zephyr/drivers/dma/dma_smartbond.c

970 lines
27 KiB
C

/*
* Copyright (c) 2023 Renesas Electronics Corporation
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <zephyr/kernel.h>
#include <zephyr/device.h>
#include <zephyr/drivers/dma.h>
#include <zephyr/irq.h>
#include <DA1469xAB.h>
#include <da1469x_config.h>
#include <system_DA1469x.h>
#include <da1469x_otp.h>
#include <zephyr/drivers/dma/dma_smartbond.h>
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(dma_smartbond, CONFIG_DMA_LOG_LEVEL);
#define DT_DRV_COMPAT renesas_smartbond_dma
#define SMARTBOND_IRQN DT_INST_IRQN(0)
#define SMARTBOND_IRQ_PRIO DT_INST_IRQ(0, priority)
#define DMA_CHANNELS_COUNT DT_PROP(DT_NODELABEL(dma), dma_channels)
#define DMA_BLOCK_COUNT DT_PROP(DT_NODELABEL(dma), block_count)
#define DMA_SECURE_CHANNEL 7
#define DMA_CTRL_REG_SET_FIELD(_field, _var, _val) \
(_var) = \
(((_var) & ~DMA_DMA0_CTRL_REG_ ## _field ## _Msk) | \
(((_val) << DMA_DMA0_CTRL_REG_ ## _field ## _Pos) & DMA_DMA0_CTRL_REG_ ## _field ## _Msk))
#define DMA_CTRL_REG_GET_FIELD(_field, _var) \
(((_var) & DMA_DMA0_CTRL_REG_ ## _field ## _Msk) >> DMA_DMA0_CTRL_REG_ ## _field ## _Pos)
#define DMA_CHN2REG(_idx) (&((struct channel_regs *)DMA)[(_idx)])
#define DMA_MUX_SHIFT(_idx) (((_idx) >> 1) * 4)
#define DMA_REQ_MUX_REG_SET(_idx, _val) \
DMA->DMA_REQ_MUX_REG = \
(DMA->DMA_REQ_MUX_REG & ~(0xf << DMA_MUX_SHIFT((_idx)))) | \
(((_val) & 0xf) << DMA_MUX_SHIFT((_idx)))
#define DMA_REQ_MUX_REG_GET(_idx) \
((DMA->DMA_REQ_MUX_REG >> DMA_MUX_SHIFT((_idx))) & 0xf)
#define CRYPTO_KEYS_BUF_ADDR 0x30040100
#define CRYPTO_KEYS_BUF_SIZE 0x100
#define IS_AES_KEYS_BUF_RANGE(_a) ((uint32_t)(_a) >= (uint32_t)(CRYPTO_KEYS_BUF_ADDR)) && \
((uint32_t)(_a) < (uint32_t)(CRYPTO_KEYS_BUF_ADDR + CRYPTO_KEYS_BUF_SIZE))
/*
* DMA channel priority level. The smaller the value the lower the priority granted to a channel
* when two or more channels request the bus at the same time. For channels of same priority an
* inherent mechanism is applied in which the lower the channel number the higher the priority.
*/
enum dma_smartbond_channel_prio {
DMA_SMARTBOND_CHANNEL_PRIO_0 = 0x0, /* Lowest channel priority */
DMA_SMARTBOND_CHANNEL_PRIO_1,
DMA_SMARTBOND_CHANNEL_PRIO_2,
DMA_SMARTBOND_CHANNEL_PRIO_3,
DMA_SMARTBOND_CHANNEL_PRIO_4,
DMA_SMARTBOND_CHANNEL_PRIO_5,
DMA_SMARTBOND_CHANNEL_PRIO_6,
DMA_SMARTBOND_CHANNEL_PRIO_7, /* Highest channel priority */
DMA_SMARTBOND_CHANNEL_PRIO_MAX
};
enum dma_smartbond_channel {
DMA_SMARTBOND_CHANNEL_0 = 0x0,
DMA_SMARTBOND_CHANNEL_1,
DMA_SMARTBOND_CHANNEL_2,
DMA_SMARTBOND_CHANNEL_3,
DMA_SMARTBOND_CHANNEL_4,
DMA_SMARTBOND_CHANNEL_5,
DMA_SMARTBOND_CHANNEL_6,
DMA_SMARTBOND_CHANNEL_7,
DMA_SMARTBOND_CHANNEL_MAX
};
enum dma_smartbond_burst_len {
DMA_SMARTBOND_BURST_LEN_1B = 0x1, /* Burst mode is disabled */
DMA_SMARTBOND_BURST_LEN_4B = 0x4, /* Perform bursts of 4 beats (INCR4) */
DMA_SMARTBOND_BURST_LEN_8B = 0x8 /* Perform bursts of 8 beats (INCR8) */
};
/*
* DMA bus width indicating how many bytes are retrived/written per transfer.
