blob: 419220fa42fd7e66077b1642a94ed2ceea4a1fad [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0-only
/*
* cs_dsp.c -- Cirrus Logic DSP firmware support
*
* Based on sound/soc/codecs/wm_adsp.c
*
* Copyright 2012 Wolfson Microelectronics plc
* Copyright (C) 2015-2021 Cirrus Logic, Inc. and
* Cirrus Logic International Semiconductor Ltd.
*/
#include <linux/ctype.h>
#include <linux/debugfs.h>
#include <linux/delay.h>
#include <linux/minmax.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/seq_file.h>
#include <linux/slab.h>
#include <linux/vmalloc.h>
#include <linux/firmware/cirrus/cs_dsp.h>
#include <linux/firmware/cirrus/wmfw.h>
#define cs_dsp_err(_dsp, fmt, ...) \
dev_err(_dsp->dev, "%s: " fmt, _dsp->name, ##__VA_ARGS__)
#define cs_dsp_warn(_dsp, fmt, ...) \
dev_warn(_dsp->dev, "%s: " fmt, _dsp->name, ##__VA_ARGS__)
#define cs_dsp_info(_dsp, fmt, ...) \
dev_info(_dsp->dev, "%s: " fmt, _dsp->name, ##__VA_ARGS__)
#define cs_dsp_dbg(_dsp, fmt, ...) \
dev_dbg(_dsp->dev, "%s: " fmt, _dsp->name, ##__VA_ARGS__)
#define ADSP1_CONTROL_1 0x00
#define ADSP1_CONTROL_2 0x02
#define ADSP1_CONTROL_3 0x03
#define ADSP1_CONTROL_4 0x04
#define ADSP1_CONTROL_5 0x06
#define ADSP1_CONTROL_6 0x07
#define ADSP1_CONTROL_7 0x08
#define ADSP1_CONTROL_8 0x09
#define ADSP1_CONTROL_9 0x0A
#define ADSP1_CONTROL_10 0x0B
#define ADSP1_CONTROL_11 0x0C
#define ADSP1_CONTROL_12 0x0D
#define ADSP1_CONTROL_13 0x0F
#define ADSP1_CONTROL_14 0x10
#define ADSP1_CONTROL_15 0x11
#define ADSP1_CONTROL_16 0x12
#define ADSP1_CONTROL_17 0x13
#define ADSP1_CONTROL_18 0x14
#define ADSP1_CONTROL_19 0x16
#define ADSP1_CONTROL_20 0x17
#define ADSP1_CONTROL_21 0x18
#define ADSP1_CONTROL_22 0x1A
#define ADSP1_CONTROL_23 0x1B
#define ADSP1_CONTROL_24 0x1C
#define ADSP1_CONTROL_25 0x1E
#define ADSP1_CONTROL_26 0x20
#define ADSP1_CONTROL_27 0x21
#define ADSP1_CONTROL_28 0x22
#define ADSP1_CONTROL_29 0x23
#define ADSP1_CONTROL_30 0x24
#define ADSP1_CONTROL_31 0x26
/*
* ADSP1 Control 19
*/
#define ADSP1_WDMA_BUFFER_LENGTH_MASK 0x00FF /* DSP1_WDMA_BUFFER_LENGTH - [7:0] */
#define ADSP1_WDMA_BUFFER_LENGTH_SHIFT 0 /* DSP1_WDMA_BUFFER_LENGTH - [7:0] */
#define ADSP1_WDMA_BUFFER_LENGTH_WIDTH 8 /* DSP1_WDMA_BUFFER_LENGTH - [7:0] */
/*
* ADSP1 Control 30
*/
#define ADSP1_DBG_CLK_ENA 0x0008 /* DSP1_DBG_CLK_ENA */
#define ADSP1_DBG_CLK_ENA_MASK 0x0008 /* DSP1_DBG_CLK_ENA */
#define ADSP1_DBG_CLK_ENA_SHIFT 3 /* DSP1_DBG_CLK_ENA */
#define ADSP1_DBG_CLK_ENA_WIDTH 1 /* DSP1_DBG_CLK_ENA */
#define ADSP1_SYS_ENA 0x0004 /* DSP1_SYS_ENA */
#define ADSP1_SYS_ENA_MASK 0x0004 /* DSP1_SYS_ENA */
#define ADSP1_SYS_ENA_SHIFT 2 /* DSP1_SYS_ENA */
#define ADSP1_SYS_ENA_WIDTH 1 /* DSP1_SYS_ENA */
#define ADSP1_CORE_ENA 0x0002 /* DSP1_CORE_ENA */
#define ADSP1_CORE_ENA_MASK 0x0002 /* DSP1_CORE_ENA */
#define ADSP1_CORE_ENA_SHIFT 1 /* DSP1_CORE_ENA */
#define ADSP1_CORE_ENA_WIDTH 1 /* DSP1_CORE_ENA */
#define ADSP1_START 0x0001 /* DSP1_START */
#define ADSP1_START_MASK 0x0001 /* DSP1_START */
#define ADSP1_START_SHIFT 0 /* DSP1_START */
#define ADSP1_START_WIDTH 1 /* DSP1_START */
/*
* ADSP1 Control 31
*/
#define ADSP1_CLK_SEL_MASK 0x0007 /* CLK_SEL_ENA */
#define ADSP1_CLK_SEL_SHIFT 0 /* CLK_SEL_ENA */
#define ADSP1_CLK_SEL_WIDTH 3 /* CLK_SEL_ENA */
#define ADSP2_CONTROL 0x0
#define ADSP2_CLOCKING 0x1
#define ADSP2V2_CLOCKING 0x2
#define ADSP2_STATUS1 0x4
#define ADSP2_WDMA_CONFIG_1 0x30
#define ADSP2_WDMA_CONFIG_2 0x31
#define ADSP2V2_WDMA_CONFIG_2 0x32
#define ADSP2_RDMA_CONFIG_1 0x34
#define ADSP2_SCRATCH0 0x40
#define ADSP2_SCRATCH1 0x41
#define ADSP2_SCRATCH2 0x42
#define ADSP2_SCRATCH3 0x43
#define ADSP2V2_SCRATCH0_1 0x40
#define ADSP2V2_SCRATCH2_3 0x42
/*
* ADSP2 Control
*/
#define ADSP2_MEM_ENA 0x0010 /* DSP1_MEM_ENA */
#define ADSP2_MEM_ENA_MASK 0x0010 /* DSP1_MEM_ENA */
#define ADSP2_MEM_ENA_SHIFT 4 /* DSP1_MEM_ENA */
#define ADSP2_MEM_ENA_WIDTH 1 /* DSP1_MEM_ENA */
#define ADSP2_SYS_ENA 0x0004 /* DSP1_SYS_ENA */
#define ADSP2_SYS_ENA_MASK 0x0004 /* DSP1_SYS_ENA */
#define ADSP2_SYS_ENA_SHIFT 2 /* DSP1_SYS_ENA */
#define ADSP2_SYS_ENA_WIDTH 1 /* DSP1_SYS_ENA */
#define ADSP2_CORE_ENA 0x0002 /* DSP1_CORE_ENA */
#define ADSP2_CORE_ENA_MASK 0x0002 /* DSP1_CORE_ENA */
#define ADSP2_CORE_ENA_SHIFT 1 /* DSP1_CORE_ENA */
#define ADSP2_CORE_ENA_WIDTH 1 /* DSP1_CORE_ENA */
#define ADSP2_START 0x0001 /* DSP1_START */
#define ADSP2_START_MASK 0x0001 /* DSP1_START */
#define ADSP2_START_SHIFT 0 /* DSP1_START */
#define ADSP2_START_WIDTH 1 /* DSP1_START */
/*
* ADSP2 clocking
*/
#define ADSP2_CLK_SEL_MASK 0x0007 /* CLK_SEL_ENA */
#define ADSP2_CLK_SEL_SHIFT 0 /* CLK_SEL_ENA */
#define ADSP2_CLK_SEL_WIDTH 3 /* CLK_SEL_ENA */
/*
* ADSP2V2 clocking
*/
#define ADSP2V2_CLK_SEL_MASK 0x70000 /* CLK_SEL_ENA */
#define ADSP2V2_CLK_SEL_SHIFT 16 /* CLK_SEL_ENA */
#define ADSP2V2_CLK_SEL_WIDTH 3 /* CLK_SEL_ENA */
#define ADSP2V2_RATE_MASK 0x7800 /* DSP_RATE */
#define ADSP2V2_RATE_SHIFT 11 /* DSP_RATE */
#define ADSP2V2_RATE_WIDTH 4 /* DSP_RATE */
/*
* ADSP2 Status 1
*/
#define ADSP2_RAM_RDY 0x0001
#define ADSP2_RAM_RDY_MASK 0x0001
#define ADSP2_RAM_RDY_SHIFT 0
#define ADSP2_RAM_RDY_WIDTH 1
/*
* ADSP2 Lock support
*/
#define ADSP2_LOCK_CODE_0 0x5555
#define ADSP2_LOCK_CODE_1 0xAAAA
#define ADSP2_WATCHDOG 0x0A
#define ADSP2_BUS_ERR_ADDR 0x52
#define ADSP2_REGION_LOCK_STATUS 0x64
#define ADSP2_LOCK_REGION_1_LOCK_REGION_0 0x66
#define ADSP2_LOCK_REGION_3_LOCK_REGION_2 0x68
#define ADSP2_LOCK_REGION_5_LOCK_REGION_4 0x6A
#define ADSP2_LOCK_REGION_7_LOCK_REGION_6 0x6C
#define ADSP2_LOCK_REGION_9_LOCK_REGION_8 0x6E
#define ADSP2_LOCK_REGION_CTRL 0x7A
#define ADSP2_PMEM_ERR_ADDR_XMEM_ERR_ADDR 0x7C
#define ADSP2_REGION_LOCK_ERR_MASK 0x8000
#define ADSP2_ADDR_ERR_MASK 0x4000
#define ADSP2_WDT_TIMEOUT_STS_MASK 0x2000
#define ADSP2_CTRL_ERR_PAUSE_ENA 0x0002
#define ADSP2_CTRL_ERR_EINT 0x0001
#define ADSP2_BUS_ERR_ADDR_MASK 0x00FFFFFF
#define ADSP2_XMEM_ERR_ADDR_MASK 0x0000FFFF
#define ADSP2_PMEM_ERR_ADDR_MASK 0x7FFF0000
#define ADSP2_PMEM_ERR_ADDR_SHIFT 16
#define ADSP2_WDT_ENA_MASK 0xFFFFFFFD
#define ADSP2_LOCK_REGION_SHIFT 16
/*
* Event control messages
*/
#define CS_DSP_FW_EVENT_SHUTDOWN 0x000001
/*
* HALO system info
*/
#define HALO_AHBM_WINDOW_DEBUG_0 0x02040
#define HALO_AHBM_WINDOW_DEBUG_1 0x02044
/*
* HALO core
*/
#define HALO_SCRATCH1 0x005c0
#define HALO_SCRATCH2 0x005c8
#define HALO_SCRATCH3 0x005d0
#define HALO_SCRATCH4 0x005d8
#define HALO_CCM_CORE_CONTROL 0x41000
#define HALO_CORE_SOFT_RESET 0x00010
#define HALO_WDT_CONTROL 0x47000
/*
* HALO MPU banks
*/
#define HALO_MPU_XMEM_ACCESS_0 0x43000
#define HALO_MPU_YMEM_ACCESS_0 0x43004
#define HALO_MPU_WINDOW_ACCESS_0 0x43008
#define HALO_MPU_XREG_ACCESS_0 0x4300C
#define HALO_MPU_YREG_ACCESS_0 0x43014
#define HALO_MPU_XMEM_ACCESS_1 0x43018
#define HALO_MPU_YMEM_ACCESS_1 0x4301C
#define HALO_MPU_WINDOW_ACCESS_1 0x43020
#define HALO_MPU_XREG_ACCESS_1 0x43024
#define HALO_MPU_YREG_ACCESS_1 0x4302C
#define HALO_MPU_XMEM_ACCESS_2 0x43030
#define HALO_MPU_YMEM_ACCESS_2 0x43034
#define HALO_MPU_WINDOW_ACCESS_2 0x43038
#define HALO_MPU_XREG_ACCESS_2 0x4303C
#define HALO_MPU_YREG_ACCESS_2 0x43044
#define HALO_MPU_XMEM_ACCESS_3 0x43048
#define HALO_MPU_YMEM_ACCESS_3 0x4304C
#define HALO_MPU_WINDOW_ACCESS_3 0x43050
#define HALO_MPU_XREG_ACCESS_3 0x43054
#define HALO_MPU_YREG_ACCESS_3 0x4305C
#define HALO_MPU_XM_VIO_ADDR 0x43100
#define HALO_MPU_XM_VIO_STATUS 0x43104
#define HALO_MPU_YM_VIO_ADDR 0x43108
#define HALO_MPU_YM_VIO_STATUS 0x4310C
#define HALO_MPU_PM_VIO_ADDR 0x43110
#define HALO_MPU_PM_VIO_STATUS 0x43114
#define HALO_MPU_LOCK_CONFIG 0x43140
/*
* HALO_AHBM_WINDOW_DEBUG_1
*/
#define HALO_AHBM_CORE_ERR_ADDR_MASK 0x0fffff00
#define HALO_AHBM_CORE_ERR_ADDR_SHIFT 8
#define HALO_AHBM_FLAGS_ERR_MASK 0x000000ff
/*
* HALO_CCM_CORE_CONTROL
*/
#define HALO_CORE_RESET 0x00000200
#define HALO_CORE_EN 0x00000001
/*
* HALO_CORE_SOFT_RESET
*/
#define HALO_CORE_SOFT_RESET_MASK 0x00000001
/*
* HALO_WDT_CONTROL
*/
#define HALO_WDT_EN_MASK 0x00000001
/*
* HALO_MPU_?M_VIO_STATUS
*/
#define HALO_MPU_VIO_STS_MASK 0x007e0000
#define HALO_MPU_VIO_STS_SHIFT 17
#define HALO_MPU_VIO_ERR_WR_MASK 0x00008000
#define HALO_MPU_VIO_ERR_SRC_MASK 0x00007fff
#define HALO_MPU_VIO_ERR_SRC_SHIFT 0
/*
* Write Sequence
*/
#define WSEQ_OP_MAX_WORDS 3
#define WSEQ_END_OF_SCRIPT 0xFFFFFF
struct cs_dsp_ops {
bool (*validate_version)(struct cs_dsp *dsp, unsigned int version);
unsigned int (*parse_sizes)(struct cs_dsp *dsp,
const char * const file,
unsigned int pos,
const struct firmware *firmware);
int (*setup_algs)(struct cs_dsp *dsp);
unsigned int (*region_to_reg)(struct cs_dsp_region const *mem,
unsigned int offset);
void (*show_fw_status)(struct cs_dsp *dsp);
void (*stop_watchdog)(struct cs_dsp *dsp);
int (*enable_memory)(struct cs_dsp *dsp);
void (*disable_memory)(struct cs_dsp *dsp);
int (*lock_memory)(struct cs_dsp *dsp, unsigned int lock_regions);
int (*enable_core)(struct cs_dsp *dsp);
void (*disable_core)(struct cs_dsp *dsp);
int (*start_core)(struct cs_dsp *dsp);
void (*stop_core)(struct cs_dsp *dsp);
};
static const struct cs_dsp_ops cs_dsp_adsp1_ops;
static const struct cs_dsp_ops cs_dsp_adsp2_ops[];
static const struct cs_dsp_ops cs_dsp_halo_ops;
static const struct cs_dsp_ops cs_dsp_halo_ao_ops;
struct cs_dsp_buf {
struct list_head list;
void *buf;
};
static struct cs_dsp_buf *cs_dsp_buf_alloc(const void *src, size_t len,
struct list_head *list)
{
struct cs_dsp_buf *buf = kzalloc(sizeof(*buf), GFP_KERNEL);
if (buf == NULL)
return NULL;
buf->buf = vmalloc(len);
if (!buf->buf) {
kfree(buf);
return NULL;
}
memcpy(buf->buf, src, len);
if (list)
list_add_tail(&buf->list, list);
return buf;
}
static void cs_dsp_buf_free(struct list_head *list)
{
while (!list_empty(list)) {
struct cs_dsp_buf *buf = list_first_entry(list,
struct cs_dsp_buf,
list);
list_del(&buf->list);
vfree(buf->buf);
kfree(buf);
}
}
/**
* cs_dsp_mem_region_name() - Return a name string for a memory type
* @type: the memory type to match
*
* Return: A const string identifying the memory region.
