src/soc/nvidia/tegra124/clock.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*
  * Copyright (c) 2013, NVIDIA CORPORATION.  All rights reserved.
  * Copyright 2014 Google Inc.
  *
  * This program is free software; you can redistribute it and/or modify it
  * under the terms and conditions of the GNU General Public License,
  * version 2, as published by the Free Software Foundation.
  *
  * This program is distributed in the hope it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
  * more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program.  If not, see <http://www.gnu.org/licenses/>.
  */
 #include <console/console.h>
 #include <delay.h>
 #include <arch/io.h>
 #include <soc/addressmap.h>
 #include <soc/clock.h>
 #include <stdlib.h>
 #include <arch/clock.h>
 #include "clk_rst.h"
 #include "flow.h"
 #include "maincpu.h"
 #include "pmc.h"
 #include "sysctr.h"

 static struct clk_rst_ctlr *clk_rst = (void *)TEGRA_CLK_RST_BASE;
 static struct flow_ctlr *flow = (void *)TEGRA_FLOW_BASE;
 static struct tegra_pmc_regs *pmc = (void *)TEGRA_PMC_BASE;
 static struct sysctr_regs *sysctr = (void *)TEGRA_SYSCTR0_BASE;

 struct pll_dividers {
 	u32	n : 10;
 	u32	m : 8;
 	u32	p : 4;
 	u32	cpcon : 4;
 	u32	lfcon : 4;
 	u32	: 2;
 };

 /* Some PLLs have more restrictive divider bit lengths or are missing some
  * fields. Make sure to use the right struct in the osc_table definition to get
  * compile-time checking, but keep the bits aligned with struct pll_dividers so
  * they can be used interchangeably at run time. Add new formats as required. */
 struct pllcx_dividers {
 	u32	n : 8;
 	u32	: 2;
 	u32	m : 8;
 	u32	p : 4;
 	u32	: 10;
 };
 struct pllpad_dividers {
 	u32	n : 10;
 	u32	m : 5;
 	u32	: 3;
 	u32	p : 3;
 	u32	: 1;
 	u32	cpcon : 4;
 	u32	: 6;
 };
 struct pllu_dividers {
 	u32	n : 10;
 	u32	m : 5;
 	u32	: 3;
 	u32	p : 1;
 	u32	: 3;
 	u32	cpcon : 4;
 	u32	lfcon : 4;
 	u32	: 2;
 };

 union __attribute__((transparent_union)) pll_fields {
 	u32 raw;
 	struct pll_dividers div;
 	struct pllcx_dividers cx;
 	struct pllpad_dividers pad;
 	struct pllu_dividers u;
 };

 /* This table defines the frequency dividers for every PLL to turn the external
  * OSC clock into the frequencies defined by TEGRA_PLL*_KHZ in soc/clock.h.
  * All PLLs have three dividers (n, m and p), with the governing formula for
  * the output frequency being CF = (IN / m), VCO = CF * n and OUT = VCO / (2^p).
  * All divisor configurations must meet the PLL's constraints for VCO and CF:
  * PLLX:  12 MHz < CF < 50 MHz, 700 MHz < VCO < 3000 MHz
  * PLLC:  12 MHz < CF < 50 MHz, 600 MHz < VCO < 1400 MHz
  * PLLM:  12 MHz < CF < 50 MHz, 400 MHz < VCO < 1066 MHz
  * PLLP:   1 MHz < CF <  6 MHz, 200 MHz < VCO <  700 MHz
  * PLLD:   1 MHz < CF <  6 MHz, 500 MHz < VCO < 1000 MHz
  * PLLU:   1 MHz < CF <  6 MHz, 480 MHz < VCO <  960 MHz
  * PLLDP: 12 MHz < CF < 38 MHz, 600 MHz < VCO < 1200 MHz
  * (values taken from Linux' drivers/clk/tegra/clk-tegra124.c). */
 struct {
 	int khz;
 	struct pllcx_dividers	pllx;	/* target:  CONFIG_PLLX_KHZ */
 	struct pllcx_dividers	pllc;	/* target:  600 MHz */
 	/* PLLM is set up dynamically by clock_sdram(). */
 	/* PLLP is hardwired to 408 MHz in HW (unless we set BASE_OVRD). */
 	struct pllu_dividers	pllu;	/* target;  960 MHz */
 	struct pllcx_dividers	plldp;	/* target;  270 MHz */
 	/* PLLDP treats p differently (OUT = VCO / (p + 1) for p < 6). */
 } static const osc_table[16] = {
 	[OSC_FREQ_12]{
 		.khz = 12000,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 12000, .m =  1, .p = 0},
 		.pllc = {.n =  50, .m =  1, .p = 0},
 		.pllu = {.n = 960, .m = 12, .p = 0, .cpcon = 12, .lfcon = 2},
 		.plldp = {.n = 90, .m =  1, .p = 3},
 	},
 	[OSC_FREQ_13]{
 		.khz = 13000,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 13000, .m =  1, .p = 0},
 		.pllc = {.n =  46, .m =  1, .p = 0},		 /* 598.0 MHz */
 		.pllu = {.n = 960, .m = 13, .p = 0, .cpcon = 12, .lfcon = 2},
 		.plldp = {.n = 83, .m =  1, .p = 3},		 /* 269.8 MHz */
 	},
 	[OSC_FREQ_16P8]{
 		.khz = 16800,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 16800, .m =  1, .p = 0},
 		.pllc = {.n =  71, .m =  1, .p = 1},		 /* 596.4 MHz */
 		.pllu = {.n = 400, .m =  7, .p = 0, .cpcon = 5, .lfcon = 2},
 		.plldp = {.n = 64, .m =  1, .p = 3},		 /* 268.8 MHz */
 	},
 	[OSC_FREQ_19P2]{
 		.khz = 19200,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 19200, .m =  1, .p = 0},
 		.pllc = {.n =  62, .m =  1, .p = 1},		 /* 595.2 MHz */
 		.pllu = {.n = 200, .m =  4, .p = 0, .cpcon = 3, .lfcon = 2},
 		.plldp = {.n = 56, .m =  1, .p = 3},		 /* 268.8 MHz */
 	},
 	[OSC_FREQ_26]{
 		.khz = 26000,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 26000, .m =  1, .p = 0},
 		.pllc = {.n =  23, .m =  1, .p = 0},		 /* 598.0 MHz */
 		.pllu = {.n = 960, .m = 26, .p = 0, .cpcon = 12, .lfcon = 2},
 		.plldp = {.n = 83, .m =  2, .p = 3},		 /* 269.8 MHz */
 	},
 	/* These oscillators get predivided as PLL inputs... n/m/p divisors for
 	 * 38.4 should always match 19.2, and 48 should always match 12. */
 	[OSC_FREQ_38P4]{
 		.khz = 38400,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 19200, .m =  1, .p = 0},
 		.pllc = {.n =  62, .m =  1, .p = 1},		 /* 595.2 MHz */
 		.pllu = {.n = 200, .m =  4, .p = 0, .cpcon = 3, .lfcon = 2},
 		.plldp = {.n = 56, .m =  1, .p = 3},		 /* 268.8 MHz */
 	},
 	[OSC_FREQ_48]{
 		.khz = 48000,
 		.pllx = {.n = TEGRA_PLLX_KHZ / 12000, .m =  1, .p = 0},
 		.pllc = {.n =  50, .m =  1, .p = 0},
 		.pllu = {.n = 960, .m = 12, .p = 0, .cpcon = 12, .lfcon = 2},
 		.plldp = {.n = 90, .m =  1, .p = 3},
 	},
 };