* Note that the bus width is the same for the source and destination.
*/
enum dma_smartbond_bus_width {
DMA_SMARTBOND_BUS_WIDTH_1B = 0x1,
DMA_SMARTBOND_BUS_WIDTH_2B = 0x2,
DMA_SMARTBOND_BUS_WIDTH_4B = 0x4
};
enum dreq_mode {
DREQ_MODE_SW = 0x0,
DREQ_MODE_HW
};
enum burst_mode {
BURST_MODE_0B = 0x0,
BURST_MODE_4B = 0x1,
BURST_MODE_8B = 0x2
};
enum bus_width {
BUS_WIDTH_1B = 0x0,
BUS_WIDTH_2B = 0x1,
BUS_WIDTH_4B = 0x2
};
enum addr_adj {
ADDR_ADJ_NO_CHANGE = 0x0,
ADDR_ADJ_INCR
};
enum copy_mode {
COPY_MODE_BLOCK = 0x0,
COPY_MODE_INIT
};
enum req_sense {
REQ_SENSE_LEVEL = 0x0,
REQ_SENSE_EDGE
};
struct channel_regs {
__IO uint32_t DMA_A_START;
__IO uint32_t DMA_B_START;
__IO uint32_t DMA_INT_REG;
__IO uint32_t DMA_LEN_REG;
__IO uint32_t DMA_CTRL_REG;
__I uint32_t DMA_IDX_REG;
__I uint32_t RESERVED[2];
};
struct dma_channel_data {
dma_callback_t cb;
void *user_data;
enum dma_smartbond_bus_width bus_width;
enum dma_smartbond_burst_len burst_len;
enum dma_channel_direction dir;
bool is_dma_configured;
};
struct dma_smartbond_data {
/* Should be the first member of the driver data */
struct dma_context dma_ctx;
ATOMIC_DEFINE(channels_atomic, DMA_CHANNELS_COUNT);
/* User callbacks and data to be stored per channel */
struct dma_channel_data channel_data[DMA_CHANNELS_COUNT];
};
/* True if there is any DMA activity on any channel, false otheriwise. */
static bool dma_smartbond_is_dma_active(void)
{
int idx;
struct channel_regs *regs;
for (idx = 0; idx < DMA_CHANNELS_COUNT; idx++) {
regs = DMA_CHN2REG(idx);
if (DMA_CTRL_REG_GET_FIELD(DMA_ON, regs->DMA_CTRL_REG)) {
return true;
}
}
return false;
}
static void dma_smartbond_set_channel_status(uint32_t channel, bool status)
{
unsigned int key;
struct channel_regs *regs = DMA_CHN2REG(channel);
key = irq_lock();
if (status) {
/* Make sure the status register for the requested channel is cleared. */
DMA->DMA_CLEAR_INT_REG |= BIT(channel);
/* Enable interrupts for the requested channel. */
DMA->DMA_INT_MASK_REG |= BIT(channel);
/* Check if this is the first attempt to enable DMA interrupts. */
if (!irq_is_enabled(SMARTBOND_IRQN)) {
irq_enable(SMARTBOND_IRQN);
}
DMA_CTRL_REG_SET_FIELD(DMA_ON, regs->DMA_CTRL_REG, 0x1);
} else {
DMA_CTRL_REG_SET_FIELD(DMA_ON, regs->DMA_CTRL_REG, 0x0);
/*
* It might happen that DMA is already in progress. Make sure the current
* on-going transfer is complete (cannot be interrupted).