*/
const char *cs_dsp_mem_region_name(unsigned int type)
{
switch (type) {
case WMFW_ADSP1_PM:
return "PM";
case WMFW_HALO_PM_PACKED:
return "PM_PACKED";
case WMFW_ADSP1_DM:
return "DM";
case WMFW_ADSP2_XM:
return "XM";
case WMFW_HALO_XM_PACKED:
return "XM_PACKED";
case WMFW_ADSP2_YM:
return "YM";
case WMFW_HALO_YM_PACKED:
return "YM_PACKED";
case WMFW_ADSP1_ZM:
return "ZM";
default:
return NULL;
}
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_mem_region_name, FW_CS_DSP);
#ifdef CONFIG_DEBUG_FS
static void cs_dsp_debugfs_save_wmfwname(struct cs_dsp *dsp, const char *s)
{
char *tmp = kasprintf(GFP_KERNEL, "%s\n", s);
kfree(dsp->wmfw_file_name);
dsp->wmfw_file_name = tmp;
}
static void cs_dsp_debugfs_save_binname(struct cs_dsp *dsp, const char *s)
{
char *tmp = kasprintf(GFP_KERNEL, "%s\n", s);
kfree(dsp->bin_file_name);
dsp->bin_file_name = tmp;
}
static void cs_dsp_debugfs_clear(struct cs_dsp *dsp)
{
kfree(dsp->wmfw_file_name);
kfree(dsp->bin_file_name);
dsp->wmfw_file_name = NULL;
dsp->bin_file_name = NULL;
}
static ssize_t cs_dsp_debugfs_wmfw_read(struct file *file,
char __user *user_buf,
size_t count, loff_t *ppos)
{
struct cs_dsp *dsp = file->private_data;
ssize_t ret;
mutex_lock(&dsp->pwr_lock);
if (!dsp->wmfw_file_name || !dsp->booted)
ret = 0;
else
ret = simple_read_from_buffer(user_buf, count, ppos,
dsp->wmfw_file_name,
strlen(dsp->wmfw_file_name));
mutex_unlock(&dsp->pwr_lock);
return ret;
}
static ssize_t cs_dsp_debugfs_bin_read(struct file *file,
char __user *user_buf,
size_t count, loff_t *ppos)
{
struct cs_dsp *dsp = file->private_data;
ssize_t ret;
mutex_lock(&dsp->pwr_lock);
if (!dsp->bin_file_name || !dsp->booted)
ret = 0;
else
ret = simple_read_from_buffer(user_buf, count, ppos,
dsp->bin_file_name,
strlen(dsp->bin_file_name));
mutex_unlock(&dsp->pwr_lock);
return ret;
}
static const struct {
const char *name;
const struct file_operations fops;
} cs_dsp_debugfs_fops[] = {
{
.name = "wmfw_file_name",
.fops = {
.open = simple_open,
.read = cs_dsp_debugfs_wmfw_read,
},
},
{
.name = "bin_file_name",
.fops = {
.open = simple_open,
.read = cs_dsp_debugfs_bin_read,
},
},
};
static int cs_dsp_coeff_base_reg(struct cs_dsp_coeff_ctl *ctl, unsigned int *reg,
unsigned int off);
static int cs_dsp_debugfs_read_controls_show(struct seq_file *s, void *ignored)
{
struct cs_dsp *dsp = s->private;
struct cs_dsp_coeff_ctl *ctl;
unsigned int reg;
list_for_each_entry(ctl, &dsp->ctl_list, list) {
cs_dsp_coeff_base_reg(ctl, &reg, 0);
seq_printf(s, "%22.*s: %#8zx %s:%08x %#8x %s %#8x %#4x %c%c%c%c %s %s\n",
ctl->subname_len, ctl->subname, ctl->len,
cs_dsp_mem_region_name(ctl->alg_region.type),
ctl->offset, reg, ctl->fw_name, ctl->alg_region.alg, ctl->type,
ctl->flags & WMFW_CTL_FLAG_VOLATILE ? 'V' : '-',
ctl->flags & WMFW_CTL_FLAG_SYS ? 'S' : '-',
ctl->flags & WMFW_CTL_FLAG_READABLE ? 'R' : '-',
ctl->flags & WMFW_CTL_FLAG_WRITEABLE ? 'W' : '-',
ctl->enabled ? "enabled" : "disabled",
ctl->set ? "dirty" : "clean");
}
return 0;
}
DEFINE_SHOW_ATTRIBUTE(cs_dsp_debugfs_read_controls);
/**
* cs_dsp_init_debugfs() - Create and populate DSP representation in debugfs
* @dsp: pointer to DSP structure
* @debugfs_root: pointer to debugfs directory in which to create this DSP
* representation
*/
void cs_dsp_init_debugfs(struct cs_dsp *dsp, struct dentry *debugfs_root)
{
struct dentry *root = NULL;
int i;
root = debugfs_create_dir(dsp->name, debugfs_root);
debugfs_create_bool("booted", 0444, root, &dsp->booted);
debugfs_create_bool("running", 0444, root, &dsp->running);
debugfs_create_x32("fw_id", 0444, root, &dsp->fw_id);
debugfs_create_x32("fw_version", 0444, root, &dsp->fw_id_version);
for (i = 0; i < ARRAY_SIZE(cs_dsp_debugfs_fops); ++i)
debugfs_create_file(cs_dsp_debugfs_fops[i].name, 0444, root,
dsp, &cs_dsp_debugfs_fops[i].fops);
debugfs_create_file("controls", 0444, root, dsp,
&cs_dsp_debugfs_read_controls_fops);
dsp->debugfs_root = root;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_init_debugfs, FW_CS_DSP);
/**
* cs_dsp_cleanup_debugfs() - Removes DSP representation from debugfs
* @dsp: pointer to DSP structure
*/
void cs_dsp_cleanup_debugfs(struct cs_dsp *dsp)
{
cs_dsp_debugfs_clear(dsp);
debugfs_remove_recursive(dsp->debugfs_root);
dsp->debugfs_root = ERR_PTR(-ENODEV);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_cleanup_debugfs, FW_CS_DSP);
#else
void cs_dsp_init_debugfs(struct cs_dsp *dsp, struct dentry *debugfs_root)
{
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_init_debugfs, FW_CS_DSP);
void cs_dsp_cleanup_debugfs(struct cs_dsp *dsp)
{
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_cleanup_debugfs, FW_CS_DSP);
static inline void cs_dsp_debugfs_save_wmfwname(struct cs_dsp *dsp,
const char *s)
{
}
static inline void cs_dsp_debugfs_save_binname(struct cs_dsp *dsp,
const char *s)
{
}
static inline void cs_dsp_debugfs_clear(struct cs_dsp *dsp)
{
}
#endif
static const struct cs_dsp_region *cs_dsp_find_region(struct cs_dsp *dsp,
int type)
{
int i;
for (i = 0; i < dsp->num_mems; i++)
if (dsp->mem[i].type == type)
return &dsp->mem[i];
return NULL;
}
static unsigned int cs_dsp_region_to_reg(struct cs_dsp_region const *mem,
unsigned int offset)
{
switch (mem->type) {
case WMFW_ADSP1_PM:
return mem->base + (offset * 3);
case WMFW_ADSP1_DM:
case WMFW_ADSP2_XM:
case WMFW_ADSP2_YM:
case WMFW_ADSP1_ZM:
return mem->base + (offset * 2);
default:
WARN(1, "Unknown memory region type");
return offset;
}
}
static unsigned int cs_dsp_halo_region_to_reg(struct cs_dsp_region const *mem,
unsigned int offset)
{
switch (mem->type) {
case WMFW_ADSP2_XM:
case WMFW_ADSP2_YM:
return mem->base + (offset * 4);
case WMFW_HALO_XM_PACKED:
case WMFW_HALO_YM_PACKED:
return (mem->base + (offset * 3)) & ~0x3;
case WMFW_HALO_PM_PACKED:
return mem->base + (offset * 5);
default:
WARN(1, "Unknown memory region type");
return offset;
}
}
static void cs_dsp_read_fw_status(struct cs_dsp *dsp,
int noffs, unsigned int *offs)
{
unsigned int i;
int ret;
for (i = 0; i < noffs; ++i) {
ret = regmap_read(dsp->regmap, dsp->base + offs[i], &offs[i]);
if (ret) {
cs_dsp_err(dsp, "Failed to read SCRATCH%u: %d\n", i, ret);
return;
}
}
}
static void cs_dsp_adsp2_show_fw_status(struct cs_dsp *dsp)
{
unsigned int offs[] = {
ADSP2_SCRATCH0, ADSP2_SCRATCH1, ADSP2_SCRATCH2, ADSP2_SCRATCH3,
};
cs_dsp_read_fw_status(dsp, ARRAY_SIZE(offs), offs);
cs_dsp_dbg(dsp, "FW SCRATCH 0:0x%x 1:0x%x 2:0x%x 3:0x%x\n",
offs[0], offs[1], offs[2], offs[3]);
}
static void cs_dsp_adsp2v2_show_fw_status(struct cs_dsp *dsp)
{
unsigned int offs[] = { ADSP2V2_SCRATCH0_1, ADSP2V2_SCRATCH2_3 };
cs_dsp_read_fw_status(dsp, ARRAY_SIZE(offs), offs);
cs_dsp_dbg(dsp, "FW SCRATCH 0:0x%x 1:0x%x 2:0x%x 3:0x%x\n",
offs[0] & 0xFFFF, offs[0] >> 16,
offs[1] & 0xFFFF, offs[1] >> 16);
}
static void cs_dsp_halo_show_fw_status(struct cs_dsp *dsp)
{
unsigned int offs[] = {
HALO_SCRATCH1, HALO_SCRATCH2, HALO_SCRATCH3, HALO_SCRATCH4,
};
cs_dsp_read_fw_status(dsp, ARRAY_SIZE(offs), offs);
cs_dsp_dbg(dsp, "FW SCRATCH 0:0x%x 1:0x%x 2:0x%x 3:0x%x\n",
offs[0], offs[1], offs[2], offs[3]);
}
static int cs_dsp_coeff_base_reg(struct cs_dsp_coeff_ctl *ctl, unsigned int *reg,
unsigned int off)
{
const struct cs_dsp_alg_region *alg_region = &ctl->alg_region;
struct cs_dsp *dsp = ctl->dsp;
const struct cs_dsp_region *mem;
mem = cs_dsp_find_region(dsp, alg_region->type);
if (!mem) {
cs_dsp_err(dsp, "No base for region %x\n",
alg_region->type);
return -EINVAL;
}
*reg = dsp->ops->region_to_reg(mem, ctl->alg_region.base + ctl->offset + off);
return 0;
}
/**
* cs_dsp_coeff_write_acked_control() - Sends event_id to the acked control
* @ctl: pointer to acked coefficient control
* @event_id: the value to write to the given acked control
*
* Once the value has been written to the control the function shall block
* until the running firmware acknowledges the write or timeout is exceeded.
*
* Must be called with pwr_lock held.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_coeff_write_acked_control(struct cs_dsp_coeff_ctl *ctl, unsigned int event_id)
{
struct cs_dsp *dsp = ctl->dsp;
__be32 val = cpu_to_be32(event_id);
unsigned int reg;
int i, ret;
lockdep_assert_held(&dsp->pwr_lock);
if (!dsp->running)
return -EPERM;
ret = cs_dsp_coeff_base_reg(ctl, &reg, 0);
if (ret)
return ret;
cs_dsp_dbg(dsp, "Sending 0x%x to acked control alg 0x%x %s:0x%x\n",
event_id, ctl->alg_region.alg,
cs_dsp_mem_region_name(ctl->alg_region.type), ctl->offset);
ret = regmap_raw_write(dsp->regmap, reg, &val, sizeof(val));
if (ret) {
cs_dsp_err(dsp, "Failed to write %x: %d\n", reg, ret);
return ret;
}
/*
* Poll for ack, we initially poll at ~1ms intervals for firmwares
* that respond quickly, then go to ~10ms polls. A firmware is unlikely
* to ack instantly so we do the first 1ms delay before reading the
* control to avoid a pointless bus transaction
*/
for (i = 0; i < CS_DSP_ACKED_CTL_TIMEOUT_MS;) {
switch (i) {
case 0 ... CS_DSP_ACKED_CTL_N_QUICKPOLLS - 1:
usleep_range(1000, 2000);
i++;
break;
default:
usleep_range(10000, 20000);
i += 10;
break;
}
ret = regmap_raw_read(dsp->regmap, reg, &val, sizeof(val));
if (ret) {
cs_dsp_err(dsp, "Failed to read %x: %d\n", reg, ret);
return ret;
}
if (val == 0) {
cs_dsp_dbg(dsp, "Acked control ACKED at poll %u\n", i);
return 0;
}
}
cs_dsp_warn(dsp, "Acked control @0x%x alg:0x%x %s:0x%x timed out\n",
reg, ctl->alg_region.alg,
cs_dsp_mem_region_name(ctl->alg_region.type),
ctl->offset);
return -ETIMEDOUT;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_coeff_write_acked_control, FW_CS_DSP);
static int cs_dsp_coeff_write_ctrl_raw(struct cs_dsp_coeff_ctl *ctl,
unsigned int off, const void *buf, size_t len)
{
struct cs_dsp *dsp = ctl->dsp;
void *scratch;
int ret;
unsigned int reg;
ret = cs_dsp_coeff_base_reg(ctl, &reg, off);
if (ret)
return ret;
scratch = kmemdup(buf, len, GFP_KERNEL | GFP_DMA);
if (!scratch)
return -ENOMEM;
ret = regmap_raw_write(dsp->regmap, reg, scratch,
len);
if (ret) {
cs_dsp_err(dsp, "Failed to write %zu bytes to %x: %d\n",
len, reg, ret);
kfree(scratch);
return ret;
}
cs_dsp_dbg(dsp, "Wrote %zu bytes to %x\n", len, reg);
kfree(scratch);
return 0;
}
/**
* cs_dsp_coeff_write_ctrl() - Writes the given buffer to the given coefficient control
* @ctl: pointer to coefficient control
* @off: word offset at which data should be written
* @buf: the buffer to write to the given control
* @len: the length of the buffer in bytes
*
* Must be called with pwr_lock held.
*
* Return: < 0 on error, 1 when the control value changed and 0 when it has not.
*/
int cs_dsp_coeff_write_ctrl(struct cs_dsp_coeff_ctl *ctl,
unsigned int off, const void *buf, size_t len)
{
int ret = 0;
if (!ctl)
return -ENOENT;
lockdep_assert_held(&ctl->dsp->pwr_lock);
if (ctl->flags && !(ctl->flags & WMFW_CTL_FLAG_WRITEABLE))
return -EPERM;
if (len + off * sizeof(u32) > ctl->len)
return -EINVAL;
if (ctl->flags & WMFW_CTL_FLAG_VOLATILE) {
ret = -EPERM;
} else if (buf != ctl->cache) {
if (memcmp(ctl->cache + off * sizeof(u32), buf, len))
memcpy(ctl->cache + off * sizeof(u32), buf, len);
else
return 0;
}
ctl->set = 1;
if (ctl->enabled && ctl->dsp->running)
ret = cs_dsp_coeff_write_ctrl_raw(ctl, off, buf, len);
if (ret < 0)
return ret;
return 1;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_coeff_write_ctrl, FW_CS_DSP);
/**
* cs_dsp_coeff_lock_and_write_ctrl() - Writes the given buffer to the given coefficient control
* @ctl: pointer to coefficient control
* @off: word offset at which data should be written
* @buf: the buffer to write to the given control
* @len: the length of the buffer in bytes
*
* Same as cs_dsp_coeff_write_ctrl() but takes pwr_lock.
