Unverified Commit e33aca3e authored by Antonio Niño Díaz's avatar Antonio Niño Díaz Committed by GitHub
Browse files

Merge pull request #1732 from jollysxilinx/integration

plat: xilinx: Clock and PLL EEMI API Support
parents a9f803b7 ff966c27
......@@ -332,18 +332,6 @@ static struct pm_clock_node acpu_nodes[] = {
.mult = NA_MULT,
.div = NA_DIV,
},
{
.type = TYPE_GATE,
.offset = PERIPH_GATE_SHIFT,
.width = PERIPH_GATE_WIDTH,
.clkflags = CLK_SET_RATE_PARENT |
CLK_IGNORE_UNUSED |
CLK_IS_BASIC |
CLK_IS_CRITICAL,
.typeflags = NA_TYPE_FLAGS,
.mult = NA_MULT,
.div = NA_DIV,
},
};
static struct pm_clock_node generic_mux_div_nodes[] = {
......@@ -478,6 +466,20 @@ static struct pm_clock_node acpu_half_nodes[] = {
},
};
static struct pm_clock_node acpu_full_nodes[] = {
{
.type = TYPE_GATE,
.offset = 24,
.width = PERIPH_GATE_WIDTH,
.clkflags = CLK_IGNORE_UNUSED |
CLK_SET_RATE_PARENT |
CLK_IS_BASIC,
.typeflags = NA_TYPE_FLAGS,
.mult = NA_MULT,
.div = NA_DIV,
},
};
static struct pm_clock_node wdt_nodes[] = {
{
.type = TYPE_MUX,
......@@ -1207,6 +1209,17 @@ static struct pm_clock clocks[] = {
.nodes = &acpu_nodes,
.num_nodes = ARRAY_SIZE(acpu_nodes),
},
[CLK_ACPU_FULL] = {
.name = "acpu_full",
.control_reg = CRF_APB_ACPU_CTRL,
.status_reg = 0,
.parents = &((int32_t []) {
CLK_ACPU | PARENT_CLK_NODE2 << CLK_PARENTS_ID_LEN,
CLK_NA_PARENT
}),
.nodes = &acpu_full_nodes,
.num_nodes = ARRAY_SIZE(acpu_full_nodes),
},
[CLK_DBG_TRACE] = {
.name = "dbg_trace",
.control_reg = CRF_APB_DBG_TRACE_CTRL,
......@@ -2242,7 +2255,29 @@ static struct pm_ext_clock ext_clocks[] = {
};
/* Array of clock which are invalid for this variant */
static uint32_t pm_clk_invalid_list[] = {CLK_USB0, CLK_USB1, CLK_CSU_SPB};
static uint32_t pm_clk_invalid_list[] = {CLK_USB0, CLK_USB1, CLK_CSU_SPB,
CLK_ACPU_FULL,
CLK_ACPU_HALF,
CLK_APLL_TO_LPD,
CLK_DBG_FPD,
CLK_DBG_LPD,
CLK_DBG_TRACE,
CLK_DBG_TSTMP,
CLK_DDR_REF,
CLK_TOPSW_MAIN,
CLK_TOPSW_LSBUS,
CLK_GTGREF0_REF,
CLK_LPD_SWITCH,
CLK_LPD_LSBUS,
CLK_CPU_R5,
CLK_CPU_R5_CORE,
CLK_CSU_SPB,
CLK_CSU_PLL,
CLK_PCAP,
CLK_IOU_SWITCH,
CLK_DLL_REF,
CLK_TIMESTAMP_REF,
};
/**
* pm_clock_valid - Check if clock is valid or not
......@@ -2491,716 +2526,343 @@ enum pm_ret_status pm_api_clock_get_attributes(unsigned int clock_id,
}
/**
* pll_get_lockbit() - Returns lockbit index for pll id
* @pll_id: Id of the pll
*
* This function return the PLL_LOCKED bit index in
* pll status register accosiated with given pll id.
*
* Return: Returns bit index
* struct pm_pll - PLL related data required to map IOCTL-based PLL control
* implemented by linux to system-level EEMI APIs
* @nid: PLL node ID
* @cid: PLL clock ID
* @pre_src: Pre-source PLL clock ID
* @post_src: Post-source PLL clock ID
* @div2: DIV2 PLL clock ID
* @bypass: PLL output clock ID that maps to bypass select output
* @mode: PLL mode currently set via IOCTL (PLL_FRAC_MODE/PLL_INT_MODE)
*/
static int pll_get_lockbit(unsigned int pll_id)
{
switch (pll_id) {
case CLK_APLL_INT:
case CLK_IOPLL_INT:
return 0;
case CLK_DPLL_INT:
case CLK_RPLL_INT:
return 1;
case CLK_VPLL_INT:
return 2;
default:
return -1;
}
}
struct pm_pll {
const enum pm_node_id nid;
const enum clock_id cid;
const enum clock_id pre_src;
const enum clock_id post_src;
const enum clock_id div2;
const enum clock_id bypass;
uint8_t mode;
};
/**
* pm_api_pll_bypass_and_reset() - Bypass and reset PLL
* @clock_id: Id of the PLL
*
* This function is to bypass and reset PLL.
*/
static inline enum pm_ret_status
pm_api_pll_bypass_and_reset(unsigned int clock_id, unsigned int flag)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int reg, val;
int lockbit;
reg = clocks[clock_id].control_reg;
if (flag & CLK_PLL_RESET_ASSERT) {
ret = pm_mmio_write(reg, PLLCTRL_BP_MASK, PLLCTRL_BP_MASK);
if (ret != PM_RET_SUCCESS)
return ret;
ret = pm_mmio_write(reg, PLLCTRL_RESET_MASK,
PLLCTRL_RESET_MASK);
if (ret != PM_RET_SUCCESS)
return ret;
}
if (flag & CLK_PLL_RESET_RELEASE) {
ret = pm_mmio_write(reg, PLLCTRL_RESET_MASK,
~PLLCTRL_RESET_MASK);
if (ret != PM_RET_SUCCESS)
return ret;
lockbit = pll_get_lockbit(clock_id);
do {
ret = pm_mmio_read(clocks[clock_id].status_reg, &val);
if (ret != PM_RET_SUCCESS)
return ret;
} while ((lockbit >= 0) && !(val & (1 << lockbit)));
ret = pm_mmio_write(reg, PLLCTRL_BP_MASK,
~(unsigned int)PLLCTRL_BP_MASK);
}
return ret;
}
static struct pm_pll pm_plls[] = {
{
.nid = NODE_IOPLL,
.cid = CLK_IOPLL_INT,
.pre_src = CLK_IOPLL_PRE_SRC,
.post_src = CLK_IOPLL_POST_SRC,
.div2 = CLK_IOPLL_INT_MUX,
.bypass = CLK_IOPLL,
}, {
.nid = NODE_RPLL,
.cid = CLK_RPLL_INT,
.pre_src = CLK_RPLL_PRE_SRC,
.post_src = CLK_RPLL_POST_SRC,
.div2 = CLK_RPLL_INT_MUX,
.bypass = CLK_RPLL,
}, {
.nid = NODE_APLL,
.cid = CLK_APLL_INT,
.pre_src = CLK_APLL_PRE_SRC,
.post_src = CLK_APLL_POST_SRC,
.div2 = CLK_APLL_INT_MUX,
.bypass = CLK_APLL,
}, {
.nid = NODE_VPLL,
.cid = CLK_VPLL_INT,
.pre_src = CLK_VPLL_PRE_SRC,
.post_src = CLK_VPLL_POST_SRC,
.div2 = CLK_VPLL_INT_MUX,
.bypass = CLK_VPLL,
}, {
.nid = NODE_DPLL,
.cid = CLK_DPLL_INT,
.pre_src = CLK_DPLL_PRE_SRC,
.post_src = CLK_DPLL_POST_SRC,
.div2 = CLK_DPLL_INT_MUX,
.bypass = CLK_DPLL,
},
};
/**
* pm_api_clk_enable_disable() - Enable/Disable the clock for given id
* @clock_id: Id of the clock to be enabled
* @enable: Enable(1)/Disable(0)
*
* This function is to enable/disable the clock which is not PLL.