*/
while (DMA_CTRL_REG_GET_FIELD(DMA_ON, regs->DMA_CTRL_REG)) {
}
/* Disable interrupts for the requested channel */
DMA->DMA_INT_MASK_REG &= ~(BIT(channel));
/* Clear the status register; the requested channel should be considered obsolete */
DMA->DMA_CLEAR_INT_REG |= BIT(channel);
/* DMA interrupts should be disabled only if all channels are disabled. */
if (!dma_smartbond_is_dma_active()) {
irq_disable(SMARTBOND_IRQN);
}
}
irq_unlock(key);
}
static bool dma_channel_dst_addr_check_and_adjust(uint32_t channel, uint32_t *dst)
{
uint32_t phy_address;
uint32_t secure_boot_reg;
bool is_aes_keys_protected, is_qspic_keys_protected;
phy_address = black_orca_phy_addr(*dst);
secure_boot_reg = CRG_TOP->SECURE_BOOT_REG;
is_aes_keys_protected =
(secure_boot_reg & CRG_TOP_SECURE_BOOT_REG_PROT_AES_KEY_READ_Msk);
is_qspic_keys_protected =
(secure_boot_reg & CRG_TOP_SECURE_BOOT_REG_PROT_QSPI_KEY_READ_Msk);
/*
* If the destination address reflects the AES key buffer area and secure keys are protected
* then only the secure channel #7 can be used to transfer data to AES key buffer.
*/
if ((IS_AES_KEYS_BUF_RANGE(phy_address) &&
(is_aes_keys_protected || is_qspic_keys_protected) &&
(channel != DMA_SECURE_CHANNEL))) {
LOG_ERR("Keys are protected. Only secure channel #7 can be employed.");
return false;
}
if (IS_QSPIF_ADDRESS(phy_address) || IS_QSPIF_CACHED_ADDRESS(phy_address) ||
IS_OTP_ADDRESS(phy_address) || IS_OTP_P_ADDRESS(phy_address)) {
LOG_ERR("Invalid destination location.");
return false;
}
*dst = phy_address;
return true;
}
static bool dma_channel_src_addr_check_and_adjust(uint32_t channel, uint32_t *src)
{
uint32_t phy_address;
uint32_t secure_boot_reg;
bool is_aes_keys_protected, is_qspic_keys_protected;
/* DMA can only access physical addresses, not remapped. */
phy_address = black_orca_phy_addr(*src);
if (IS_QSPIF_CACHED_ADDRESS(phy_address)) {
/*
* To achiebe max. perfomance, peripherals should not access the Flash memory
* through the instruction cache controller (avoid cache misses).
*/
phy_address += (MCU_QSPIF_M_BASE - MCU_QSPIF_M_CACHED_BASE);
} else if (IS_OTP_ADDRESS(phy_address)) {
/* Peripherals should access OTP through its peripheral address space. */
phy_address += (MCU_OTP_M_P_BASE - MCU_OTP_M_BASE);
}
secure_boot_reg = CRG_TOP->SECURE_BOOT_REG;
is_aes_keys_protected =
(secure_boot_reg & CRG_TOP_SECURE_BOOT_REG_PROT_AES_KEY_READ_Msk);
is_qspic_keys_protected =
(secure_boot_reg & CRG_TOP_SECURE_BOOT_REG_PROT_QSPI_KEY_READ_Msk);
/*
* If the source address reflects protected area in OTP then only the
* secure channel #7 can be used to fetch secure keys data.
*/
if (((IS_ADDRESS_USER_DATA_KEYS_SEGMENT(phy_address) && is_aes_keys_protected) ||
(IS_ADDRESS_QSPI_FW_KEYS_SEGMENT(phy_address) && is_qspic_keys_protected)) &&
(channel != DMA_SECURE_CHANNEL)) {
LOG_ERR("Keys are protected. Only secure channel #7 can be employed.");
return false;
}
*src = phy_address;
return true;
}
static bool dma_channel_update_dreq_mode(enum dma_channel_direction direction,
uint32_t *dma_ctrl_reg)
{
switch (direction) {
case MEMORY_TO_HOST:
case HOST_TO_MEMORY:
case MEMORY_TO_MEMORY:
/* DMA channel starts immediately */
