src/soc/qualcomm/common/clock.c - coreboot - Gitiles

 /* SPDX-License-Identifier: GPL-2.0-only */

 #include <assert.h>
 #include <commonlib/helpers.h>
 #include <delay.h>
 #include <device/mmio.h>
 #include <soc/clock.h>
 #include <timer.h>
 #include <types.h>

 /* Clock Branch Operations */
 static bool clock_is_off(u32 *cbcr_addr)
 {
 	return (read32(cbcr_addr) & CLK_CTL_OFF_BMSK);
 }

 enum cb_err clock_enable_vote(void *cbcr_addr, void *vote_addr,
 				uint32_t vote_bit)
 {
 	int count = 100;

 	setbits32(vote_addr, BIT(vote_bit));

 	/* Ensure clock is enabled */
 	while (count-- > 0) {
 		if (!clock_is_off(cbcr_addr))
 			return CB_SUCCESS;
 		udelay(1);
 	}
 	printk(BIOS_ERR, "Failed to enable clock, register val: 0x%x\n",
 			read32(cbcr_addr));
 	return CB_ERR;
 }

 enum cb_err clock_enable(void *cbcr_addr)
 {
 	int count = 100;

 	/* Set clock enable bit */
 	setbits32(cbcr_addr, BIT(CLK_CTL_EN_SHFT));

 	/* Ensure clock is enabled */
 	while (count-- > 0) {
 		if (!clock_is_off(cbcr_addr))
 			return CB_SUCCESS;
 		udelay(1);
 	}
 	printk(BIOS_ERR, "Failed to enable clock, register val: 0x%x\n",
 			read32(cbcr_addr));
 	return CB_ERR;
 }

 /* Clock Block Reset Operations */
 void clock_reset_bcr(void *bcr_addr, bool assert)
 {
 	if (assert)
 		setbits32(bcr_addr, BIT(CLK_CTL_BCR_BLK_SHFT));
 	else
 		clrbits32(bcr_addr, BIT(CLK_CTL_BCR_BLK_SHFT));
 }

 /* Clock GDSC Operations */
 enum cb_err enable_and_poll_gdsc_status(void *gdscr_addr)
 {
 	if (read32(gdscr_addr) & CLK_CTL_OFF_BMSK)
 		return CB_SUCCESS;

 	clrbits32(gdscr_addr, BIT(GDSC_ENABLE_BIT));

 	/* Ensure gdsc is enabled */
 	if (!wait_us(100, (read32(gdscr_addr) & CLK_CTL_OFF_BMSK)))
 		return CB_ERR;

 	return CB_SUCCESS;
 }

 /* Clock Root clock Generator with MND Operations */
 static void clock_configure_mnd(struct clock_rcg *clk, uint32_t m, uint32_t n,
 				uint32_t d_2)
 {
 	struct clock_rcg_mnd *mnd = (struct clock_rcg_mnd *)clk;

 	setbits32(&clk->rcg_cfg,
 			RCG_MODE_DUAL_EDGE << CLK_CTL_CFG_MODE_SHFT);

 	write32(&mnd->m, m & CLK_CTL_RCG_MND_BMSK);
 	write32(&mnd->n, ~(n-m) & CLK_CTL_RCG_MND_BMSK);
 	write32(&mnd->d_2, ~(d_2) & CLK_CTL_RCG_MND_BMSK);
 }

 /* Clock Root clock Generator Operations */
 enum cb_err clock_configure(struct clock_rcg *clk,
 			struct clock_freq_config *clk_cfg, uint32_t hz,
 			uint32_t num_perfs)
 {
 	uint32_t reg_val, idx;

 	for (idx = 0; idx < num_perfs; idx++)
 		if (hz <= clk_cfg[idx].hz)
 			break;

 	reg_val = (clk_cfg[idx].src << CLK_CTL_CFG_SRC_SEL_SHFT) |
 			(clk_cfg[idx].div << CLK_CTL_CFG_SRC_DIV_SHFT);

 	/* Set clock config */
 	write32(&clk->rcg_cfg, reg_val);

 	if (clk_cfg[idx].m != 0)
 		clock_configure_mnd(clk, clk_cfg[idx].m, clk_cfg[idx].n,
 				clk_cfg[idx].d_2);