* pm_clock_get_pll() - Get PLL structure by PLL clock ID
* @clock_id Clock ID of the target PLL
*
* Return: Returns status, either success or error+reason.
* @return Pointer to PLL structure if found, NULL otherwise
*/
static enum pm_ret_status pm_api_clk_enable_disable(unsigned int clock_id,
unsigned int enable)
struct pm_pll *pm_clock_get_pll(enum clock_id clock_id)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
struct pm_clock_node *nodes = *clocks[clock_id].nodes;
uint8_t num_nodes = clocks[clock_id].num_nodes;
unsigned int reg, val;
uint8_t i = 0;
uint8_t offset = NA_SHIFT, width = NA_WIDTH;
if (clock_id == CLK_GEM0_TX || clock_id == CLK_GEM1_TX ||
clock_id == CLK_GEM2_TX || clock_id == CLK_GEM3_TX)
reg = clocks[clock_id].status_reg;
else
reg = clocks[clock_id].control_reg;
uint32_t i;
for (i = 0; i < num_nodes; i++) {
if (nodes->type == TYPE_GATE) {
offset = nodes->offset;
width = nodes->width;
break;
for (i = 0; i < ARRAY_SIZE(pm_plls); i++) {
if (pm_plls[i].cid == clock_id)
return &pm_plls[i];
}
nodes++;
}
if (width == NA_WIDTH)
return PM_RET_ERROR_NOTSUPPORTED;
ret = pm_mmio_read(reg, &val);
if (ret != PM_RET_SUCCESS)
return ret;
if ((val & BIT_MASK(offset, width)) == enable)
return PM_RET_SUCCESS;
if (enable == 0)
val &= ~(BIT_MASK(offset, width));
else
val |= BIT_MASK(offset, width);
ret = pm_mmio_write(reg, BIT_MASK(offset, width), val);
return ret;
return NULL;
}
/**
* pm_api_clock_enable() - Enable the clock for given id
* @clock_id: Id of the clock to be enabled
* pm_clock_get_pll_node_id() - Get PLL node ID by PLL clock ID
* @clock_id Clock ID of the target PLL
* @node_id Location to store node ID of the target PLL
*
* This function is used by master to enable the clock
* including peripherals and PLL clocks.
*
* Return: Returns status, either success or error+reason.
* @return PM_RET_SUCCESS if node ID is found, PM_RET_ERROR_ARGS otherwise
*/
enum pm_ret_status pm_api_clock_enable(unsigned int clock_id)
enum pm_ret_status pm_clock_get_pll_node_id(enum clock_id clock_id,
enum pm_node_id *node_id)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
if (!pm_clock_valid(clock_id))
return PM_RET_ERROR_ARGS;
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
/*
* PLL type clock should not enable explicitly.
* It is done by FSBL on boot-up and by PMUFW whenever required.
*/
if (!ISPLL(clock_id))
ret = pm_api_clk_enable_disable(clock_id, 1);
return ret;
}
struct pm_pll *pll = pm_clock_get_pll(clock_id);
/**
* pm_api_clock_disable - Disable the clock for given id
* @clock_id Id of the clock to be disable
*
* This function is used by master to disable the clock
* including peripherals and PLL clocks.
*
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_api_clock_disable(unsigned int clock_id)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
if (pll) {
*node_id = pll->nid;
return PM_RET_SUCCESS;
}
if (!pm_clock_valid(clock_id))
return PM_RET_ERROR_ARGS;
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
/*
* PLL type clock should not be disabled explicitly.
* It is done by PMUFW if required.
*/
if (!ISPLL(clock_id))
ret = pm_api_clk_enable_disable(clock_id, 0);
return ret;
}
/**
* pm_api_get_pll_state() - Get state of PLL
* @clock_id Id of the PLL
* @state State of PLL(1: Enable, 0: Reset)
*
* This function is to check state of PLL.
*/
static inline enum pm_ret_status pm_api_get_pll_state(unsigned int clock_id,
unsigned int *state)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int reg, val;
reg = clocks[clock_id].control_reg;
ret = pm_mmio_read(reg, &val);
/* state:
* 1 - PLL is enabled
* 0 - PLL is in reset state
*/
*state = !(val & PLLCTRL_RESET_MASK);
return ret;
}
/**
* pm_api_get_clk_state() - Get the state of clock for given id
* @clock_id: Id of the clock to be enabled
* @state: Enable(1)/Disable(0)
*
* This function is to get state of the clock which is not PLL.
* pm_clock_get_pll_by_related_clk() - Get PLL structure by PLL-related clock ID
* @clock_id Clock ID
*
* Return: Returns status, either success or error+reason.
* @return Pointer to PLL structure if found, NULL otherwise
*/
static enum pm_ret_status pm_api_get_clk_state(unsigned int clock_id,
unsigned int *state)
struct pm_pll *pm_clock_get_pll_by_related_clk(enum clock_id clock_id)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
struct pm_clock_node *nodes = *clocks[clock_id].nodes;
uint8_t num_nodes = clocks[clock_id].num_nodes;
unsigned int reg, val;
uint8_t i = 0;
uint8_t offset = NA_SHIFT, width = NA_WIDTH;
reg = clocks[clock_id].control_reg;
for (i = 0; i < num_nodes; i++) {
if (nodes->type == TYPE_GATE) {
offset = nodes->offset;
width = nodes->width;
uint32_t i;
for (i = 0; i < ARRAY_SIZE(pm_plls); i++) {
if (pm_plls[i].pre_src == clock_id ||
pm_plls[i].post_src == clock_id ||
pm_plls[i].div2 == clock_id ||
pm_plls[i].bypass == clock_id) {
return &pm_plls[i];
}
nodes++;
}
if (width == NA_WIDTH)
return PM_RET_ERROR_NOTSUPPORTED;
ret = pm_mmio_read(reg, &val);
*state = (val & BIT_MASK(offset, width)) >> offset;
return ret;
return NULL;
}
/**
* pm_api_clock_getstate - Get the clock state for given id
* @clock_id Id of the clock to be queried
* @state 1/0 (Enabled/Disabled)
* pm_clock_pll_enable() - "Enable" the PLL clock (lock the PLL)
* @pll: PLL to be locked
*
* This function is used by master to get the state of clock
* including peripherals and PLL clocks.