*
* Return: A negative number on error, 1 when the control value changed and 0 when it has not.
*/
int cs_dsp_coeff_lock_and_write_ctrl(struct cs_dsp_coeff_ctl *ctl,
unsigned int off, const void *buf, size_t len)
{
struct cs_dsp *dsp = ctl->dsp;
int ret;
lockdep_assert_not_held(&dsp->pwr_lock);
mutex_lock(&dsp->pwr_lock);
ret = cs_dsp_coeff_write_ctrl(ctl, off, buf, len);
mutex_unlock(&dsp->pwr_lock);
return ret;
}
EXPORT_SYMBOL_GPL(cs_dsp_coeff_lock_and_write_ctrl);
static int cs_dsp_coeff_read_ctrl_raw(struct cs_dsp_coeff_ctl *ctl,
unsigned int off, void *buf, size_t len)
{
struct cs_dsp *dsp = ctl->dsp;
void *scratch;
int ret;
unsigned int reg;
ret = cs_dsp_coeff_base_reg(ctl, &reg, off);
if (ret)
return ret;
scratch = kmalloc(len, GFP_KERNEL | GFP_DMA);
if (!scratch)
return -ENOMEM;
ret = regmap_raw_read(dsp->regmap, reg, scratch, len);
if (ret) {
cs_dsp_err(dsp, "Failed to read %zu bytes from %x: %d\n",
len, reg, ret);
kfree(scratch);
return ret;
}
cs_dsp_dbg(dsp, "Read %zu bytes from %x\n", len, reg);
memcpy(buf, scratch, len);
kfree(scratch);
return 0;
}
/**
* cs_dsp_coeff_read_ctrl() - Reads the given coefficient control into the given buffer
* @ctl: pointer to coefficient control
* @off: word offset at which data should be read
* @buf: the buffer to store to the given control
* @len: the length of the buffer in bytes
*
* Must be called with pwr_lock held.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_coeff_read_ctrl(struct cs_dsp_coeff_ctl *ctl,
unsigned int off, void *buf, size_t len)
{
int ret = 0;
if (!ctl)
return -ENOENT;
lockdep_assert_held(&ctl->dsp->pwr_lock);
if (len + off * sizeof(u32) > ctl->len)
return -EINVAL;
if (ctl->flags & WMFW_CTL_FLAG_VOLATILE) {
if (ctl->enabled && ctl->dsp->running)
return cs_dsp_coeff_read_ctrl_raw(ctl, off, buf, len);
else
return -EPERM;
} else {
if (!ctl->flags && ctl->enabled && ctl->dsp->running)
ret = cs_dsp_coeff_read_ctrl_raw(ctl, 0, ctl->cache, ctl->len);
if (buf != ctl->cache)
memcpy(buf, ctl->cache + off * sizeof(u32), len);
}
return ret;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_coeff_read_ctrl, FW_CS_DSP);
/**
* cs_dsp_coeff_lock_and_read_ctrl() - Reads the given coefficient control into the given buffer
* @ctl: pointer to coefficient control
* @off: word offset at which data should be read
* @buf: the buffer to store to the given control
* @len: the length of the buffer in bytes
*
* Same as cs_dsp_coeff_read_ctrl() but takes pwr_lock.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_coeff_lock_and_read_ctrl(struct cs_dsp_coeff_ctl *ctl,
unsigned int off, void *buf, size_t len)
{
struct cs_dsp *dsp = ctl->dsp;
int ret;
lockdep_assert_not_held(&dsp->pwr_lock);
mutex_lock(&dsp->pwr_lock);
ret = cs_dsp_coeff_read_ctrl(ctl, off, buf, len);
mutex_unlock(&dsp->pwr_lock);
return ret;
}
EXPORT_SYMBOL_GPL(cs_dsp_coeff_lock_and_read_ctrl);
static int cs_dsp_coeff_init_control_caches(struct cs_dsp *dsp)
{
struct cs_dsp_coeff_ctl *ctl;
int ret;
list_for_each_entry(ctl, &dsp->ctl_list, list) {
if (!ctl->enabled || ctl->set)
continue;
if (ctl->flags & WMFW_CTL_FLAG_VOLATILE)
continue;
/*
* For readable controls populate the cache from the DSP memory.
* For non-readable controls the cache was zero-filled when
* created so we don't need to do anything.
*/
if (!ctl->flags || (ctl->flags & WMFW_CTL_FLAG_READABLE)) {
ret = cs_dsp_coeff_read_ctrl_raw(ctl, 0, ctl->cache, ctl->len);
if (ret < 0)
return ret;
}
}
return 0;
}
static int cs_dsp_coeff_sync_controls(struct cs_dsp *dsp)
{
struct cs_dsp_coeff_ctl *ctl;
int ret;
list_for_each_entry(ctl, &dsp->ctl_list, list) {
if (!ctl->enabled)
continue;
if (ctl->set && !(ctl->flags & WMFW_CTL_FLAG_VOLATILE)) {
ret = cs_dsp_coeff_write_ctrl_raw(ctl, 0, ctl->cache,
ctl->len);
if (ret < 0)
return ret;
}
}
return 0;
}
static void cs_dsp_signal_event_controls(struct cs_dsp *dsp,
unsigned int event)
{
struct cs_dsp_coeff_ctl *ctl;
int ret;
list_for_each_entry(ctl, &dsp->ctl_list, list) {
if (ctl->type != WMFW_CTL_TYPE_HOSTEVENT)
continue;
if (!ctl->enabled)
continue;
ret = cs_dsp_coeff_write_acked_control(ctl, event);
if (ret)
cs_dsp_warn(dsp,
"Failed to send 0x%x event to alg 0x%x (%d)\n",
event, ctl->alg_region.alg, ret);
}
}
static void cs_dsp_free_ctl_blk(struct cs_dsp_coeff_ctl *ctl)
{
kfree(ctl->cache);
kfree(ctl->subname);
kfree(ctl);
}
static int cs_dsp_create_control(struct cs_dsp *dsp,
const struct cs_dsp_alg_region *alg_region,
unsigned int offset, unsigned int len,
const char *subname, unsigned int subname_len,
unsigned int flags, unsigned int type)
{
struct cs_dsp_coeff_ctl *ctl;
int ret;
list_for_each_entry(ctl, &dsp->ctl_list, list) {
if (ctl->fw_name == dsp->fw_name &&
ctl->alg_region.alg == alg_region->alg &&
ctl->alg_region.type == alg_region->type) {
if ((!subname && !ctl->subname) ||
(subname && (ctl->subname_len == subname_len) &&
!strncmp(ctl->subname, subname, ctl->subname_len))) {
if (!ctl->enabled)
ctl->enabled = 1;
return 0;
}
}
}
ctl = kzalloc(sizeof(*ctl), GFP_KERNEL);
if (!ctl)
return -ENOMEM;
ctl->fw_name = dsp->fw_name;
ctl->alg_region = *alg_region;
if (subname && dsp->wmfw_ver >= 2) {
ctl->subname_len = subname_len;
ctl->subname = kasprintf(GFP_KERNEL, "%.*s", subname_len, subname);
if (!ctl->subname) {
ret = -ENOMEM;
goto err_ctl;
}
}
ctl->enabled = 1;
ctl->set = 0;
ctl->dsp = dsp;
ctl->flags = flags;
ctl->type = type;
ctl->offset = offset;
ctl->len = len;
ctl->cache = kzalloc(ctl->len, GFP_KERNEL);
if (!ctl->cache) {
ret = -ENOMEM;
goto err_ctl_subname;
}
list_add(&ctl->list, &dsp->ctl_list);
if (dsp->client_ops->control_add) {
ret = dsp->client_ops->control_add(ctl);
if (ret)
goto err_list_del;
}
return 0;
err_list_del:
list_del(&ctl->list);
kfree(ctl->cache);
err_ctl_subname:
kfree(ctl->subname);
err_ctl:
kfree(ctl);
return ret;
}
struct cs_dsp_coeff_parsed_alg {
int id;
const u8 *name;
int name_len;
int ncoeff;
};
struct cs_dsp_coeff_parsed_coeff {
int offset;
int mem_type;
const u8 *name;
int name_len;
unsigned int ctl_type;
int flags;
int len;
};
static int cs_dsp_coeff_parse_string(int bytes, const u8 **pos, unsigned int avail,
const u8 **str)
{
int length, total_field_len;
/* String fields are at least one __le32 */
if (sizeof(__le32) > avail) {
*pos = NULL;
return 0;
}
switch (bytes) {
case 1:
length = **pos;
break;
case 2:
length = le16_to_cpu(*((__le16 *)*pos));
break;
default:
return 0;
}
total_field_len = ((length + bytes) + 3) & ~0x03;
if ((unsigned int)total_field_len > avail) {
*pos = NULL;
return 0;
}
if (str)
*str = *pos + bytes;
*pos += total_field_len;
return length;
}
static int cs_dsp_coeff_parse_int(int bytes, const u8 **pos)
{
int val = 0;
switch (bytes) {
case 2:
val = le16_to_cpu(*((__le16 *)*pos));
break;
case 4:
val = le32_to_cpu(*((__le32 *)*pos));
break;
default:
break;
}
*pos += bytes;
return val;
}
static int cs_dsp_coeff_parse_alg(struct cs_dsp *dsp,
const struct wmfw_region *region,
struct cs_dsp_coeff_parsed_alg *blk)
{
const struct wmfw_adsp_alg_data *raw;
unsigned int data_len = le32_to_cpu(region->len);
unsigned int pos;
const u8 *tmp;
raw = (const struct wmfw_adsp_alg_data *)region->data;
switch (dsp->wmfw_ver) {
case 0:
case 1:
if (sizeof(*raw) > data_len)
return -EOVERFLOW;
blk->id = le32_to_cpu(raw->id);
blk->name = raw->name;
blk->name_len = strnlen(raw->name, ARRAY_SIZE(raw->name));
blk->ncoeff = le32_to_cpu(raw->ncoeff);
pos = sizeof(*raw);
break;
default:
if (sizeof(raw->id) > data_len)
return -EOVERFLOW;
tmp = region->data;
blk->id = cs_dsp_coeff_parse_int(sizeof(raw->id), &tmp);
pos = tmp - region->data;
tmp = &region->data[pos];
blk->name_len = cs_dsp_coeff_parse_string(sizeof(u8), &tmp, data_len - pos,
&blk->name);
if (!tmp)
return -EOVERFLOW;
pos = tmp - region->data;
cs_dsp_coeff_parse_string(sizeof(u16), &tmp, data_len - pos, NULL);
if (!tmp)
return -EOVERFLOW;
pos = tmp - region->data;
if (sizeof(raw->ncoeff) > (data_len - pos))
return -EOVERFLOW;
blk->ncoeff = cs_dsp_coeff_parse_int(sizeof(raw->ncoeff), &tmp);
pos += sizeof(raw->ncoeff);
break;
}
if ((int)blk->ncoeff < 0)
return -EOVERFLOW;
cs_dsp_dbg(dsp, "Algorithm ID: %#x\n", blk->id);
cs_dsp_dbg(dsp, "Algorithm name: %.*s\n", blk->name_len, blk->name);
cs_dsp_dbg(dsp, "# of coefficient descriptors: %#x\n", blk->ncoeff);
return pos;
}
static int cs_dsp_coeff_parse_coeff(struct cs_dsp *dsp,
const struct wmfw_region *region,
unsigned int pos,
struct cs_dsp_coeff_parsed_coeff *blk)
{
const struct wmfw_adsp_coeff_data *raw;
unsigned int data_len = le32_to_cpu(region->len);
unsigned int blk_len, blk_end_pos;
const u8 *tmp;
raw = (const struct wmfw_adsp_coeff_data *)&region->data[pos];
if (sizeof(raw->hdr) > (data_len - pos))
return -EOVERFLOW;
blk_len = le32_to_cpu(raw->hdr.size);
if (blk_len > S32_MAX)
return -EOVERFLOW;
if (blk_len > (data_len - pos - sizeof(raw->hdr)))
return -EOVERFLOW;
blk_end_pos = pos + sizeof(raw->hdr) + blk_len;
blk->offset = le16_to_cpu(raw->hdr.offset);
blk->mem_type = le16_to_cpu(raw->hdr.type);
switch (dsp->wmfw_ver) {
case 0:
case 1:
if (sizeof(*raw) > (data_len - pos))
return -EOVERFLOW;
blk->name = raw->name;
blk->name_len = strnlen(raw->name, ARRAY_SIZE(raw->name));
blk->ctl_type = le16_to_cpu(raw->ctl_type);
blk->flags = le16_to_cpu(raw->flags);
blk->len = le32_to_cpu(raw->len);
break;
default:
pos += sizeof(raw->hdr);
tmp = &region->data[pos];
blk->name_len = cs_dsp_coeff_parse_string(sizeof(u8), &tmp, data_len - pos,
&blk->name);
if (!tmp)
return -EOVERFLOW;
pos = tmp - region->data;
cs_dsp_coeff_parse_string(sizeof(u8), &tmp, data_len - pos, NULL);
if (!tmp)
return -EOVERFLOW;
pos = tmp - region->data;
cs_dsp_coeff_parse_string(sizeof(u16), &tmp, data_len - pos, NULL);
if (!tmp)
return -EOVERFLOW;
pos = tmp - region->data;
if (sizeof(raw->ctl_type) + sizeof(raw->flags) + sizeof(raw->len) >
(data_len - pos))
return -EOVERFLOW;
blk->ctl_type = cs_dsp_coeff_parse_int(sizeof(raw->ctl_type), &tmp);
pos += sizeof(raw->ctl_type);
blk->flags = cs_dsp_coeff_parse_int(sizeof(raw->flags), &tmp);
pos += sizeof(raw->flags);
blk->len = cs_dsp_coeff_parse_int(sizeof(raw->len), &tmp);
break;
}
cs_dsp_dbg(dsp, "\tCoefficient type: %#x\n", blk->mem_type);