 /* Get the oscillator frequency, from the corresponding hardware
  * configuration field. This is actually a per-soc thing. Avoid the
  * temptation to make it common.
  */
 static u32 clock_get_osc_bits(void)
 {
 	return (readl(&clk_rst->osc_ctrl) & OSC_FREQ_MASK) >> OSC_FREQ_SHIFT;
 }

 int clock_get_osc_khz(void)
 {
 	return osc_table[clock_get_osc_bits()].khz;
 }

 int clock_get_pll_input_khz(void)
 {
 	u32 osc_ctrl = readl(&clk_rst->osc_ctrl);
 	u32 osc_bits = (osc_ctrl & OSC_FREQ_MASK) >> OSC_FREQ_SHIFT;
 	u32 pll_ref_div = (osc_ctrl & OSC_PREDIV_MASK) >> OSC_PREDIV_SHIFT;
 	return osc_table[osc_bits].khz >> pll_ref_div;
 }

 void clock_init_arm_generic_timer(void)
 {
 	uint32_t freq = clock_get_osc_khz() * 1000;
 	// Set the cntfrq register.
 	set_cntfrq(freq);

 	// Record the system timer frequency.
 	write32(freq, &sysctr->cntfid0);
 	// Enable the system counter.
 	uint32_t cntcr = read32(&sysctr->cntcr);
 	cntcr |= SYSCTR_CNTCR_EN | SYSCTR_CNTCR_HDBG;
 	write32(cntcr, &sysctr->cntcr);
 }

 #define SOR0_CLK_SEL0			(1 << 14)
 #define SOR0_CLK_SEL1			(1 << 15)

 void sor_clock_stop(void)
 {
 	/* The Serial Output Resource clock has to be off
 	 * before we start the plldp. Learned the hard way.
 	 * FIXME: this has to be cleaned up a bit more.
 	 * Waiting on some new info from Nvidia.
 	 */
 	clrbits_le32(&clk_rst->clk_src_sor, SOR0_CLK_SEL0 | SOR0_CLK_SEL1);
 }

 void sor_clock_start(void)
 {
 	/* uses PLLP, has a non-standard bit layout. */
 	setbits_le32(&clk_rst->clk_src_sor, SOR0_CLK_SEL0);
 }

 static void init_pll(u32 *base, u32 *misc, const union pll_fields pll, u32 lock)
 {
 	u32 dividers =  pll.div.n << PLL_BASE_DIVN_SHIFT |
 			pll.div.m << PLL_BASE_DIVM_SHIFT |
 			pll.div.p << PLL_BASE_DIVP_SHIFT;
 	u32 misc_con = pll.div.cpcon << PLL_MISC_CPCON_SHIFT |
 		       pll.div.lfcon << PLL_MISC_LFCON_SHIFT;

 	/* Write dividers but BYPASS the PLL while we're messing with it. */
 	writel(dividers | PLL_BASE_BYPASS, base);
 	/*
 	 * Set Lock bit, CPCON and LFCON fields (default to 0 if it doesn't
 	 * exist for this PLL)
 	 */
 	writel(lock | misc_con, misc);

 	/* Enable PLL and take it back out of BYPASS */
 	writel(dividers | PLL_BASE_ENABLE, base);

 	/* Wait for lock ready */
 	while (!(readl(base) & PLL_BASE_LOCK));
 }

 static void init_utmip_pll(void)
 {
 	int khz = clock_get_pll_input_khz();

 	/* Shut off PLL crystal clock while we mess with it */
 	clrbits_le32(&clk_rst->utmip_pll_cfg2, 1 << 30); /* PHY_XTAL_CLKEN */
 	udelay(1);

 	write32(80 << 16 |			/* (rst) phy_divn */
 		1 << 8 |			/* (rst) phy_divm */
 		0, &clk_rst->utmip_pll_cfg0);	/* 960MHz * 1 / 80 == 12 MHz */

 	write32(div_round_up(khz, 8000) << 27 |	/* pllu_enbl_cnt / 8 (1us) */
 		0 << 16 |			/* PLLU pwrdn */
 		0 << 14 |			/* pll_enable pwrdn */
 		0 << 12 |			/* pll_active pwrdn */
 		div_round_up(khz, 102) << 0 |	/* phy_stbl_cnt / 256 (2.5ms) */
 		0, &clk_rst->utmip_pll_cfg1);

 	/* TODO: TRM can't decide if actv is 5us or 10us, keep an eye on it */
 	write32(0 << 24 |			/* SAMP_D/XDEV pwrdn */
 		div_round_up(khz, 3200) << 18 |	/* phy_actv_cnt / 16 (5us) */
 		div_round_up(khz, 256) << 6 |	/* pllu_stbl_cnt / 256 (1ms) */
 		0 << 4 |			/* SAMP_C/USB3 pwrdn */
 		0 << 2 |			/* SAMP_B/XHOST pwrdn */
 		0 << 0 |			/* SAMP_A/USBD pwrdn */
 		0, &clk_rst->utmip_pll_cfg2);

 	setbits_le32(&clk_rst->utmip_pll_cfg2, 1 << 30); /* PHY_XTAL_CLKEN */
 }

 /* Graphics just has to be different. There's a few more bits we
  * need to set in here, but it makes sense just to restrict all the
  * special bits to this one function.
  */
 static void graphics_pll(void)
 {
 	int osc = clock_get_osc_bits();
 	u32 *cfg = &clk_rst->plldp_ss_cfg;
 	/* the vendor code sets the dither bit (28)
 	 * an undocumented bit (24)
 	 * and clamp while we mess with it (22)
 	 * Dither is pretty important to display port
 	 * so we really do need to handle these bits.
 	 * I'm not willing to not clamp it, even if
 	 * it might "mostly work" with it not set,
 	 * I don't want to find out in a few months
 	 * that it is needed.
 	 */
 	u32 scfg = (1<<28) | (1<<24) | (1<<22);
 	writel(scfg, cfg);
 	init_pll(&clk_rst->plldp_base, &clk_rst->plldp_misc,
 		osc_table[osc].plldp, PLLDPD2_MISC_LOCK_ENABLE);
 	/* leave dither and undoc bits set, release clamp */
 	scfg = (1<<28) | (1<<24);
 	writel(scfg, cfg);

 	/* disp1 will be set when panel information (pixel clock) is
 	 * retrieved (clock_display).
 	 */
 }

 /*
  * Init PLLD clock source.
  *
  * @frequency: the requested plld frequency
  *
  * Return the plld frequency if success, otherwise return 0.
  */
 u32
 clock_display(u32 frequency)
 {
 	/**
 	 * plld (fo) = vco >> p, where 500MHz < vco < 1000MHz
 	 *           = (cf * n) >> p, where 1MHz < cf < 6MHz
 	 *           = ((ref / m) * n) >> p
 	 *
 	 * Iterate the possible values of p (3 bits, 2^7) to find out a minimum
 	 * safe vco, then find best (m, n). since m has only 5 bits, we can
 	 * iterate all possible values.  Note Tegra 124 supports 11 bits for n,
 	 * but our pll_fields has only 10 bits for n.
 	 *
 	 * Note values undershoot or overshoot target output frequency may not
 	 * work if the values are not in "safe" range by panel specification.
 	 */
 	struct pllpad_dividers plld = { 0 };
 	u32 ref = clock_get_pll_input_khz() * 1000, m, n, p = 0;
 	u32 cf, vco, rounded_rate = frequency;
 	u32 diff, best_diff;
 	const u32 max_m = 1 << 5, max_n = 1 << 10, max_p = 1 << 3,
 		  mhz = 1000 * 1000, min_vco = 500 * mhz, max_vco = 1000 * mhz,
 		  min_cf = 1 * mhz, max_cf = 6 * mhz;

 	for (vco = frequency; vco < min_vco && p < max_p; p++)
 		vco <<= 1;

 	if (vco < min_vco || vco > max_vco) {
 		printk(BIOS_ERR, "%s: Cannot find out a supported VCO"
 			" for Frequency (%u).\n", __func__, frequency);
 		return 0;
 	}

 	plld.p = p;
 	best_diff = vco;

 	for (m = 1; m < max_m && best_diff; m++) {
 		cf = ref / m;
 		if (cf < min_cf)
 			break;
 		if (cf > max_cf)
 			continue;

 		n = vco / cf;
 		if (n >= max_n)
 			continue;

 		diff = vco - n * cf;
 		if (n + 1 < max_n && diff > cf / 2) {
 			n++;
 			diff = cf - diff;
 		}

 		if (diff >= best_diff)
 			continue;