* This function is used to map IOCTL/linux-based PLL handling to system-level
* EEMI APIs
*
* Return: Returns status, either success or error+reason.
* Return: Error if the argument is not valid or status as returned by PMU
*/
enum pm_ret_status pm_api_clock_getstate(unsigned int clock_id,
unsigned int *state)
enum pm_ret_status pm_clock_pll_enable(struct pm_pll *pll)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
if (!pm_clock_valid(clock_id))
if (!pll)
return PM_RET_ERROR_ARGS;
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
if (ISPLL(clock_id))
ret = pm_api_get_pll_state(clock_id, state);
else
ret = pm_api_get_clk_state(clock_id, state);
return ret;
}
static enum pm_ret_status pm_api_clk_set_divider(unsigned int clock_id,
uint32_t divider)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
struct pm_clock_node *nodes;
uint8_t num_nodes;
uint16_t div1, div2;
unsigned int reg, mask = 0, val = 0, i;
uint8_t div1_width = NA_WIDTH, div1_offset = NA_SHIFT;
uint8_t div2_width = NA_WIDTH, div2_offset = NA_SHIFT;
div1 = (uint16_t)(divider & 0xFFFFU);
div2 = (uint16_t)((divider >> 16) & 0xFFFFU);
reg = clocks[clock_id].control_reg;
nodes = *clocks[clock_id].nodes;
num_nodes = clocks[clock_id].num_nodes;
for (i = 0; i < num_nodes; i++) {
if (nodes->type == TYPE_DIV1) {
div1_offset = nodes->offset;
div1_width = nodes->width;
}
if (nodes->type == TYPE_DIV2) {
div2_offset = nodes->offset;
div2_width = nodes->width;
}
nodes++;
}
if (div1 != (uint16_t)-1) {
if (div1_width == NA_WIDTH)
return PM_RET_ERROR_NOTSUPPORTED;
val |= div1 << div1_offset;
mask |= BIT_MASK(div1_offset, div1_width);
}
if (div2 != (uint16_t)-1) {
if (div2_width == NA_WIDTH)
return PM_RET_ERROR_NOTSUPPORTED;
val |= div2 << div2_offset;
mask |= BIT_MASK(div2_offset, div2_width);
}
ret = pm_mmio_write(reg, mask, val);
/* Set the PLL mode according to the buffered mode value */
if (pll->mode == PLL_FRAC_MODE)
return pm_pll_set_mode(pll->nid, PM_PLL_MODE_FRACTIONAL);
return ret;
}
static enum pm_ret_status pm_api_pll_set_divider(unsigned int clock_id,
unsigned int divider)
{
unsigned int reg = clocks[clock_id].control_reg;
enum pm_ret_status ret;
pm_api_pll_bypass_and_reset(clock_id, CLK_PLL_RESET_ASSERT);
ret = pm_mmio_write(reg, PLL_FBDIV_MASK, divider << PLL_FBDIV_SHIFT);
pm_api_pll_bypass_and_reset(clock_id, CLK_PLL_RESET_RELEASE);
return ret;
return pm_pll_set_mode(pll->nid, PM_PLL_MODE_INTEGER);
}
/**
* pm_api_clock_setdivider - Set the clock divider for given id
* @clock_id Id of the clock
* @divider Divider value
* pm_clock_pll_disable - "Disable" the PLL clock (bypass/reset the PLL)
* @pll PLL to be bypassed/reset
*
* This function is used by master to set divider for any clock
* to achieve desired rate.
* This function is used to map IOCTL/linux-based PLL handling to system-level
* EEMI APIs
*
* Return: Returns status, either success or error+reason.
* Return: Error if the argument is not valid or status as returned by PMU
*/
enum pm_ret_status pm_api_clock_setdivider(unsigned int clock_id,
unsigned int divider)
enum pm_ret_status pm_clock_pll_disable(struct pm_pll *pll)
{
enum pm_ret_status ret;
if (!pm_clock_valid(clock_id))
if (!pll)
return PM_RET_ERROR_ARGS;
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
if (ISPLL(clock_id))
ret = pm_api_pll_set_divider(clock_id, divider);
else
ret = pm_api_clk_set_divider(clock_id, divider);
return ret;
}
static enum pm_ret_status pm_api_clk_get_divider(unsigned int clock_id,
uint32_t *divider)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
struct pm_clock_node *nodes;
uint8_t num_nodes;
unsigned int reg, val, i, div1 = 0, div2 = 0;
uint8_t div1_width = NA_WIDTH, div1_offset = NA_SHIFT;
uint8_t div2_width = NA_WIDTH, div2_offset = NA_SHIFT;
reg = clocks[clock_id].control_reg;
nodes = *clocks[clock_id].nodes;
num_nodes = clocks[clock_id].num_nodes;
for (i = 0; i < num_nodes; i++) {
if (nodes->type == TYPE_DIV1) {
div1_offset = nodes->offset;
div1_width = nodes->width;
}
if (nodes->type == TYPE_DIV2) {
div2_offset = nodes->offset;
div2_width = nodes->width;
}
nodes++;
}
ret = pm_mmio_read(reg, &val);
if (div1_width == NA_WIDTH)
return PM_RET_ERROR_ARGS;
div1 = (val & BIT_MASK(div1_offset, div1_width)) >> div1_offset;
if (div2_width != NA_WIDTH)
div2 = (val & BIT_MASK(div2_offset, div2_width)) >> div2_offset;
*divider = div1 | (div2 << 16);
return ret;
}
static enum pm_ret_status pm_api_pll_get_divider(unsigned int clock_id,
unsigned int *divider)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int reg, val;
reg = clocks[clock_id].control_reg;
ret = pm_mmio_read(reg, &val);
*divider = (val & PLL_FBDIV_MASK) >> PLL_FBDIV_SHIFT;
return ret;
return pm_pll_set_mode(pll->nid, PM_PLL_MODE_RESET);
}
/**
* pm_api_clock_getdivider - Get the clock divider for given id
* @clock_id Id of the clock
* @divider Divider value
* pm_clock_pll_get_state - Get state of the PLL
* @pll Pointer to the target PLL structure
* @state Location to store the state: 1/0 ("Enabled"/"Disabled")
*
* This function is used by master to get divider values
* for any clock.
* "Enable" actually means that the PLL is locked and its bypass is deasserted,
* "Disable" means that it is bypassed.
*
* Return: Returns status, either success or error+reason.
* Return: PM_RET_ERROR_ARGS error if the argument is not valid, success if
* returned state value is valid or an error if returned by PMU
*/
enum pm_ret_status pm_api_clock_getdivider(unsigned int clock_id,
unsigned int *divider)
enum pm_ret_status pm_clock_pll_get_state(struct pm_pll *pll,
unsigned int *state)
{
enum pm_ret_status ret;
enum pm_ret_status status;
enum pm_pll_mode mode;
if (!pm_clock_valid(clock_id))
if (!pll || !state)
return PM_RET_ERROR_ARGS;
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
status = pm_pll_get_mode(pll->nid, &mode);
if (status != PM_RET_SUCCESS)
return status;
if (ISPLL(clock_id))
ret = pm_api_pll_get_divider(clock_id, divider);
if (mode == PM_PLL_MODE_RESET)
*state = 0;
else
ret = pm_api_clk_get_divider(clock_id, divider);
return ret;
}
/**
* pm_api_clock_setrate - Set the clock rate for given id
* @clock_id Id of the clock
* @rate Rate value in hz
*
* This function is used by master to set rate for any clock.