cs_dsp_dbg(dsp, "\tCoefficient offset: %#x\n", blk->offset);
cs_dsp_dbg(dsp, "\tCoefficient name: %.*s\n", blk->name_len, blk->name);
cs_dsp_dbg(dsp, "\tCoefficient flags: %#x\n", blk->flags);
cs_dsp_dbg(dsp, "\tALSA control type: %#x\n", blk->ctl_type);
cs_dsp_dbg(dsp, "\tALSA control len: %#x\n", blk->len);
return blk_end_pos;
}
static int cs_dsp_check_coeff_flags(struct cs_dsp *dsp,
const struct cs_dsp_coeff_parsed_coeff *coeff_blk,
unsigned int f_required,
unsigned int f_illegal)
{
if ((coeff_blk->flags & f_illegal) ||
((coeff_blk->flags & f_required) != f_required)) {
cs_dsp_err(dsp, "Illegal flags 0x%x for control type 0x%x\n",
coeff_blk->flags, coeff_blk->ctl_type);
return -EINVAL;
}
return 0;
}
static int cs_dsp_parse_coeff(struct cs_dsp *dsp,
const struct wmfw_region *region)
{
struct cs_dsp_alg_region alg_region = {};
struct cs_dsp_coeff_parsed_alg alg_blk;
struct cs_dsp_coeff_parsed_coeff coeff_blk;
int i, pos, ret;
pos = cs_dsp_coeff_parse_alg(dsp, region, &alg_blk);
if (pos < 0)
return pos;
for (i = 0; i < alg_blk.ncoeff; i++) {
pos = cs_dsp_coeff_parse_coeff(dsp, region, pos, &coeff_blk);
if (pos < 0)
return pos;
switch (coeff_blk.ctl_type) {
case WMFW_CTL_TYPE_BYTES:
break;
case WMFW_CTL_TYPE_ACKED:
if (coeff_blk.flags & WMFW_CTL_FLAG_SYS)
continue; /* ignore */
ret = cs_dsp_check_coeff_flags(dsp, &coeff_blk,
WMFW_CTL_FLAG_VOLATILE |
WMFW_CTL_FLAG_WRITEABLE |
WMFW_CTL_FLAG_READABLE,
0);
if (ret)
return -EINVAL;
break;
case WMFW_CTL_TYPE_HOSTEVENT:
case WMFW_CTL_TYPE_FWEVENT:
ret = cs_dsp_check_coeff_flags(dsp, &coeff_blk,
WMFW_CTL_FLAG_SYS |
WMFW_CTL_FLAG_VOLATILE |
WMFW_CTL_FLAG_WRITEABLE |
WMFW_CTL_FLAG_READABLE,
0);
if (ret)
return -EINVAL;
break;
case WMFW_CTL_TYPE_HOST_BUFFER:
ret = cs_dsp_check_coeff_flags(dsp, &coeff_blk,
WMFW_CTL_FLAG_SYS |
WMFW_CTL_FLAG_VOLATILE |
WMFW_CTL_FLAG_READABLE,
0);
if (ret)
return -EINVAL;
break;
default:
cs_dsp_err(dsp, "Unknown control type: %d\n",
coeff_blk.ctl_type);
return -EINVAL;
}
alg_region.type = coeff_blk.mem_type;
alg_region.alg = alg_blk.id;
ret = cs_dsp_create_control(dsp, &alg_region,
coeff_blk.offset,
coeff_blk.len,
coeff_blk.name,
coeff_blk.name_len,
coeff_blk.flags,
coeff_blk.ctl_type);
if (ret < 0)
cs_dsp_err(dsp, "Failed to create control: %.*s, %d\n",
coeff_blk.name_len, coeff_blk.name, ret);
}
return 0;
}
static unsigned int cs_dsp_adsp1_parse_sizes(struct cs_dsp *dsp,
const char * const file,
unsigned int pos,
const struct firmware *firmware)
{
const struct wmfw_adsp1_sizes *adsp1_sizes;
adsp1_sizes = (void *)&firmware->data[pos];
if (sizeof(*adsp1_sizes) > firmware->size - pos) {
cs_dsp_err(dsp, "%s: file truncated\n", file);
return 0;
}
cs_dsp_dbg(dsp, "%s: %d DM, %d PM, %d ZM\n", file,
le32_to_cpu(adsp1_sizes->dm), le32_to_cpu(adsp1_sizes->pm),
le32_to_cpu(adsp1_sizes->zm));
return pos + sizeof(*adsp1_sizes);
}
static unsigned int cs_dsp_adsp2_parse_sizes(struct cs_dsp *dsp,
const char * const file,
unsigned int pos,
const struct firmware *firmware)
{
const struct wmfw_adsp2_sizes *adsp2_sizes;
adsp2_sizes = (void *)&firmware->data[pos];
if (sizeof(*adsp2_sizes) > firmware->size - pos) {
cs_dsp_err(dsp, "%s: file truncated\n", file);
return 0;
}
cs_dsp_dbg(dsp, "%s: %d XM, %d YM %d PM, %d ZM\n", file,
le32_to_cpu(adsp2_sizes->xm), le32_to_cpu(adsp2_sizes->ym),
le32_to_cpu(adsp2_sizes->pm), le32_to_cpu(adsp2_sizes->zm));
return pos + sizeof(*adsp2_sizes);
}
static bool cs_dsp_validate_version(struct cs_dsp *dsp, unsigned int version)
{
switch (version) {
case 0:
cs_dsp_warn(dsp, "Deprecated file format %d\n", version);
return true;
case 1:
case 2:
return true;
default:
return false;
}
}
static bool cs_dsp_halo_validate_version(struct cs_dsp *dsp, unsigned int version)
{
switch (version) {
case 3:
return true;
default:
return false;
}
}
static int cs_dsp_load(struct cs_dsp *dsp, const struct firmware *firmware,
const char *file)
{
LIST_HEAD(buf_list);
struct regmap *regmap = dsp->regmap;
unsigned int pos = 0;
const struct wmfw_header *header;
const struct wmfw_footer *footer;
const struct wmfw_region *region;
const struct cs_dsp_region *mem;
const char *region_name;
struct cs_dsp_buf *buf;
unsigned int reg;
int regions = 0;
int ret, offset, type;
if (!firmware)
return 0;
ret = -EINVAL;
if (sizeof(*header) >= firmware->size) {
ret = -EOVERFLOW;
goto out_fw;
}
header = (void *)&firmware->data[0];
if (memcmp(&header->magic[0], "WMFW", 4) != 0) {
cs_dsp_err(dsp, "%s: invalid magic\n", file);
goto out_fw;
}
if (!dsp->ops->validate_version(dsp, header->ver)) {
cs_dsp_err(dsp, "%s: unknown file format %d\n",
file, header->ver);
goto out_fw;
}
dsp->wmfw_ver = header->ver;
if (header->core != dsp->type) {
cs_dsp_err(dsp, "%s: invalid core %d != %d\n",
file, header->core, dsp->type);
goto out_fw;
}
pos = sizeof(*header);
pos = dsp->ops->parse_sizes(dsp, file, pos, firmware);
if ((pos == 0) || (sizeof(*footer) > firmware->size - pos)) {
ret = -EOVERFLOW;
goto out_fw;
}
footer = (void *)&firmware->data[pos];
pos += sizeof(*footer);
if (le32_to_cpu(header->len) != pos) {
ret = -EOVERFLOW;
goto out_fw;
}
cs_dsp_info(dsp, "%s: format %d timestamp %#llx\n", file, header->ver,
le64_to_cpu(footer->timestamp));
while (pos < firmware->size) {
/* Is there enough data for a complete block header? */
if (sizeof(*region) > firmware->size - pos) {
ret = -EOVERFLOW;
goto out_fw;
}
region = (void *)&(firmware->data[pos]);
if (le32_to_cpu(region->len) > firmware->size - pos - sizeof(*region)) {
ret = -EOVERFLOW;
goto out_fw;
}
region_name = "Unknown";
reg = 0;
offset = le32_to_cpu(region->offset) & 0xffffff;
type = be32_to_cpu(region->type) & 0xff;
switch (type) {
case WMFW_INFO_TEXT:
case WMFW_NAME_TEXT:
region_name = "Info/Name";
cs_dsp_info(dsp, "%s: %.*s\n", file,
min(le32_to_cpu(region->len), 100), region->data);
break;
case WMFW_ALGORITHM_DATA:
region_name = "Algorithm";
ret = cs_dsp_parse_coeff(dsp, region);
if (ret != 0)
goto out_fw;
break;
case WMFW_ABSOLUTE:
region_name = "Absolute";
reg = offset;
break;
case WMFW_ADSP1_PM:
case WMFW_ADSP1_DM:
case WMFW_ADSP2_XM:
case WMFW_ADSP2_YM:
case WMFW_ADSP1_ZM:
case WMFW_HALO_PM_PACKED:
case WMFW_HALO_XM_PACKED:
case WMFW_HALO_YM_PACKED:
mem = cs_dsp_find_region(dsp, type);
if (!mem) {
cs_dsp_err(dsp, "No region of type: %x\n", type);
ret = -EINVAL;
goto out_fw;
}
region_name = cs_dsp_mem_region_name(type);
reg = dsp->ops->region_to_reg(mem, offset);
break;
default:
cs_dsp_warn(dsp,
"%s.%d: Unknown region type %x at %d(%x)\n",
file, regions, type, pos, pos);
break;
}
cs_dsp_dbg(dsp, "%s.%d: %d bytes at %d in %s\n", file,
regions, le32_to_cpu(region->len), offset,
region_name);
if (reg) {
buf = cs_dsp_buf_alloc(region->data,
le32_to_cpu(region->len),
&buf_list);
if (!buf) {
cs_dsp_err(dsp, "Out of memory\n");
ret = -ENOMEM;
goto out_fw;
}
ret = regmap_raw_write_async(regmap, reg, buf->buf,
le32_to_cpu(region->len));
if (ret != 0) {
cs_dsp_err(dsp,
"%s.%d: Failed to write %d bytes at %d in %s: %d\n",
file, regions,
le32_to_cpu(region->len), offset,
region_name, ret);
goto out_fw;
}
}
pos += le32_to_cpu(region->len) + sizeof(*region);
regions++;
}
ret = regmap_async_complete(regmap);
if (ret != 0) {
cs_dsp_err(dsp, "Failed to complete async write: %d\n", ret);
goto out_fw;
}
if (pos > firmware->size)
cs_dsp_warn(dsp, "%s.%d: %zu bytes at end of file\n",
file, regions, pos - firmware->size);
cs_dsp_debugfs_save_wmfwname(dsp, file);
out_fw:
regmap_async_complete(regmap);
cs_dsp_buf_free(&buf_list);
if (ret == -EOVERFLOW)
cs_dsp_err(dsp, "%s: file content overflows file data\n", file);
return ret;
}
/**
* cs_dsp_get_ctl() - Finds a matching coefficient control
* @dsp: pointer to DSP structure
* @name: pointer to string to match with a control's subname
* @type: the algorithm type to match
* @alg: the algorithm id to match
*
* Find cs_dsp_coeff_ctl with input name as its subname
*
* Return: pointer to the control on success, NULL if not found
*/
struct cs_dsp_coeff_ctl *cs_dsp_get_ctl(struct cs_dsp *dsp, const char *name, int type,
unsigned int alg)
{
struct cs_dsp_coeff_ctl *pos, *rslt = NULL;
lockdep_assert_held(&dsp->pwr_lock);
list_for_each_entry(pos, &dsp->ctl_list, list) {
if (!pos->subname)
continue;
if (strncmp(pos->subname, name, pos->subname_len) == 0 &&
pos->fw_name == dsp->fw_name &&
pos->alg_region.alg == alg &&
pos->alg_region.type == type) {
rslt = pos;
break;
}
}
return rslt;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_get_ctl, FW_CS_DSP);
static void cs_dsp_ctl_fixup_base(struct cs_dsp *dsp,
const struct cs_dsp_alg_region *alg_region)
{
struct cs_dsp_coeff_ctl *ctl;
list_for_each_entry(ctl, &dsp->ctl_list, list) {
if (ctl->fw_name == dsp->fw_name &&
alg_region->alg == ctl->alg_region.alg &&
alg_region->type == ctl->alg_region.type) {
ctl->alg_region.base = alg_region->base;
}
}
}
static void *cs_dsp_read_algs(struct cs_dsp *dsp, size_t n_algs,
const struct cs_dsp_region *mem,
unsigned int pos, unsigned int len)
{
void *alg;
unsigned int reg;
int ret;
__be32 val;
if (n_algs == 0) {
cs_dsp_err(dsp, "No algorithms\n");
return ERR_PTR(-EINVAL);
}
if (n_algs > 1024) {
cs_dsp_err(dsp, "Algorithm count %zx excessive\n", n_algs);
return ERR_PTR(-EINVAL);
}
/* Read the terminator first to validate the length */
reg = dsp->ops->region_to_reg(mem, pos + len);
ret = regmap_raw_read(dsp->regmap, reg, &val, sizeof(val));
if (ret != 0) {
cs_dsp_err(dsp, "Failed to read algorithm list end: %d\n",
ret);
return ERR_PTR(ret);
}
if (be32_to_cpu(val) != 0xbedead)
cs_dsp_warn(dsp, "Algorithm list end %x 0x%x != 0xbedead\n",
reg, be32_to_cpu(val));
/* Convert length from DSP words to bytes */
len *= sizeof(u32);
alg = kzalloc(len, GFP_KERNEL | GFP_DMA);
if (!alg)
return ERR_PTR(-ENOMEM);
reg = dsp->ops->region_to_reg(mem, pos);
ret = regmap_raw_read(dsp->regmap, reg, alg, len);
if (ret != 0) {
cs_dsp_err(dsp, "Failed to read algorithm list: %d\n", ret);
kfree(alg);
return ERR_PTR(ret);
}
return alg;
}
/**
* cs_dsp_find_alg_region() - Finds a matching algorithm region
* @dsp: pointer to DSP structure
* @type: the algorithm type to match
* @id: the algorithm id to match
*
* Return: Pointer to matching algorithm region, or NULL if not found.