 		best_diff = diff;
 		plld.m = m;
 		plld.n = n;
 	}

 	if (plld.n < 50)
 		plld.cpcon = 2;
 	else if (plld.n < 300)
 		plld.cpcon = 3;
 	else if (plld.n < 600)
 		plld.cpcon = 8;
 	else
 		plld.cpcon = 12;

 	if (best_diff) {
 		printk(BIOS_WARNING, "%s: Failed to match output frequency %u, "
 		       "best difference is %u.\n", __func__, frequency,
 		       best_diff);
 		rounded_rate = (ref / plld.m * plld.n) >> plld.p;
 	}

 	printk(BIOS_DEBUG, "%s: PLLD=%u ref=%u, m/n/p/cpcon=%u/%u/%u/%u\n",
 	       __func__, rounded_rate, ref, plld.m, plld.n, plld.p, plld.cpcon);

 	init_pll(&clk_rst->plld_base, &clk_rst->plld_misc, plld,
 		 (PLLUD_MISC_LOCK_ENABLE | PLLD_MISC_CLK_ENABLE));

 	return rounded_rate;
 }

 /* Initialize the UART and put it on CLK_M so we can use it during clock_init().
  * Will later move it to PLLP in clock_config(). The divisor must be very small
  * to accomodate 12KHz OSCs, so we override the 16.0 UART divider with the 15.1
  * CLK_SOURCE divider to get more precision. (This might still not be enough for
  * some OSCs... if you use 13KHz, be prepared to have a bad time.) The 1900 has
  * been determined through trial and error (must lead to div 13 at 24MHz). */
 void clock_early_uart(void)
 {
 	write32(CLK_M << CLK_SOURCE_SHIFT | CLK_UART_DIV_OVERRIDE |
 		CLK_DIVIDER(TEGRA_CLK_M_KHZ, 1900), &clk_rst->clk_src_uarta);
 	setbits_le32(&clk_rst->clk_out_enb_l, CLK_L_UARTA);
 	udelay(2);
 	clrbits_le32(&clk_rst->rst_dev_l, CLK_L_UARTA);
 }

 /* Enable output clock (CLK1~3) for external peripherals. */
 void clock_external_output(int clk_id)
 {
 	switch (clk_id) {
 	case 1:
 		setbits_le32(&pmc->clk_out_cntrl, 1 << 2);
 		break;
 	case 2:
 		setbits_le32(&pmc->clk_out_cntrl, 1 << 10);
 		break;
 	case 3:
 		setbits_le32(&pmc->clk_out_cntrl, 1 << 18);
 		break;
 	default:
 		printk(BIOS_CRIT, "ERROR: Unknown output clock id %d\n",
 		       clk_id);
 		break;
 	}
 }

 /* Start PLLM for SDRAM. */
 void clock_sdram(u32 m, u32 n, u32 p, u32 setup, u32 ph45, u32 ph90,
 		 u32 ph135, u32 kvco, u32 kcp, u32 stable_time, u32 emc_source,
 		 u32 same_freq)
 {
 	u32 misc1 = ((setup << PLLM_MISC1_SETUP_SHIFT) |
 		     (ph45 << PLLM_MISC1_PD_LSHIFT_PH45_SHIFT) |
 		     (ph90 << PLLM_MISC1_PD_LSHIFT_PH90_SHIFT) |
 		     (ph135 << PLLM_MISC1_PD_LSHIFT_PH135_SHIFT)),
 	    misc2 = ((kvco << PLLM_MISC2_KVCO_SHIFT) |
 		     (kcp << PLLM_MISC2_KCP_SHIFT)),
 	    base;

 	if (same_freq)
 		emc_source |= CLK_SOURCE_EMC_MC_EMC_SAME_FREQ;
 	else
 		emc_source &= ~CLK_SOURCE_EMC_MC_EMC_SAME_FREQ;

 	/*
 	 * Note PLLM_BASE.PLLM_OUT1_RSTN must be in RESET_ENABLE mode, and
 	 * PLLM_BASE.ENABLE must be in DISABLE state (both are the default
 	 * values after coldboot reset).
 	 */

 	writel(misc1, &clk_rst->pllm_misc1);
 	writel(misc2, &clk_rst->pllm_misc2);

 	/* PLLM.BASE needs BYPASS=0, different from general init_pll */
 	base = readl(&clk_rst->pllm_base);
 	base &= ~(PLLCMX_BASE_DIVN_MASK | PLLCMX_BASE_DIVM_MASK |
 		  PLLM_BASE_DIVP_MASK | PLL_BASE_BYPASS);
 	base |= ((m << PLL_BASE_DIVM_SHIFT) | (n << PLL_BASE_DIVN_SHIFT) |
 		 (p << PLL_BASE_DIVP_SHIFT));
 	writel(base, &clk_rst->pllm_base);

 	setbits_le32(&clk_rst->pllm_base, PLL_BASE_ENABLE);
 	/* stable_time is required, before we can start to check lock. */
 	udelay(stable_time);

 	while (!(readl(&clk_rst->pllm_base) & PLL_BASE_LOCK)) {
 		udelay(1);
 	}
 	/*
 	 * After PLLM reports being locked, we have to delay 10us before
 	 * enabling PLLM_OUT.
 	 */
 	udelay(10);

 	/* Put OUT1 out of reset state (start to output). */
 	setbits_le32(&clk_rst->pllm_out, PLLM_OUT1_RSTN_RESET_DISABLE);

 	/* Enable and start MEM(MC) and EMC. */
 	clock_enable_clear_reset(0, CLK_H_MEM | CLK_H_EMC, 0, 0, 0, 0);
 	writel(emc_source, &clk_rst->clk_src_emc);
 	udelay(IO_STABILIZATION_DELAY);
 }

 void clock_cpu0_config(void *entry)
 {
 	void * const evp_cpu_reset = (uint8_t *)TEGRA_EVP_BASE + 0x100;

 	write32(CONFIG_STACK_TOP, &maincpu_stack_pointer);
 	write32((uintptr_t)entry, &maincpu_entry_point);
 	write32((uintptr_t)&maincpu_setup, evp_cpu_reset);

 	/* Set active CPU cluster to G */
 	clrbits_le32(&flow->cluster_control, 1);

 	// Set up cclk_brst and divider.
 	write32((CRC_CCLK_BRST_POL_PLLX_OUT0 << 0) |
 		(CRC_CCLK_BRST_POL_PLLX_OUT0 << 4) |
 		(CRC_CCLK_BRST_POL_PLLX_OUT0 << 8) |
 		(CRC_CCLK_BRST_POL_PLLX_OUT0 << 12) |
 		(CRC_CCLK_BRST_POL_CPU_STATE_RUN << 28),
 		&clk_rst->cclk_brst_pol);
 	write32(CRC_SUPER_CCLK_DIVIDER_SUPER_CDIV_ENB,
 		&clk_rst->super_cclk_div);

 	// Enable the clocks for CPUs 0-3.
 	uint32_t cpu_cmplx_clr = read32(&clk_rst->clk_cpu_cmplx_clr);
 	cpu_cmplx_clr |= CRC_CLK_CLR_CPU0_STP | CRC_CLK_CLR_CPU1_STP |
 			 CRC_CLK_CLR_CPU2_STP | CRC_CLK_CLR_CPU3_STP;
 	write32(cpu_cmplx_clr, &clk_rst->clk_cpu_cmplx_clr);