DMA_CTRL_REG_SET_FIELD(DREQ_MODE, *dma_ctrl_reg, DREQ_MODE_SW);
break;
case PERIPHERAL_TO_MEMORY:
case PERIPHERAL_TO_PERIPHERAL:
/* DMA channels starts by peripheral DMA req */
DMA_CTRL_REG_SET_FIELD(DREQ_MODE, *dma_ctrl_reg, DREQ_MODE_HW);
break;
default:
return false;
};
return true;
}
static bool dma_channel_update_src_addr_adj(enum dma_addr_adj addr_adj, uint32_t *dma_ctrl_reg)
{
switch (addr_adj) {
case DMA_ADDR_ADJ_NO_CHANGE:
DMA_CTRL_REG_SET_FIELD(AINC, *dma_ctrl_reg, ADDR_ADJ_NO_CHANGE);
break;
case DMA_ADDR_ADJ_INCREMENT:
DMA_CTRL_REG_SET_FIELD(AINC, *dma_ctrl_reg, ADDR_ADJ_INCR);
break;
default:
return false;
}
return true;
}
static bool dma_channel_update_dst_addr_adj(enum dma_addr_adj addr_adj, uint32_t *dma_ctrl_reg)
{
switch (addr_adj) {
case DMA_ADDR_ADJ_NO_CHANGE:
DMA_CTRL_REG_SET_FIELD(BINC, *dma_ctrl_reg, ADDR_ADJ_NO_CHANGE);
break;
case DMA_ADDR_ADJ_INCREMENT:
DMA_CTRL_REG_SET_FIELD(BINC, *dma_ctrl_reg, ADDR_ADJ_INCR);
break;
default:
return false;
}
return true;
}
static bool dma_channel_update_bus_width(uint16_t bw, uint32_t *dma_ctrl_reg)
{
switch (bw) {
case DMA_SMARTBOND_BUS_WIDTH_1B:
DMA_CTRL_REG_SET_FIELD(BW, *dma_ctrl_reg, BUS_WIDTH_1B);
break;
case DMA_SMARTBOND_BUS_WIDTH_2B:
DMA_CTRL_REG_SET_FIELD(BW, *dma_ctrl_reg, BUS_WIDTH_2B);
break;
case DMA_SMARTBOND_BUS_WIDTH_4B:
DMA_CTRL_REG_SET_FIELD(BW, *dma_ctrl_reg, BUS_WIDTH_4B);
break;
default:
return false;
}
return true;
}
static bool dma_channel_update_burst_mode(uint16_t burst, uint32_t *dma_ctrl_reg)
{
switch (burst) {
case DMA_SMARTBOND_BURST_LEN_1B:
DMA_CTRL_REG_SET_FIELD(BURST_MODE, *dma_ctrl_reg, BURST_MODE_0B);
break;
case DMA_SMARTBOND_BURST_LEN_4B:
DMA_CTRL_REG_SET_FIELD(BURST_MODE, *dma_ctrl_reg, BURST_MODE_4B);
break;
case DMA_SMARTBOND_BURST_LEN_8B:
DMA_CTRL_REG_SET_FIELD(BURST_MODE, *dma_ctrl_reg, BURST_MODE_8B);
break;
default:
return false;
}
return true;
}
static void dma_channel_update_req_sense(enum dma_smartbond_trig_mux trig_mux,
uint32_t channel, uint32_t *dma_ctrl_reg)
{
switch (trig_mux) {
case DMA_SMARTBOND_TRIG_MUX_UART:
case DMA_SMARTBOND_TRIG_MUX_UART2:
case DMA_SMARTBOND_TRIG_MUX_UART3:
case DMA_SMARTBOND_TRIG_MUX_I2C:
case DMA_SMARTBOND_TRIG_MUX_I2C2:
case DMA_SMARTBOND_TRIG_MUX_USB:
/* Odd channel numbers should reflect TX path */
if (channel & BIT(0)) {
DMA_CTRL_REG_SET_FIELD(REQ_SENSE, *dma_ctrl_reg, REQ_SENSE_EDGE);
break;
}
default:
DMA_CTRL_REG_SET_FIELD(REQ_SENSE, *dma_ctrl_reg, REQ_SENSE_LEVEL);
}
}
static void dma_set_mux_request(enum dma_smartbond_trig_mux trig_mux, uint32_t channel)
{
unsigned int key;
key = irq_lock();
DMA_REQ_MUX_REG_SET(channel, trig_mux);
/*
* Having same trigger for different channels can cause unpredictable results.
* The audio triggers (src and pcm) are an exception, as they use 2 pairs each
* for DMA access.
* The lesser significant selector has higher priority and will control
* the DMA acknowledge signal driven to the selected peripheral. Make sure
* the current selector does not match with selectors of
* higher priorities (dma channels of lower indexing). It's OK if a
* channel of higher indexing defines the same peripheral request source
* (should be ignored as it has lower priority).