 	/* Commit config to RCG */
 	setbits32(&clk->rcg_cmd, BIT(CLK_CTL_CMD_UPDATE_SHFT));

 	return CB_SUCCESS;
 }

 /* Clock Root clock Generator with DFS Operations */
 void clock_configure_dfsr_table(int qup, struct clock_freq_config *clk_cfg,
 		uint32_t num_perfs)
 {
 	struct qupv3_clock *qup_clk;
 	unsigned int idx, s = qup % QUP_WRAP1_S0;
 	uint32_t reg_val;

 	qup_clk = qup < QUP_WRAP1_S0 ?
 				&gcc->qup_wrap0_s[s] : &gcc->qup_wrap1_s[s];

 	clrsetbits32(&qup_clk->dfsr_clk.cmd_dfsr,
 			BIT(CLK_CTL_CMD_RCG_SW_CTL_SHFT),
 			BIT(CLK_CTL_CMD_DFSR_SHFT));

 	for (idx = 0; idx < num_perfs; idx++) {
 		reg_val = (clk_cfg[idx].src << CLK_CTL_CFG_SRC_SEL_SHFT) |
 			(clk_cfg[idx].div << CLK_CTL_CFG_SRC_DIV_SHFT);

 		write32(&qup_clk->dfsr_clk.perf_dfsr[idx], reg_val);

 		if (clk_cfg[idx].m == 0)
 			continue;

 		setbits32(&qup_clk->dfsr_clk.perf_dfsr[idx],
 				RCG_MODE_DUAL_EDGE << CLK_CTL_CFG_MODE_SHFT);

 		reg_val = clk_cfg[idx].m & CLK_CTL_RCG_MND_BMSK;
 		write32(&qup_clk->dfsr_clk.perf_m_dfsr[idx], reg_val);

 		reg_val = ~(clk_cfg[idx].n - clk_cfg[idx].m)
 				& CLK_CTL_RCG_MND_BMSK;
 		write32(&qup_clk->dfsr_clk.perf_n_dfsr[idx], reg_val);

 		reg_val = ~(clk_cfg[idx].d_2) & CLK_CTL_RCG_MND_BMSK;
 		write32(&qup_clk->dfsr_clk.perf_d_dfsr[idx], reg_val);
 	}
 }

 /* General Purpose PLL configuration and enable Operations */
 enum cb_err clock_configure_enable_gpll(struct alpha_pll_reg_val_config *cfg,
 					bool enable, int br_enable)
 {
 	if (cfg->l_val)
 		write32(cfg->reg_l, cfg->l_val);

 	if (cfg->cal_l_val)
 		write32(cfg->reg_cal_l, cfg->cal_l_val);

 	if (cfg->alpha_val)
 		write32(cfg->reg_alpha, cfg->alpha_val);

 	if (cfg->user_ctl_val)
 		write32(cfg->reg_user_ctl, cfg->user_ctl_val);

 	if (cfg->user_ctl_hi_val)
 		write32(cfg->reg_user_ctl_hi, cfg->user_ctl_hi_val);

 	if (cfg->user_ctl_hi1_val)
 		write32(cfg->reg_user_ctl_hi1, cfg->user_ctl_hi1_val);

 	if (cfg->config_ctl_val)
 		write32(cfg->reg_config_ctl, cfg->config_ctl_val);

 	if (cfg->config_ctl_hi_val)
 		write32(cfg->reg_config_ctl_hi, cfg->config_ctl_hi_val);

 	if (cfg->config_ctl_hi1_val)
 		write32(cfg->reg_config_ctl_hi1, cfg->config_ctl_hi1_val);

 	if (cfg->fsm_enable)
 		setbits32(cfg->reg_mode, BIT(PLL_FSM_EN_SHFT));

 	if (enable) {
 		setbits32(cfg->reg_opmode, BIT(PLL_STANDBY_MODE));

 		/*
 		* H/W requires a 1us delay between placing PLL in STANDBY and
 		* de-asserting the reset.
 		*/
 		udelay(1);
 		setbits32(cfg->reg_mode, BIT(PLL_RESET_N_SHFT));

 		/*
 		* H/W requires a 10us delay between de-asserting the reset and
 		* enabling the PLL branch bit.
 		*/
 		udelay(10);
 		setbits32(cfg->reg_apcs_pll_br_en, BIT(br_enable));

