*/
if (uc->config.pkt_mode || !uc->cyclic) {
unsigned int div = dev_width * elcnt;
if (uc->cyclic)
d->static_tr.bstcnt = d->residue / d->sglen / div;
else
d->static_tr.bstcnt = d->residue / div;
if (uc->config.dir == DMA_DEV_TO_MEM &&
d->static_tr.bstcnt > uc->ud->match_data->statictr_z_mask)
return -EINVAL;
} else {
d->static_tr.bstcnt = 0;
}
return 0;
}
static struct udma_desc *
udma_prep_slave_sg_pkt(struct udma_chan *uc, struct scatterlist *sgl,
unsigned int sglen, enum dma_transfer_direction dir,
unsigned long tx_flags, void *context)
{
struct scatterlist *sgent;
struct cppi5_host_desc_t *h_desc = NULL;
struct udma_desc *d;
u32 ring_id;
unsigned int i;
d = kzalloc(sizeof(*d) + sglen * sizeof(d->hwdesc[0]), GFP_NOWAIT);
if (!d)
return NULL;
d->sglen = sglen;
d->hwdesc_count = sglen;
if (dir == DMA_DEV_TO_MEM)
ring_id = k3_ringacc_get_ring_id(uc->rflow->r_ring);
else
ring_id = k3_ringacc_get_ring_id(uc->tchan->tc_ring);
for_each_sg(sgl, sgent, sglen, i) {
struct udma_hwdesc *hwdesc = &d->hwdesc[i];
dma_addr_t sg_addr = sg_dma_address(sgent);
struct cppi5_host_desc_t *desc;
size_t sg_len = sg_dma_len(sgent);
hwdesc->cppi5_desc_vaddr = dma_pool_zalloc(uc->hdesc_pool,
GFP_NOWAIT,
&hwdesc->cppi5_desc_paddr);
if (!hwdesc->cppi5_desc_vaddr) {
dev_err(uc->ud->dev,
"descriptor%d allocation failed\n", i);
udma_free_hwdesc(uc, d);
kfree(d);
return NULL;
}
d->residue += sg_len;
hwdesc->cppi5_desc_size = uc->config.hdesc_size;
desc = hwdesc->cppi5_desc_vaddr;
if (i == 0) {
cppi5_hdesc_init(desc, 0, 0);
/* Flow and Packed ID */
cppi5_desc_set_pktids(&desc->hdr, uc->id,
CPPI5_INFO1_DESC_FLOWID_DEFAULT);
cppi5_desc_set_retpolicy(&desc->hdr, 0, ring_id);
} else {
cppi5_hdesc_reset_hbdesc(desc);
cppi5_desc_set_retpolicy(&desc->hdr, 0, 0xffff);
}
/* attach the sg buffer to the descriptor */
cppi5_hdesc_attach_buf(desc, sg_addr, sg_len, sg_addr, sg_len);
/* Attach link as host buffer descriptor */
if (h_desc)
cppi5_hdesc_link_hbdesc(h_desc,
hwdesc->cppi5_desc_paddr);
if (dir == DMA_MEM_TO_DEV)
h_desc = desc;
}
if (d->residue >= SZ_4M) {
dev_err(uc->ud->dev,
"%s: Transfer size %u is over the supported 4M range\n",
__func__, d->residue);
udma_free_hwdesc(uc, d);
kfree(d);
return NULL;
}
h_desc = d->hwdesc[0].cppi5_desc_vaddr;
cppi5_hdesc_set_pktlen(h_desc, d->residue);
return d;
}
static int udma_attach_metadata(struct dma_async_tx_descriptor *desc,
void *data, size_t len)
{
struct udma_desc *d = to_udma_desc(desc);
struct udma_chan *uc = to_udma_chan(desc->chan);
struct cppi5_host_desc_t *h_desc;
u32 psd_size = len;
u32 flags = 0;
if (!uc->config.pkt_mode || !uc->config.metadata_size)
return -ENOTSUPP;
if (!data || len > uc->config.metadata_size)
return -EINVAL;
if (uc->config.needs_epib && len < CPPI5_INFO0_HDESC_EPIB_SIZE)
return -EINVAL;
h_desc = d->hwdesc[0].cppi5_desc_vaddr;
if (d->dir == DMA_MEM_TO_DEV)
memcpy(h_desc->epib, data, len);
if (uc->config.needs_epib)
psd_size -= CPPI5_INFO0_HDESC_EPIB_SIZE;
d->metadata = data;
d->metadata_size = len;
if (uc->config.needs_epib)
flags |= CPPI5_INFO0_HDESC_EPIB_PRESENT;
cppi5_hdesc_update_flags(h_desc, flags);
cppi5_hdesc_update_psdata_size(h_desc, psd_size);
return 0;
}
static void *udma_get_metadata_ptr(struct dma_async_tx_descriptor *desc,
size_t *payload_len, size_t *max_len)
{
struct udma_desc *d = to_udma_desc(desc);
struct udma_chan *uc = to_udma_chan(desc->chan);
struct cppi5_host_desc_t *h_desc;
if (!uc->config.pkt_mode || !uc->config.metadata_size)
return ERR_PTR(-ENOTSUPP);
h_desc = d->hwdesc[0].cppi5_desc_vaddr;
*max_len = uc->config.metadata_size;
*payload_len = cppi5_hdesc_epib_present(&h_desc->hdr) ?