*
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_api_clock_setrate(unsigned int clock_id,
uint64_t rate)
{
return PM_RET_ERROR_NOTSUPPORTED;
}
*state = 1;
/**
* pm_api_clock_getrate - Get the clock rate for given id
* @clock_id Id of the clock
* @rate rate value in hz
*
* This function is used by master to get rate
* for any clock.
*
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_api_clock_getrate(unsigned int clock_id,
uint64_t *rate)
{
return PM_RET_ERROR_NOTSUPPORTED;
return PM_RET_SUCCESS;
}
/**
* pm_api_clock_setparent - Set the clock parent for given id
* pm_clock_pll_set_parent - Set the clock parent for PLL-related clock id
* @pll Target PLL structure
* @clock_id Id of the clock
* @parent_idx parent index
* @parent_index parent index (=mux select value)
*
* This function is used by master to set parent for any clock.
* The whole clock-tree implementation relies on the fact that parent indexes
* match to the multiplexer select values. This function has to rely on that
* assumption as well => parent_index is actually the mux select value.
*
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_api_clock_setparent(unsigned int clock_id,
unsigned int parent_idx)
enum pm_ret_status pm_clock_pll_set_parent(struct pm_pll *pll,
enum clock_id clock_id,
unsigned int parent_index)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
struct pm_clock_node *nodes;
uint8_t num_nodes;
unsigned int reg, val;
int32_t *clk_parents;
unsigned int i = 0;
uint8_t offset = NA_SHIFT, width = NA_WIDTH;
if (!pm_clock_valid(clock_id))
if (!pll)
return PM_RET_ERROR_ARGS;
if (pll->pre_src == clock_id)
return pm_pll_set_parameter(pll->nid, PM_PLL_PARAM_PRE_SRC,
parent_index);
if (pll->post_src == clock_id)
return pm_pll_set_parameter(pll->nid, PM_PLL_PARAM_POST_SRC,
parent_index);
if (pll->div2 == clock_id)
return pm_pll_set_parameter(pll->nid, PM_PLL_PARAM_DIV2,
parent_index);
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
clk_parents = *clocks[clock_id].parents;
for (i = 0; i <= parent_idx; i++)
if (clk_parents[i] == CLK_NA_PARENT)
return PM_RET_ERROR_ARGS;
nodes = *clocks[clock_id].nodes;
num_nodes = clocks[clock_id].num_nodes;
for (i = 0; i < num_nodes; i++) {
if (nodes->type == TYPE_MUX) {
offset = nodes->offset;
width = nodes->width;
}
nodes++;
}
if (width == NA_WIDTH)
return PM_RET_ERROR_NOTSUPPORTED;
reg = clocks[clock_id].control_reg;
val = parent_idx << offset;
ret = pm_mmio_write(reg, BIT_MASK(offset, width), val);
return ret;
}
/**
* pm_api_clock_getparent - Get the clock parent for given id
* pm_clock_pll_get_parent - Get mux select value of PLL-related clock parent
* @pll Target PLL structure
* @clock_id Id of the clock
* @parent_idx parent index
* @parent_index parent index (=mux select value)
*
* This function is used by master to get parent index
* for any clock.
* This function is used by master to get parent index for PLL-related clock.
*
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_api_clock_getparent(unsigned int clock_id,
unsigned int *parent_idx)
enum pm_ret_status pm_clock_pll_get_parent(struct pm_pll *pll,
enum clock_id clock_id,
unsigned int *parent_index)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
struct pm_clock_node *nodes;
uint8_t num_nodes;
unsigned int reg, val;
uint8_t i = 0, offset = NA_SHIFT, width = NA_WIDTH;
if (!pm_clock_valid(clock_id))
if (!pll)
return PM_RET_ERROR_ARGS;
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
nodes = *clocks[clock_id].nodes;
num_nodes = clocks[clock_id].num_nodes;
for (i = 0; i < num_nodes; i++) {
if (nodes->type == TYPE_MUX) {
offset = nodes->offset;
width = nodes->width;
}
nodes++;
if (pll->pre_src == clock_id)
return pm_pll_get_parameter(pll->nid, PM_PLL_PARAM_PRE_SRC,
parent_index);
if (pll->post_src == clock_id)
return pm_pll_get_parameter(pll->nid, PM_PLL_PARAM_POST_SRC,
parent_index);
if (pll->div2 == clock_id)
return pm_pll_get_parameter(pll->nid, PM_PLL_PARAM_DIV2,
parent_index);
if (pll->bypass == clock_id) {
*parent_index = 0;
return PM_RET_SUCCESS;
}
if (width == NA_WIDTH)
return PM_RET_ERROR_NOTSUPPORTED;
reg = clocks[clock_id].control_reg;
ret = pm_mmio_read(reg, &val);
val >>= offset;
val &= ((1U << width) - 1);
*parent_idx = val;
return ret;
return PM_RET_ERROR_ARGS;
}
/**
* pm_api_clk_set_pll_mode() - Set PLL mode
* @pll PLL id
* @mode Mode fraction/integar
* pm_clock_set_pll_mode() - Set PLL mode
* @clock_id PLL clock id
* @mode Mode fractional/integer
*
* This function sets PLL mode.
* This function buffers/saves the PLL mode that is set.
*
* @return Returns status, either success or error+reason
* @return Success if mode is buffered or error if an argument is invalid
*/
enum pm_ret_status pm_api_clk_set_pll_mode(unsigned int pll,
enum pm_ret_status pm_clock_set_pll_mode(enum clock_id clock_id,
unsigned int mode)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int reg;
if (!pm_clock_valid(pll))
return PM_RET_ERROR_ARGS;
if (pm_clock_type(pll) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
if (!ISPLL(pll))
return PM_RET_ERROR_NOTSUPPORTED;
struct pm_pll *pll = pm_clock_get_pll(clock_id);
if (mode != PLL_FRAC_MODE && mode != PLL_INT_MODE)
if (!pll || (mode != PLL_FRAC_MODE && mode != PLL_INT_MODE))
return PM_RET_ERROR_ARGS;
pll->mode = mode;
reg = clocks[pll].control_reg + PLL_FRAC_OFFSET;
ret = pm_mmio_write(reg, PLL_FRAC_MODE_MASK,
mode << PLL_FRAC_MODE_SHIFT);
return ret;
return PM_RET_SUCCESS;
}
/**
* pm_ioctl_get_pll_mode() - Get PLL mode
* @pll PLL id
* @mode Mode fraction/integar
* pm_clock_get_pll_mode() - Get PLL mode
* @clock_id PLL clock id
* @mode Location to store the mode (fractional/integer)
*
* This function returns current PLL mode.
* This function returns buffered PLL mode.