 		/* Wait for Lock Detection */
 		if (!wait_us(100, read32(cfg->reg_mode) & PLL_LOCK_DET_BMSK)) {
 			printk(BIOS_ERR, "PLL did not lock!\n");
 			return CB_ERR;
 		}
 	}

 	return CB_SUCCESS;
 }

 enum cb_err agera_pll_enable(struct alpha_pll_reg_val_config *cfg)
 {
 	setbits32(cfg->reg_mode, BIT(PLL_BYPASSNL_SHFT));

 	/*
 	* H/W requires a 5us delay between disabling the bypass and
 	* de-asserting the reset.
 	*/
 	udelay(5);
 	setbits32(cfg->reg_mode, BIT(PLL_RESET_SHFT));

 	if (!wait_us(100, read32(cfg->reg_mode) & PLL_LOCK_DET_BMSK)) {
 		printk(BIOS_ERR, "CPU PLL did not lock!\n");
 		return CB_ERR;
 	}

 	setbits32(cfg->reg_mode, BIT(PLL_OUTCTRL_SHFT));

 	return CB_SUCCESS;
 }

 enum cb_err zonda_pll_enable(struct alpha_pll_reg_val_config *cfg)
 {
 	setbits32(cfg->reg_mode, BIT(PLL_BYPASSNL_SHFT));

 	/*
 	* H/W requires a 1us delay between disabling the bypass and
 	* de-asserting the reset.
 	*/
 	udelay(1);
 	setbits32(cfg->reg_mode, BIT(PLL_RESET_SHFT));
 	setbits32(cfg->reg_opmode, PLL_RUN_MODE);

 	if (!wait_us(100, read32(cfg->reg_mode) & PLL_LOCK_DET_BMSK)) {
 		printk(BIOS_ERR, "CPU PLL did not lock!\n");
 		return CB_ERR;
 	}

 	setbits32(cfg->reg_user_ctl, PLL_USERCTL_BMSK);
 	setbits32(cfg->reg_mode, BIT(PLL_OUTCTRL_SHFT));

 	return CB_SUCCESS;
 }

 /* Bring subsystem out of RESET */
 void clock_reset_subsystem(u32 *misc, u32 shft)
 {
 	clrbits32(misc, BIT(shft));
 }
	/* SPDX-License-Identifier: GPL-2.0-only */

	#include <assert.h>
	#include <commonlib/helpers.h>
	#include <delay.h>
	#include <device/mmio.h>
	#include <soc/clock.h>
	#include <timer.h>
	#include <types.h>

	/* Clock Branch Operations */
	static bool clock_is_off(u32 *cbcr_addr)
	{
	return (read32(cbcr_addr) & CLK_CTL_OFF_BMSK);
	}

	enum cb_err clock_enable_vote(void cbcr_addr, void vote_addr,
	uint32_t vote_bit)
	{
	int count = 100;

	setbits32(vote_addr, BIT(vote_bit));

	/* Ensure clock is enabled */
	while (count-- > 0) {
	if (!clock_is_off(cbcr_addr))
	return CB_SUCCESS;
	udelay(1);
	}
	printk(BIOS_ERR, "Failed to enable clock, register val: 0x%x\n",
	read32(cbcr_addr));
	return CB_ERR;
	}

	enum cb_err clock_enable(void *cbcr_addr)
	{
	int count = 100;

	/* Set clock enable bit */
	setbits32(cbcr_addr, BIT(CLK_CTL_EN_SHFT));

	/* Ensure clock is enabled */
	while (count-- > 0) {
	if (!clock_is_off(cbcr_addr))
	return CB_SUCCESS;
	udelay(1);
	}
	printk(BIOS_ERR, "Failed to enable clock, register val: 0x%x\n",
	read32(cbcr_addr));
	return CB_ERR;
	}

	/* Clock Block Reset Operations */
	void clock_reset_bcr(void *bcr_addr, bool assert)
	{
	if (assert)
	setbits32(bcr_addr, BIT(CLK_CTL_BCR_BLK_SHFT));
	else
	clrbits32(bcr_addr, BIT(CLK_CTL_BCR_BLK_SHFT));
	}