 	// Enable other CPU related clocks.
 	setbits_le32(&clk_rst->clk_out_enb_l, CLK_L_CPU);
 	setbits_le32(&clk_rst->clk_out_enb_v, CLK_V_CPUG);
 	setbits_le32(&clk_rst->clk_out_enb_v, CLK_V_CPULP);
 }

 void clock_cpu0_remove_reset(void)
 {
 	// Disable the reset on the non-CPU parts of the fast cluster.
 	write32(CRC_RST_CPUG_CLR_NONCPU,
 		&clk_rst->rst_cpug_cmplx_clr);
 	// Disable the various resets on the CPUs.
 	write32(CRC_RST_CPUG_CLR_CPU0 | CRC_RST_CPUG_CLR_CPU1 |
 		CRC_RST_CPUG_CLR_CPU2 | CRC_RST_CPUG_CLR_CPU3 |
 		CRC_RST_CPUG_CLR_DBG0 | CRC_RST_CPUG_CLR_DBG1 |
 		CRC_RST_CPUG_CLR_DBG2 | CRC_RST_CPUG_CLR_DBG3 |
 		CRC_RST_CPUG_CLR_CORE0 | CRC_RST_CPUG_CLR_CORE1 |
 		CRC_RST_CPUG_CLR_CORE2 | CRC_RST_CPUG_CLR_CORE3 |
 		CRC_RST_CPUG_CLR_CX0 | CRC_RST_CPUG_CLR_CX1 |
 		CRC_RST_CPUG_CLR_CX2 | CRC_RST_CPUG_CLR_CX3 |
 		CRC_RST_CPUG_CLR_L2 | CRC_RST_CPUG_CLR_PDBG,
 		&clk_rst->rst_cpug_cmplx_clr);

 	// Disable the reset on the non-CPU parts of the slow cluster.
 	write32(CRC_RST_CPULP_CLR_NONCPU,
 		&clk_rst->rst_cpulp_cmplx_clr);
 	// Disable the various resets on the LP CPU.
 	write32(CRC_RST_CPULP_CLR_CPU0 | CRC_RST_CPULP_CLR_DBG0 |
 		CRC_RST_CPULP_CLR_CORE0 | CRC_RST_CPULP_CLR_CX0 |
 		CRC_RST_CPULP_CLR_L2 | CRC_RST_CPULP_CLR_PDBG,
 		&clk_rst->rst_cpulp_cmplx_clr);
 }

 void clock_halt_avp(void)
 {
 	for (;;) {
 		write32(FLOW_EVENT_JTAG | FLOW_EVENT_LIC_IRQ |
 			FLOW_EVENT_GIC_IRQ | FLOW_MODE_WAITEVENT,
 			&flow->halt_cop_events);
 	}
 }

 void clock_init(void)
 {
 	u32 osc = clock_get_osc_bits();

 	/* Set PLLC dynramp_step A to 0x2b and B to 0xb (from U-Boot -- why? */
 	writel(0x2b << 17 | 0xb << 9, &clk_rst->pllc_misc2);

 	/* Max out the AVP clock before everything else (need PLLC for that). */
 	init_pll(&clk_rst->pllc_base, &clk_rst->pllc_misc,
 		osc_table[osc].pllc, PLLC_MISC_LOCK_ENABLE);

 	/* Typical ratios are 1:2:2 or 1:2:3 sclk:hclk:pclk (See: APB DMA
 	 * features section in the TRM). */
 	write32(TEGRA_HCLK_RATIO << HCLK_DIVISOR_SHIFT |
 		TEGRA_PCLK_RATIO << PCLK_DIVISOR_SHIFT,
 		&clk_rst->clk_sys_rate);
 	write32(CLK_DIVIDER(TEGRA_PLLC_KHZ, TEGRA_SCLK_KHZ) <<
 		PLL_OUT_RATIO_SHIFT | PLL_OUT_CLKEN |
 		PLL_OUT_RSTN, &clk_rst->pllc_out);
 	write32(SCLK_SYS_STATE_RUN << SCLK_SYS_STATE_SHIFT |
 		SCLK_SOURCE_PLLC_OUT1 << SCLK_RUN_SHIFT,
 		&clk_rst->sclk_brst_pol);		/* sclk = 300 MHz */

 	/* Change the oscillator drive strength (from U-Boot -- why?) */
 	clrsetbits_le32(&clk_rst->osc_ctrl, OSC_XOFS_MASK,
 			OSC_DRIVE_STRENGTH << OSC_XOFS_SHIFT);

 	/*
 	 * Ambiguous quote from u-boot. TODO: what's this mean?
 	 * "should update same value in PMC_OSC_EDPD_OVER XOFS
 	 * field for warmboot "
 	 */
 	clrsetbits_le32(&pmc->osc_edpd_over, PMC_OSC_EDPD_OVER_XOFS_MASK,
 			OSC_DRIVE_STRENGTH << PMC_OSC_EDPD_OVER_XOFS_SHIFT);

 	/* Disable IDDQ for PLLX before we set it up (from U-Boot -- why?) */
 	clrbits_le32(&clk_rst->pllx_misc3, PLLX_IDDQ_MASK);

 	/* Set up PLLP_OUT(1|2|3|4) divisor to generate (9.6|48|102|204)MHz */
 	write32((CLK_DIVIDER(TEGRA_PLLP_KHZ, 9600) << PLL_OUT_RATIO_SHIFT |
 		 PLL_OUT_OVR | PLL_OUT_CLKEN | PLL_OUT_RSTN) << PLL_OUT1_SHIFT |
 		(CLK_DIVIDER(TEGRA_PLLP_KHZ, 48000) << PLL_OUT_RATIO_SHIFT |
 		 PLL_OUT_OVR | PLL_OUT_CLKEN | PLL_OUT_RSTN) << PLL_OUT2_SHIFT,
 		&clk_rst->pllp_outa);
 	write32((CLK_DIVIDER(TEGRA_PLLP_KHZ, 102000) << PLL_OUT_RATIO_SHIFT |
 		 PLL_OUT_OVR | PLL_OUT_CLKEN | PLL_OUT_RSTN) << PLL_OUT3_SHIFT |
 		(CLK_DIVIDER(TEGRA_PLLP_KHZ, 204000) << PLL_OUT_RATIO_SHIFT |
 		 PLL_OUT_OVR | PLL_OUT_CLKEN | PLL_OUT_RSTN) << PLL_OUT4_SHIFT,
 		&clk_rst->pllp_outb);

 	/* init pllx */
 	init_pll(&clk_rst->pllx_base, &clk_rst->pllx_misc,
 		osc_table[osc].pllx, PLLPAXS_MISC_LOCK_ENABLE);

 	/* init pllu */
 	init_pll(&clk_rst->pllu_base, &clk_rst->pllu_misc,
 		osc_table[osc].pllu, PLLUD_MISC_LOCK_ENABLE);

 	init_utmip_pll();
 	graphics_pll();
 }

 void clock_enable_clear_reset(u32 l, u32 h, u32 u, u32 v, u32 w, u32 x)
 {
 	if (l) writel(l, &clk_rst->clk_enb_l_set);
 	if (h) writel(h, &clk_rst->clk_enb_h_set);
 	if (u) writel(u, &clk_rst->clk_enb_u_set);
 	if (v) writel(v, &clk_rst->clk_enb_v_set);
 	if (w) writel(w, &clk_rst->clk_enb_w_set);
 	if (x) writel(x, &clk_rst->clk_enb_x_set);

 	/* Give clocks time to stabilize. */
 	udelay(IO_STABILIZATION_DELAY);

 	if (l) writel(l, &clk_rst->rst_dev_l_clr);
 	if (h) writel(h, &clk_rst->rst_dev_h_clr);
 	if (u) writel(u, &clk_rst->rst_dev_u_clr);
 	if (v) writel(v, &clk_rst->rst_dev_v_clr);
 	if (w) writel(w, &clk_rst->rst_dev_w_clr);
 	if (x) writel(x, &clk_rst->rst_dev_x_clr);
 }

 void clock_reset_l(u32 bit)
 {
 	writel(bit, &clk_rst->rst_dev_l_set);
 	udelay(1);
 	writel(bit, &clk_rst->rst_dev_l_clr);
 }

 void clock_reset_h(u32 bit)
 {
 	writel(bit, &clk_rst->rst_dev_h_set);
 	udelay(1);
 	writel(bit, &clk_rst->rst_dev_h_clr);
 }

 void clock_reset_u(u32 bit)
 {
 	writel(bit, &clk_rst->rst_dev_u_set);
 	udelay(1);
 	writel(bit, &clk_rst->rst_dev_u_clr);
 }

 void clock_reset_v(u32 bit)
 {
 	writel(bit, &clk_rst->rst_dev_v_set);
 	udelay(1);
 	writel(bit, &clk_rst->rst_dev_v_clr);
 }