CPPI5_INFO0_HDESC_EPIB_SIZE : 0;
*payload_len += cppi5_hdesc_get_psdata_size(h_desc);
return h_desc->epib;
}
static int udma_set_metadata_len(struct dma_async_tx_descriptor *desc,
size_t payload_len)
{
struct udma_desc *d = to_udma_desc(desc);
struct udma_chan *uc = to_udma_chan(desc->chan);
struct cppi5_host_desc_t *h_desc;
u32 psd_size = payload_len;
u32 flags = 0;
if (!uc->config.pkt_mode || !uc->config.metadata_size)
return -ENOTSUPP;
if (payload_len > uc->config.metadata_size)
return -EINVAL;
if (uc->config.needs_epib && payload_len < CPPI5_INFO0_HDESC_EPIB_SIZE)
return -EINVAL;
h_desc = d->hwdesc[0].cppi5_desc_vaddr;
if (uc->config.needs_epib) {
psd_size -= CPPI5_INFO0_HDESC_EPIB_SIZE;
flags |= CPPI5_INFO0_HDESC_EPIB_PRESENT;
}
cppi5_hdesc_update_flags(h_desc, flags);
cppi5_hdesc_update_psdata_size(h_desc, psd_size);
return 0;
}
static struct dma_descriptor_metadata_ops metadata_ops = {
.attach = udma_attach_metadata,
.get_ptr = udma_get_metadata_ptr,
.set_len = udma_set_metadata_len,
};
static struct dma_async_tx_descriptor *
udma_prep_slave_sg(struct dma_chan *chan, struct scatterlist *sgl,
unsigned int sglen, enum dma_transfer_direction dir,
unsigned long tx_flags, void *context)
{
struct udma_chan *uc = to_udma_chan(chan);
enum dma_slave_buswidth dev_width;
struct udma_desc *d;
u32 burst;
if (dir != uc->config.dir) {
dev_err(chan->device->dev,
"%s: chan%d is for %s, not supporting %s\n",
__func__, uc->id,
dmaengine_get_direction_text(uc->config.dir),
dmaengine_get_direction_text(dir));
return NULL;
}
if (dir == DMA_DEV_TO_MEM) {
dev_width = uc->cfg.src_addr_width;
burst = uc->cfg.src_maxburst;
} else if (dir == DMA_MEM_TO_DEV) {
dev_width = uc->cfg.dst_addr_width;
burst = uc->cfg.dst_maxburst;
} else {
dev_err(chan->device->dev, "%s: bad direction?\n", __func__);
return NULL;
}
if (!burst)
burst = 1;
if (uc->config.pkt_mode)
d = udma_prep_slave_sg_pkt(uc, sgl, sglen, dir, tx_flags,
context);
else
d = udma_prep_slave_sg_tr(uc, sgl, sglen, dir, tx_flags,
context);
if (!d)
return NULL;
d->dir = dir;
d->desc_idx = 0;
d->tr_idx = 0;
/* static TR for remote PDMA */
if (udma_configure_statictr(uc, d, dev_width, burst)) {
dev_err(uc->ud->dev,
"%s: StaticTR Z is limited to maximum 4095 (%u)\n",
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
__func__, d->static_tr.bstcnt);
udma_free_hwdesc(uc, d);
kfree(d);
return NULL;
}
if (uc->config.metadata_size)
d->vd.tx.metadata_ops = &metadata_ops;
return vchan_tx_prep(&uc->vc, &d->vd, tx_flags);
}
static struct udma_desc *
udma_prep_dma_cyclic_tr(struct udma_chan *uc, dma_addr_t buf_addr,
size_t buf_len, size_t period_len,
enum dma_transfer_direction dir, unsigned long flags)
{
struct udma_desc *d;
size_t tr_size, period_addr;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
struct cppi5_tr_type1_t *tr_req;
unsigned int periods = buf_len / period_len;
u16 tr0_cnt0, tr0_cnt1, tr1_cnt0;
unsigned int i;
int num_tr;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (!is_slave_direction(dir)) {
dev_err(uc->ud->dev, "Only slave cyclic is supported\n");
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
return NULL;
}
num_tr = udma_get_tr_counters(period_len, __ffs(buf_addr), &tr0_cnt0,
&tr0_cnt1, &tr1_cnt0);
if (num_tr < 0) {
dev_err(uc->ud->dev, "size %zu is not supported\n",
period_len);
return NULL;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
/* Now allocate and setup the descriptor. */
tr_size = sizeof(struct cppi5_tr_type1_t);
d = udma_alloc_tr_desc(uc, tr_size, periods * num_tr, dir);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (!d)
return NULL;
tr_req = d->hwdesc[0].tr_req_base;
period_addr = buf_addr;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
for (i = 0; i < periods; i++) {
int tr_idx = i * num_tr;
cppi5_tr_init(&tr_req[tr_idx].flags, CPPI5_TR_TYPE1, false,
false, CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
tr_req[tr_idx].addr = period_addr;
tr_req[tr_idx].icnt0 = tr0_cnt0;
tr_req[tr_idx].icnt1 = tr0_cnt1;
tr_req[tr_idx].dim1 = tr0_cnt0;
if (num_tr == 2) {
cppi5_tr_csf_set(&tr_req[tr_idx].flags,
CPPI5_TR_CSF_SUPR_EVT);
tr_idx++;
cppi5_tr_init(&tr_req[tr_idx].flags, CPPI5_TR_TYPE1,
false, false,
CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
tr_req[tr_idx].addr = period_addr + tr0_cnt1 * tr0_cnt0;
tr_req[tr_idx].icnt0 = tr1_cnt0;
tr_req[tr_idx].icnt1 = 1;
tr_req[tr_idx].dim1 = tr1_cnt0;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
if (!(flags & DMA_PREP_INTERRUPT))
cppi5_tr_csf_set(&tr_req[tr_idx].flags,
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
CPPI5_TR_CSF_SUPR_EVT);
period_addr += period_len;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
}
return d;
}
static struct udma_desc *
udma_prep_dma_cyclic_pkt(struct udma_chan *uc, dma_addr_t buf_addr,
size_t buf_len, size_t period_len,
enum dma_transfer_direction dir, unsigned long flags)
{
struct udma_desc *d;
u32 ring_id;
int i;
int periods = buf_len / period_len;
if (periods > (K3_UDMA_DEFAULT_RING_SIZE - 1))
return NULL;
if (period_len >= SZ_4M)
return NULL;
d = kzalloc(sizeof(*d) + periods * sizeof(d->hwdesc[0]), GFP_NOWAIT);
if (!d)
return NULL;
d->hwdesc_count = periods;
/* TODO: re-check this... */
if (dir == DMA_DEV_TO_MEM)
ring_id = k3_ringacc_get_ring_id(uc->rflow->r_ring);
else
ring_id = k3_ringacc_get_ring_id(uc->tchan->tc_ring);
for (i = 0; i < periods; i++) {
struct udma_hwdesc *hwdesc = &d->hwdesc[i];
dma_addr_t period_addr = buf_addr + (period_len * i);
struct cppi5_host_desc_t *h_desc;
hwdesc->cppi5_desc_vaddr = dma_pool_zalloc(uc->hdesc_pool,
GFP_NOWAIT,
&hwdesc->cppi5_desc_paddr);
if (!hwdesc->cppi5_desc_vaddr) {
dev_err(uc->ud->dev,
"descriptor%d allocation failed\n", i);
udma_free_hwdesc(uc, d);
kfree(d);
return NULL;
}
hwdesc->cppi5_desc_size = uc->config.hdesc_size;
h_desc = hwdesc->cppi5_desc_vaddr;
cppi5_hdesc_init(h_desc, 0, 0);
cppi5_hdesc_set_pktlen(h_desc, period_len);
/* Flow and Packed ID */
cppi5_desc_set_pktids(&h_desc->hdr, uc->id,
CPPI5_INFO1_DESC_FLOWID_DEFAULT);
cppi5_desc_set_retpolicy(&h_desc->hdr, 0, ring_id);
/* attach each period to a new descriptor */
cppi5_hdesc_attach_buf(h_desc,
period_addr, period_len,
period_addr, period_len);