*/
if (trig_mux != DMA_SMARTBOND_TRIG_MUX_NONE) {
switch (channel) {
case DMA_SMARTBOND_CHANNEL_7:
case DMA_SMARTBOND_CHANNEL_6:
if (DMA_REQ_MUX_REG_GET(DMA_SMARTBOND_CHANNEL_5) == trig_mux) {
DMA_REQ_MUX_REG_SET(DMA_SMARTBOND_CHANNEL_5,
DMA_SMARTBOND_TRIG_MUX_NONE);
}
/* fall-through */
case DMA_SMARTBOND_CHANNEL_5:
case DMA_SMARTBOND_CHANNEL_4:
if (DMA_REQ_MUX_REG_GET(DMA_SMARTBOND_CHANNEL_3) == trig_mux) {
DMA_REQ_MUX_REG_SET(DMA_SMARTBOND_CHANNEL_3,
DMA_SMARTBOND_TRIG_MUX_NONE);
}
/* fall-through */
case DMA_SMARTBOND_CHANNEL_3:
case DMA_SMARTBOND_CHANNEL_2:
if (DMA_REQ_MUX_REG_GET(DMA_SMARTBOND_CHANNEL_1) == trig_mux) {
DMA_REQ_MUX_REG_SET(DMA_SMARTBOND_CHANNEL_1,
DMA_SMARTBOND_TRIG_MUX_NONE);
}
case DMA_SMARTBOND_CHANNEL_1:
case DMA_SMARTBOND_CHANNEL_0:
break;
}
}
irq_unlock(key);
}
static int dma_smartbond_config(const struct device *dev, uint32_t channel, struct dma_config *cfg)
{
struct dma_smartbond_data *data = dev->data;
struct channel_regs *regs;
uint32_t dma_ctrl_reg;
uint32_t src_dst_address;
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
regs = DMA_CHN2REG(channel);
dma_ctrl_reg = regs->DMA_CTRL_REG;
if (DMA_CTRL_REG_GET_FIELD(DMA_ON, dma_ctrl_reg)) {
LOG_ERR("Requested channel is enabled. It should first be disabled");
return -EIO;
}
if (cfg == NULL || cfg->head_block == NULL) {
LOG_ERR("Missing configuration structure");
return -EINVAL;
}
/* Error handling is not supported; just warn user. */
if (cfg->error_callback_en) {
LOG_WRN("Error handling is not supported");
}
if (!cfg->complete_callback_en) {
data->channel_data[channel].cb = cfg->dma_callback;
data->channel_data[channel].user_data = cfg->user_data;
} else {
LOG_WRN("User callback can only be called at completion only and not per block.");
/* Nulify pointers to indicate notifications are disabled. */
data->channel_data[channel].cb = NULL;
data->channel_data[channel].user_data = NULL;
}
data->channel_data[channel].dir = cfg->channel_direction;
if (cfg->block_count > DMA_BLOCK_COUNT) {
LOG_WRN("A single block is supported. The rest blocks will be discarded");
}
if (cfg->channel_priority >= DMA_SMARTBOND_CHANNEL_PRIO_MAX) {
cfg->channel_priority = DMA_SMARTBOND_CHANNEL_PRIO_7;
LOG_WRN("Channel priority exceeded max. Setting to highest valid level");
}
DMA_CTRL_REG_SET_FIELD(DMA_PRIO, dma_ctrl_reg, cfg->channel_priority);
if (((cfg->source_burst_length != cfg->dest_burst_length) ||
!dma_channel_update_burst_mode(cfg->source_burst_length, &dma_ctrl_reg))) {
LOG_ERR("Invalid burst mode or source and destination mode mismatch");
return -EINVAL;
}
data->channel_data[channel].burst_len = cfg->source_burst_length;
if (cfg->source_data_size != cfg->dest_data_size ||
!dma_channel_update_bus_width(cfg->source_data_size, &dma_ctrl_reg)) {
LOG_ERR("Invalid bus width or source and destination bus width mismatch");
return -EINVAL;
}
data->channel_data[channel].bus_width = cfg->source_data_size;
if (cfg->source_chaining_en || cfg->dest_chaining_en ||
cfg->head_block->source_gather_en || cfg->head_block->dest_scatter_en ||
cfg->head_block->source_reload_en || cfg->head_block->dest_reload_en) {
LOG_WRN("Chainning, scattering, gathering or reloading is not supported");
}
if (!dma_channel_update_src_addr_adj(cfg->head_block->source_addr_adj,
&dma_ctrl_reg)) {
LOG_ERR("Invalid source address adjustment");
return -EINVAL;
}
if (!dma_channel_update_dst_addr_adj(cfg->head_block->dest_addr_adj, &dma_ctrl_reg)) {
LOG_ERR("Invalid destination address adjustment");
return -EINVAL;
}
if (!dma_channel_update_dreq_mode(cfg->channel_direction, &dma_ctrl_reg)) {
LOG_ERR("Inavlid channel direction");
return -EINVAL;
}
/* Cyclic is valid only when DREQ_MODE is set */
if (cfg->cyclic && DMA_CTRL_REG_GET_FIELD(DREQ_MODE, dma_ctrl_reg) != DREQ_MODE_HW) {
LOG_ERR("Circular mode is only supported for non memory-memory transfers");
return -EINVAL;
}
DMA_CTRL_REG_SET_FIELD(CIRCULAR, dma_ctrl_reg, cfg->cyclic);
if (DMA_CTRL_REG_GET_FIELD(DREQ_MODE, dma_ctrl_reg) == DREQ_MODE_SW &&
DMA_CTRL_REG_GET_FIELD(AINC, dma_ctrl_reg) == ADDR_ADJ_NO_CHANGE &&
DMA_CTRL_REG_GET_FIELD(BINC, dma_ctrl_reg) == ADDR_ADJ_INCR) {
/*
* Valid for memory initialization to a specific value. This process
* cannot be interrupted by other DMA channels.