*
* @return Returns status, either success or error+reason
* @return Success if mode is stored or error if an argument is invalid
*/
enum pm_ret_status pm_api_clk_get_pll_mode(unsigned int pll,
enum pm_ret_status pm_clock_get_pll_mode(enum clock_id clock_id,
unsigned int *mode)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int val, reg;
struct pm_pll *pll = pm_clock_get_pll(clock_id);
if (!pm_clock_valid(pll))
if (!pll || !mode)
return PM_RET_ERROR_ARGS;
*mode = pll->mode;
if (pm_clock_type(pll) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
if (!ISPLL(pll))
return PM_RET_ERROR_NOTSUPPORTED;
reg = clocks[pll].control_reg + PLL_FRAC_OFFSET;
ret = pm_mmio_read(reg, &val);
val = val & PLL_FRAC_MODE_MASK;
if (val == 0)
*mode = PLL_INT_MODE;
else
*mode = PLL_FRAC_MODE;
return ret;
return PM_RET_SUCCESS;
}
/**
* pm_api_clk_set_pll_frac_data() - Set PLL fraction data
* @pll PLL id
* @data fraction data
*
* This function sets fraction data. It is valid for fraction
* mode only.
* pm_clock_id_is_valid() - Check if given clock ID is valid
* @clock_id ID of the clock to be checked
*
* @return Returns status, either success or error+reason
* @return Returns success if clock_id is valid, otherwise an error
*/
enum pm_ret_status pm_api_clk_set_pll_frac_data(unsigned int pll,
unsigned int data)
enum pm_ret_status pm_clock_id_is_valid(unsigned int clock_id)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int val, reg, mode = 0;
if (!pm_clock_valid(pll))
if (!pm_clock_valid(clock_id))
return PM_RET_ERROR_ARGS;
if (pm_clock_type(pll) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
if (!ISPLL(pll))
if (pm_clock_type(clock_id) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
ret = pm_api_clk_get_pll_mode(pll, &mode);
if (ret != PM_RET_SUCCESS)
return ret;
if (mode == PLL_FRAC_MODE) {
reg = clocks[pll].control_reg + PLL_FRAC_OFFSET;
val = data << PLL_FRAC_DATA_SHIFT;
ret = pm_mmio_write(reg, PLL_FRAC_DATA_MASK, val);
} else {
return PM_RET_ERROR_ARGS;
}
return ret;
return PM_RET_SUCCESS;
}
/**
* pm_api_clk_get_pll_frac_data() - Get PLL fraction data
* @pll PLL id
* @data fraction data
*
* This function returns fraction data value.
* pm_clock_has_div() - Check if the clock has divider with given ID
* @clock_id Clock ID
* @div_id Divider ID
*
* @return Returns status, either success or error+reason
* @return True(1)=clock has the divider, false(0)=otherwise
*/
enum pm_ret_status pm_api_clk_get_pll_frac_data(unsigned int pll,
unsigned int *data)
uint8_t pm_clock_has_div(unsigned int clock_id, enum pm_clock_div_id div_id)
{
enum pm_ret_status ret = PM_RET_SUCCESS;
unsigned int val, reg;
if (!pm_clock_valid(pll))
return PM_RET_ERROR_ARGS;
if (pm_clock_type(pll) != CLK_TYPE_OUTPUT)
return PM_RET_ERROR_NOTSUPPORTED;
if (!ISPLL(pll))
return PM_RET_ERROR_NOTSUPPORTED;
uint32_t i;
struct pm_clock_node *nodes;
reg = clocks[pll].control_reg + PLL_FRAC_OFFSET;
if (clock_id >= CLK_MAX_OUTPUT_CLK)
return 0;
ret = pm_mmio_read(reg, &val);
*data = (val & PLL_FRAC_DATA_MASK);
nodes = *clocks[clock_id].nodes;
for (i = 0; i < clocks[clock_id].num_nodes; i++) {
if (nodes[i].type == TYPE_DIV1) {
if (div_id == PM_CLOCK_DIV0_ID)
return 1;
} else if (nodes[i].type == TYPE_DIV2) {
if (div_id == PM_CLOCK_DIV1_ID)
return 1;
}
}
return ret;
return 0;
}
......@@ -56,7 +56,7 @@
#define END_OF_CLK "END_OF_CLK"
//CLock Ids
enum {
enum clock_id {
CLK_IOPLL,
CLK_RPLL,
CLK_APLL,
......@@ -160,6 +160,7 @@ enum {
CLK_VPLL_POST_SRC,
CLK_CAN0_MIO,
CLK_CAN1_MIO,
CLK_ACPU_FULL,
END_OF_OUTPUT_CLKS,
};
......@@ -275,6 +276,10 @@ enum {
#define TYPE_DIV2 5U
#define TYPE_GATE 6U
struct pm_pll;
struct pm_pll *pm_clock_get_pll(enum clock_id clock_id);
struct pm_pll *pm_clock_get_pll_by_related_clk(enum clock_id clock_id);
uint8_t pm_clock_has_div(unsigned int clock_id, enum pm_clock_div_id div_id);
enum pm_ret_status pm_api_clock_get_name(unsigned int clock_id, char *name);
enum pm_ret_status pm_api_clock_get_num_clocks(unsigned int *nclocks);
......@@ -289,29 +294,24 @@ enum pm_ret_status pm_api_clock_get_parents(unsigned int clock_id,
uint32_t *parents);
enum pm_ret_status pm_api_clock_get_attributes(unsigned int clock_id,
uint32_t *attr);
enum pm_ret_status pm_api_clock_enable(unsigned int clock_id);
enum pm_ret_status pm_api_clock_disable(unsigned int clock_id);
enum pm_ret_status pm_api_clock_getstate(unsigned int clock_id,
enum pm_ret_status pm_clock_get_pll_node_id(enum clock_id clock_id,
enum pm_node_id *node_id);
enum pm_ret_status pm_clock_id_is_valid(unsigned int clock_id);
enum pm_ret_status pm_clock_pll_enable(struct pm_pll *pll);
enum pm_ret_status pm_clock_pll_disable(struct pm_pll *pll);
enum pm_ret_status pm_clock_pll_get_state(struct pm_pll *pll,
unsigned int *state);
enum pm_ret_status pm_api_clock_setdivider(unsigned int clock_id,
unsigned int divider);
enum pm_ret_status pm_api_clock_getdivider(unsigned int clock_id,
unsigned int *divider);
enum pm_ret_status pm_api_clock_setrate(unsigned int clock_id,
uint64_t rate);
enum pm_ret_status pm_api_clock_getrate(unsigned int clock_id,
uint64_t *rate);
enum pm_ret_status pm_api_clock_setparent(unsigned int clock_id,
unsigned int parent_idx);
enum pm_ret_status pm_api_clock_getparent(unsigned int clock_id,
unsigned int *parent_idx);
enum pm_ret_status pm_api_clk_set_pll_mode(unsigned int pll,
enum pm_ret_status pm_clock_pll_set_parent(struct pm_pll *pll,
enum clock_id clock_id,
unsigned int parent_index);
enum pm_ret_status pm_clock_pll_get_parent(struct pm_pll *pll,
enum clock_id clock_id,
unsigned int *parent_index);
enum pm_ret_status pm_clock_set_pll_mode(enum clock_id clock_id,
unsigned int mode);
enum pm_ret_status pm_api_clk_get_pll_mode(unsigned int pll,
enum pm_ret_status pm_clock_get_pll_mode(enum clock_id clock_id,
unsigned int *mode);
enum pm_ret_status pm_api_clk_set_pll_frac_data(unsigned int pll,
unsigned int data);
enum pm_ret_status pm_api_clk_get_pll_frac_data(unsigned int pll,
unsigned int *data);
#endif /* PM_API_CLOCK_H */
......@@ -333,7 +333,7 @@ reset_release:
/**
* pm_ioctl_set_pll_frac_mode() - Ioctl function for
* setting pll mode
* @pll PLL id
* @pll PLL clock id
* @mode Mode fraction/integar
*
* This function sets PLL mode
......@@ -343,13 +343,13 @@ reset_release:
static enum pm_ret_status pm_ioctl_set_pll_frac_mode
(unsigned int pll, unsigned int mode)
{
return pm_api_clk_set_pll_mode(pll, mode);
return pm_clock_set_pll_mode(pll, mode);
}
/**
* pm_ioctl_get_pll_frac_mode() - Ioctl function for
* getting pll mode
* @pll PLL id
* @pll PLL clock id
* @mode Mode fraction/integar
*
* This function return current PLL mode
......@@ -359,13 +359,13 @@ static enum pm_ret_status pm_ioctl_set_pll_frac_mode
static enum pm_ret_status pm_ioctl_get_pll_frac_mode
(unsigned int pll, unsigned int *mode)
{
return pm_api_clk_get_pll_mode(pll, mode);
return pm_clock_get_pll_mode(pll, mode);
}
/**
* pm_ioctl_set_pll_frac_data() - Ioctl function for
* setting pll fraction data
* @pll PLL id
* @pll PLL clock id
* @data fraction data
*
* This function sets fraction data.