*/
struct cs_dsp_alg_region *cs_dsp_find_alg_region(struct cs_dsp *dsp,
int type, unsigned int id)
{
struct cs_dsp_alg_region *alg_region;
lockdep_assert_held(&dsp->pwr_lock);
list_for_each_entry(alg_region, &dsp->alg_regions, list) {
if (id == alg_region->alg && type == alg_region->type)
return alg_region;
}
return NULL;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_find_alg_region, FW_CS_DSP);
static struct cs_dsp_alg_region *cs_dsp_create_region(struct cs_dsp *dsp,
int type, __be32 id,
__be32 ver, __be32 base)
{
struct cs_dsp_alg_region *alg_region;
alg_region = kzalloc(sizeof(*alg_region), GFP_KERNEL);
if (!alg_region)
return ERR_PTR(-ENOMEM);
alg_region->type = type;
alg_region->alg = be32_to_cpu(id);
alg_region->ver = be32_to_cpu(ver);
alg_region->base = be32_to_cpu(base);
list_add_tail(&alg_region->list, &dsp->alg_regions);
if (dsp->wmfw_ver > 0)
cs_dsp_ctl_fixup_base(dsp, alg_region);
return alg_region;
}
static void cs_dsp_free_alg_regions(struct cs_dsp *dsp)
{
struct cs_dsp_alg_region *alg_region;
while (!list_empty(&dsp->alg_regions)) {
alg_region = list_first_entry(&dsp->alg_regions,
struct cs_dsp_alg_region,
list);
list_del(&alg_region->list);
kfree(alg_region);
}
}
static void cs_dsp_parse_wmfw_id_header(struct cs_dsp *dsp,
struct wmfw_id_hdr *fw, int nalgs)
{
dsp->fw_id = be32_to_cpu(fw->id);
dsp->fw_id_version = be32_to_cpu(fw->ver);
cs_dsp_info(dsp, "Firmware: %x v%d.%d.%d, %d algorithms\n",
dsp->fw_id, (dsp->fw_id_version & 0xff0000) >> 16,
(dsp->fw_id_version & 0xff00) >> 8, dsp->fw_id_version & 0xff,
nalgs);
}
static void cs_dsp_parse_wmfw_v3_id_header(struct cs_dsp *dsp,
struct wmfw_v3_id_hdr *fw, int nalgs)
{
dsp->fw_id = be32_to_cpu(fw->id);
dsp->fw_id_version = be32_to_cpu(fw->ver);
dsp->fw_vendor_id = be32_to_cpu(fw->vendor_id);
cs_dsp_info(dsp, "Firmware: %x vendor: 0x%x v%d.%d.%d, %d algorithms\n",
dsp->fw_id, dsp->fw_vendor_id,
(dsp->fw_id_version & 0xff0000) >> 16,
(dsp->fw_id_version & 0xff00) >> 8, dsp->fw_id_version & 0xff,
nalgs);
}
static int cs_dsp_create_regions(struct cs_dsp *dsp, __be32 id, __be32 ver,
int nregions, const int *type, __be32 *base)
{
struct cs_dsp_alg_region *alg_region;
int i;
for (i = 0; i < nregions; i++) {
alg_region = cs_dsp_create_region(dsp, type[i], id, ver, base[i]);
if (IS_ERR(alg_region))
return PTR_ERR(alg_region);
}
return 0;
}
static int cs_dsp_adsp1_setup_algs(struct cs_dsp *dsp)
{
struct wmfw_adsp1_id_hdr adsp1_id;
struct wmfw_adsp1_alg_hdr *adsp1_alg;
struct cs_dsp_alg_region *alg_region;
const struct cs_dsp_region *mem;
unsigned int pos, len;
size_t n_algs;
int i, ret;
mem = cs_dsp_find_region(dsp, WMFW_ADSP1_DM);
if (WARN_ON(!mem))
return -EINVAL;
ret = regmap_raw_read(dsp->regmap, mem->base, &adsp1_id,
sizeof(adsp1_id));
if (ret != 0) {
cs_dsp_err(dsp, "Failed to read algorithm info: %d\n",
ret);
return ret;
}
n_algs = be32_to_cpu(adsp1_id.n_algs);
cs_dsp_parse_wmfw_id_header(dsp, &adsp1_id.fw, n_algs);
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP1_ZM,
adsp1_id.fw.id, adsp1_id.fw.ver,
adsp1_id.zm);
if (IS_ERR(alg_region))
return PTR_ERR(alg_region);
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP1_DM,
adsp1_id.fw.id, adsp1_id.fw.ver,
adsp1_id.dm);
if (IS_ERR(alg_region))
return PTR_ERR(alg_region);
/* Calculate offset and length in DSP words */
pos = sizeof(adsp1_id) / sizeof(u32);
len = (sizeof(*adsp1_alg) * n_algs) / sizeof(u32);
adsp1_alg = cs_dsp_read_algs(dsp, n_algs, mem, pos, len);
if (IS_ERR(adsp1_alg))
return PTR_ERR(adsp1_alg);
for (i = 0; i < n_algs; i++) {
cs_dsp_info(dsp, "%d: ID %x v%d.%d.%d DM@%x ZM@%x\n",
i, be32_to_cpu(adsp1_alg[i].alg.id),
(be32_to_cpu(adsp1_alg[i].alg.ver) & 0xff0000) >> 16,
(be32_to_cpu(adsp1_alg[i].alg.ver) & 0xff00) >> 8,
be32_to_cpu(adsp1_alg[i].alg.ver) & 0xff,
be32_to_cpu(adsp1_alg[i].dm),
be32_to_cpu(adsp1_alg[i].zm));
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP1_DM,
adsp1_alg[i].alg.id,
adsp1_alg[i].alg.ver,
adsp1_alg[i].dm);
if (IS_ERR(alg_region)) {
ret = PTR_ERR(alg_region);
goto out;
}
if (dsp->wmfw_ver == 0) {
if (i + 1 < n_algs) {
len = be32_to_cpu(adsp1_alg[i + 1].dm);
len -= be32_to_cpu(adsp1_alg[i].dm);
len *= 4;
cs_dsp_create_control(dsp, alg_region, 0,
len, NULL, 0, 0,
WMFW_CTL_TYPE_BYTES);
} else {
cs_dsp_warn(dsp, "Missing length info for region DM with ID %x\n",
be32_to_cpu(adsp1_alg[i].alg.id));
}
}
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP1_ZM,
adsp1_alg[i].alg.id,
adsp1_alg[i].alg.ver,
adsp1_alg[i].zm);
if (IS_ERR(alg_region)) {
ret = PTR_ERR(alg_region);
goto out;
}
if (dsp->wmfw_ver == 0) {
if (i + 1 < n_algs) {
len = be32_to_cpu(adsp1_alg[i + 1].zm);
len -= be32_to_cpu(adsp1_alg[i].zm);
len *= 4;
cs_dsp_create_control(dsp, alg_region, 0,
len, NULL, 0, 0,
WMFW_CTL_TYPE_BYTES);
} else {
cs_dsp_warn(dsp, "Missing length info for region ZM with ID %x\n",
be32_to_cpu(adsp1_alg[i].alg.id));
}
}
}
out:
kfree(adsp1_alg);
return ret;
}
static int cs_dsp_adsp2_setup_algs(struct cs_dsp *dsp)
{
struct wmfw_adsp2_id_hdr adsp2_id;
struct wmfw_adsp2_alg_hdr *adsp2_alg;
struct cs_dsp_alg_region *alg_region;
const struct cs_dsp_region *mem;
unsigned int pos, len;
size_t n_algs;
int i, ret;
mem = cs_dsp_find_region(dsp, WMFW_ADSP2_XM);
if (WARN_ON(!mem))
return -EINVAL;
ret = regmap_raw_read(dsp->regmap, mem->base, &adsp2_id,
sizeof(adsp2_id));
if (ret != 0) {
cs_dsp_err(dsp, "Failed to read algorithm info: %d\n",
ret);
return ret;
}
n_algs = be32_to_cpu(adsp2_id.n_algs);
cs_dsp_parse_wmfw_id_header(dsp, &adsp2_id.fw, n_algs);
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP2_XM,
adsp2_id.fw.id, adsp2_id.fw.ver,
adsp2_id.xm);
if (IS_ERR(alg_region))
return PTR_ERR(alg_region);
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP2_YM,
adsp2_id.fw.id, adsp2_id.fw.ver,
adsp2_id.ym);
if (IS_ERR(alg_region))
return PTR_ERR(alg_region);
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP2_ZM,
adsp2_id.fw.id, adsp2_id.fw.ver,
adsp2_id.zm);
if (IS_ERR(alg_region))
return PTR_ERR(alg_region);
/* Calculate offset and length in DSP words */
pos = sizeof(adsp2_id) / sizeof(u32);
len = (sizeof(*adsp2_alg) * n_algs) / sizeof(u32);
adsp2_alg = cs_dsp_read_algs(dsp, n_algs, mem, pos, len);
if (IS_ERR(adsp2_alg))
return PTR_ERR(adsp2_alg);
for (i = 0; i < n_algs; i++) {
cs_dsp_dbg(dsp,
"%d: ID %x v%d.%d.%d XM@%x YM@%x ZM@%x\n",
i, be32_to_cpu(adsp2_alg[i].alg.id),
(be32_to_cpu(adsp2_alg[i].alg.ver) & 0xff0000) >> 16,
(be32_to_cpu(adsp2_alg[i].alg.ver) & 0xff00) >> 8,
be32_to_cpu(adsp2_alg[i].alg.ver) & 0xff,
be32_to_cpu(adsp2_alg[i].xm),
be32_to_cpu(adsp2_alg[i].ym),
be32_to_cpu(adsp2_alg[i].zm));
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP2_XM,
adsp2_alg[i].alg.id,
adsp2_alg[i].alg.ver,
adsp2_alg[i].xm);
if (IS_ERR(alg_region)) {
ret = PTR_ERR(alg_region);
goto out;
}
if (dsp->wmfw_ver == 0) {
if (i + 1 < n_algs) {
len = be32_to_cpu(adsp2_alg[i + 1].xm);
len -= be32_to_cpu(adsp2_alg[i].xm);
len *= 4;
cs_dsp_create_control(dsp, alg_region, 0,
len, NULL, 0, 0,
WMFW_CTL_TYPE_BYTES);
} else {
cs_dsp_warn(dsp, "Missing length info for region XM with ID %x\n",
be32_to_cpu(adsp2_alg[i].alg.id));
}
}
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP2_YM,
adsp2_alg[i].alg.id,
adsp2_alg[i].alg.ver,
adsp2_alg[i].ym);
if (IS_ERR(alg_region)) {
ret = PTR_ERR(alg_region);
goto out;
}
if (dsp->wmfw_ver == 0) {
if (i + 1 < n_algs) {
len = be32_to_cpu(adsp2_alg[i + 1].ym);
len -= be32_to_cpu(adsp2_alg[i].ym);
len *= 4;
cs_dsp_create_control(dsp, alg_region, 0,
len, NULL, 0, 0,
WMFW_CTL_TYPE_BYTES);
} else {
cs_dsp_warn(dsp, "Missing length info for region YM with ID %x\n",
be32_to_cpu(adsp2_alg[i].alg.id));
}
}
alg_region = cs_dsp_create_region(dsp, WMFW_ADSP2_ZM,
adsp2_alg[i].alg.id,
adsp2_alg[i].alg.ver,
adsp2_alg[i].zm);
if (IS_ERR(alg_region)) {
ret = PTR_ERR(alg_region);
goto out;
}
if (dsp->wmfw_ver == 0) {
if (i + 1 < n_algs) {
len = be32_to_cpu(adsp2_alg[i + 1].zm);
len -= be32_to_cpu(adsp2_alg[i].zm);
len *= 4;
cs_dsp_create_control(dsp, alg_region, 0,
len, NULL, 0, 0,
WMFW_CTL_TYPE_BYTES);
} else {
cs_dsp_warn(dsp, "Missing length info for region ZM with ID %x\n",
be32_to_cpu(adsp2_alg[i].alg.id));
}
}
}
out:
kfree(adsp2_alg);
return ret;
}
static int cs_dsp_halo_create_regions(struct cs_dsp *dsp, __be32 id, __be32 ver,
__be32 xm_base, __be32 ym_base)
{
static const int types[] = {
WMFW_ADSP2_XM, WMFW_HALO_XM_PACKED,
WMFW_ADSP2_YM, WMFW_HALO_YM_PACKED
};
__be32 bases[] = { xm_base, xm_base, ym_base, ym_base };
return cs_dsp_create_regions(dsp, id, ver, ARRAY_SIZE(types), types, bases);
}
static int cs_dsp_halo_setup_algs(struct cs_dsp *dsp)
{
struct wmfw_halo_id_hdr halo_id;
struct wmfw_halo_alg_hdr *halo_alg;
const struct cs_dsp_region *mem;
unsigned int pos, len;
size_t n_algs;
int i, ret;
mem = cs_dsp_find_region(dsp, WMFW_ADSP2_XM);
if (WARN_ON(!mem))
return -EINVAL;
ret = regmap_raw_read(dsp->regmap, mem->base, &halo_id,
sizeof(halo_id));
if (ret != 0) {
cs_dsp_err(dsp, "Failed to read algorithm info: %d\n",
ret);
return ret;
}
n_algs = be32_to_cpu(halo_id.n_algs);
cs_dsp_parse_wmfw_v3_id_header(dsp, &halo_id.fw, n_algs);
ret = cs_dsp_halo_create_regions(dsp, halo_id.fw.id, halo_id.fw.ver,
halo_id.xm_base, halo_id.ym_base);
if (ret)
return ret;
/* Calculate offset and length in DSP words */
pos = sizeof(halo_id) / sizeof(u32);
len = (sizeof(*halo_alg) * n_algs) / sizeof(u32);
halo_alg = cs_dsp_read_algs(dsp, n_algs, mem, pos, len);
if (IS_ERR(halo_alg))
return PTR_ERR(halo_alg);
for (i = 0; i < n_algs; i++) {
cs_dsp_dbg(dsp,
"%d: ID %x v%d.%d.%d XM@%x YM@%x\n",
i, be32_to_cpu(halo_alg[i].alg.id),
(be32_to_cpu(halo_alg[i].alg.ver) & 0xff0000) >> 16,
(be32_to_cpu(halo_alg[i].alg.ver) & 0xff00) >> 8,
be32_to_cpu(halo_alg[i].alg.ver) & 0xff,
be32_to_cpu(halo_alg[i].xm_base),
be32_to_cpu(halo_alg[i].ym_base));
ret = cs_dsp_halo_create_regions(dsp, halo_alg[i].alg.id,
halo_alg[i].alg.ver,
halo_alg[i].xm_base,
halo_alg[i].ym_base);
if (ret)
goto out;
}
out:
kfree(halo_alg);
return ret;
}
static int cs_dsp_load_coeff(struct cs_dsp *dsp, const struct firmware *firmware,
const char *file)
{
LIST_HEAD(buf_list);
struct regmap *regmap = dsp->regmap;
struct wmfw_coeff_hdr *hdr;
struct wmfw_coeff_item *blk;
const struct cs_dsp_region *mem;
struct cs_dsp_alg_region *alg_region;
const char *region_name;
int ret, pos, blocks, type, offset, reg, version;
struct cs_dsp_buf *buf;
if (!firmware)
return 0;
ret = -EINVAL;
if (sizeof(*hdr) >= firmware->size) {
cs_dsp_err(dsp, "%s: coefficient file too short, %zu bytes\n",
file, firmware->size);
goto out_fw;
}
hdr = (void *)&firmware->data[0];
if (memcmp(hdr->magic, "WMDR", 4) != 0) {
cs_dsp_err(dsp, "%s: invalid coefficient magic\n", file);
goto out_fw;
}
switch (be32_to_cpu(hdr->rev) & 0xff) {
case 1:
case 2:
break;
default:
cs_dsp_err(dsp, "%s: Unsupported coefficient file format %d\n",
file, be32_to_cpu(hdr->rev) & 0xff);
ret = -EINVAL;
goto out_fw;
}
cs_dsp_info(dsp, "%s: v%d.%d.%d\n", file,
(le32_to_cpu(hdr->ver) >> 16) & 0xff,
(le32_to_cpu(hdr->ver) >> 8) & 0xff,
le32_to_cpu(hdr->ver) & 0xff);
pos = le32_to_cpu(hdr->len);
blocks = 0;
while (pos < firmware->size) {
/* Is there enough data for a complete block header? */
if (sizeof(*blk) > firmware->size - pos) {
ret = -EOVERFLOW;
goto out_fw;
}
blk = (void *)(&firmware->data[pos]);
if (le32_to_cpu(blk->len) > firmware->size - pos - sizeof(*blk)) {
ret = -EOVERFLOW;
goto out_fw;
}
type = le16_to_cpu(blk->type);
offset = le16_to_cpu(blk->offset);
version = le32_to_cpu(blk->ver) >> 8;
cs_dsp_dbg(dsp, "%s.%d: %x v%d.%d.%d\n",
file, blocks, le32_to_cpu(blk->id),
(le32_to_cpu(blk->ver) >> 16) & 0xff,
(le32_to_cpu(blk->ver) >> 8) & 0xff,
le32_to_cpu(blk->ver) & 0xff);
cs_dsp_dbg(dsp, "%s.%d: %d bytes at 0x%x in %x\n",
file, blocks, le32_to_cpu(blk->len), offset, type);
reg = 0;
region_name = "Unknown";
switch (type) {
case (WMFW_NAME_TEXT << 8):
cs_dsp_info(dsp, "%s: %.*s\n", dsp->fw_name,
min(le32_to_cpu(blk->len), 100), blk->data);
break;
case (WMFW_INFO_TEXT << 8):
case (WMFW_METADATA << 8):
break;
case (WMFW_ABSOLUTE << 8):
/*
* Old files may use this for global
* coefficients.