*/
DMA_CTRL_REG_SET_FIELD(DMA_INIT, dma_ctrl_reg, COPY_MODE_INIT);
} else {
DMA_CTRL_REG_SET_FIELD(DMA_INIT, dma_ctrl_reg, COPY_MODE_BLOCK);
}
dma_channel_update_req_sense(cfg->dma_slot, channel, &dma_ctrl_reg);
regs->DMA_CTRL_REG = dma_ctrl_reg;
/* Requested address might be changed */
src_dst_address = cfg->head_block->source_address;
if (!dma_channel_src_addr_check_and_adjust(channel, &src_dst_address)) {
return -EINVAL;
}
if (src_dst_address % cfg->source_data_size) {
LOG_ERR("Source address is not bus width aligned");
return -EINVAL;
}
regs->DMA_A_START = src_dst_address;
src_dst_address = cfg->head_block->dest_address;
if (!dma_channel_dst_addr_check_and_adjust(channel, &src_dst_address)) {
return -EINVAL;
}
if (src_dst_address % cfg->dest_data_size) {
LOG_ERR("Destination address is not bus width aligned");
return -EINVAL;
}
regs->DMA_B_START = src_dst_address;
if (cfg->head_block->block_size % (cfg->source_data_size * cfg->source_burst_length)) {
LOG_ERR("Requested data size is not multiple of bus width");
return -EINVAL;
}
regs->DMA_LEN_REG = (cfg->head_block->block_size / cfg->source_data_size) - 1;
/* Interrupt will be raised once all transfers are complete. */
regs->DMA_INT_REG = (cfg->head_block->block_size / cfg->source_data_size) - 1;
if ((cfg->source_handshake != cfg->dest_handshake) ||
(cfg->source_handshake != 0)/*HW*/) {
LOG_ERR("Source/destination handshakes mismatch or invalid");
return -EINVAL;
}
dma_set_mux_request(cfg->dma_slot, channel);
/* Designate that channel has been configured */
data->channel_data[channel].is_dma_configured = true;
return 0;
}
static int dma_smartbond_reload(const struct device *dev, uint32_t channel, uint32_t src,
uint32_t dst, size_t size)
{
struct dma_smartbond_data *data = dev->data;
struct channel_regs *regs;
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
regs = DMA_CHN2REG(channel);
if (!data->channel_data[channel].is_dma_configured) {
LOG_ERR("Requested DMA channel should first be configured");
return -EINVAL;
}
if (size == 0) {
LOG_ERR("Min. transfer size is one");
return -EINVAL;
}
if (DMA_CTRL_REG_GET_FIELD(DMA_ON, regs->DMA_CTRL_REG)) {
LOG_ERR("Channel is busy, settings cannot be changed mid-transfer");
return -EBUSY;
}
if (src % data->channel_data[channel].bus_width) {
LOG_ERR("Source address is not bus width aligned");
return -EINVAL;
}
if (!dma_channel_src_addr_check_and_adjust(channel, &src)) {
return -EINVAL;
}
regs->DMA_A_START = src;
if (dst % data->channel_data[channel].bus_width) {
LOG_ERR("Destination address is not bus width aligned");
return -EINVAL;
}
if (!dma_channel_dst_addr_check_and_adjust(channel, &dst)) {
return -EINVAL;
}
regs->DMA_B_START = dst;
if (size % (data->channel_data[channel].burst_len *
data->channel_data[channel].bus_width)) {
LOG_ERR("Requested data size is not multiple of bus width");
return -EINVAL;
}
regs->DMA_LEN_REG = (size / data->channel_data[channel].bus_width) - 1;
/* Interrupt will be raised once all transfers are complete. */
regs->DMA_INT_REG = (size / data->channel_data[channel].bus_width) - 1;
return 0;
}
static int dma_smartbond_start(const struct device *dev, uint32_t channel)
{
struct channel_regs *regs;
struct dma_smartbond_data *data = dev->data;
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
regs = DMA_CHN2REG(channel);
if (!data->channel_data[channel].is_dma_configured) {
LOG_ERR("Requested DMA channel should first be configured");