}
return d;
}
static struct dma_async_tx_descriptor *
udma_prep_dma_cyclic(struct dma_chan *chan, dma_addr_t buf_addr, size_t buf_len,
size_t period_len, enum dma_transfer_direction dir,
unsigned long flags)
{
struct udma_chan *uc = to_udma_chan(chan);
enum dma_slave_buswidth dev_width;
struct udma_desc *d;
u32 burst;
if (dir != uc->config.dir) {
dev_err(chan->device->dev,
"%s: chan%d is for %s, not supporting %s\n",
__func__, uc->id,
dmaengine_get_direction_text(uc->config.dir),
dmaengine_get_direction_text(dir));
return NULL;
}
uc->cyclic = true;
if (dir == DMA_DEV_TO_MEM) {
dev_width = uc->cfg.src_addr_width;
burst = uc->cfg.src_maxburst;
} else if (dir == DMA_MEM_TO_DEV) {
dev_width = uc->cfg.dst_addr_width;
burst = uc->cfg.dst_maxburst;
} else {
dev_err(uc->ud->dev, "%s: bad direction?\n", __func__);
return NULL;
}
if (!burst)
burst = 1;
if (uc->config.pkt_mode)
d = udma_prep_dma_cyclic_pkt(uc, buf_addr, buf_len, period_len,
dir, flags);
else
d = udma_prep_dma_cyclic_tr(uc, buf_addr, buf_len, period_len,
dir, flags);
if (!d)
return NULL;
d->sglen = buf_len / period_len;
d->dir = dir;
d->residue = buf_len;
/* static TR for remote PDMA */
if (udma_configure_statictr(uc, d, dev_width, burst)) {
dev_err(uc->ud->dev,
"%s: StaticTR Z is limited to maximum 4095 (%u)\n",
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
__func__, d->static_tr.bstcnt);
udma_free_hwdesc(uc, d);
kfree(d);
return NULL;
}
if (uc->config.metadata_size)
d->vd.tx.metadata_ops = &metadata_ops;
return vchan_tx_prep(&uc->vc, &d->vd, flags);
}
static struct dma_async_tx_descriptor *
udma_prep_dma_memcpy(struct dma_chan *chan, dma_addr_t dest, dma_addr_t src,
size_t len, unsigned long tx_flags)
{
struct udma_chan *uc = to_udma_chan(chan);
struct udma_desc *d;
struct cppi5_tr_type15_t *tr_req;
int num_tr;
size_t tr_size = sizeof(struct cppi5_tr_type15_t);
u16 tr0_cnt0, tr0_cnt1, tr1_cnt0;
if (uc->config.dir != DMA_MEM_TO_MEM) {
dev_err(chan->device->dev,
"%s: chan%d is for %s, not supporting %s\n",
__func__, uc->id,
dmaengine_get_direction_text(uc->config.dir),
dmaengine_get_direction_text(DMA_MEM_TO_MEM));
return NULL;
}
num_tr = udma_get_tr_counters(len, __ffs(src | dest), &tr0_cnt0,
&tr0_cnt1, &tr1_cnt0);
if (num_tr < 0) {
dev_err(uc->ud->dev, "size %zu is not supported\n",
len);
return NULL;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
}
d = udma_alloc_tr_desc(uc, tr_size, num_tr, DMA_MEM_TO_MEM);
if (!d)
return NULL;
d->dir = DMA_MEM_TO_MEM;
d->desc_idx = 0;
d->tr_idx = 0;
d->residue = len;
tr_req = d->hwdesc[0].tr_req_base;
cppi5_tr_init(&tr_req[0].flags, CPPI5_TR_TYPE15, false, true,
CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
cppi5_tr_csf_set(&tr_req[0].flags, CPPI5_TR_CSF_SUPR_EVT);
tr_req[0].addr = src;
tr_req[0].icnt0 = tr0_cnt0;
tr_req[0].icnt1 = tr0_cnt1;
tr_req[0].icnt2 = 1;
tr_req[0].icnt3 = 1;
tr_req[0].dim1 = tr0_cnt0;
tr_req[0].daddr = dest;
tr_req[0].dicnt0 = tr0_cnt0;
tr_req[0].dicnt1 = tr0_cnt1;
tr_req[0].dicnt2 = 1;
tr_req[0].dicnt3 = 1;
tr_req[0].ddim1 = tr0_cnt0;
if (num_tr == 2) {
cppi5_tr_init(&tr_req[1].flags, CPPI5_TR_TYPE15, false, true,
CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
cppi5_tr_csf_set(&tr_req[1].flags, CPPI5_TR_CSF_SUPR_EVT);
tr_req[1].addr = src + tr0_cnt1 * tr0_cnt0;
tr_req[1].icnt0 = tr1_cnt0;
tr_req[1].icnt1 = 1;
tr_req[1].icnt2 = 1;
tr_req[1].icnt3 = 1;
tr_req[1].daddr = dest + tr0_cnt1 * tr0_cnt0;
tr_req[1].dicnt0 = tr1_cnt0;
tr_req[1].dicnt1 = 1;
tr_req[1].dicnt2 = 1;
tr_req[1].dicnt3 = 1;
}
cppi5_tr_csf_set(&tr_req[num_tr - 1].flags, CPPI5_TR_CSF_EOP);
if (uc->config.metadata_size)
d->vd.tx.metadata_ops = &metadata_ops;
return vchan_tx_prep(&uc->vc, &d->vd, tx_flags);
}
static void udma_issue_pending(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
unsigned long flags;
spin_lock_irqsave(&uc->vc.lock, flags);
/* If we have something pending and no active descriptor, then */
if (vchan_issue_pending(&uc->vc) && !uc->desc) {
/*
* start a descriptor if the channel is NOT [marked as
* terminating _and_ it is still running (teardown has not
* completed yet)].
*/
if (!(uc->state == UDMA_CHAN_IS_TERMINATING &&
udma_is_chan_running(uc)))
udma_start(uc);
}
spin_unlock_irqrestore(&uc->vc.lock, flags);
}
static enum dma_status udma_tx_status(struct dma_chan *chan,
dma_cookie_t cookie,
struct dma_tx_state *txstate)
{
struct udma_chan *uc = to_udma_chan(chan);
enum dma_status ret;
unsigned long flags;
spin_lock_irqsave(&uc->vc.lock, flags);
ret = dma_cookie_status(chan, cookie, txstate);
if (ret == DMA_IN_PROGRESS && udma_is_chan_paused(uc))
ret = DMA_PAUSED;
if (ret == DMA_COMPLETE || !txstate)
goto out;
if (uc->desc && uc->desc->vd.tx.cookie == cookie) {
u32 peer_bcnt = 0;
u32 bcnt = 0;
u32 residue = uc->desc->residue;
u32 delay = 0;
if (uc->desc->dir == DMA_MEM_TO_DEV) {
bcnt = udma_tchanrt_read(uc->tchan,
UDMA_TCHAN_RT_SBCNT_REG);
if (uc->config.ep_type != PSIL_EP_NATIVE) {
peer_bcnt = udma_tchanrt_read(uc->tchan,
UDMA_TCHAN_RT_PEER_BCNT_REG);
if (bcnt > peer_bcnt)
delay = bcnt - peer_bcnt;
}
} else if (uc->desc->dir == DMA_DEV_TO_MEM) {
bcnt = udma_rchanrt_read(uc->rchan,
UDMA_RCHAN_RT_BCNT_REG);
if (uc->config.ep_type != PSIL_EP_NATIVE) {
peer_bcnt = udma_rchanrt_read(uc->rchan,
UDMA_RCHAN_RT_PEER_BCNT_REG);
if (peer_bcnt > bcnt)
delay = peer_bcnt - bcnt;
}
} else {
bcnt = udma_tchanrt_read(uc->tchan,
UDMA_TCHAN_RT_BCNT_REG);
}
bcnt -= uc->bcnt;
if (bcnt && !(bcnt % uc->desc->residue))
residue = 0;
else
residue -= bcnt % uc->desc->residue;
if (!residue && (uc->config.dir == DMA_DEV_TO_MEM || !delay)) {
ret = DMA_COMPLETE;
delay = 0;
}
dma_set_residue(txstate, residue);
dma_set_in_flight_bytes(txstate, delay);
} else {
ret = DMA_COMPLETE;
}
out:
spin_unlock_irqrestore(&uc->vc.lock, flags);
return ret;
}
static int udma_pause(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
/* pause the channel */
switch (uc->config.dir) {
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
case DMA_DEV_TO_MEM:
udma_rchanrt_update_bits(uc->rchan,
UDMA_RCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_PAUSE,
UDMA_PEER_RT_EN_PAUSE);
break;
case DMA_MEM_TO_DEV:
udma_tchanrt_update_bits(uc->tchan,