 void clock_reset_w(u32 bit)
 {
 	writel(bit, &clk_rst->rst_dev_w_set);
 	udelay(1);
 	writel(bit, &clk_rst->rst_dev_w_clr);
 }

 void clock_reset_x(u32 bit)
 {
 	writel(bit, &clk_rst->rst_dev_x_set);
 	udelay(1);
 	writel(bit, &clk_rst->rst_dev_x_clr);
 }
	/*
	* Copyright (c) 2013, NVIDIA CORPORATION. All rights reserved.
	* Copyright 2014 Google Inc.
	*
	* This program is free software; you can redistribute it and/or modify it
	* under the terms and conditions of the GNU General Public License,
	* version 2, as published by the Free Software Foundation.
	*
	* This program is distributed in the hope it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
	* more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program. If not, see <http://www.gnu.org/licenses/>.
	*/
	#include <console/console.h>
	#include <delay.h>
	#include <arch/io.h>
	#include <soc/addressmap.h>
	#include <soc/clock.h>
	#include <stdlib.h>
	#include <arch/clock.h>
	#include "clk_rst.h"
	#include "flow.h"
	#include "maincpu.h"
	#include "pmc.h"
	#include "sysctr.h"

	static struct clk_rst_ctlr clk_rst = (void )TEGRA_CLK_RST_BASE;
	static struct flow_ctlr flow = (void )TEGRA_FLOW_BASE;
	static struct tegra_pmc_regs pmc = (void )TEGRA_PMC_BASE;
	static struct sysctr_regs sysctr = (void )TEGRA_SYSCTR0_BASE;

	struct pll_dividers {
	u32 n : 10;
	u32 m : 8;
	u32 p : 4;
	u32 cpcon : 4;
	u32 lfcon : 4;
	u32 : 2;
	};

	/* Some PLLs have more restrictive divider bit lengths or are missing some
	* fields. Make sure to use the right struct in the osc_table definition to get
	* compile-time checking, but keep the bits aligned with struct pll_dividers so
	* they can be used interchangeably at run time. Add new formats as required. */
	struct pllcx_dividers {
	u32 n : 8;
	u32 : 2;
	u32 m : 8;
	u32 p : 4;
	u32 : 10;
	};
	struct pllpad_dividers {
	u32 n : 10;
	u32 m : 5;
	u32 : 3;
	u32 p : 3;
	u32 : 1;
	u32 cpcon : 4;
	u32 : 6;
	};
	struct pllu_dividers {
	u32 n : 10;
	u32 m : 5;
	u32 : 3;
	u32 p : 1;
	u32 : 3;
	u32 cpcon : 4;
	u32 lfcon : 4;
	u32 : 2;
	};

	union __attribute__((transparent_union)) pll_fields {
	u32 raw;
	struct pll_dividers div;
	struct pllcx_dividers cx;
	struct pllpad_dividers pad;
	struct pllu_dividers u;
	};

	/* This table defines the frequency dividers for every PLL to turn the external
	* OSC clock into the frequencies defined by TEGRA_PLL*_KHZ in soc/clock.h.
	* All PLLs have three dividers (n, m and p), with the governing formula for
	* the output frequency being CF = (IN / m), VCO = CF * n and OUT = VCO / (2^p).
	* All divisor configurations must meet the PLL's constraints for VCO and CF:
	* PLLX: 12 MHz < CF < 50 MHz, 700 MHz < VCO < 3000 MHz
	* PLLC: 12 MHz < CF < 50 MHz, 600 MHz < VCO < 1400 MHz
	* PLLM: 12 MHz < CF < 50 MHz, 400 MHz < VCO < 1066 MHz
	* PLLP: 1 MHz < CF < 6 MHz, 200 MHz < VCO < 700 MHz
	* PLLD: 1 MHz < CF < 6 MHz, 500 MHz < VCO < 1000 MHz
	* PLLU: 1 MHz < CF < 6 MHz, 480 MHz < VCO < 960 MHz
	* PLLDP: 12 MHz < CF < 38 MHz, 600 MHz < VCO < 1200 MHz
	* (values taken from Linux' drivers/clk/tegra/clk-tegra124.c). */
	struct {
	int khz;
	struct pllcx_dividers pllx; /* target: CONFIG_PLLX_KHZ */
	struct pllcx_dividers pllc; /* target: 600 MHz */
	/* PLLM is set up dynamically by clock_sdram(). */
	/* PLLP is hardwired to 408 MHz in HW (unless we set BASE_OVRD). */
	struct pllu_dividers pllu; /* target; 960 MHz */
	struct pllcx_dividers plldp; /* target; 270 MHz */
	/* PLLDP treats p differently (OUT = VCO / (p + 1) for p < 6). */
	} static const osc_table[16] = {
	[OSC_FREQ_12]{
	.khz = 12000,
	.pllx = {.n = TEGRA_PLLX_KHZ / 12000, .m = 1, .p = 0},
	.pllc = {.n = 50, .m = 1, .p = 0},
	.pllu = {.n = 960, .m = 12, .p = 0, .cpcon = 12, .lfcon = 2},
	.plldp = {.n = 90, .m = 1, .p = 3},
	},
	[OSC_FREQ_13]{
	.khz = 13000,
	.pllx = {.n = TEGRA_PLLX_KHZ / 13000, .m = 1, .p = 0},
	.pllc = {.n = 46, .m = 1, .p = 0}, /* 598.0 MHz */
	.pllu = {.n = 960, .m = 13, .p = 0, .cpcon = 12, .lfcon = 2},
	.plldp = {.n = 83, .m = 1, .p = 3}, /* 269.8 MHz */
	},
	[OSC_FREQ_16P8]{
	.khz = 16800,
	.pllx = {.n = TEGRA_PLLX_KHZ / 16800, .m = 1, .p = 0},
	.pllc = {.n = 71, .m = 1, .p = 1}, /* 596.4 MHz */
	.pllu = {.n = 400, .m = 7, .p = 0, .cpcon = 5, .lfcon = 2},
	.plldp = {.n = 64, .m = 1, .p = 3}, /* 268.8 MHz */
	},
	[OSC_FREQ_19P2]{
	.khz = 19200,
	.pllx = {.n = TEGRA_PLLX_KHZ / 19200, .m = 1, .p = 0},
	.pllc = {.n = 62, .m = 1, .p = 1}, /* 595.2 MHz */
	.pllu = {.n = 200, .m = 4, .p = 0, .cpcon = 3, .lfcon = 2},
	.plldp = {.n = 56, .m = 1, .p = 3}, /* 268.8 MHz */
	},
	[OSC_FREQ_26]{
	.khz = 26000,
	.pllx = {.n = TEGRA_PLLX_KHZ / 26000, .m = 1, .p = 0},
	.pllc = {.n = 23, .m = 1, .p = 0}, /* 598.0 MHz */
	.pllu = {.n = 960, .m = 26, .p = 0, .cpcon = 12, .lfcon = 2},
	.plldp = {.n = 83, .m = 2, .p = 3}, /* 269.8 MHz */
	},
	/* These oscillators get predivided as PLL inputs... n/m/p divisors for
	* 38.4 should always match 19.2, and 48 should always match 12. */
	[OSC_FREQ_38P4]{
	.khz = 38400,
	.pllx = {.n = TEGRA_PLLX_KHZ / 19200, .m = 1, .p = 0},
	.pllc = {.n = 62, .m = 1, .p = 1}, /* 595.2 MHz */
	.pllu = {.n = 200, .m = 4, .p = 0, .cpcon = 3, .lfcon = 2},
	.plldp = {.n = 56, .m = 1, .p = 3}, /* 268.8 MHz */
	},
	[OSC_FREQ_48]{
	.khz = 48000,
	.pllx = {.n = TEGRA_PLLX_KHZ / 12000, .m = 1, .p = 0},
	.pllc = {.n = 50, .m = 1, .p = 0},
	.pllu = {.n = 960, .m = 12, .p = 0, .cpcon = 12, .lfcon = 2},
	.plldp = {.n = 90, .m = 1, .p = 3},
	},
	};