*/
if (le32_to_cpu(blk->id) == dsp->fw_id &&
offset == 0) {
region_name = "global coefficients";
mem = cs_dsp_find_region(dsp, type);
if (!mem) {
cs_dsp_err(dsp, "No ZM\n");
break;
}
reg = dsp->ops->region_to_reg(mem, 0);
} else {
region_name = "register";
reg = offset;
}
break;
case WMFW_ADSP1_DM:
case WMFW_ADSP1_ZM:
case WMFW_ADSP2_XM:
case WMFW_ADSP2_YM:
case WMFW_HALO_XM_PACKED:
case WMFW_HALO_YM_PACKED:
case WMFW_HALO_PM_PACKED:
cs_dsp_dbg(dsp, "%s.%d: %d bytes in %x for %x\n",
file, blocks, le32_to_cpu(blk->len),
type, le32_to_cpu(blk->id));
region_name = cs_dsp_mem_region_name(type);
mem = cs_dsp_find_region(dsp, type);
if (!mem) {
cs_dsp_err(dsp, "No base for region %x\n", type);
break;
}
alg_region = cs_dsp_find_alg_region(dsp, type,
le32_to_cpu(blk->id));
if (alg_region) {
if (version != alg_region->ver)
cs_dsp_warn(dsp,
"Algorithm coefficient version %d.%d.%d but expected %d.%d.%d\n",
(version >> 16) & 0xFF,
(version >> 8) & 0xFF,
version & 0xFF,
(alg_region->ver >> 16) & 0xFF,
(alg_region->ver >> 8) & 0xFF,
alg_region->ver & 0xFF);
reg = alg_region->base;
reg = dsp->ops->region_to_reg(mem, reg);
reg += offset;
} else {
cs_dsp_err(dsp, "No %s for algorithm %x\n",
region_name, le32_to_cpu(blk->id));
}
break;
default:
cs_dsp_err(dsp, "%s.%d: Unknown region type %x at %d\n",
file, blocks, type, pos);
break;
}
if (reg) {
buf = cs_dsp_buf_alloc(blk->data,
le32_to_cpu(blk->len),
&buf_list);
if (!buf) {
cs_dsp_err(dsp, "Out of memory\n");
ret = -ENOMEM;
goto out_fw;
}
cs_dsp_dbg(dsp, "%s.%d: Writing %d bytes at %x\n",
file, blocks, le32_to_cpu(blk->len),
reg);
ret = regmap_raw_write_async(regmap, reg, buf->buf,
le32_to_cpu(blk->len));
if (ret != 0) {
cs_dsp_err(dsp,
"%s.%d: Failed to write to %x in %s: %d\n",
file, blocks, reg, region_name, ret);
}
}
pos += (le32_to_cpu(blk->len) + sizeof(*blk) + 3) & ~0x03;
blocks++;
}
ret = regmap_async_complete(regmap);
if (ret != 0)
cs_dsp_err(dsp, "Failed to complete async write: %d\n", ret);
if (pos > firmware->size)
cs_dsp_warn(dsp, "%s.%d: %zu bytes at end of file\n",
file, blocks, pos - firmware->size);
cs_dsp_debugfs_save_binname(dsp, file);
out_fw:
regmap_async_complete(regmap);
cs_dsp_buf_free(&buf_list);
if (ret == -EOVERFLOW)
cs_dsp_err(dsp, "%s: file content overflows file data\n", file);
return ret;
}
static int cs_dsp_create_name(struct cs_dsp *dsp)
{
if (!dsp->name) {
dsp->name = devm_kasprintf(dsp->dev, GFP_KERNEL, "DSP%d",
dsp->num);
if (!dsp->name)
return -ENOMEM;
}
return 0;
}
static int cs_dsp_common_init(struct cs_dsp *dsp)
{
int ret;
ret = cs_dsp_create_name(dsp);
if (ret)
return ret;
INIT_LIST_HEAD(&dsp->alg_regions);
INIT_LIST_HEAD(&dsp->ctl_list);
mutex_init(&dsp->pwr_lock);
#ifdef CONFIG_DEBUG_FS
/* Ensure this is invalid if client never provides a debugfs root */
dsp->debugfs_root = ERR_PTR(-ENODEV);
#endif
return 0;
}
/**
* cs_dsp_adsp1_init() - Initialise a cs_dsp structure representing a ADSP1 device
* @dsp: pointer to DSP structure
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_adsp1_init(struct cs_dsp *dsp)
{
dsp->ops = &cs_dsp_adsp1_ops;
return cs_dsp_common_init(dsp);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_adsp1_init, FW_CS_DSP);
/**
* cs_dsp_adsp1_power_up() - Load and start the named firmware
* @dsp: pointer to DSP structure
* @wmfw_firmware: the firmware to be sent
* @wmfw_filename: file name of firmware to be sent
* @coeff_firmware: the coefficient data to be sent
* @coeff_filename: file name of coefficient to data be sent
* @fw_name: the user-friendly firmware name
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_adsp1_power_up(struct cs_dsp *dsp,
const struct firmware *wmfw_firmware, const char *wmfw_filename,
const struct firmware *coeff_firmware, const char *coeff_filename,
const char *fw_name)
{
unsigned int val;
int ret;
mutex_lock(&dsp->pwr_lock);
dsp->fw_name = fw_name;
regmap_update_bits(dsp->regmap, dsp->base + ADSP1_CONTROL_30,
ADSP1_SYS_ENA, ADSP1_SYS_ENA);
/*
* For simplicity set the DSP clock rate to be the
* SYSCLK rate rather than making it configurable.
*/
if (dsp->sysclk_reg) {
ret = regmap_read(dsp->regmap, dsp->sysclk_reg, &val);
if (ret != 0) {
cs_dsp_err(dsp, "Failed to read SYSCLK state: %d\n", ret);
goto err_mutex;
}
val = (val & dsp->sysclk_mask) >> dsp->sysclk_shift;
ret = regmap_update_bits(dsp->regmap,
dsp->base + ADSP1_CONTROL_31,
ADSP1_CLK_SEL_MASK, val);
if (ret != 0) {
cs_dsp_err(dsp, "Failed to set clock rate: %d\n", ret);
goto err_mutex;
}
}
ret = cs_dsp_load(dsp, wmfw_firmware, wmfw_filename);
if (ret != 0)
goto err_ena;
ret = cs_dsp_adsp1_setup_algs(dsp);
if (ret != 0)
goto err_ena;
ret = cs_dsp_load_coeff(dsp, coeff_firmware, coeff_filename);
if (ret != 0)
goto err_ena;
/* Initialize caches for enabled and unset controls */
ret = cs_dsp_coeff_init_control_caches(dsp);
if (ret != 0)
goto err_ena;
/* Sync set controls */
ret = cs_dsp_coeff_sync_controls(dsp);
if (ret != 0)
goto err_ena;
dsp->booted = true;
/* Start the core running */
regmap_update_bits(dsp->regmap, dsp->base + ADSP1_CONTROL_30,
ADSP1_CORE_ENA | ADSP1_START,
ADSP1_CORE_ENA | ADSP1_START);
dsp->running = true;
mutex_unlock(&dsp->pwr_lock);
return 0;
err_ena:
regmap_update_bits(dsp->regmap, dsp->base + ADSP1_CONTROL_30,
ADSP1_SYS_ENA, 0);
err_mutex:
mutex_unlock(&dsp->pwr_lock);
return ret;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_adsp1_power_up, FW_CS_DSP);
/**
* cs_dsp_adsp1_power_down() - Halts the DSP
* @dsp: pointer to DSP structure
*/
void cs_dsp_adsp1_power_down(struct cs_dsp *dsp)
{
struct cs_dsp_coeff_ctl *ctl;
mutex_lock(&dsp->pwr_lock);
dsp->running = false;
dsp->booted = false;
/* Halt the core */
regmap_update_bits(dsp->regmap, dsp->base + ADSP1_CONTROL_30,
ADSP1_CORE_ENA | ADSP1_START, 0);
regmap_update_bits(dsp->regmap, dsp->base + ADSP1_CONTROL_19,
ADSP1_WDMA_BUFFER_LENGTH_MASK, 0);
regmap_update_bits(dsp->regmap, dsp->base + ADSP1_CONTROL_30,
ADSP1_SYS_ENA, 0);
list_for_each_entry(ctl, &dsp->ctl_list, list)
ctl->enabled = 0;
cs_dsp_free_alg_regions(dsp);
mutex_unlock(&dsp->pwr_lock);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_adsp1_power_down, FW_CS_DSP);
static int cs_dsp_adsp2v2_enable_core(struct cs_dsp *dsp)
{
unsigned int val;
int ret, count;
/* Wait for the RAM to start, should be near instantaneous */
for (count = 0; count < 10; ++count) {
ret = regmap_read(dsp->regmap, dsp->base + ADSP2_STATUS1, &val);
if (ret != 0)
return ret;
if (val & ADSP2_RAM_RDY)
break;
usleep_range(250, 500);
}
if (!(val & ADSP2_RAM_RDY)) {
cs_dsp_err(dsp, "Failed to start DSP RAM\n");
return -EBUSY;
}
cs_dsp_dbg(dsp, "RAM ready after %d polls\n", count);
return 0;
}
static int cs_dsp_adsp2_enable_core(struct cs_dsp *dsp)
{
int ret;
ret = regmap_update_bits_async(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_SYS_ENA, ADSP2_SYS_ENA);
if (ret != 0)
return ret;
return cs_dsp_adsp2v2_enable_core(dsp);
}
static int cs_dsp_adsp2_lock(struct cs_dsp *dsp, unsigned int lock_regions)
{
struct regmap *regmap = dsp->regmap;
unsigned int code0, code1, lock_reg;
if (!(lock_regions & CS_ADSP2_REGION_ALL))
return 0;
lock_regions &= CS_ADSP2_REGION_ALL;
lock_reg = dsp->base + ADSP2_LOCK_REGION_1_LOCK_REGION_0;
while (lock_regions) {
code0 = code1 = 0;
if (lock_regions & BIT(0)) {
code0 = ADSP2_LOCK_CODE_0;
code1 = ADSP2_LOCK_CODE_1;
}
if (lock_regions & BIT(1)) {
code0 |= ADSP2_LOCK_CODE_0 << ADSP2_LOCK_REGION_SHIFT;
code1 |= ADSP2_LOCK_CODE_1 << ADSP2_LOCK_REGION_SHIFT;
}
regmap_write(regmap, lock_reg, code0);
regmap_write(regmap, lock_reg, code1);
lock_regions >>= 2;
lock_reg += 2;
}
return 0;
}
static int cs_dsp_adsp2_enable_memory(struct cs_dsp *dsp)
{
return regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_MEM_ENA, ADSP2_MEM_ENA);
}
static void cs_dsp_adsp2_disable_memory(struct cs_dsp *dsp)
{
regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_MEM_ENA, 0);
}
static void cs_dsp_adsp2_disable_core(struct cs_dsp *dsp)
{
regmap_write(dsp->regmap, dsp->base + ADSP2_RDMA_CONFIG_1, 0);
regmap_write(dsp->regmap, dsp->base + ADSP2_WDMA_CONFIG_1, 0);
regmap_write(dsp->regmap, dsp->base + ADSP2_WDMA_CONFIG_2, 0);
regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_SYS_ENA, 0);
}
static void cs_dsp_adsp2v2_disable_core(struct cs_dsp *dsp)
{
regmap_write(dsp->regmap, dsp->base + ADSP2_RDMA_CONFIG_1, 0);
regmap_write(dsp->regmap, dsp->base + ADSP2_WDMA_CONFIG_1, 0);
regmap_write(dsp->regmap, dsp->base + ADSP2V2_WDMA_CONFIG_2, 0);
}
static int cs_dsp_halo_configure_mpu(struct cs_dsp *dsp, unsigned int lock_regions)
{
struct reg_sequence config[] = {
{ dsp->base + HALO_MPU_LOCK_CONFIG, 0x5555 },
{ dsp->base + HALO_MPU_LOCK_CONFIG, 0xAAAA },
{ dsp->base + HALO_MPU_XMEM_ACCESS_0, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_YMEM_ACCESS_0, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_WINDOW_ACCESS_0, lock_regions },
{ dsp->base + HALO_MPU_XREG_ACCESS_0, lock_regions },
{ dsp->base + HALO_MPU_YREG_ACCESS_0, lock_regions },
{ dsp->base + HALO_MPU_XMEM_ACCESS_1, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_YMEM_ACCESS_1, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_WINDOW_ACCESS_1, lock_regions },
{ dsp->base + HALO_MPU_XREG_ACCESS_1, lock_regions },
{ dsp->base + HALO_MPU_YREG_ACCESS_1, lock_regions },
{ dsp->base + HALO_MPU_XMEM_ACCESS_2, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_YMEM_ACCESS_2, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_WINDOW_ACCESS_2, lock_regions },
{ dsp->base + HALO_MPU_XREG_ACCESS_2, lock_regions },
{ dsp->base + HALO_MPU_YREG_ACCESS_2, lock_regions },
{ dsp->base + HALO_MPU_XMEM_ACCESS_3, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_YMEM_ACCESS_3, 0xFFFFFFFF },
{ dsp->base + HALO_MPU_WINDOW_ACCESS_3, lock_regions },
{ dsp->base + HALO_MPU_XREG_ACCESS_3, lock_regions },
{ dsp->base + HALO_MPU_YREG_ACCESS_3, lock_regions },
{ dsp->base + HALO_MPU_LOCK_CONFIG, 0 },
};
return regmap_multi_reg_write(dsp->regmap, config, ARRAY_SIZE(config));
}
/**
* cs_dsp_set_dspclk() - Applies the given frequency to the given cs_dsp
* @dsp: pointer to DSP structure
* @freq: clock rate to set
*
* This is only for use on ADSP2 cores.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_set_dspclk(struct cs_dsp *dsp, unsigned int freq)
{
int ret;
ret = regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CLOCKING,
ADSP2_CLK_SEL_MASK,
freq << ADSP2_CLK_SEL_SHIFT);
if (ret)
cs_dsp_err(dsp, "Failed to set clock rate: %d\n", ret);
return ret;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_set_dspclk, FW_CS_DSP);
static void cs_dsp_stop_watchdog(struct cs_dsp *dsp)
{
regmap_update_bits(dsp->regmap, dsp->base + ADSP2_WATCHDOG,
ADSP2_WDT_ENA_MASK, 0);
}
static void cs_dsp_halo_stop_watchdog(struct cs_dsp *dsp)
{
regmap_update_bits(dsp->regmap, dsp->base + HALO_WDT_CONTROL,
HALO_WDT_EN_MASK, 0);
}
/**
* cs_dsp_power_up() - Downloads firmware to the DSP
* @dsp: pointer to DSP structure
* @wmfw_firmware: the firmware to be sent
* @wmfw_filename: file name of firmware to be sent
* @coeff_firmware: the coefficient data to be sent
* @coeff_filename: file name of coefficient to data be sent
* @fw_name: the user-friendly firmware name
*
* This function is used on ADSP2 and Halo DSP cores, it powers-up the DSP core
* and downloads the firmware but does not start the firmware running. The
* cs_dsp booted flag will be set once completed and if the core has a low-power
* memory retention mode it will be put into this state after the firmware is
* downloaded.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_power_up(struct cs_dsp *dsp,
const struct firmware *wmfw_firmware, const char *wmfw_filename,
const struct firmware *coeff_firmware, const char *coeff_filename,
const char *fw_name)
{
int ret;
mutex_lock(&dsp->pwr_lock);
dsp->fw_name = fw_name;
if (dsp->ops->enable_memory) {
ret = dsp->ops->enable_memory(dsp);
if (ret != 0)
goto err_mutex;
}
if (dsp->ops->enable_core) {
ret = dsp->ops->enable_core(dsp);
if (ret != 0)
goto err_mem;
}
ret = cs_dsp_load(dsp, wmfw_firmware, wmfw_filename);
if (ret != 0)
goto err_ena;
ret = dsp->ops->setup_algs(dsp);
if (ret != 0)
goto err_ena;
ret = cs_dsp_load_coeff(dsp, coeff_firmware, coeff_filename);
if (ret != 0)
goto err_ena;
/* Initialize caches for enabled and unset controls */
ret = cs_dsp_coeff_init_control_caches(dsp);
if (ret != 0)
goto err_ena;
if (dsp->ops->disable_core)
dsp->ops->disable_core(dsp);
dsp->booted = true;
mutex_unlock(&dsp->pwr_lock);
return 0;
err_ena:
if (dsp->ops->disable_core)
dsp->ops->disable_core(dsp);
err_mem:
if (dsp->ops->disable_memory)
dsp->ops->disable_memory(dsp);
err_mutex:
mutex_unlock(&dsp->pwr_lock);
return ret;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_power_up, FW_CS_DSP);
/**
* cs_dsp_power_down() - Powers-down the DSP
* @dsp: pointer to DSP structure
*
* cs_dsp_stop() must have been called before this function. The core will be
* fully powered down and so the memory will not be retained.