UDMA_TCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_PAUSE,
UDMA_PEER_RT_EN_PAUSE);
break;
case DMA_MEM_TO_MEM:
udma_tchanrt_update_bits(uc->tchan, UDMA_TCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_PAUSE,
UDMA_CHAN_RT_CTL_PAUSE);
break;
default:
return -EINVAL;
}
return 0;
}
static int udma_resume(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
/* resume the channel */
switch (uc->config.dir) {
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
case DMA_DEV_TO_MEM:
udma_rchanrt_update_bits(uc->rchan,
UDMA_RCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_PAUSE, 0);
break;
case DMA_MEM_TO_DEV:
udma_tchanrt_update_bits(uc->tchan,
UDMA_TCHAN_RT_PEER_RT_EN_REG,
UDMA_PEER_RT_EN_PAUSE, 0);
break;
case DMA_MEM_TO_MEM:
udma_tchanrt_update_bits(uc->tchan, UDMA_TCHAN_RT_CTL_REG,
UDMA_CHAN_RT_CTL_PAUSE, 0);
break;
default:
return -EINVAL;
}
return 0;
}
static int udma_terminate_all(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
unsigned long flags;
LIST_HEAD(head);
spin_lock_irqsave(&uc->vc.lock, flags);
if (udma_is_chan_running(uc))
udma_stop(uc);
if (uc->desc) {
uc->terminated_desc = uc->desc;
uc->desc = NULL;
uc->terminated_desc->terminated = true;
cancel_delayed_work(&uc->tx_drain.work);
}
uc->paused = false;
vchan_get_all_descriptors(&uc->vc, &head);
spin_unlock_irqrestore(&uc->vc.lock, flags);
vchan_dma_desc_free_list(&uc->vc, &head);
return 0;
}
static void udma_synchronize(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
unsigned long timeout = msecs_to_jiffies(1000);
vchan_synchronize(&uc->vc);
if (uc->state == UDMA_CHAN_IS_TERMINATING) {
timeout = wait_for_completion_timeout(&uc->teardown_completed,
timeout);
if (!timeout) {
dev_warn(uc->ud->dev, "chan%d teardown timeout!\n",
uc->id);
udma_dump_chan_stdata(uc);
udma_reset_chan(uc, true);
}
}
udma_reset_chan(uc, false);
if (udma_is_chan_running(uc))
dev_warn(uc->ud->dev, "chan%d refused to stop!\n", uc->id);
cancel_delayed_work_sync(&uc->tx_drain.work);
udma_reset_rings(uc);
}
static void udma_desc_pre_callback(struct virt_dma_chan *vc,
struct virt_dma_desc *vd,
struct dmaengine_result *result)
{
struct udma_chan *uc = to_udma_chan(&vc->chan);
struct udma_desc *d;
if (!vd)
return;
d = to_udma_desc(&vd->tx);
if (d->metadata_size)
udma_fetch_epib(uc, d);
/* Provide residue information for the client */
if (result) {
void *desc_vaddr = udma_curr_cppi5_desc_vaddr(d, d->desc_idx);
if (cppi5_desc_get_type(desc_vaddr) ==
CPPI5_INFO0_DESC_TYPE_VAL_HOST) {
result->residue = d->residue -
cppi5_hdesc_get_pktlen(desc_vaddr);
if (result->residue)
result->result = DMA_TRANS_ABORTED;
else
result->result = DMA_TRANS_NOERROR;
} else {
result->residue = 0;
result->result = DMA_TRANS_NOERROR;
}
}
}
/*
* This tasklet handles the completion of a DMA descriptor by
* calling its callback and freeing it.
*/
static void udma_vchan_complete(unsigned long arg)
{
struct virt_dma_chan *vc = (struct virt_dma_chan *)arg;
struct virt_dma_desc *vd, *_vd;
struct dmaengine_desc_callback cb;
LIST_HEAD(head);
spin_lock_irq(&vc->lock);
list_splice_tail_init(&vc->desc_completed, &head);
vd = vc->cyclic;
if (vd) {
vc->cyclic = NULL;
dmaengine_desc_get_callback(&vd->tx, &cb);
} else {
memset(&cb, 0, sizeof(cb));
}
spin_unlock_irq(&vc->lock);
udma_desc_pre_callback(vc, vd, NULL);
dmaengine_desc_callback_invoke(&cb, NULL);
list_for_each_entry_safe(vd, _vd, &head, node) {
struct dmaengine_result result;
dmaengine_desc_get_callback(&vd->tx, &cb);
list_del(&vd->node);
udma_desc_pre_callback(vc, vd, &result);
dmaengine_desc_callback_invoke(&cb, &result);
vchan_vdesc_fini(vd);
}
}
static void udma_free_chan_resources(struct dma_chan *chan)
{
struct udma_chan *uc = to_udma_chan(chan);
struct udma_dev *ud = to_udma_dev(chan->device);
udma_terminate_all(chan);
if (uc->terminated_desc) {
udma_reset_chan(uc, false);
udma_reset_rings(uc);
}
cancel_delayed_work_sync(&uc->tx_drain.work);
destroy_delayed_work_on_stack(&uc->tx_drain.work);
if (uc->irq_num_ring > 0) {
free_irq(uc->irq_num_ring, uc);
uc->irq_num_ring = 0;
}
if (uc->irq_num_udma > 0) {
free_irq(uc->irq_num_udma, uc);
uc->irq_num_udma = 0;
}
/* Release PSI-L pairing */
if (uc->psil_paired) {
navss_psil_unpair(ud, uc->config.src_thread,
uc->config.dst_thread);
uc->psil_paired = false;
}
vchan_free_chan_resources(&uc->vc);
tasklet_kill(&uc->vc.task);
udma_free_tx_resources(uc);
udma_free_rx_resources(uc);
udma_reset_uchan(uc);
if (uc->use_dma_pool) {
dma_pool_destroy(uc->hdesc_pool);
uc->use_dma_pool = false;
}
}
static struct platform_driver udma_driver;
static bool udma_dma_filter_fn(struct dma_chan *chan, void *param)
{
struct udma_chan_config *ucc;
struct psil_endpoint_config *ep_config;
struct udma_chan *uc;
struct udma_dev *ud;
u32 *args;
if (chan->device->dev->driver != &udma_driver.driver)
return false;
uc = to_udma_chan(chan);
ucc = &uc->config;
ud = uc->ud;
args = param;
ucc->remote_thread_id = args[0];
if (ucc->remote_thread_id & K3_PSIL_DST_THREAD_ID_OFFSET)
ucc->dir = DMA_MEM_TO_DEV;
else
ucc->dir = DMA_DEV_TO_MEM;
ep_config = psil_get_ep_config(ucc->remote_thread_id);
if (IS_ERR(ep_config)) {
dev_err(ud->dev, "No configuration for psi-l thread 0x%04x\n",
ucc->remote_thread_id);
ucc->dir = DMA_MEM_TO_MEM;
ucc->remote_thread_id = -1;
return false;
}
ucc->pkt_mode = ep_config->pkt_mode;
ucc->channel_tpl = ep_config->channel_tpl;
ucc->notdpkt = ep_config->notdpkt;
ucc->ep_type = ep_config->ep_type;
if (ucc->ep_type != PSIL_EP_NATIVE) {
const struct udma_match_data *match_data = ud->match_data;
if (match_data->flags & UDMA_FLAG_PDMA_ACC32)
ucc->enable_acc32 = ep_config->pdma_acc32;
if (match_data->flags & UDMA_FLAG_PDMA_BURST)
ucc->enable_burst = ep_config->pdma_burst;
}
ucc->needs_epib = ep_config->needs_epib;
ucc->psd_size = ep_config->psd_size;
ucc->metadata_size =
(ucc->needs_epib ? CPPI5_INFO0_HDESC_EPIB_SIZE : 0) +
ucc->psd_size;
if (ucc->pkt_mode)
ucc->hdesc_size = ALIGN(sizeof(struct cppi5_host_desc_t) +
ucc->metadata_size, ud->desc_align);
dev_dbg(ud->dev, "chan%d: Remote thread: 0x%04x (%s)\n", uc->id,
ucc->remote_thread_id, dmaengine_get_direction_text(ucc->dir));
return true;
}
static struct dma_chan *udma_of_xlate(struct of_phandle_args *dma_spec,