	/* Clock GDSC Operations */
	enum cb_err enable_and_poll_gdsc_status(void *gdscr_addr)
	{
	if (read32(gdscr_addr) & CLK_CTL_OFF_BMSK)
	return CB_SUCCESS;

	clrbits32(gdscr_addr, BIT(GDSC_ENABLE_BIT));

	/* Ensure gdsc is enabled */
	if (!wait_us(100, (read32(gdscr_addr) & CLK_CTL_OFF_BMSK)))
	return CB_ERR;

	return CB_SUCCESS;
	}

	/* Clock Root clock Generator with MND Operations */
	static void clock_configure_mnd(struct clock_rcg *clk, uint32_t m, uint32_t n,
	uint32_t d_2)
	{
	struct clock_rcg_mnd mnd = (struct clock_rcg_mnd )clk;

	setbits32(&clk->rcg_cfg,
	RCG_MODE_DUAL_EDGE << CLK_CTL_CFG_MODE_SHFT);

	write32(&mnd->m, m & CLK_CTL_RCG_MND_BMSK);
	write32(&mnd->n, ~(n-m) & CLK_CTL_RCG_MND_BMSK);
	write32(&mnd->d_2, ~(d_2) & CLK_CTL_RCG_MND_BMSK);
	}

	/* Clock Root clock Generator Operations */
	enum cb_err clock_configure(struct clock_rcg *clk,
	struct clock_freq_config *clk_cfg, uint32_t hz,
	uint32_t num_perfs)
	{
	uint32_t reg_val, idx;

	for (idx = 0; idx < num_perfs; idx++)
	if (hz <= clk_cfg[idx].hz)
	break;

	reg_val = (clk_cfg[idx].src << CLK_CTL_CFG_SRC_SEL_SHFT) \|
	(clk_cfg[idx].div << CLK_CTL_CFG_SRC_DIV_SHFT);

	/* Set clock config */
	write32(&clk->rcg_cfg, reg_val);

	if (clk_cfg[idx].m != 0)
	clock_configure_mnd(clk, clk_cfg[idx].m, clk_cfg[idx].n,
	clk_cfg[idx].d_2);

	/* Commit config to RCG */
	setbits32(&clk->rcg_cmd, BIT(CLK_CTL_CMD_UPDATE_SHFT));

	return CB_SUCCESS;
	}

	/* Clock Root clock Generator with DFS Operations */
	void clock_configure_dfsr_table(int qup, struct clock_freq_config *clk_cfg,
	uint32_t num_perfs)
	{
	struct qupv3_clock *qup_clk;
	unsigned int idx, s = qup % QUP_WRAP1_S0;
	uint32_t reg_val;

	qup_clk = qup < QUP_WRAP1_S0 ?
	&gcc->qup_wrap0_s[s] : &gcc->qup_wrap1_s[s];

	clrsetbits32(&qup_clk->dfsr_clk.cmd_dfsr,
	BIT(CLK_CTL_CMD_RCG_SW_CTL_SHFT),
	BIT(CLK_CTL_CMD_DFSR_SHFT));

	for (idx = 0; idx < num_perfs; idx++) {
	reg_val = (clk_cfg[idx].src << CLK_CTL_CFG_SRC_SEL_SHFT) \|
	(clk_cfg[idx].div << CLK_CTL_CFG_SRC_DIV_SHFT);

	write32(&qup_clk->dfsr_clk.perf_dfsr[idx], reg_val);

	if (clk_cfg[idx].m == 0)
	continue;

	setbits32(&qup_clk->dfsr_clk.perf_dfsr[idx],
	RCG_MODE_DUAL_EDGE << CLK_CTL_CFG_MODE_SHFT);

	reg_val = clk_cfg[idx].m & CLK_CTL_RCG_MND_BMSK;
	write32(&qup_clk->dfsr_clk.perf_m_dfsr[idx], reg_val);

	reg_val = ~(clk_cfg[idx].n - clk_cfg[idx].m)
	& CLK_CTL_RCG_MND_BMSK;
	write32(&qup_clk->dfsr_clk.perf_n_dfsr[idx], reg_val);

	reg_val = ~(clk_cfg[idx].d_2) & CLK_CTL_RCG_MND_BMSK;
	write32(&qup_clk->dfsr_clk.perf_d_dfsr[idx], reg_val);
	}
	}