	/* Get the oscillator frequency, from the corresponding hardware
	* configuration field. This is actually a per-soc thing. Avoid the
	* temptation to make it common.
	*/
	static u32 clock_get_osc_bits(void)
	{
	return (readl(&clk_rst->osc_ctrl) & OSC_FREQ_MASK) >> OSC_FREQ_SHIFT;
	}

	int clock_get_osc_khz(void)
	{
	return osc_table[clock_get_osc_bits()].khz;
	}

	int clock_get_pll_input_khz(void)
	{
	u32 osc_ctrl = readl(&clk_rst->osc_ctrl);
	u32 osc_bits = (osc_ctrl & OSC_FREQ_MASK) >> OSC_FREQ_SHIFT;
	u32 pll_ref_div = (osc_ctrl & OSC_PREDIV_MASK) >> OSC_PREDIV_SHIFT;
	return osc_table[osc_bits].khz >> pll_ref_div;
	}

	void clock_init_arm_generic_timer(void)
	{
	uint32_t freq = clock_get_osc_khz() * 1000;
	// Set the cntfrq register.
	set_cntfrq(freq);

	// Record the system timer frequency.
	write32(freq, &sysctr->cntfid0);
	// Enable the system counter.
	uint32_t cntcr = read32(&sysctr->cntcr);
	cntcr \|= SYSCTR_CNTCR_EN \| SYSCTR_CNTCR_HDBG;
	write32(cntcr, &sysctr->cntcr);
	}

	#define SOR0_CLK_SEL0 (1 << 14)
	#define SOR0_CLK_SEL1 (1 << 15)

	void sor_clock_stop(void)
	{
	/* The Serial Output Resource clock has to be off
	* before we start the plldp. Learned the hard way.
	* FIXME: this has to be cleaned up a bit more.
	* Waiting on some new info from Nvidia.
	*/
	clrbits_le32(&clk_rst->clk_src_sor, SOR0_CLK_SEL0 \| SOR0_CLK_SEL1);
	}

	void sor_clock_start(void)
	{
	/* uses PLLP, has a non-standard bit layout. */
	setbits_le32(&clk_rst->clk_src_sor, SOR0_CLK_SEL0);
	}

	static void init_pll(u32 base, u32 misc, const union pll_fields pll, u32 lock)
	{
	u32 dividers = pll.div.n << PLL_BASE_DIVN_SHIFT \|
	pll.div.m << PLL_BASE_DIVM_SHIFT \|
	pll.div.p << PLL_BASE_DIVP_SHIFT;
	u32 misc_con = pll.div.cpcon << PLL_MISC_CPCON_SHIFT \|
	pll.div.lfcon << PLL_MISC_LFCON_SHIFT;

	/* Write dividers but BYPASS the PLL while we're messing with it. */
	writel(dividers \| PLL_BASE_BYPASS, base);
	/*
	* Set Lock bit, CPCON and LFCON fields (default to 0 if it doesn't
	* exist for this PLL)
	*/
	writel(lock \| misc_con, misc);

	/* Enable PLL and take it back out of BYPASS */
	writel(dividers \| PLL_BASE_ENABLE, base);

	/* Wait for lock ready */
	while (!(readl(base) & PLL_BASE_LOCK));
	}

	static void init_utmip_pll(void)
	{
	int khz = clock_get_pll_input_khz();

	/* Shut off PLL crystal clock while we mess with it */
	clrbits_le32(&clk_rst->utmip_pll_cfg2, 1 << 30); /* PHY_XTAL_CLKEN */
	udelay(1);

	write32(80 << 16 \| /* (rst) phy_divn */
	1 << 8 \| /* (rst) phy_divm */
	0, &clk_rst->utmip_pll_cfg0); /* 960MHz * 1 / 80 == 12 MHz */

	write32(div_round_up(khz, 8000) << 27 \| /* pllu_enbl_cnt / 8 (1us) */
	0 << 16 \| /* PLLU pwrdn */
	0 << 14 \| /* pll_enable pwrdn */
	0 << 12 \| /* pll_active pwrdn */
	div_round_up(khz, 102) << 0 \| /* phy_stbl_cnt / 256 (2.5ms) */
	0, &clk_rst->utmip_pll_cfg1);

	/* TODO: TRM can't decide if actv is 5us or 10us, keep an eye on it */
	write32(0 << 24 \| /* SAMP_D/XDEV pwrdn */
	div_round_up(khz, 3200) << 18 \| /* phy_actv_cnt / 16 (5us) */
	div_round_up(khz, 256) << 6 \| /* pllu_stbl_cnt / 256 (1ms) */
	0 << 4 \| /* SAMP_C/USB3 pwrdn */
	0 << 2 \| /* SAMP_B/XHOST pwrdn */
	0 << 0 \| /* SAMP_A/USBD pwrdn */
	0, &clk_rst->utmip_pll_cfg2);

	setbits_le32(&clk_rst->utmip_pll_cfg2, 1 << 30); /* PHY_XTAL_CLKEN */
	}

	/* Graphics just has to be different. There's a few more bits we
	* need to set in here, but it makes sense just to restrict all the
	* special bits to this one function.
	*/
	static void graphics_pll(void)
	{
	int osc = clock_get_osc_bits();
	u32 *cfg = &clk_rst->plldp_ss_cfg;
	/* the vendor code sets the dither bit (28)
	* an undocumented bit (24)
	* and clamp while we mess with it (22)
	* Dither is pretty important to display port
	* so we really do need to handle these bits.
	* I'm not willing to not clamp it, even if
	* it might "mostly work" with it not set,
	* I don't want to find out in a few months
	* that it is needed.
	*/
	u32 scfg = (1<<28) \| (1<<24) \| (1<<22);
	writel(scfg, cfg);
	init_pll(&clk_rst->plldp_base, &clk_rst->plldp_misc,
	osc_table[osc].plldp, PLLDPD2_MISC_LOCK_ENABLE);
	/* leave dither and undoc bits set, release clamp */
	scfg = (1<<28) \| (1<<24);
	writel(scfg, cfg);

	/* disp1 will be set when panel information (pixel clock) is
	* retrieved (clock_display).
	*/
	}

	/*
	* Init PLLD clock source.
	*
	* @frequency: the requested plld frequency
	*
	* Return the plld frequency if success, otherwise return 0.
	*/
	u32
	clock_display(u32 frequency)
	{
	/**
	* plld (fo) = vco >> p, where 500MHz < vco < 1000MHz
	* = (cf * n) >> p, where 1MHz < cf < 6MHz
	* = ((ref / m) * n) >> p
	*
	* Iterate the possible values of p (3 bits, 2^7) to find out a minimum
	* safe vco, then find best (m, n). since m has only 5 bits, we can
	* iterate all possible values. Note Tegra 124 supports 11 bits for n,
	* but our pll_fields has only 10 bits for n.
	*
	* Note values undershoot or overshoot target output frequency may not
	* work if the values are not in "safe" range by panel specification.
	*/
	struct pllpad_dividers plld = { 0 };
	u32 ref = clock_get_pll_input_khz() * 1000, m, n, p = 0;
	u32 cf, vco, rounded_rate = frequency;
	u32 diff, best_diff;
	const u32 max_m = 1 << 5, max_n = 1 << 10, max_p = 1 << 3,
	mhz = 1000 * 1000, min_vco = 500 * mhz, max_vco = 1000 * mhz,
	min_cf = 1 * mhz, max_cf = 6 * mhz;

	for (vco = frequency; vco < min_vco && p < max_p; p++)
	vco <<= 1;

	if (vco < min_vco \|\| vco > max_vco) {
	printk(BIOS_ERR, "%s: Cannot find out a supported VCO"
	" for Frequency (%u).\n", __func__, frequency);
	return 0;
	}

	plld.p = p;
	best_diff = vco;

	for (m = 1; m < max_m && best_diff; m++) {
	cf = ref / m;
	if (cf < min_cf)
	break;
	if (cf > max_cf)
	continue;

	n = vco / cf;
	if (n >= max_n)
	continue;

	diff = vco - n * cf;
	if (n + 1 < max_n && diff > cf / 2) {
	n++;
	diff = cf - diff;
	}

	if (diff >= best_diff)
	continue;