struct of_dma *ofdma)
{
struct udma_dev *ud = ofdma->of_dma_data;
dma_cap_mask_t mask = ud->ddev.cap_mask;
struct dma_chan *chan;
if (dma_spec->args_count != 1)
return NULL;
chan = __dma_request_channel(&mask, udma_dma_filter_fn,
&dma_spec->args[0], ofdma->of_node);
if (!chan) {
dev_err(ud->dev, "get channel fail in %s.\n", __func__);
return ERR_PTR(-EINVAL);
}
return chan;
}
static struct udma_match_data am654_main_data = {
.psil_base = 0x1000,
.enable_memcpy_support = true,
.statictr_z_mask = GENMASK(11, 0),
.rchan_oes_offset = 0x2000,
.tpl_levels = 2,
.level_start_idx = {
[0] = 8, /* Normal channels */
[1] = 0, /* High Throughput channels */
},
};
static struct udma_match_data am654_mcu_data = {
.psil_base = 0x6000,
dmaengine: ti: k3-udma: Add glue layer for non DMAengine users Certain users can not use right now the DMAengine API due to missing features in the core. Prime example is Networking. These users can use the glue layer interface to avoid misuse of DMAengine API and when the core gains the needed features they can be converted to use generic API. The most prominent features the glue layer clients are depending on: - most PSI-L native peripheral use extra rflow ranges on a receive channel and depending on the peripheral's configuration packets from a single free descriptor ring is going to be received to different receive ring - it is also possible to have different free descriptor rings per rflow and an rflow can also support 4 additional free descriptor ring based on the size of the incoming packet - out of order completion of descriptors on a channel - when we have several queues to handle different priority packets the descriptors will be completed 'out-of-order' - the notion of prep_slave_sg is not matching with what the streaming type of operation is demanding for networking - Streaming type of operation - Ability to fill the free descriptor ring with descriptors in anticipation of incoming traffic and when a packet arrives UDMAP will form a packet and gives it to the client driver - the descriptors are not backed with exact size data buffers as we don't know the size of the packet we will receive, but as a generic pool of buffers to be used by the receive channel - NAPI type of operation (polling instead of interrupt driven transfer) - without this we can not sustain gigabit speeds and we need to support NAPI - not to limit this to networking, but other high performance operations Signed-off-by: Grygorii Strashko <grygorii.strashko@ti.com> Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-12-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:51 +07:00
.enable_memcpy_support = true, /* TEST: DMA domains */
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
.statictr_z_mask = GENMASK(11, 0),
.rchan_oes_offset = 0x2000,
.tpl_levels = 2,
.level_start_idx = {
[0] = 2, /* Normal channels */
[1] = 0, /* High Throughput channels */
},
};
static struct udma_match_data j721e_main_data = {
.psil_base = 0x1000,
.enable_memcpy_support = true,
.flags = UDMA_FLAG_PDMA_ACC32 | UDMA_FLAG_PDMA_BURST,
.statictr_z_mask = GENMASK(23, 0),
.rchan_oes_offset = 0x400,
.tpl_levels = 3,
.level_start_idx = {
[0] = 16, /* Normal channels */
[1] = 4, /* High Throughput channels */
[2] = 0, /* Ultra High Throughput channels */
},
};
static struct udma_match_data j721e_mcu_data = {
.psil_base = 0x6000,
.enable_memcpy_support = false, /* MEM_TO_MEM is slow via MCU UDMA */
.flags = UDMA_FLAG_PDMA_ACC32 | UDMA_FLAG_PDMA_BURST,
.statictr_z_mask = GENMASK(23, 0),
.rchan_oes_offset = 0x400,
.tpl_levels = 2,
.level_start_idx = {
[0] = 2, /* Normal channels */
[1] = 0, /* High Throughput channels */
},
};
static const struct of_device_id udma_of_match[] = {
{
.compatible = "ti,am654-navss-main-udmap",
.data = &am654_main_data,
},
{
.compatible = "ti,am654-navss-mcu-udmap",
.data = &am654_mcu_data,
}, {
.compatible = "ti,j721e-navss-main-udmap",
.data = &j721e_main_data,
}, {
.compatible = "ti,j721e-navss-mcu-udmap",
.data = &j721e_mcu_data,
},
{ /* Sentinel */ },
};
static int udma_get_mmrs(struct platform_device *pdev, struct udma_dev *ud)
{
struct resource *res;
int i;
for (i = 0; i < MMR_LAST; i++) {
res = platform_get_resource_byname(pdev, IORESOURCE_MEM,
mmr_names[i]);
ud->mmrs[i] = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(ud->mmrs[i]))
return PTR_ERR(ud->mmrs[i]);
}
return 0;
}
static int udma_setup_resources(struct udma_dev *ud)
{
struct device *dev = ud->dev;
int ch_count, ret, i, j;
u32 cap2, cap3;
struct ti_sci_resource_desc *rm_desc;
struct ti_sci_resource *rm_res, irq_res;
struct udma_tisci_rm *tisci_rm = &ud->tisci_rm;
static const char * const range_names[] = { "ti,sci-rm-range-tchan",
"ti,sci-rm-range-rchan",
"ti,sci-rm-range-rflow" };
cap2 = udma_read(ud->mmrs[MMR_GCFG], 0x28);
cap3 = udma_read(ud->mmrs[MMR_GCFG], 0x2c);
ud->rflow_cnt = cap3 & 0x3fff;
ud->tchan_cnt = cap2 & 0x1ff;
ud->echan_cnt = (cap2 >> 9) & 0x1ff;
ud->rchan_cnt = (cap2 >> 18) & 0x1ff;
ch_count = ud->tchan_cnt + ud->rchan_cnt;
ud->tchan_map = devm_kmalloc_array(dev, BITS_TO_LONGS(ud->tchan_cnt),
sizeof(unsigned long), GFP_KERNEL);
ud->tchans = devm_kcalloc(dev, ud->tchan_cnt, sizeof(*ud->tchans),
GFP_KERNEL);
ud->rchan_map = devm_kmalloc_array(dev, BITS_TO_LONGS(ud->rchan_cnt),
sizeof(unsigned long), GFP_KERNEL);
ud->rchans = devm_kcalloc(dev, ud->rchan_cnt, sizeof(*ud->rchans),
GFP_KERNEL);
ud->rflow_gp_map = devm_kmalloc_array(dev, BITS_TO_LONGS(ud->rflow_cnt),
sizeof(unsigned long),
GFP_KERNEL);
ud->rflow_gp_map_allocated = devm_kcalloc(dev,
BITS_TO_LONGS(ud->rflow_cnt),
sizeof(unsigned long),
GFP_KERNEL);
ud->rflow_in_use = devm_kcalloc(dev, BITS_TO_LONGS(ud->rflow_cnt),
sizeof(unsigned long),
GFP_KERNEL);
ud->rflows = devm_kcalloc(dev, ud->rflow_cnt, sizeof(*ud->rflows),
GFP_KERNEL);
if (!ud->tchan_map || !ud->rchan_map || !ud->rflow_gp_map ||
!ud->rflow_gp_map_allocated || !ud->tchans || !ud->rchans ||
!ud->rflows || !ud->rflow_in_use)
return -ENOMEM;
/*
* RX flows with the same Ids as RX channels are reserved to be used
* as default flows if remote HW can't generate flow_ids. Those
* RX flows can be requested only explicitly by id.