return -EINVAL;
}
/* Should return succss if the requested channel is already started. */
if (DMA_CTRL_REG_GET_FIELD(DMA_ON, regs->DMA_CTRL_REG)) {
return 0;
}
dma_smartbond_set_channel_status(channel, true);
return 0;
}
static int dma_smartbond_stop(const struct device *dev, uint32_t channel)
{
struct channel_regs *regs;
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
regs = DMA_CHN2REG(channel);
/*
* In normal mode DMA_ON is cleared automatically. However we need to clear
* the corresponding register mask and disable NVIC if there is no other
* channel in use.
*/
dma_smartbond_set_channel_status(channel, false);
return 0;
}
static int dma_smartbond_suspend(const struct device *dev, uint32_t channel)
{
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
/*
* Freezing the DMA engine is valid for memory-to-memory operations.
* Valid memory locations are SYSRAM and/or PSRAM.
*/
LOG_WRN("DMA is freezed globally");
/*
* Freezing the DMA engine can be done universally and not per channel!.
* An attempt to disable the channel would result in resetting the IDX
* register next time the channel was re-enabled.
*/
GPREG->SET_FREEZE_REG = GPREG_SET_FREEZE_REG_FRZ_DMA_Msk;
return 0;
}
static int dma_smartbond_resume(const struct device *dev, uint32_t channel)
{
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
LOG_WRN("DMA is unfreezed globally");
/* Unfreezing the DMA engine can be done unviversally and not per channel! */
GPREG->RESET_FREEZE_REG = GPREG_RESET_FREEZE_REG_FRZ_DMA_Msk;
return 0;
}
static int dma_smartbond_get_status(const struct device *dev, uint32_t channel,
struct dma_status *stat)
{
struct channel_regs *regs;
int key;
struct dma_smartbond_data *data = dev->data;
uint8_t bus_width;
uint32_t dma_ctrl_reg, dma_idx_reg, dma_len_reg;
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
if (stat == NULL) {
LOG_ERR("User should provide a valid pointer to store the status info requested");
}
if (!data->channel_data[channel].is_dma_configured) {
LOG_ERR("Requested DMA channel should first be configured");
return -EINVAL;
}
regs = DMA_CHN2REG(channel);
/*
* The DMA is running in parallel with CPU and so it might happen that an on-going transfer
* might be completed the moment user parses the status results. Disable interrupts globally
* so there is no chance for a new transfer to be initiated from within ISR and so changing
* the channel registers values.
*/
key = irq_lock();
dma_ctrl_reg = regs->DMA_CTRL_REG;
dma_idx_reg = regs->DMA_IDX_REG;
dma_len_reg = regs->DMA_LEN_REG;
/* Calculate how many byes each transfer consists of. */
bus_width = DMA_CTRL_REG_GET_FIELD(BW, dma_ctrl_reg);
if (bus_width == BUS_WIDTH_1B) {
bus_width = 1;
} else {
bus_width <<= 1;
}
/* Convert transfers to bytes. */
stat->total_copied = dma_idx_reg * bus_width;
stat->pending_length = ((dma_len_reg + 1) - dma_idx_reg) * bus_width;
stat->busy = DMA_CTRL_REG_GET_FIELD(DMA_ON, dma_ctrl_reg);
stat->dir = data->channel_data[channel].dir;
/* DMA does not support circular buffer functionality */
stat->free = 0;
stat->read_position = 0;
stat->write_position = 0;
irq_unlock(key);
return 0;
}
static int dma_smartbond_get_attribute(const struct device *dev, uint32_t type, uint32_t *value)
{
if (value == NULL) {
LOG_ERR("User should provide a valid pointer to attribute value");
return -EINVAL;
}
switch (type) {
/*
* Source and destination addresses should be multiple of a channel's bus width.