	best_diff = diff;
	plld.m = m;
	plld.n = n;
	}

	if (plld.n < 50)
	plld.cpcon = 2;
	else if (plld.n < 300)
	plld.cpcon = 3;
	else if (plld.n < 600)
	plld.cpcon = 8;
	else
	plld.cpcon = 12;

	if (best_diff) {
	printk(BIOS_WARNING, "%s: Failed to match output frequency %u, "
	"best difference is %u.\n", __func__, frequency,
	best_diff);
	rounded_rate = (ref / plld.m * plld.n) >> plld.p;
	}

	printk(BIOS_DEBUG, "%s: PLLD=%u ref=%u, m/n/p/cpcon=%u/%u/%u/%u\n",
	__func__, rounded_rate, ref, plld.m, plld.n, plld.p, plld.cpcon);

	init_pll(&clk_rst->plld_base, &clk_rst->plld_misc, plld,
	(PLLUD_MISC_LOCK_ENABLE \| PLLD_MISC_CLK_ENABLE));

	return rounded_rate;
	}

	/* Initialize the UART and put it on CLK_M so we can use it during clock_init().
	* Will later move it to PLLP in clock_config(). The divisor must be very small
	* to accomodate 12KHz OSCs, so we override the 16.0 UART divider with the 15.1
	* CLK_SOURCE divider to get more precision. (This might still not be enough for
	* some OSCs... if you use 13KHz, be prepared to have a bad time.) The 1900 has
	* been determined through trial and error (must lead to div 13 at 24MHz). */
	void clock_early_uart(void)
	{
	write32(CLK_M << CLK_SOURCE_SHIFT \| CLK_UART_DIV_OVERRIDE \|
	CLK_DIVIDER(TEGRA_CLK_M_KHZ, 1900), &clk_rst->clk_src_uarta);
	setbits_le32(&clk_rst->clk_out_enb_l, CLK_L_UARTA);
	udelay(2);
	clrbits_le32(&clk_rst->rst_dev_l, CLK_L_UARTA);
	}

	/* Enable output clock (CLK1~3) for external peripherals. */
	void clock_external_output(int clk_id)
	{
	switch (clk_id) {
	case 1:
	setbits_le32(&pmc->clk_out_cntrl, 1 << 2);
	break;
	case 2:
	setbits_le32(&pmc->clk_out_cntrl, 1 << 10);
	break;
	case 3:
	setbits_le32(&pmc->clk_out_cntrl, 1 << 18);
	break;
	default:
	printk(BIOS_CRIT, "ERROR: Unknown output clock id %d\n",
	clk_id);
	break;
	}
	}

	/* Start PLLM for SDRAM. */
	void clock_sdram(u32 m, u32 n, u32 p, u32 setup, u32 ph45, u32 ph90,
	u32 ph135, u32 kvco, u32 kcp, u32 stable_time, u32 emc_source,
	u32 same_freq)
	{
	u32 misc1 = ((setup << PLLM_MISC1_SETUP_SHIFT) \|
	(ph45 << PLLM_MISC1_PD_LSHIFT_PH45_SHIFT) \|
	(ph90 << PLLM_MISC1_PD_LSHIFT_PH90_SHIFT) \|
	(ph135 << PLLM_MISC1_PD_LSHIFT_PH135_SHIFT)),
	misc2 = ((kvco << PLLM_MISC2_KVCO_SHIFT) \|
	(kcp << PLLM_MISC2_KCP_SHIFT)),
	base;

	if (same_freq)
	emc_source \|= CLK_SOURCE_EMC_MC_EMC_SAME_FREQ;
	else
	emc_source &= ~CLK_SOURCE_EMC_MC_EMC_SAME_FREQ;

	/*
	* Note PLLM_BASE.PLLM_OUT1_RSTN must be in RESET_ENABLE mode, and
	* PLLM_BASE.ENABLE must be in DISABLE state (both are the default
	* values after coldboot reset).
	*/

	writel(misc1, &clk_rst->pllm_misc1);
	writel(misc2, &clk_rst->pllm_misc2);

	/* PLLM.BASE needs BYPASS=0, different from general init_pll */
	base = readl(&clk_rst->pllm_base);
	base &= ~(PLLCMX_BASE_DIVN_MASK \| PLLCMX_BASE_DIVM_MASK \|
	PLLM_BASE_DIVP_MASK \| PLL_BASE_BYPASS);
	base \|= ((m << PLL_BASE_DIVM_SHIFT) \| (n << PLL_BASE_DIVN_SHIFT) \|
	(p << PLL_BASE_DIVP_SHIFT));
	writel(base, &clk_rst->pllm_base);

	setbits_le32(&clk_rst->pllm_base, PLL_BASE_ENABLE);
	/* stable_time is required, before we can start to check lock. */
	udelay(stable_time);

	while (!(readl(&clk_rst->pllm_base) & PLL_BASE_LOCK)) {
	udelay(1);
	}
	/*
	* After PLLM reports being locked, we have to delay 10us before
	* enabling PLLM_OUT.
	*/
	udelay(10);

	/* Put OUT1 out of reset state (start to output). */
	setbits_le32(&clk_rst->pllm_out, PLLM_OUT1_RSTN_RESET_DISABLE);

	/* Enable and start MEM(MC) and EMC. */
	clock_enable_clear_reset(0, CLK_H_MEM \| CLK_H_EMC, 0, 0, 0, 0);
	writel(emc_source, &clk_rst->clk_src_emc);
	udelay(IO_STABILIZATION_DELAY);
	}

	void clock_cpu0_config(void *entry)
	{
	void * const evp_cpu_reset = (uint8_t *)TEGRA_EVP_BASE + 0x100;

	write32(CONFIG_STACK_TOP, &maincpu_stack_pointer);
	write32((uintptr_t)entry, &maincpu_entry_point);
	write32((uintptr_t)&maincpu_setup, evp_cpu_reset);

	/* Set active CPU cluster to G */
	clrbits_le32(&flow->cluster_control, 1);

	// Set up cclk_brst and divider.
	write32((CRC_CCLK_BRST_POL_PLLX_OUT0 << 0) \|
	(CRC_CCLK_BRST_POL_PLLX_OUT0 << 4) \|
	(CRC_CCLK_BRST_POL_PLLX_OUT0 << 8) \|
	(CRC_CCLK_BRST_POL_PLLX_OUT0 << 12) \|
	(CRC_CCLK_BRST_POL_CPU_STATE_RUN << 28),
	&clk_rst->cclk_brst_pol);
	write32(CRC_SUPER_CCLK_DIVIDER_SUPER_CDIV_ENB,
	&clk_rst->super_cclk_div);

	// Enable the clocks for CPUs 0-3.
	uint32_t cpu_cmplx_clr = read32(&clk_rst->clk_cpu_cmplx_clr);
	cpu_cmplx_clr \|= CRC_CLK_CLR_CPU0_STP \| CRC_CLK_CLR_CPU1_STP \|
	CRC_CLK_CLR_CPU2_STP \| CRC_CLK_CLR_CPU3_STP;
	write32(cpu_cmplx_clr, &clk_rst->clk_cpu_cmplx_clr);

	// Enable other CPU related clocks.
	setbits_le32(&clk_rst->clk_out_enb_l, CLK_L_CPU);
	setbits_le32(&clk_rst->clk_out_enb_v, CLK_V_CPUG);
	setbits_le32(&clk_rst->clk_out_enb_v, CLK_V_CPULP);
	}

	void clock_cpu0_remove_reset(void)
	{
	// Disable the reset on the non-CPU parts of the fast cluster.
	write32(CRC_RST_CPUG_CLR_NONCPU,
	&clk_rst->rst_cpug_cmplx_clr);
	// Disable the various resets on the CPUs.
	write32(CRC_RST_CPUG_CLR_CPU0 \| CRC_RST_CPUG_CLR_CPU1 \|
	CRC_RST_CPUG_CLR_CPU2 \| CRC_RST_CPUG_CLR_CPU3 \|
	CRC_RST_CPUG_CLR_DBG0 \| CRC_RST_CPUG_CLR_DBG1 \|
	CRC_RST_CPUG_CLR_DBG2 \| CRC_RST_CPUG_CLR_DBG3 \|
	CRC_RST_CPUG_CLR_CORE0 \| CRC_RST_CPUG_CLR_CORE1 \|
	CRC_RST_CPUG_CLR_CORE2 \| CRC_RST_CPUG_CLR_CORE3 \|
	CRC_RST_CPUG_CLR_CX0 \| CRC_RST_CPUG_CLR_CX1 \|
	CRC_RST_CPUG_CLR_CX2 \| CRC_RST_CPUG_CLR_CX3 \|
	CRC_RST_CPUG_CLR_L2 \| CRC_RST_CPUG_CLR_PDBG,
	&clk_rst->rst_cpug_cmplx_clr);