*/
bitmap_set(ud->rflow_gp_map_allocated, 0, ud->rchan_cnt);
/* by default no GP rflows are assigned to Linux */
bitmap_set(ud->rflow_gp_map, 0, ud->rflow_cnt);
/* Get resource ranges from tisci */
for (i = 0; i < RM_RANGE_LAST; i++)
tisci_rm->rm_ranges[i] =
devm_ti_sci_get_of_resource(tisci_rm->tisci, dev,
tisci_rm->tisci_dev_id,
(char *)range_names[i]);
/* tchan ranges */
rm_res = tisci_rm->rm_ranges[RM_RANGE_TCHAN];
if (IS_ERR(rm_res)) {
bitmap_zero(ud->tchan_map, ud->tchan_cnt);
} else {
bitmap_fill(ud->tchan_map, ud->tchan_cnt);
for (i = 0; i < rm_res->sets; i++) {
rm_desc = &rm_res->desc[i];
bitmap_clear(ud->tchan_map, rm_desc->start,
rm_desc->num);
dev_dbg(dev, "ti-sci-res: tchan: %d:%d\n",
rm_desc->start, rm_desc->num);
}
}
irq_res.sets = rm_res->sets;
/* rchan and matching default flow ranges */
rm_res = tisci_rm->rm_ranges[RM_RANGE_RCHAN];
if (IS_ERR(rm_res)) {
bitmap_zero(ud->rchan_map, ud->rchan_cnt);
} else {
bitmap_fill(ud->rchan_map, ud->rchan_cnt);
for (i = 0; i < rm_res->sets; i++) {
rm_desc = &rm_res->desc[i];
bitmap_clear(ud->rchan_map, rm_desc->start,
rm_desc->num);
dev_dbg(dev, "ti-sci-res: rchan: %d:%d\n",
rm_desc->start, rm_desc->num);
}
}
irq_res.sets += rm_res->sets;
irq_res.desc = kcalloc(irq_res.sets, sizeof(*irq_res.desc), GFP_KERNEL);
rm_res = tisci_rm->rm_ranges[RM_RANGE_TCHAN];
for (i = 0; i < rm_res->sets; i++) {
irq_res.desc[i].start = rm_res->desc[i].start;
irq_res.desc[i].num = rm_res->desc[i].num;
}
rm_res = tisci_rm->rm_ranges[RM_RANGE_RCHAN];
for (j = 0; j < rm_res->sets; j++, i++) {
irq_res.desc[i].start = rm_res->desc[j].start +
ud->match_data->rchan_oes_offset;
irq_res.desc[i].num = rm_res->desc[j].num;
}
ret = ti_sci_inta_msi_domain_alloc_irqs(ud->dev, &irq_res);
kfree(irq_res.desc);
if (ret) {
dev_err(ud->dev, "Failed to allocate MSI interrupts\n");
return ret;
}
/* GP rflow ranges */
rm_res = tisci_rm->rm_ranges[RM_RANGE_RFLOW];
if (IS_ERR(rm_res)) {
/* all gp flows are assigned exclusively to Linux */
bitmap_clear(ud->rflow_gp_map, ud->rchan_cnt,
ud->rflow_cnt - ud->rchan_cnt);
} else {
for (i = 0; i < rm_res->sets; i++) {
rm_desc = &rm_res->desc[i];
bitmap_clear(ud->rflow_gp_map, rm_desc->start,
rm_desc->num);
dev_dbg(dev, "ti-sci-res: rflow: %d:%d\n",
rm_desc->start, rm_desc->num);
}
}
ch_count -= bitmap_weight(ud->tchan_map, ud->tchan_cnt);
ch_count -= bitmap_weight(ud->rchan_map, ud->rchan_cnt);
if (!ch_count)
return -ENODEV;
ud->channels = devm_kcalloc(dev, ch_count, sizeof(*ud->channels),
GFP_KERNEL);
if (!ud->channels)
return -ENOMEM;
dev_info(dev, "Channels: %d (tchan: %u, rchan: %u, gp-rflow: %u)\n",
ch_count,
ud->tchan_cnt - bitmap_weight(ud->tchan_map, ud->tchan_cnt),
ud->rchan_cnt - bitmap_weight(ud->rchan_map, ud->rchan_cnt),
ud->rflow_cnt - bitmap_weight(ud->rflow_gp_map,
ud->rflow_cnt));
return ch_count;
}
static int udma_setup_rx_flush(struct udma_dev *ud)
{
struct udma_rx_flush *rx_flush = &ud->rx_flush;
struct cppi5_desc_hdr_t *tr_desc;
struct cppi5_tr_type1_t *tr_req;
struct cppi5_host_desc_t *desc;
struct device *dev = ud->dev;
struct udma_hwdesc *hwdesc;
size_t tr_size;
/* Allocate 1K buffer for discarded data on RX channel teardown */
rx_flush->buffer_size = SZ_1K;
rx_flush->buffer_vaddr = devm_kzalloc(dev, rx_flush->buffer_size,
GFP_KERNEL);
if (!rx_flush->buffer_vaddr)
return -ENOMEM;
rx_flush->buffer_paddr = dma_map_single(dev, rx_flush->buffer_vaddr,
rx_flush->buffer_size,
DMA_TO_DEVICE);
if (dma_mapping_error(dev, rx_flush->buffer_paddr))
return -ENOMEM;
/* Set up descriptor to be used for TR mode */
hwdesc = &rx_flush->hwdescs[0];
tr_size = sizeof(struct cppi5_tr_type1_t);
hwdesc->cppi5_desc_size = cppi5_trdesc_calc_size(tr_size, 1);
hwdesc->cppi5_desc_size = ALIGN(hwdesc->cppi5_desc_size,
ud->desc_align);
hwdesc->cppi5_desc_vaddr = devm_kzalloc(dev, hwdesc->cppi5_desc_size,
GFP_KERNEL);
if (!hwdesc->cppi5_desc_vaddr)
return -ENOMEM;
hwdesc->cppi5_desc_paddr = dma_map_single(dev, hwdesc->cppi5_desc_vaddr,
hwdesc->cppi5_desc_size,
DMA_TO_DEVICE);
if (dma_mapping_error(dev, hwdesc->cppi5_desc_paddr))
return -ENOMEM;
/* Start of the TR req records */
hwdesc->tr_req_base = hwdesc->cppi5_desc_vaddr + tr_size;
/* Start address of the TR response array */
hwdesc->tr_resp_base = hwdesc->tr_req_base + tr_size;
tr_desc = hwdesc->cppi5_desc_vaddr;
cppi5_trdesc_init(tr_desc, 1, tr_size, 0, 0);
cppi5_desc_set_pktids(tr_desc, 0, CPPI5_INFO1_DESC_FLOWID_DEFAULT);
cppi5_desc_set_retpolicy(tr_desc, 0, 0);
tr_req = hwdesc->tr_req_base;
cppi5_tr_init(&tr_req->flags, CPPI5_TR_TYPE1, false, false,
CPPI5_TR_EVENT_SIZE_COMPLETION, 0);
cppi5_tr_csf_set(&tr_req->flags, CPPI5_TR_CSF_SUPR_EVT);
tr_req->addr = rx_flush->buffer_paddr;
tr_req->icnt0 = rx_flush->buffer_size;
tr_req->icnt1 = 1;
/* Set up descriptor to be used for packet mode */
hwdesc = &rx_flush->hwdescs[1];
hwdesc->cppi5_desc_size = ALIGN(sizeof(struct cppi5_host_desc_t) +