......@@ -376,13 +376,21 @@ static enum pm_ret_status pm_ioctl_get_pll_frac_mode
static enum pm_ret_status pm_ioctl_set_pll_frac_data
(unsigned int pll, unsigned int data)
{
return pm_api_clk_set_pll_frac_data(pll, data);
enum pm_node_id pll_nid;
enum pm_ret_status status;
/* Get PLL node ID using PLL clock ID */
status = pm_clock_get_pll_node_id(pll, &pll_nid);
if (status != PM_RET_SUCCESS)
return status;
return pm_pll_set_parameter(pll_nid, PM_PLL_PARAM_DATA, data);
}
/**
* pm_ioctl_get_pll_frac_data() - Ioctl function for
* getting pll fraction data
* @pll PLL id
* @pll PLL clock id
* @data fraction data
*
* This function returns fraction data value.
......@@ -392,7 +400,15 @@ static enum pm_ret_status pm_ioctl_set_pll_frac_data
static enum pm_ret_status pm_ioctl_get_pll_frac_data
(unsigned int pll, unsigned int *data)
{
return pm_api_clk_get_pll_frac_data(pll, data);
enum pm_node_id pll_nid;
enum pm_ret_status status;
/* Get PLL node ID using PLL clock ID */
status = pm_clock_get_pll_node_id(pll, &pll_nid);
if (status != PM_RET_SUCCESS)
return status;
return pm_pll_get_parameter(pll_nid, PM_PLL_PARAM_DATA, data);
}
/**
......
......@@ -844,6 +844,36 @@ static enum pm_ret_status pm_clock_get_attributes(unsigned int clock_id,
return pm_api_clock_get_attributes(clock_id, attr);
}
/**
* pm_clock_gate() - Configure clock gate
* @clock_id Id of the clock to be configured
* @enable Flag 0=disable (gate the clock), !0=enable (activate the clock)
*
* @return Error if an argument is not valid or status as returned by the
* PM controller (PMU)
*/
static enum pm_ret_status pm_clock_gate(unsigned int clock_id,
unsigned char enable)
{
uint32_t payload[PAYLOAD_ARG_CNT];
enum pm_ret_status status;
enum pm_api_id api_id;
/* Check if clock ID is valid and return an error if it is not */
status = pm_clock_id_is_valid(clock_id);
if (status != PM_RET_SUCCESS)
return status;
if (enable)
api_id = PM_CLOCK_ENABLE;
else
api_id = PM_CLOCK_DISABLE;
/* Send request to the PMU */
PM_PACK_PAYLOAD2(payload, api_id, clock_id);
return pm_ipi_send_sync(primary_proc, payload, NULL, 0);
}
/**
* pm_clock_enable() - Enable the clock for given id
* @clock_id: Id of the clock to be enabled
......@@ -851,12 +881,20 @@ static enum pm_ret_status pm_clock_get_attributes(unsigned int clock_id,
* This function is used by master to enable the clock
* including peripherals and PLL clocks.
*
* Return: Returns status, either success or error+reason.
* @return: Error if an argument is not valid or status as returned by the
* pm_clock_gate
*/
enum pm_ret_status pm_clock_enable(unsigned int clock_id)
{
return pm_api_clock_enable(clock_id);
struct pm_pll *pll;
/* First try to handle it as a PLL */
pll = pm_clock_get_pll(clock_id);
if (pll)
return pm_clock_pll_enable(pll);
/* It's an on-chip clock, PMU should configure clock's gate */
return pm_clock_gate(clock_id, 1);
}
/**
......@@ -866,12 +904,20 @@ enum pm_ret_status pm_clock_enable(unsigned int clock_id)
* This function is used by master to disable the clock
* including peripherals and PLL clocks.
*
* Return: Returns status, either success or error+reason.