	// Disable the reset on the non-CPU parts of the slow cluster.
	write32(CRC_RST_CPULP_CLR_NONCPU,
	&clk_rst->rst_cpulp_cmplx_clr);
	// Disable the various resets on the LP CPU.
	write32(CRC_RST_CPULP_CLR_CPU0 \| CRC_RST_CPULP_CLR_DBG0 \|
	CRC_RST_CPULP_CLR_CORE0 \| CRC_RST_CPULP_CLR_CX0 \|
	CRC_RST_CPULP_CLR_L2 \| CRC_RST_CPULP_CLR_PDBG,
	&clk_rst->rst_cpulp_cmplx_clr);
	}

	void clock_halt_avp(void)
	{
	for (;;) {
	write32(FLOW_EVENT_JTAG \| FLOW_EVENT_LIC_IRQ \|
	FLOW_EVENT_GIC_IRQ \| FLOW_MODE_WAITEVENT,
	&flow->halt_cop_events);
	}
	}

	void clock_init(void)
	{
	u32 osc = clock_get_osc_bits();

	/* Set PLLC dynramp_step A to 0x2b and B to 0xb (from U-Boot -- why? */
	writel(0x2b << 17 \| 0xb << 9, &clk_rst->pllc_misc2);

	/* Max out the AVP clock before everything else (need PLLC for that). */
	init_pll(&clk_rst->pllc_base, &clk_rst->pllc_misc,
	osc_table[osc].pllc, PLLC_MISC_LOCK_ENABLE);

	/* Typical ratios are 1:2:2 or 1:2:3 sclk:hclk:pclk (See: APB DMA
	* features section in the TRM). */
	write32(TEGRA_HCLK_RATIO << HCLK_DIVISOR_SHIFT \|
	TEGRA_PCLK_RATIO << PCLK_DIVISOR_SHIFT,
	&clk_rst->clk_sys_rate);
	write32(CLK_DIVIDER(TEGRA_PLLC_KHZ, TEGRA_SCLK_KHZ) <<
	PLL_OUT_RATIO_SHIFT \| PLL_OUT_CLKEN \|
	PLL_OUT_RSTN, &clk_rst->pllc_out);
	write32(SCLK_SYS_STATE_RUN << SCLK_SYS_STATE_SHIFT \|
	SCLK_SOURCE_PLLC_OUT1 << SCLK_RUN_SHIFT,
	&clk_rst->sclk_brst_pol); /* sclk = 300 MHz */

	/* Change the oscillator drive strength (from U-Boot -- why?) */
	clrsetbits_le32(&clk_rst->osc_ctrl, OSC_XOFS_MASK,
	OSC_DRIVE_STRENGTH << OSC_XOFS_SHIFT);

	/*
	* Ambiguous quote from u-boot. TODO: what's this mean?
	* "should update same value in PMC_OSC_EDPD_OVER XOFS
	* field for warmboot "
	*/
	clrsetbits_le32(&pmc->osc_edpd_over, PMC_OSC_EDPD_OVER_XOFS_MASK,
	OSC_DRIVE_STRENGTH << PMC_OSC_EDPD_OVER_XOFS_SHIFT);

	/* Disable IDDQ for PLLX before we set it up (from U-Boot -- why?) */
	clrbits_le32(&clk_rst->pllx_misc3, PLLX_IDDQ_MASK);

	/* Set up PLLP_OUT(1\|2\|3\|4) divisor to generate (9.6\|48\|102\|204)MHz */
	write32((CLK_DIVIDER(TEGRA_PLLP_KHZ, 9600) << PLL_OUT_RATIO_SHIFT \|
	PLL_OUT_OVR \| PLL_OUT_CLKEN \| PLL_OUT_RSTN) << PLL_OUT1_SHIFT \|
	(CLK_DIVIDER(TEGRA_PLLP_KHZ, 48000) << PLL_OUT_RATIO_SHIFT \|
	PLL_OUT_OVR \| PLL_OUT_CLKEN \| PLL_OUT_RSTN) << PLL_OUT2_SHIFT,
	&clk_rst->pllp_outa);
	write32((CLK_DIVIDER(TEGRA_PLLP_KHZ, 102000) << PLL_OUT_RATIO_SHIFT \|
	PLL_OUT_OVR \| PLL_OUT_CLKEN \| PLL_OUT_RSTN) << PLL_OUT3_SHIFT \|
	(CLK_DIVIDER(TEGRA_PLLP_KHZ, 204000) << PLL_OUT_RATIO_SHIFT \|
	PLL_OUT_OVR \| PLL_OUT_CLKEN \| PLL_OUT_RSTN) << PLL_OUT4_SHIFT,
	&clk_rst->pllp_outb);

	/* init pllx */
	init_pll(&clk_rst->pllx_base, &clk_rst->pllx_misc,
	osc_table[osc].pllx, PLLPAXS_MISC_LOCK_ENABLE);

	/* init pllu */
	init_pll(&clk_rst->pllu_base, &clk_rst->pllu_misc,
	osc_table[osc].pllu, PLLUD_MISC_LOCK_ENABLE);

	init_utmip_pll();
	graphics_pll();
	}

	void clock_enable_clear_reset(u32 l, u32 h, u32 u, u32 v, u32 w, u32 x)
	{
	if (l) writel(l, &clk_rst->clk_enb_l_set);
	if (h) writel(h, &clk_rst->clk_enb_h_set);
	if (u) writel(u, &clk_rst->clk_enb_u_set);
	if (v) writel(v, &clk_rst->clk_enb_v_set);
	if (w) writel(w, &clk_rst->clk_enb_w_set);
	if (x) writel(x, &clk_rst->clk_enb_x_set);

	/* Give clocks time to stabilize. */
	udelay(IO_STABILIZATION_DELAY);

	if (l) writel(l, &clk_rst->rst_dev_l_clr);
	if (h) writel(h, &clk_rst->rst_dev_h_clr);
	if (u) writel(u, &clk_rst->rst_dev_u_clr);
	if (v) writel(v, &clk_rst->rst_dev_v_clr);
	if (w) writel(w, &clk_rst->rst_dev_w_clr);
	if (x) writel(x, &clk_rst->rst_dev_x_clr);
	}

	void clock_reset_l(u32 bit)
	{
	writel(bit, &clk_rst->rst_dev_l_set);
	udelay(1);
	writel(bit, &clk_rst->rst_dev_l_clr);
	}

	void clock_reset_h(u32 bit)
	{
	writel(bit, &clk_rst->rst_dev_h_set);
	udelay(1);
	writel(bit, &clk_rst->rst_dev_h_clr);
	}

	void clock_reset_u(u32 bit)
	{
	writel(bit, &clk_rst->rst_dev_u_set);
	udelay(1);
	writel(bit, &clk_rst->rst_dev_u_clr);
	}

	void clock_reset_v(u32 bit)
	{
	writel(bit, &clk_rst->rst_dev_v_set);
	udelay(1);
	writel(bit, &clk_rst->rst_dev_v_clr);
	}

	void clock_reset_w(u32 bit)
	{
	writel(bit, &clk_rst->rst_dev_w_set);
	udelay(1);
	writel(bit, &clk_rst->rst_dev_w_clr);
	}

	void clock_reset_x(u32 bit)
	{
	writel(bit, &clk_rst->rst_dev_x_set);
	udelay(1);
	writel(bit, &clk_rst->rst_dev_x_clr);
	}