CPPI5_INFO0_HDESC_EPIB_SIZE +
CPPI5_INFO0_HDESC_PSDATA_MAX_SIZE,
ud->desc_align);
hwdesc->cppi5_desc_vaddr = devm_kzalloc(dev, hwdesc->cppi5_desc_size,
GFP_KERNEL);
if (!hwdesc->cppi5_desc_vaddr)
return -ENOMEM;
hwdesc->cppi5_desc_paddr = dma_map_single(dev, hwdesc->cppi5_desc_vaddr,
hwdesc->cppi5_desc_size,
DMA_TO_DEVICE);
if (dma_mapping_error(dev, hwdesc->cppi5_desc_paddr))
return -ENOMEM;
desc = hwdesc->cppi5_desc_vaddr;
cppi5_hdesc_init(desc, 0, 0);
cppi5_desc_set_pktids(&desc->hdr, 0, CPPI5_INFO1_DESC_FLOWID_DEFAULT);
cppi5_desc_set_retpolicy(&desc->hdr, 0, 0);
cppi5_hdesc_attach_buf(desc,
rx_flush->buffer_paddr, rx_flush->buffer_size,
rx_flush->buffer_paddr, rx_flush->buffer_size);
dma_sync_single_for_device(dev, hwdesc->cppi5_desc_paddr,
hwdesc->cppi5_desc_size, DMA_TO_DEVICE);
return 0;
}
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
#define TI_UDMAC_BUSWIDTHS (BIT(DMA_SLAVE_BUSWIDTH_1_BYTE) | \
BIT(DMA_SLAVE_BUSWIDTH_2_BYTES) | \
BIT(DMA_SLAVE_BUSWIDTH_3_BYTES) | \
BIT(DMA_SLAVE_BUSWIDTH_4_BYTES) | \
BIT(DMA_SLAVE_BUSWIDTH_8_BYTES))
static int udma_probe(struct platform_device *pdev)
{
struct device_node *navss_node = pdev->dev.parent->of_node;
struct device *dev = &pdev->dev;
struct udma_dev *ud;
const struct of_device_id *match;
int i, ret;
int ch_count;
ret = dma_coerce_mask_and_coherent(dev, DMA_BIT_MASK(48));
if (ret)
dev_err(dev, "failed to set dma mask stuff\n");
ud = devm_kzalloc(dev, sizeof(*ud), GFP_KERNEL);
if (!ud)
return -ENOMEM;
ret = udma_get_mmrs(pdev, ud);
if (ret)
return ret;
ud->tisci_rm.tisci = ti_sci_get_by_phandle(dev->of_node, "ti,sci");
if (IS_ERR(ud->tisci_rm.tisci))
return PTR_ERR(ud->tisci_rm.tisci);
ret = of_property_read_u32(dev->of_node, "ti,sci-dev-id",
&ud->tisci_rm.tisci_dev_id);
if (ret) {
dev_err(dev, "ti,sci-dev-id read failure %d\n", ret);
return ret;
}
pdev->id = ud->tisci_rm.tisci_dev_id;
ret = of_property_read_u32(navss_node, "ti,sci-dev-id",
&ud->tisci_rm.tisci_navss_dev_id);
if (ret) {
dev_err(dev, "NAVSS ti,sci-dev-id read failure %d\n", ret);
return ret;
}
ud->tisci_rm.tisci_udmap_ops = &ud->tisci_rm.tisci->ops.rm_udmap_ops;
ud->tisci_rm.tisci_psil_ops = &ud->tisci_rm.tisci->ops.rm_psil_ops;
ud->ringacc = of_k3_ringacc_get_by_phandle(dev->of_node, "ti,ringacc");
if (IS_ERR(ud->ringacc))
return PTR_ERR(ud->ringacc);
dev->msi_domain = of_msi_get_domain(dev, dev->of_node,
DOMAIN_BUS_TI_SCI_INTA_MSI);
if (!dev->msi_domain) {
dev_err(dev, "Failed to get MSI domain\n");
return -EPROBE_DEFER;
}
match = of_match_node(udma_of_match, dev->of_node);
if (!match) {
dev_err(dev, "No compatible match found\n");
return -ENODEV;
}
ud->match_data = match->data;
dma_cap_set(DMA_SLAVE, ud->ddev.cap_mask);
dma_cap_set(DMA_CYCLIC, ud->ddev.cap_mask);
ud->ddev.device_alloc_chan_resources = udma_alloc_chan_resources;
ud->ddev.device_config = udma_slave_config;
ud->ddev.device_prep_slave_sg = udma_prep_slave_sg;
ud->ddev.device_prep_dma_cyclic = udma_prep_dma_cyclic;
ud->ddev.device_issue_pending = udma_issue_pending;
ud->ddev.device_tx_status = udma_tx_status;
ud->ddev.device_pause = udma_pause;
ud->ddev.device_resume = udma_resume;
ud->ddev.device_terminate_all = udma_terminate_all;
ud->ddev.device_synchronize = udma_synchronize;
ud->ddev.device_free_chan_resources = udma_free_chan_resources;
ud->ddev.src_addr_widths = TI_UDMAC_BUSWIDTHS;
ud->ddev.dst_addr_widths = TI_UDMAC_BUSWIDTHS;
ud->ddev.directions = BIT(DMA_DEV_TO_MEM) | BIT(DMA_MEM_TO_DEV);
ud->ddev.residue_granularity = DMA_RESIDUE_GRANULARITY_BURST;
ud->ddev.copy_align = DMAENGINE_ALIGN_8_BYTES;
ud->ddev.desc_metadata_modes = DESC_METADATA_CLIENT |
DESC_METADATA_ENGINE;
if (ud->match_data->enable_memcpy_support) {
dma_cap_set(DMA_MEMCPY, ud->ddev.cap_mask);
ud->ddev.device_prep_dma_memcpy = udma_prep_dma_memcpy;
ud->ddev.directions |= BIT(DMA_MEM_TO_MEM);
}
ud->ddev.dev = dev;
ud->dev = dev;
ud->psil_base = ud->match_data->psil_base;
INIT_LIST_HEAD(&ud->ddev.channels);
INIT_LIST_HEAD(&ud->desc_to_purge);
ch_count = udma_setup_resources(ud);
if (ch_count <= 0)
return ch_count;
spin_lock_init(&ud->lock);
INIT_WORK(&ud->purge_work, udma_purge_desc_work);
ud->desc_align = 64;
if (ud->desc_align < dma_get_cache_alignment())
ud->desc_align = dma_get_cache_alignment();
ret = udma_setup_rx_flush(ud);
if (ret)
return ret;