*/
void cs_dsp_power_down(struct cs_dsp *dsp)
{
struct cs_dsp_coeff_ctl *ctl;
mutex_lock(&dsp->pwr_lock);
cs_dsp_debugfs_clear(dsp);
dsp->fw_id = 0;
dsp->fw_id_version = 0;
dsp->booted = false;
if (dsp->ops->disable_memory)
dsp->ops->disable_memory(dsp);
list_for_each_entry(ctl, &dsp->ctl_list, list)
ctl->enabled = 0;
cs_dsp_free_alg_regions(dsp);
mutex_unlock(&dsp->pwr_lock);
cs_dsp_dbg(dsp, "Shutdown complete\n");
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_power_down, FW_CS_DSP);
static int cs_dsp_adsp2_start_core(struct cs_dsp *dsp)
{
return regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_CORE_ENA | ADSP2_START,
ADSP2_CORE_ENA | ADSP2_START);
}
static void cs_dsp_adsp2_stop_core(struct cs_dsp *dsp)
{
regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_CORE_ENA | ADSP2_START, 0);
}
/**
* cs_dsp_run() - Starts the firmware running
* @dsp: pointer to DSP structure
*
* cs_dsp_power_up() must have previously been called successfully.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_run(struct cs_dsp *dsp)
{
int ret;
mutex_lock(&dsp->pwr_lock);
if (!dsp->booted) {
ret = -EIO;
goto err;
}
if (dsp->ops->enable_core) {
ret = dsp->ops->enable_core(dsp);
if (ret != 0)
goto err;
}
if (dsp->client_ops->pre_run) {
ret = dsp->client_ops->pre_run(dsp);
if (ret)
goto err;
}
/* Sync set controls */
ret = cs_dsp_coeff_sync_controls(dsp);
if (ret != 0)
goto err;
if (dsp->ops->lock_memory) {
ret = dsp->ops->lock_memory(dsp, dsp->lock_regions);
if (ret != 0) {
cs_dsp_err(dsp, "Error configuring MPU: %d\n", ret);
goto err;
}
}
if (dsp->ops->start_core) {
ret = dsp->ops->start_core(dsp);
if (ret != 0)
goto err;
}
dsp->running = true;
if (dsp->client_ops->post_run) {
ret = dsp->client_ops->post_run(dsp);
if (ret)
goto err;
}
mutex_unlock(&dsp->pwr_lock);
return 0;
err:
if (dsp->ops->stop_core)
dsp->ops->stop_core(dsp);
if (dsp->ops->disable_core)
dsp->ops->disable_core(dsp);
mutex_unlock(&dsp->pwr_lock);
return ret;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_run, FW_CS_DSP);
/**
* cs_dsp_stop() - Stops the firmware
* @dsp: pointer to DSP structure
*
* Memory will not be disabled so firmware will remain loaded.
*/
void cs_dsp_stop(struct cs_dsp *dsp)
{
/* Tell the firmware to cleanup */
cs_dsp_signal_event_controls(dsp, CS_DSP_FW_EVENT_SHUTDOWN);
if (dsp->ops->stop_watchdog)
dsp->ops->stop_watchdog(dsp);
/* Log firmware state, it can be useful for analysis */
if (dsp->ops->show_fw_status)
dsp->ops->show_fw_status(dsp);
mutex_lock(&dsp->pwr_lock);
if (dsp->client_ops->pre_stop)
dsp->client_ops->pre_stop(dsp);
dsp->running = false;
if (dsp->ops->stop_core)
dsp->ops->stop_core(dsp);
if (dsp->ops->disable_core)
dsp->ops->disable_core(dsp);
if (dsp->client_ops->post_stop)
dsp->client_ops->post_stop(dsp);
mutex_unlock(&dsp->pwr_lock);
cs_dsp_dbg(dsp, "Execution stopped\n");
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_stop, FW_CS_DSP);
static int cs_dsp_halo_start_core(struct cs_dsp *dsp)
{
int ret;
ret = regmap_update_bits(dsp->regmap, dsp->base + HALO_CCM_CORE_CONTROL,
HALO_CORE_RESET | HALO_CORE_EN,
HALO_CORE_RESET | HALO_CORE_EN);
if (ret)
return ret;
return regmap_update_bits(dsp->regmap, dsp->base + HALO_CCM_CORE_CONTROL,
HALO_CORE_RESET, 0);
}
static void cs_dsp_halo_stop_core(struct cs_dsp *dsp)
{
regmap_update_bits(dsp->regmap, dsp->base + HALO_CCM_CORE_CONTROL,
HALO_CORE_EN, 0);
/* reset halo core with CORE_SOFT_RESET */
regmap_update_bits(dsp->regmap, dsp->base + HALO_CORE_SOFT_RESET,
HALO_CORE_SOFT_RESET_MASK, 1);
}
/**
* cs_dsp_adsp2_init() - Initialise a cs_dsp structure representing a ADSP2 core
* @dsp: pointer to DSP structure
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_adsp2_init(struct cs_dsp *dsp)
{
int ret;
switch (dsp->rev) {
case 0:
/*
* Disable the DSP memory by default when in reset for a small
* power saving.
*/
ret = regmap_update_bits(dsp->regmap, dsp->base + ADSP2_CONTROL,
ADSP2_MEM_ENA, 0);
if (ret) {
cs_dsp_err(dsp,
"Failed to clear memory retention: %d\n", ret);
return ret;
}
dsp->ops = &cs_dsp_adsp2_ops[0];
break;
case 1:
dsp->ops = &cs_dsp_adsp2_ops[1];
break;
default:
dsp->ops = &cs_dsp_adsp2_ops[2];
break;
}
return cs_dsp_common_init(dsp);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_adsp2_init, FW_CS_DSP);
/**
* cs_dsp_halo_init() - Initialise a cs_dsp structure representing a HALO Core DSP
* @dsp: pointer to DSP structure
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_halo_init(struct cs_dsp *dsp)
{
if (dsp->no_core_startstop)
dsp->ops = &cs_dsp_halo_ao_ops;
else
dsp->ops = &cs_dsp_halo_ops;
return cs_dsp_common_init(dsp);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_halo_init, FW_CS_DSP);
/**
* cs_dsp_remove() - Clean a cs_dsp before deletion
* @dsp: pointer to DSP structure
*/
void cs_dsp_remove(struct cs_dsp *dsp)
{
struct cs_dsp_coeff_ctl *ctl;
while (!list_empty(&dsp->ctl_list)) {
ctl = list_first_entry(&dsp->ctl_list, struct cs_dsp_coeff_ctl, list);
if (dsp->client_ops->control_remove)
dsp->client_ops->control_remove(ctl);
list_del(&ctl->list);
cs_dsp_free_ctl_blk(ctl);
}
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_remove, FW_CS_DSP);
/**
* cs_dsp_read_raw_data_block() - Reads a block of data from DSP memory
* @dsp: pointer to DSP structure
* @mem_type: the type of DSP memory containing the data to be read
* @mem_addr: the address of the data within the memory region
* @num_words: the length of the data to read
* @data: a buffer to store the fetched data
*
* If this is used to read unpacked 24-bit memory, each 24-bit DSP word will
* occupy 32-bits in data (MSbyte will be 0). This padding can be removed using
* cs_dsp_remove_padding()
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_read_raw_data_block(struct cs_dsp *dsp, int mem_type, unsigned int mem_addr,
unsigned int num_words, __be32 *data)
{
struct cs_dsp_region const *mem = cs_dsp_find_region(dsp, mem_type);
unsigned int reg;
int ret;
lockdep_assert_held(&dsp->pwr_lock);
if (!mem)
return -EINVAL;
reg = dsp->ops->region_to_reg(mem, mem_addr);
ret = regmap_raw_read(dsp->regmap, reg, data,
sizeof(*data) * num_words);
if (ret < 0)
return ret;
return 0;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_read_raw_data_block, FW_CS_DSP);
/**
* cs_dsp_read_data_word() - Reads a word from DSP memory
* @dsp: pointer to DSP structure
* @mem_type: the type of DSP memory containing the data to be read
* @mem_addr: the address of the data within the memory region
* @data: a buffer to store the fetched data
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_read_data_word(struct cs_dsp *dsp, int mem_type, unsigned int mem_addr, u32 *data)
{
__be32 raw;
int ret;
ret = cs_dsp_read_raw_data_block(dsp, mem_type, mem_addr, 1, &raw);
if (ret < 0)
return ret;
*data = be32_to_cpu(raw) & 0x00ffffffu;
return 0;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_read_data_word, FW_CS_DSP);
/**
* cs_dsp_write_data_word() - Writes a word to DSP memory
* @dsp: pointer to DSP structure
* @mem_type: the type of DSP memory containing the data to be written
* @mem_addr: the address of the data within the memory region
* @data: the data to be written
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_write_data_word(struct cs_dsp *dsp, int mem_type, unsigned int mem_addr, u32 data)
{
struct cs_dsp_region const *mem = cs_dsp_find_region(dsp, mem_type);
__be32 val = cpu_to_be32(data & 0x00ffffffu);
unsigned int reg;
lockdep_assert_held(&dsp->pwr_lock);
if (!mem)
return -EINVAL;
reg = dsp->ops->region_to_reg(mem, mem_addr);
return regmap_raw_write(dsp->regmap, reg, &val, sizeof(val));
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_write_data_word, FW_CS_DSP);
/**
* cs_dsp_remove_padding() - Convert unpacked words to packed bytes
* @buf: buffer containing DSP words read from DSP memory
* @nwords: number of words to convert
*
* DSP words from the register map have pad bytes and the data bytes
* are in swapped order. This swaps to the native endian order and
* strips the pad bytes.
*/
void cs_dsp_remove_padding(u32 *buf, int nwords)
{
const __be32 *pack_in = (__be32 *)buf;
u8 *pack_out = (u8 *)buf;
int i;
for (i = 0; i < nwords; i++) {
u32 word = be32_to_cpu(*pack_in++);
*pack_out++ = (u8)word;
*pack_out++ = (u8)(word >> 8);
*pack_out++ = (u8)(word >> 16);
}
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_remove_padding, FW_CS_DSP);
/**
* cs_dsp_adsp2_bus_error() - Handle a DSP bus error interrupt
* @dsp: pointer to DSP structure
*
* The firmware and DSP state will be logged for future analysis.
*/
void cs_dsp_adsp2_bus_error(struct cs_dsp *dsp)
{
unsigned int val;
struct regmap *regmap = dsp->regmap;
int ret = 0;
mutex_lock(&dsp->pwr_lock);
ret = regmap_read(regmap, dsp->base + ADSP2_LOCK_REGION_CTRL, &val);
if (ret) {
cs_dsp_err(dsp,
"Failed to read Region Lock Ctrl register: %d\n", ret);
goto error;
}
if (val & ADSP2_WDT_TIMEOUT_STS_MASK) {
cs_dsp_err(dsp, "watchdog timeout error\n");
dsp->ops->stop_watchdog(dsp);
if (dsp->client_ops->watchdog_expired)
dsp->client_ops->watchdog_expired(dsp);
}
if (val & (ADSP2_ADDR_ERR_MASK | ADSP2_REGION_LOCK_ERR_MASK)) {
if (val & ADSP2_ADDR_ERR_MASK)
cs_dsp_err(dsp, "bus error: address error\n");
else
cs_dsp_err(dsp, "bus error: region lock error\n");
ret = regmap_read(regmap, dsp->base + ADSP2_BUS_ERR_ADDR, &val);
if (ret) {
cs_dsp_err(dsp,
"Failed to read Bus Err Addr register: %d\n",
ret);
goto error;
}
cs_dsp_err(dsp, "bus error address = 0x%x\n",
val & ADSP2_BUS_ERR_ADDR_MASK);
ret = regmap_read(regmap,
dsp->base + ADSP2_PMEM_ERR_ADDR_XMEM_ERR_ADDR,
&val);
if (ret) {
cs_dsp_err(dsp,
"Failed to read Pmem Xmem Err Addr register: %d\n",
ret);
goto error;
}
cs_dsp_err(dsp, "xmem error address = 0x%x\n",
val & ADSP2_XMEM_ERR_ADDR_MASK);
cs_dsp_err(dsp, "pmem error address = 0x%x\n",
(val & ADSP2_PMEM_ERR_ADDR_MASK) >>
ADSP2_PMEM_ERR_ADDR_SHIFT);
}
regmap_update_bits(regmap, dsp->base + ADSP2_LOCK_REGION_CTRL,
ADSP2_CTRL_ERR_EINT, ADSP2_CTRL_ERR_EINT);
error:
mutex_unlock(&dsp->pwr_lock);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_adsp2_bus_error, FW_CS_DSP);
/**
* cs_dsp_halo_bus_error() - Handle a DSP bus error interrupt
* @dsp: pointer to DSP structure
*
* The firmware and DSP state will be logged for future analysis.
*/
void cs_dsp_halo_bus_error(struct cs_dsp *dsp)
{
struct regmap *regmap = dsp->regmap;
unsigned int fault[6];
struct reg_sequence clear[] = {
{ dsp->base + HALO_MPU_XM_VIO_STATUS, 0x0 },
{ dsp->base + HALO_MPU_YM_VIO_STATUS, 0x0 },
{ dsp->base + HALO_MPU_PM_VIO_STATUS, 0x0 },
};
int ret;
mutex_lock(&dsp->pwr_lock);
ret = regmap_read(regmap, dsp->base_sysinfo + HALO_AHBM_WINDOW_DEBUG_1,
fault);
if (ret) {
cs_dsp_warn(dsp, "Failed to read AHB DEBUG_1: %d\n", ret);
goto exit_unlock;
}
cs_dsp_warn(dsp, "AHB: STATUS: 0x%x ADDR: 0x%x\n",
*fault & HALO_AHBM_FLAGS_ERR_MASK,
(*fault & HALO_AHBM_CORE_ERR_ADDR_MASK) >>
HALO_AHBM_CORE_ERR_ADDR_SHIFT);
ret = regmap_read(regmap, dsp->base_sysinfo + HALO_AHBM_WINDOW_DEBUG_0,
fault);
if (ret) {
cs_dsp_warn(dsp, "Failed to read AHB DEBUG_0: %d\n", ret);
goto exit_unlock;
}
cs_dsp_warn(dsp, "AHB: SYS_ADDR: 0x%x\n", *fault);
ret = regmap_bulk_read(regmap, dsp->base + HALO_MPU_XM_VIO_ADDR,
fault, ARRAY_SIZE(fault));
if (ret) {
cs_dsp_warn(dsp, "Failed to read MPU fault info: %d\n", ret);
goto exit_unlock;
}
cs_dsp_warn(dsp, "XM: STATUS:0x%x ADDR:0x%x\n", fault[1], fault[0]);
cs_dsp_warn(dsp, "YM: STATUS:0x%x ADDR:0x%x\n", fault[3], fault[2]);
cs_dsp_warn(dsp, "PM: STATUS:0x%x ADDR:0x%x\n", fault[5], fault[4]);
ret = regmap_multi_reg_write(dsp->regmap, clear, ARRAY_SIZE(clear));
if (ret)
cs_dsp_warn(dsp, "Failed to clear MPU status: %d\n", ret);
exit_unlock:
mutex_unlock(&dsp->pwr_lock);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_halo_bus_error, FW_CS_DSP);
/**
* cs_dsp_halo_wdt_expire() - Handle DSP watchdog expiry
* @dsp: pointer to DSP structure
*
* This is logged for future analysis.