	/* General Purpose PLL configuration and enable Operations */
	enum cb_err clock_configure_enable_gpll(struct alpha_pll_reg_val_config *cfg,
	bool enable, int br_enable)
	{
	if (cfg->l_val)
	write32(cfg->reg_l, cfg->l_val);

	if (cfg->cal_l_val)
	write32(cfg->reg_cal_l, cfg->cal_l_val);

	if (cfg->alpha_val)
	write32(cfg->reg_alpha, cfg->alpha_val);

	if (cfg->user_ctl_val)
	write32(cfg->reg_user_ctl, cfg->user_ctl_val);

	if (cfg->user_ctl_hi_val)
	write32(cfg->reg_user_ctl_hi, cfg->user_ctl_hi_val);

	if (cfg->user_ctl_hi1_val)
	write32(cfg->reg_user_ctl_hi1, cfg->user_ctl_hi1_val);

	if (cfg->config_ctl_val)
	write32(cfg->reg_config_ctl, cfg->config_ctl_val);

	if (cfg->config_ctl_hi_val)
	write32(cfg->reg_config_ctl_hi, cfg->config_ctl_hi_val);

	if (cfg->config_ctl_hi1_val)
	write32(cfg->reg_config_ctl_hi1, cfg->config_ctl_hi1_val);

	if (cfg->fsm_enable)
	setbits32(cfg->reg_mode, BIT(PLL_FSM_EN_SHFT));

	if (enable) {
	setbits32(cfg->reg_opmode, BIT(PLL_STANDBY_MODE));

	/*
	* H/W requires a 1us delay between placing PLL in STANDBY and
	* de-asserting the reset.
	*/
	udelay(1);
	setbits32(cfg->reg_mode, BIT(PLL_RESET_N_SHFT));

	/*
	* H/W requires a 10us delay between de-asserting the reset and
	* enabling the PLL branch bit.
	*/
	udelay(10);
	setbits32(cfg->reg_apcs_pll_br_en, BIT(br_enable));

	/* Wait for Lock Detection */
	if (!wait_us(100, read32(cfg->reg_mode) & PLL_LOCK_DET_BMSK)) {
	printk(BIOS_ERR, "PLL did not lock!\n");
	return CB_ERR;
	}
	}

	return CB_SUCCESS;
	}

	enum cb_err agera_pll_enable(struct alpha_pll_reg_val_config *cfg)
	{
	setbits32(cfg->reg_mode, BIT(PLL_BYPASSNL_SHFT));

	/*
	* H/W requires a 5us delay between disabling the bypass and
	* de-asserting the reset.
	*/
	udelay(5);
	setbits32(cfg->reg_mode, BIT(PLL_RESET_SHFT));

	if (!wait_us(100, read32(cfg->reg_mode) & PLL_LOCK_DET_BMSK)) {
	printk(BIOS_ERR, "CPU PLL did not lock!\n");
	return CB_ERR;
	}

	setbits32(cfg->reg_mode, BIT(PLL_OUTCTRL_SHFT));

	return CB_SUCCESS;
	}

	enum cb_err zonda_pll_enable(struct alpha_pll_reg_val_config *cfg)
	{
	setbits32(cfg->reg_mode, BIT(PLL_BYPASSNL_SHFT));

	/*
	* H/W requires a 1us delay between disabling the bypass and
	* de-asserting the reset.
	*/
	udelay(1);
	setbits32(cfg->reg_mode, BIT(PLL_RESET_SHFT));
	setbits32(cfg->reg_opmode, PLL_RUN_MODE);

	if (!wait_us(100, read32(cfg->reg_mode) & PLL_LOCK_DET_BMSK)) {
	printk(BIOS_ERR, "CPU PLL did not lock!\n");
	return CB_ERR;
	}

	setbits32(cfg->reg_user_ctl, PLL_USERCTL_BMSK);
	setbits32(cfg->reg_mode, BIT(PLL_OUTCTRL_SHFT));

	return CB_SUCCESS;
	}

	/* Bring subsystem out of RESET */
	void clock_reset_subsystem(u32 *misc, u32 shft)
	{
	clrbits32(misc, BIT(shft));
	}