dmaengine: ti: New driver for K3 UDMA Split patch for review containing: defines, structs, io and low level functions and interrupt callbacks. DMA driver for Texas Instruments K3 NAVSS Unified DMA – Peripheral Root Complex (UDMA-P) The UDMA-P is intended to perform similar (but significantly upgraded) functions as the packet-oriented DMA used on previous SoC devices. The UDMA-P module supports the transmission and reception of various packet types. The UDMA-P is architected to facilitate the segmentation and reassembly of SoC DMA data structure compliant packets to/from smaller data blocks that are natively compatible with the specific requirements of each connected peripheral. Multiple Tx and Rx channels are provided within the DMA which allow multiple segmentation or reassembly operations to be ongoing. The DMA controller maintains state information for each of the channels which allows packet segmentation and reassembly operations to be time division multiplexed between channels in order to share the underlying DMA hardware. An external DMA scheduler is used to control the ordering and rate at which this multiplexing occurs for Transmit operations. The ordering and rate of Receive operations is indirectly controlled by the order in which blocks are pushed into the DMA on the Rx PSI-L interface. The UDMA-P also supports acting as both a UTC and UDMA-C for its internal channels. Channels in the UDMA-P can be configured to be either Packet-Based or Third-Party channels on a channel by channel basis. The initial driver supports: - MEM_TO_MEM (TR mode) - DEV_TO_MEM (Packet / TR mode) - MEM_TO_DEV (Packet / TR mode) - Cyclic (Packet / TR mode) - Metadata for descriptors Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Reviewed-by: Grygorii Strashko <grygorii.strashko@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-11-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:50 +07:00
for (i = 0; i < ud->tchan_cnt; i++) {
struct udma_tchan *tchan = &ud->tchans[i];
tchan->id = i;
tchan->reg_rt = ud->mmrs[MMR_TCHANRT] + i * 0x1000;
}
for (i = 0; i < ud->rchan_cnt; i++) {
struct udma_rchan *rchan = &ud->rchans[i];
rchan->id = i;
rchan->reg_rt = ud->mmrs[MMR_RCHANRT] + i * 0x1000;
}
for (i = 0; i < ud->rflow_cnt; i++) {
struct udma_rflow *rflow = &ud->rflows[i];
rflow->id = i;
}
for (i = 0; i < ch_count; i++) {
struct udma_chan *uc = &ud->channels[i];
uc->ud = ud;
uc->vc.desc_free = udma_desc_free;
uc->id = i;
uc->tchan = NULL;
uc->rchan = NULL;
uc->config.remote_thread_id = -1;
uc->config.dir = DMA_MEM_TO_MEM;
uc->name = devm_kasprintf(dev, GFP_KERNEL, "%s chan%d",
dev_name(dev), i);
vchan_init(&uc->vc, &ud->ddev);
/* Use custom vchan completion handling */
tasklet_init(&uc->vc.task, udma_vchan_complete,
(unsigned long)&uc->vc);
init_completion(&uc->teardown_completed);
}
ret = dma_async_device_register(&ud->ddev);
if (ret) {
dev_err(dev, "failed to register slave DMA engine: %d\n", ret);
return ret;
}
platform_set_drvdata(pdev, ud);
ret = of_dma_controller_register(dev->of_node, udma_of_xlate, ud);
if (ret) {
dev_err(dev, "failed to register of_dma controller\n");
dma_async_device_unregister(&ud->ddev);
}
return ret;
}
static struct platform_driver udma_driver = {
.driver = {
.name = "ti-udma",
.of_match_table = udma_of_match,
.suppress_bind_attrs = true,
},
.probe = udma_probe,
};
builtin_platform_driver(udma_driver);
dmaengine: ti: k3-udma: Add glue layer for non DMAengine users Certain users can not use right now the DMAengine API due to missing features in the core. Prime example is Networking. These users can use the glue layer interface to avoid misuse of DMAengine API and when the core gains the needed features they can be converted to use generic API. The most prominent features the glue layer clients are depending on: - most PSI-L native peripheral use extra rflow ranges on a receive channel and depending on the peripheral's configuration packets from a single free descriptor ring is going to be received to different receive ring - it is also possible to have different free descriptor rings per rflow and an rflow can also support 4 additional free descriptor ring based on the size of the incoming packet - out of order completion of descriptors on a channel - when we have several queues to handle different priority packets the descriptors will be completed 'out-of-order' - the notion of prep_slave_sg is not matching with what the streaming type of operation is demanding for networking - Streaming type of operation - Ability to fill the free descriptor ring with descriptors in anticipation of incoming traffic and when a packet arrives UDMAP will form a packet and gives it to the client driver - the descriptors are not backed with exact size data buffers as we don't know the size of the packet we will receive, but as a generic pool of buffers to be used by the receive channel - NAPI type of operation (polling instead of interrupt driven transfer) - without this we can not sustain gigabit speeds and we need to support NAPI - not to limit this to networking, but other high performance operations Signed-off-by: Grygorii Strashko <grygorii.strashko@ti.com> Signed-off-by: Peter Ujfalusi <peter.ujfalusi@ti.com> Tested-by: Keerthy <j-keerthy@ti.com> Link: https://lore.kernel.org/r/20191223110458.30766-12-peter.ujfalusi@ti.com Signed-off-by: Vinod Koul <vkoul@kernel.org>
2019-12-23 18:04:51 +07:00
/* Private interfaces to UDMA */
#include "k3-udma-private.c"