*/
void cs_dsp_halo_wdt_expire(struct cs_dsp *dsp)
{
mutex_lock(&dsp->pwr_lock);
cs_dsp_warn(dsp, "WDT Expiry Fault\n");
dsp->ops->stop_watchdog(dsp);
if (dsp->client_ops->watchdog_expired)
dsp->client_ops->watchdog_expired(dsp);
mutex_unlock(&dsp->pwr_lock);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_halo_wdt_expire, FW_CS_DSP);
static const struct cs_dsp_ops cs_dsp_adsp1_ops = {
.validate_version = cs_dsp_validate_version,
.parse_sizes = cs_dsp_adsp1_parse_sizes,
.region_to_reg = cs_dsp_region_to_reg,
};
static const struct cs_dsp_ops cs_dsp_adsp2_ops[] = {
{
.parse_sizes = cs_dsp_adsp2_parse_sizes,
.validate_version = cs_dsp_validate_version,
.setup_algs = cs_dsp_adsp2_setup_algs,
.region_to_reg = cs_dsp_region_to_reg,
.show_fw_status = cs_dsp_adsp2_show_fw_status,
.enable_memory = cs_dsp_adsp2_enable_memory,
.disable_memory = cs_dsp_adsp2_disable_memory,
.enable_core = cs_dsp_adsp2_enable_core,
.disable_core = cs_dsp_adsp2_disable_core,
.start_core = cs_dsp_adsp2_start_core,
.stop_core = cs_dsp_adsp2_stop_core,
},
{
.parse_sizes = cs_dsp_adsp2_parse_sizes,
.validate_version = cs_dsp_validate_version,
.setup_algs = cs_dsp_adsp2_setup_algs,
.region_to_reg = cs_dsp_region_to_reg,
.show_fw_status = cs_dsp_adsp2v2_show_fw_status,
.enable_memory = cs_dsp_adsp2_enable_memory,
.disable_memory = cs_dsp_adsp2_disable_memory,
.lock_memory = cs_dsp_adsp2_lock,
.enable_core = cs_dsp_adsp2v2_enable_core,
.disable_core = cs_dsp_adsp2v2_disable_core,
.start_core = cs_dsp_adsp2_start_core,
.stop_core = cs_dsp_adsp2_stop_core,
},
{
.parse_sizes = cs_dsp_adsp2_parse_sizes,
.validate_version = cs_dsp_validate_version,
.setup_algs = cs_dsp_adsp2_setup_algs,
.region_to_reg = cs_dsp_region_to_reg,
.show_fw_status = cs_dsp_adsp2v2_show_fw_status,
.stop_watchdog = cs_dsp_stop_watchdog,
.enable_memory = cs_dsp_adsp2_enable_memory,
.disable_memory = cs_dsp_adsp2_disable_memory,
.lock_memory = cs_dsp_adsp2_lock,
.enable_core = cs_dsp_adsp2v2_enable_core,
.disable_core = cs_dsp_adsp2v2_disable_core,
.start_core = cs_dsp_adsp2_start_core,
.stop_core = cs_dsp_adsp2_stop_core,
},
};
static const struct cs_dsp_ops cs_dsp_halo_ops = {
.parse_sizes = cs_dsp_adsp2_parse_sizes,
.validate_version = cs_dsp_halo_validate_version,
.setup_algs = cs_dsp_halo_setup_algs,
.region_to_reg = cs_dsp_halo_region_to_reg,
.show_fw_status = cs_dsp_halo_show_fw_status,
.stop_watchdog = cs_dsp_halo_stop_watchdog,
.lock_memory = cs_dsp_halo_configure_mpu,
.start_core = cs_dsp_halo_start_core,
.stop_core = cs_dsp_halo_stop_core,
};
static const struct cs_dsp_ops cs_dsp_halo_ao_ops = {
.parse_sizes = cs_dsp_adsp2_parse_sizes,
.validate_version = cs_dsp_halo_validate_version,
.setup_algs = cs_dsp_halo_setup_algs,
.region_to_reg = cs_dsp_halo_region_to_reg,
.show_fw_status = cs_dsp_halo_show_fw_status,
};
/**
* cs_dsp_chunk_write() - Format data to a DSP memory chunk
* @ch: Pointer to the chunk structure
* @nbits: Number of bits to write
* @val: Value to write
*
* This function sequentially writes values into the format required for DSP
* memory, it handles both inserting of the padding bytes and converting to
* big endian. Note that data is only committed to the chunk when a whole DSP
* words worth of data is available.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_chunk_write(struct cs_dsp_chunk *ch, int nbits, u32 val)
{
int nwrite, i;
nwrite = min(CS_DSP_DATA_WORD_BITS - ch->cachebits, nbits);
ch->cache <<= nwrite;
ch->cache |= val >> (nbits - nwrite);
ch->cachebits += nwrite;
nbits -= nwrite;
if (ch->cachebits == CS_DSP_DATA_WORD_BITS) {
if (cs_dsp_chunk_end(ch))
return -ENOSPC;
ch->cache &= 0xFFFFFF;
for (i = 0; i < sizeof(ch->cache); i++, ch->cache <<= BITS_PER_BYTE)
*ch->data++ = (ch->cache & 0xFF000000) >> CS_DSP_DATA_WORD_BITS;
ch->bytes += sizeof(ch->cache);
ch->cachebits = 0;
}
if (nbits)
return cs_dsp_chunk_write(ch, nbits, val);
return 0;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_chunk_write, FW_CS_DSP);
/**
* cs_dsp_chunk_flush() - Pad remaining data with zero and commit to chunk
* @ch: Pointer to the chunk structure
*
* As cs_dsp_chunk_write only writes data when a whole DSP word is ready to
* be written out it is possible that some data will remain in the cache, this
* function will pad that data with zeros upto a whole DSP word and write out.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_chunk_flush(struct cs_dsp_chunk *ch)
{
if (!ch->cachebits)
return 0;
return cs_dsp_chunk_write(ch, CS_DSP_DATA_WORD_BITS - ch->cachebits, 0);
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_chunk_flush, FW_CS_DSP);
/**
* cs_dsp_chunk_read() - Parse data from a DSP memory chunk
* @ch: Pointer to the chunk structure
* @nbits: Number of bits to read
*
* This function sequentially reads values from a DSP memory formatted buffer,
* it handles both removing of the padding bytes and converting from big endian.
*
* Return: A negative number is returned on error, otherwise the read value.
*/
int cs_dsp_chunk_read(struct cs_dsp_chunk *ch, int nbits)
{
int nread, i;
u32 result;
if (!ch->cachebits) {
if (cs_dsp_chunk_end(ch))
return -ENOSPC;
ch->cache = 0;
ch->cachebits = CS_DSP_DATA_WORD_BITS;
for (i = 0; i < sizeof(ch->cache); i++, ch->cache <<= BITS_PER_BYTE)
ch->cache |= *ch->data++;
ch->bytes += sizeof(ch->cache);
}
nread = min(ch->cachebits, nbits);
nbits -= nread;
result = ch->cache >> ((sizeof(ch->cache) * BITS_PER_BYTE) - nread);
ch->cache <<= nread;
ch->cachebits -= nread;
if (nbits)
result = (result << nbits) | cs_dsp_chunk_read(ch, nbits);
return result;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_chunk_read, FW_CS_DSP);
struct cs_dsp_wseq_op {
struct list_head list;
u32 address;
u32 data;
u16 offset;
u8 operation;
};
static void cs_dsp_wseq_clear(struct cs_dsp *dsp, struct cs_dsp_wseq *wseq)
{
struct cs_dsp_wseq_op *op, *op_tmp;
list_for_each_entry_safe(op, op_tmp, &wseq->ops, list) {
list_del(&op->list);
devm_kfree(dsp->dev, op);
}
}
static int cs_dsp_populate_wseq(struct cs_dsp *dsp, struct cs_dsp_wseq *wseq)
{
struct cs_dsp_wseq_op *op = NULL;
struct cs_dsp_chunk chunk;
u8 *words;
int ret;
if (!wseq->ctl) {
cs_dsp_err(dsp, "No control for write sequence\n");
return -EINVAL;
}
words = kzalloc(wseq->ctl->len, GFP_KERNEL);
if (!words)
return -ENOMEM;
ret = cs_dsp_coeff_read_ctrl(wseq->ctl, 0, words, wseq->ctl->len);
if (ret) {
cs_dsp_err(dsp, "Failed to read %s: %d\n", wseq->ctl->subname, ret);
goto err_free;
}
INIT_LIST_HEAD(&wseq->ops);
chunk = cs_dsp_chunk(words, wseq->ctl->len);
while (!cs_dsp_chunk_end(&chunk)) {
op = devm_kzalloc(dsp->dev, sizeof(*op), GFP_KERNEL);
if (!op) {
ret = -ENOMEM;
goto err_free;
}
op->offset = cs_dsp_chunk_bytes(&chunk);
op->operation = cs_dsp_chunk_read(&chunk, 8);
switch (op->operation) {
case CS_DSP_WSEQ_END:
op->data = WSEQ_END_OF_SCRIPT;
break;
case CS_DSP_WSEQ_UNLOCK:
op->data = cs_dsp_chunk_read(&chunk, 16);
break;
case CS_DSP_WSEQ_ADDR8:
op->address = cs_dsp_chunk_read(&chunk, 8);
op->data = cs_dsp_chunk_read(&chunk, 32);
break;
case CS_DSP_WSEQ_H16:
case CS_DSP_WSEQ_L16:
op->address = cs_dsp_chunk_read(&chunk, 24);
op->data = cs_dsp_chunk_read(&chunk, 16);
break;
case CS_DSP_WSEQ_FULL:
op->address = cs_dsp_chunk_read(&chunk, 32);
op->data = cs_dsp_chunk_read(&chunk, 32);
break;
default:
ret = -EINVAL;
cs_dsp_err(dsp, "Unsupported op: %X\n", op->operation);
devm_kfree(dsp->dev, op);
goto err_free;
}
list_add_tail(&op->list, &wseq->ops);
if (op->operation == CS_DSP_WSEQ_END)
break;
}
if (op && op->operation != CS_DSP_WSEQ_END) {
cs_dsp_err(dsp, "%s missing end terminator\n", wseq->ctl->subname);
ret = -ENOENT;
}
err_free:
kfree(words);
return ret;
}
/**
* cs_dsp_wseq_init() - Initialize write sequences contained within the loaded DSP firmware
* @dsp: Pointer to DSP structure
* @wseqs: List of write sequences to initialize
* @num_wseqs: Number of write sequences to initialize
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_wseq_init(struct cs_dsp *dsp, struct cs_dsp_wseq *wseqs, unsigned int num_wseqs)
{
int i, ret;
lockdep_assert_held(&dsp->pwr_lock);
for (i = 0; i < num_wseqs; i++) {
ret = cs_dsp_populate_wseq(dsp, &wseqs[i]);
if (ret) {
cs_dsp_wseq_clear(dsp, &wseqs[i]);
return ret;
}
}
return 0;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_wseq_init, FW_CS_DSP);
static struct cs_dsp_wseq_op *cs_dsp_wseq_find_op(u32 addr, u8 op_code,
struct list_head *wseq_ops)
{
struct cs_dsp_wseq_op *op;
list_for_each_entry(op, wseq_ops, list) {
if (op->operation == op_code && op->address == addr)
return op;
}
return NULL;
}
/**
* cs_dsp_wseq_write() - Add or update an entry in a write sequence
* @dsp: Pointer to a DSP structure
* @wseq: Write sequence to write to
* @addr: Address of the register to be written to
* @data: Data to be written
* @op_code: The type of operation of the new entry
* @update: If true, searches for the first entry in the write sequence with
* the same address and op_code, and replaces it. If false, creates a new entry
* at the tail
*
* This function formats register address and value pairs into the format
* required for write sequence entries, and either updates or adds the
* new entry into the write sequence.
*
* If update is set to true and no matching entry is found, it will add a new entry.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_wseq_write(struct cs_dsp *dsp, struct cs_dsp_wseq *wseq,
u32 addr, u32 data, u8 op_code, bool update)
{
struct cs_dsp_wseq_op *op_end, *op_new = NULL;
u32 words[WSEQ_OP_MAX_WORDS];
struct cs_dsp_chunk chunk;
int new_op_size, ret;
if (update)
op_new = cs_dsp_wseq_find_op(addr, op_code, &wseq->ops);
/* If entry to update is not found, treat it as a new operation */
if (!op_new) {
op_end = cs_dsp_wseq_find_op(0, CS_DSP_WSEQ_END, &wseq->ops);
if (!op_end) {
cs_dsp_err(dsp, "Missing terminator for %s\n", wseq->ctl->subname);
return -EINVAL;
}
op_new = devm_kzalloc(dsp->dev, sizeof(*op_new), GFP_KERNEL);
if (!op_new)
return -ENOMEM;
op_new->operation = op_code;
op_new->address = addr;
op_new->offset = op_end->offset;
update = false;
}
op_new->data = data;
chunk = cs_dsp_chunk(words, sizeof(words));
cs_dsp_chunk_write(&chunk, 8, op_new->operation);
switch (op_code) {
case CS_DSP_WSEQ_FULL:
cs_dsp_chunk_write(&chunk, 32, op_new->address);
cs_dsp_chunk_write(&chunk, 32, op_new->data);
break;
case CS_DSP_WSEQ_L16:
case CS_DSP_WSEQ_H16:
cs_dsp_chunk_write(&chunk, 24, op_new->address);
cs_dsp_chunk_write(&chunk, 16, op_new->data);
break;
default:
ret = -EINVAL;
cs_dsp_err(dsp, "Operation %X not supported\n", op_code);
goto op_new_free;
}
new_op_size = cs_dsp_chunk_bytes(&chunk);
if (!update) {
if (wseq->ctl->len - op_end->offset < new_op_size) {
cs_dsp_err(dsp, "Not enough memory in %s for entry\n", wseq->ctl->subname);
ret = -E2BIG;
goto op_new_free;
}
op_end->offset += new_op_size;
ret = cs_dsp_coeff_write_ctrl(wseq->ctl, op_end->offset / sizeof(u32),
&op_end->data, sizeof(u32));
if (ret)
goto op_new_free;
list_add_tail(&op_new->list, &op_end->list);
}
ret = cs_dsp_coeff_write_ctrl(wseq->ctl, op_new->offset / sizeof(u32),
words, new_op_size);
if (ret)
goto op_new_free;
return 0;
op_new_free:
devm_kfree(dsp->dev, op_new);
return ret;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_wseq_write, FW_CS_DSP);
/**
* cs_dsp_wseq_multi_write() - Add or update multiple entries in a write sequence
* @dsp: Pointer to a DSP structure
* @wseq: Write sequence to write to
* @reg_seq: List of address-data pairs
* @num_regs: Number of address-data pairs
* @op_code: The types of operations of the new entries
* @update: If true, searches for the first entry in the write sequence with
* the same address and op_code, and replaces it. If false, creates a new entry
* at the tail
*
* This function calls cs_dsp_wseq_write() for multiple address-data pairs.
*
* Return: Zero for success, a negative number on error.
*/
int cs_dsp_wseq_multi_write(struct cs_dsp *dsp, struct cs_dsp_wseq *wseq,
const struct reg_sequence *reg_seq, int num_regs,
u8 op_code, bool update)
{
int i, ret;
for (i = 0; i < num_regs; i++) {
ret = cs_dsp_wseq_write(dsp, wseq, reg_seq[i].reg,
reg_seq[i].def, op_code, update);
if (ret)
return ret;
}
return 0;
}
EXPORT_SYMBOL_NS_GPL(cs_dsp_wseq_multi_write, FW_CS_DSP);
MODULE_DESCRIPTION("Cirrus Logic DSP Support");
MODULE_AUTHOR("Simon Trimmer <simont@opensource.cirrus.com>");
MODULE_LICENSE("GPL v2");