* @return: Error if an argument is not valid or status as returned by the
* pm_clock_gate
*/
enum pm_ret_status pm_clock_disable(unsigned int clock_id)
{
return pm_api_clock_disable(clock_id);
struct pm_pll *pll;
/* First try to handle it as a PLL */
pll = pm_clock_get_pll(clock_id);
if (pll)
return pm_clock_pll_disable(pll);
/* It's an on-chip clock, PMU should configure clock's gate */
return pm_clock_gate(clock_id, 0);
}
/**
......@@ -887,7 +933,23 @@ enum pm_ret_status pm_clock_disable(unsigned int clock_id)
enum pm_ret_status pm_clock_getstate(unsigned int clock_id,
unsigned int *state)
{
return pm_api_clock_getstate(clock_id, state);
struct pm_pll *pll;
uint32_t payload[PAYLOAD_ARG_CNT];
enum pm_ret_status status;
/* First try to handle it as a PLL */
pll = pm_clock_get_pll(clock_id);
if (pll)
return pm_clock_pll_get_state(pll, state);
/* Check if clock ID is a valid on-chip clock */
status = pm_clock_id_is_valid(clock_id);
if (status != PM_RET_SUCCESS)
return status;
/* Send request to the PMU */
PM_PACK_PAYLOAD2(payload, PM_CLOCK_GETSTATE, clock_id);
return pm_ipi_send_sync(primary_proc, payload, state, 1);
}
/**
......@@ -903,7 +965,37 @@ enum pm_ret_status pm_clock_getstate(unsigned int clock_id,
enum pm_ret_status pm_clock_setdivider(unsigned int clock_id,
unsigned int divider)
{
return pm_api_clock_setdivider(clock_id, divider);
enum pm_ret_status status;
enum pm_node_id nid;
enum pm_clock_div_id div_id;
uint32_t payload[PAYLOAD_ARG_CNT];
const uint32_t div0 = 0xFFFF0000;
const uint32_t div1 = 0x0000FFFF;
uint32_t val;
/* Get PLL node ID using PLL clock ID */
status = pm_clock_get_pll_node_id(clock_id, &nid);
if (status == PM_RET_SUCCESS)
return pm_pll_set_parameter(nid, PM_PLL_PARAM_FBDIV, divider);
/* Check if clock ID is a valid on-chip clock */
status = pm_clock_id_is_valid(clock_id);
if (status != PM_RET_SUCCESS)
return status;
if (div0 == (divider & div0)) {
div_id = PM_CLOCK_DIV0_ID;
val = divider & ~div0;
} else if (div1 == (divider & div1)) {
div_id = PM_CLOCK_DIV1_ID;
val = (divider & ~div1) >> 16;
} else {
return PM_RET_ERROR_ARGS;
}
/* Send request to the PMU */
PM_PACK_PAYLOAD4(payload, PM_CLOCK_SETDIVIDER, clock_id, div_id, val);
return pm_ipi_send_sync(primary_proc, payload, NULL, 0);
}
/**
......@@ -919,7 +1011,42 @@ enum pm_ret_status pm_clock_setdivider(unsigned int clock_id,
enum pm_ret_status pm_clock_getdivider(unsigned int clock_id,
unsigned int *divider)
{
return pm_api_clock_getdivider(clock_id, divider);
enum pm_ret_status status;
enum pm_node_id nid;
uint32_t payload[PAYLOAD_ARG_CNT];
uint32_t val;
/* Get PLL node ID using PLL clock ID */
status = pm_clock_get_pll_node_id(clock_id, &nid);
if (status == PM_RET_SUCCESS)
return pm_pll_get_parameter(nid, PM_PLL_PARAM_FBDIV, divider);
/* Check if clock ID is a valid on-chip clock */
status = pm_clock_id_is_valid(clock_id);
if (status != PM_RET_SUCCESS)
return status;
if (pm_clock_has_div(clock_id, PM_CLOCK_DIV0_ID)) {
/* Send request to the PMU to get div0 */
PM_PACK_PAYLOAD3(payload, PM_CLOCK_GETDIVIDER, clock_id,
PM_CLOCK_DIV0_ID);
status = pm_ipi_send_sync(primary_proc, payload, &val, 1);
if (status != PM_RET_SUCCESS)
return status;
*divider = val;
}
if (pm_clock_has_div(clock_id, PM_CLOCK_DIV1_ID)) {
/* Send request to the PMU to get div1 */
PM_PACK_PAYLOAD3(payload, PM_CLOCK_GETDIVIDER, clock_id,
PM_CLOCK_DIV1_ID);
status = pm_ipi_send_sync(primary_proc, payload, &val, 1);
if (status != PM_RET_SUCCESS)
return status;
*divider |= val << 16;
}
return status;
}
/**
......@@ -934,7 +1061,7 @@ enum pm_ret_status pm_clock_getdivider(unsigned int clock_id,
enum pm_ret_status pm_clock_setrate(unsigned int clock_id,
uint64_t rate)
{
return pm_api_clock_setrate(clock_id, rate);
return PM_RET_ERROR_NOTSUPPORTED;
}
/**
......@@ -950,28 +1077,44 @@ enum pm_ret_status pm_clock_setrate(unsigned int clock_id,
enum pm_ret_status pm_clock_getrate(unsigned int clock_id,
uint64_t *rate)
{
return pm_api_clock_getrate(clock_id, rate);
return PM_RET_ERROR_NOTSUPPORTED;
}
/**
* pm_clock_setparent - Set the clock parent for given id
* @clock_id: Id of the clock
* @parent_id: parent id
* @parent_index: Index of the parent clock into clock's parents array
*
* This function is used by master to set parent for any clock.
*
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_clock_setparent(unsigned int clock_id,
unsigned int parent_id)
unsigned int parent_index)
{
return pm_api_clock_setparent(clock_id, parent_id);
struct pm_pll *pll;
uint32_t payload[PAYLOAD_ARG_CNT];
enum pm_ret_status status;
/* First try to handle it as a PLL */
pll = pm_clock_get_pll_by_related_clk(clock_id);
if (pll)
return pm_clock_pll_set_parent(pll, clock_id, parent_index);
/* Check if clock ID is a valid on-chip clock */
status = pm_clock_id_is_valid(clock_id);
if (status != PM_RET_SUCCESS)
return status;
/* Send request to the PMU */
PM_PACK_PAYLOAD3(payload, PM_CLOCK_SETPARENT, clock_id, parent_index);
return pm_ipi_send_sync(primary_proc, payload, NULL, 0);
}
/**
* pm_clock_getparent - Get the clock parent for given id
* @clock_id: Id of the clock
* @parent_id: parent id
* @parent_index: parent index
*
* This function is used by master to get parent index
* for any clock.
......@@ -979,9 +1122,25 @@ enum pm_ret_status pm_clock_setparent(unsigned int clock_id,
* Return: Returns status, either success or error+reason.
*/
enum pm_ret_status pm_clock_getparent(unsigned int clock_id,
unsigned int *parent_id)
unsigned int *parent_index)
{
return pm_api_clock_getparent(clock_id, parent_id);
struct pm_pll *pll;
uint32_t payload[PAYLOAD_ARG_CNT];
enum pm_ret_status status;
/* First try to handle it as a PLL */
pll = pm_clock_get_pll_by_related_clk(clock_id);
if (pll)
return pm_clock_pll_get_parent(pll, clock_id, parent_index);
/* Check if clock ID is a valid on-chip clock */
status = pm_clock_id_is_valid(clock_id);
if (status != PM_RET_SUCCESS)
return status;
/* Send request to the PMU */
PM_PACK_PAYLOAD2(payload, PM_CLOCK_GETPARENT, clock_id);
return pm_ipi_send_sync(primary_proc, payload, parent_index, 1);
}
/**
......@@ -1238,3 +1397,113 @@ enum pm_ret_status pm_fpga_read(uint32_t reg_numframes,
address_high, readback_type);
return pm_ipi_send_sync(primary_proc, payload, value, 1);
}
/*
* pm_pll_set_parameter() - Set the PLL parameter value
* @nid Node id of the target PLL
* @param_id ID of the PLL parameter
* @value Parameter value to be set
*
* Setting the parameter will have physical effect once the PLL mode is set to
* integer or fractional.