* This info could be provided at runtime given that attributes of a specific
* channel could be requested.
*/
case DMA_ATTR_BUFFER_ADDRESS_ALIGNMENT:
case DMA_ATTR_COPY_ALIGNMENT:
/*
* Buffer size should be multiple of a channel's bus width multiplied by burst length.
* This info could be provided at runtime given that attributes of a specific channel
* could be requested.
*/
case DMA_ATTR_BUFFER_SIZE_ALIGNMENT:
return -ENOSYS;
case DMA_ATTR_MAX_BLOCK_COUNT:
*value = DMA_BLOCK_COUNT;
return 0;
default:
return -EINVAL;
}
}
static bool dma_smartbond_chan_filter(const struct device *dev, int channel, void *filter_param)
{
uint32_t requested_channel;
if (channel >= DMA_CHANNELS_COUNT) {
LOG_ERR("Inavlid DMA channel index");
return -EINVAL;
}
/* If user does not provide any channel request explicitly, return true. */
if (filter_param == NULL) {
return true;
}
requested_channel = *(uint32_t *)filter_param;
if (channel == requested_channel) {
return true;
}
return false;
}
static struct dma_driver_api dma_smartbond_driver_api = {
.config = dma_smartbond_config,
.reload = dma_smartbond_reload,
.start = dma_smartbond_start,
.stop = dma_smartbond_stop,
.suspend = dma_smartbond_suspend,
.resume = dma_smartbond_resume,
.get_status = dma_smartbond_get_status,
.get_attribute = dma_smartbond_get_attribute,
.chan_filter = dma_smartbond_chan_filter
};
static void smartbond_dma_isr(const void *arg)
{
uint16_t dma_int_status_reg;
int i;
struct channel_regs *regs;
struct dma_smartbond_data *data = ((const struct device *)arg)->data;
/*
* A single interrupt line is generated for all channels and so each channel
* should be parsed separately.
*/
for (i = 0, dma_int_status_reg = DMA->DMA_INT_STATUS_REG;
i < DMA_CHANNELS_COUNT && dma_int_status_reg != 0; ++i, dma_int_status_reg >>= 1) {
/* Check if the selected channel has raised the interrupt line */
if (dma_int_status_reg & BIT(0)) {
regs = DMA_CHN2REG(i);
/*
* Should be valid if callbacks are explicitly enabled by users.
* Interrupt should be triggered only when the total size of
* bytes has been transferred. Bus errors cannot raise interrupts.
*/
if (data->channel_data[i].cb) {
data->channel_data[i].cb((const struct device *)arg,
data->channel_data[i].user_data, i, DMA_STATUS_COMPLETE);
}
/* Channel line should be cleared otherwise ISR will keep firing! */
DMA->DMA_CLEAR_INT_REG = BIT(i);
}
}
}
static int dma_smartbond_init(const struct device *dev)
{
#ifdef CONFIG_DMA_64BIT
LOG_ERR("64-bit addressing mode is not supported\n");
return -ENOSYS;
#endif
int idx;
struct dma_smartbond_data *data;
data = dev->data;
data->dma_ctx.magic = DMA_MAGIC;
data->dma_ctx.dma_channels = DMA_CHANNELS_COUNT;
data->dma_ctx.atomic = data->channels_atomic;
/* Make sure that all channels are disabled. */
for (idx = 0; idx < DMA_CHANNELS_COUNT; idx++) {
dma_smartbond_set_channel_status(idx, false);
data->channel_data[idx].is_dma_configured = false;
}
IRQ_CONNECT(SMARTBOND_IRQN, SMARTBOND_IRQ_PRIO, smartbond_dma_isr,
DEVICE_DT_INST_GET(0), 0);
return 0;
}
#define SMARTBOND_DMA_INIT(inst) \
BUILD_ASSERT((inst) == 0, "multiple instances are not supported"); \
\
static struct dma_smartbond_data dma_smartbond_data_ ## inst; \
\
DEVICE_DT_INST_DEFINE(0, dma_smartbond_init, NULL, \
&dma_smartbond_data_ ## inst, NULL, \
POST_KERNEL, \
CONFIG_DMA_INIT_PRIORITY, \
&dma_smartbond_driver_api);
DT_INST_FOREACH_STATUS_OKAY(SMARTBOND_DMA_INIT)