*
* @return Error if an argument is not valid or status as returned by the
* PM controller (PMU)
*/
enum pm_ret_status pm_pll_set_parameter(enum pm_node_id nid,
enum pm_pll_param param_id,
unsigned int value)
{
uint32_t payload[PAYLOAD_ARG_CNT];
/* Check if given node ID is a PLL node */
if (nid < NODE_APLL || nid > NODE_IOPLL)
return PM_RET_ERROR_ARGS;
/* Check if parameter ID is valid and return an error if it's not */
if (param_id >= PM_PLL_PARAM_MAX)
return PM_RET_ERROR_ARGS;
/* Send request to the PMU */
PM_PACK_PAYLOAD4(payload, PM_PLL_SET_PARAMETER, nid, param_id, value);
return pm_ipi_send_sync(primary_proc, payload, NULL, 0);
}
/**
* pm_pll_get_parameter() - Get the PLL parameter value
* @nid Node id of the target PLL
* @param_id ID of the PLL parameter
* @value Location to store the parameter value
*
* @return Error if an argument is not valid or status as returned by the
* PM controller (PMU)
*/
enum pm_ret_status pm_pll_get_parameter(enum pm_node_id nid,
enum pm_pll_param param_id,
unsigned int *value)
{
uint32_t payload[PAYLOAD_ARG_CNT];
/* Check if given node ID is a PLL node */
if (nid < NODE_APLL || nid > NODE_IOPLL)
return PM_RET_ERROR_ARGS;
/* Check if parameter ID is valid and return an error if it's not */
if (param_id >= PM_PLL_PARAM_MAX)
return PM_RET_ERROR_ARGS;
/* Send request to the PMU */
PM_PACK_PAYLOAD3(payload, PM_PLL_GET_PARAMETER, nid, param_id);
return pm_ipi_send_sync(primary_proc, payload, value, 1);
}
/**
* pm_pll_set_mode() - Set the PLL mode
* @nid Node id of the target PLL
* @mode PLL mode to be set
*
* If reset mode is set the PM controller will first bypass the PLL and then
* assert the reset. If integer or fractional mode is set the PM controller will
* ensure that the complete PLL programming sequence is satisfied. After this
* function returns success the PLL is locked and its bypass is deasserted.
*
* @return Error if an argument is not valid or status as returned by the
* PM controller (PMU)
*/
enum pm_ret_status pm_pll_set_mode(enum pm_node_id nid, enum pm_pll_mode mode)
{
uint32_t payload[PAYLOAD_ARG_CNT];
/* Check if given node ID is a PLL node */
if (nid < NODE_APLL || nid > NODE_IOPLL)
return PM_RET_ERROR_ARGS;
/* Check if PLL mode is valid */
if (mode >= PM_PLL_MODE_MAX)
return PM_RET_ERROR_ARGS;
/* Send request to the PMU */
PM_PACK_PAYLOAD3(payload, PM_PLL_SET_MODE, nid, mode);
return pm_ipi_send_sync(primary_proc, payload, NULL, 0);
}
/**
* pm_pll_get_mode() - Get the PLL mode
* @nid Node id of the target PLL
* @mode Location to store the mode of the PLL
*
* @return Error if an argument is not valid or status as returned by the
* PM controller (PMU)
*/
enum pm_ret_status pm_pll_get_mode(enum pm_node_id nid, enum pm_pll_mode *mode)
{
uint32_t payload[PAYLOAD_ARG_CNT];
/* Check if given node ID is a PLL node */
if (nid < NODE_APLL || nid > NODE_IOPLL)
return PM_RET_ERROR_ARGS;
/* Send request to the PMU */
PM_PACK_PAYLOAD2(payload, PM_PLL_GET_MODE, nid);
return pm_ipi_send_sync(primary_proc, payload, mode, 1);
}
......@@ -177,4 +177,15 @@ enum pm_ret_status pm_aes_engine(uint32_t address_high,
uint32_t address_low,
uint32_t *value);
enum pm_ret_status pm_pll_set_parameter(enum pm_node_id nid,
enum pm_pll_param param_id,
unsigned int value);
enum pm_ret_status pm_pll_get_parameter(enum pm_node_id nid,
enum pm_pll_param param_id,
unsigned int *value);
enum pm_ret_status pm_pll_set_mode(enum pm_node_id nid, enum pm_pll_mode mode);
enum pm_ret_status pm_pll_get_mode(enum pm_node_id nid, enum pm_pll_mode *mode);
#endif /* PM_API_SYS_H */
......@@ -92,6 +92,11 @@ enum pm_api_id {
/* FPGA PL Readback */
PM_FPGA_READ,
PM_SECURE_AES,
/* PLL control API functions */
PM_PLL_SET_PARAMETER,
PM_PLL_GET_PARAMETER,
PM_PLL_SET_MODE,
PM_PLL_GET_MODE,
PM_API_MAX
};
......@@ -265,4 +270,51 @@ enum pm_shutdown_subtype {
PMF_SHUTDOWN_SUBTYPE_SYSTEM,
};
/**
* @PM_PLL_PARAM_DIV2: Enable for divide by 2 function inside the PLL
* @PM_PLL_PARAM_FBDIV: Feedback divisor integer portion for the PLL
* @PM_PLL_PARAM_DATA: Feedback divisor fractional portion for the PLL
* @PM_PLL_PARAM_PRE_SRC: Clock source for PLL input
* @PM_PLL_PARAM_POST_SRC: Clock source for PLL Bypass mode
* @PM_PLL_PARAM_LOCK_DLY: Lock circuit config settings for lock windowsize
* @PM_PLL_PARAM_LOCK_CNT: Lock circuit counter setting
* @PM_PLL_PARAM_LFHF: PLL loop filter high frequency capacitor control
* @PM_PLL_PARAM_CP: PLL charge pump control
* @PM_PLL_PARAM_RES: PLL loop filter resistor control
*/
enum pm_pll_param {
PM_PLL_PARAM_DIV2,
PM_PLL_PARAM_FBDIV,
PM_PLL_PARAM_DATA,
PM_PLL_PARAM_PRE_SRC,
PM_PLL_PARAM_POST_SRC,
PM_PLL_PARAM_LOCK_DLY,
PM_PLL_PARAM_LOCK_CNT,
PM_PLL_PARAM_LFHF,
PM_PLL_PARAM_CP,
PM_PLL_PARAM_RES,
PM_PLL_PARAM_MAX,
};
/**
* @PM_PLL_MODE_RESET: PLL is in reset (not locked)
* @PM_PLL_MODE_INTEGER: PLL is locked in integer mode
* @PM_PLL_MODE_FRACTIONAL: PLL is locked in fractional mode
*/
enum pm_pll_mode {
PM_PLL_MODE_RESET,
PM_PLL_MODE_INTEGER,
PM_PLL_MODE_FRACTIONAL,
PM_PLL_MODE_MAX,
};
/**
* @PM_CLOCK_DIV0_ID: Clock divider 0
* @PM_CLOCK_DIV1_ID: Clock divider 1
*/
enum pm_clock_div_id {
PM_CLOCK_DIV0_ID,
PM_CLOCK_DIV1_ID,
};
#endif /* PM_DEFS_H */
......@@ -565,6 +565,30 @@ uint64_t pm_smc_handler(uint32_t smc_fid, uint64_t x1, uint64_t x2, uint64_t x3,
SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32);
}
case PM_PLL_SET_PARAMETER:
ret = pm_pll_set_parameter(pm_arg[0], pm_arg[1], pm_arg[2]);
SMC_RET1(handle, (uint64_t)ret);
case PM_PLL_GET_PARAMETER:
{
uint32_t value;
ret = pm_pll_get_parameter(pm_arg[0], pm_arg[1], &value);
SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value << 32));
}
case PM_PLL_SET_MODE:
ret = pm_pll_set_mode(pm_arg[0], pm_arg[1]);
SMC_RET1(handle, (uint64_t)ret);
case PM_PLL_GET_MODE:
{
uint32_t mode;
ret = pm_pll_get_mode(pm_arg[0], &mode);
SMC_RET1(handle, (uint64_t)ret | ((uint64_t)mode << 32));
}
default:
WARN("Unimplemented PM Service Call: 0x%x\n", smc_fid);
SMC_RET1(handle, SMC_UNK);
......
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