/* $NetBSD: exynos_soc.c,v 1.41 2022/10/29 13:29:46 jmcneill Exp $ */
/*-
* Copyright (c) 2014 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Reinoud Zandijk.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include "opt_arm_debug.h"
#include "opt_exynos.h"
#include <sys/cdefs.h>
__KERNEL_RCSID(1, "$NetBSD: exynos_soc.c,v 1.41 2022/10/29 13:29:46 jmcneill Exp $");
#include <sys/param.h>
#include <sys/bus.h>
#include <sys/cpu.h>
#include <sys/device.h>
#include <prop/proplib.h>
#include <net/if.h>
#include <net/if_ether.h>
#include <arm/locore.h>
#include <arm/mainbus/mainbus.h>
#include <arm/cortex/mpcore_var.h>
#include <arm/samsung/exynos_reg.h>
#include <arm/samsung/exynos_var.h>
#include <arm/samsung/mct_reg.h>
#include <arm/samsung/smc.h>
#include <arm/cortex/pl310_var.h>
#include <arm/cortex/pl310_reg.h>
#include <evbarm/fdt/platform.h>
#define EXYNOS_CORE_VBASE KERNEL_IO_VBASE
/* these variables are retrieved in start.S and stored in .data */
uint32_t exynos_soc_id = 0;
uint32_t exynos_pop_id = 0;
/* cpu frequencies */
struct cpu_freq {
uint64_t freq;
int P;
int M;
int S;
};
#ifdef SOC_EXYNOS4
int exynos4_l2cc_init(void);
const struct cpu_freq cpu_freq_settings_exynos4[] = {
{ 200, 3, 100, 2},
{ 300, 4, 200, 2},
{ 400, 3, 100, 1},
{ 500, 3, 125, 1},
{ 600, 4, 200, 1},
{ 700, 3, 175, 1},
{ 800, 3, 100, 0},
{ 900, 4, 150, 0},
{1000, 3, 125, 0},
{1100, 6, 275, 0},
{1200, 4, 200, 0},
{1300, 6, 325, 0},
{1400, 3, 175, 0},
{1600, 3, 200, 0},
// {1704, 3, 213, 0},
// {1800, 4, 300, 0},
// {1920, 3, 240, 0},
// {2000, 3, 250, 0},
};
#endif
#ifdef SOC_EXYNOS5
#define EXYNOS5_DEFAULT_ENTRY 7
const struct cpu_freq cpu_freq_settings_exynos5[] = {
{ 200, 3, 100, 2},
{ 333, 4, 222, 2},
{ 400, 3, 100, 1},
{ 533, 12, 533, 1},
{ 600, 4, 200, 1},
{ 667, 7, 389, 1},
{ 800, 3, 100, 0},
{ 900, 4, 150, 0},
{1000, 3, 125, 0},
{1066, 12, 533, 0},
{1200, 3, 150, 0},
{1400, 3, 175, 0},
{1600, 3, 200, 0},
};
#endif
static struct cpu_freq const *cpu_freq_settings = NULL;
static int ncpu_freq_settings = 0;
static int cpu_freq_target = 0;
#define NFRQS 18
static char sysctl_cpu_freqs_txt[NFRQS*5];
bus_space_handle_t exynos_core_bsh;
bus_space_handle_t exynos_audiocore_bsh;
bus_space_handle_t exynos_wdt_bsh;
bus_space_handle_t exynos_pmu_bsh;
bus_space_handle_t exynos_cmu_bsh;
bus_space_handle_t exynos_cmu_apll_bsh;
bus_space_handle_t exynos_sysreg_bsh;
static int sysctl_cpufreq_target(SYSCTLFN_ARGS);
static int sysctl_cpufreq_current(SYSCTLFN_ARGS);
#ifdef ARM_TRUSTZONE_FIRMWARE
int
exynos_do_idle(void)
{
exynos_smc(SMC_CMD_SLEEP, 0, 0, 0);
return 0;
}
int
exynos_set_cpu_boot_addr(int cpu, vaddr_t boot_addr)
{
/* XXX we need to map in iRAM space for this XXX */
return 0;
}
int
exynos_cpu_boot(int cpu)
{
exynos_smc(SMC_CMD_CPU1BOOT, cpu, 0, 0);
return 0;
}
#ifdef SOC_EXYNOS4
/*
* The latency values used below are `magic' and probably chosen empirically.
* For the 4210 variant the data latency is lower, a 0x110. This is currently
* not enforced.
*
* The prefetch values are also different for the revision 0 of the
* Exynos4412, but why?
*/
int
exynos4_l2cc_init(void)
{
const uint32_t tag_latency = 0x110;
const uint32_t data_latency = IS_EXYNOS4410_P() ? 0x110 : 0x120;
const uint32_t prefetch4412 = /* 0111 0001 0000 0000 0000 0000 0000 0111 */
PREFETCHCTL_DBLLINEF_EN |
PREFETCHCTL_INSTRPREF_EN |
PREFETCHCTL_DATAPREF_EN |
PREFETCHCTL_PREF_DROP_EN |
PREFETCHCTL_PREFETCH_OFFSET_7;
const uint32_t prefetch4412_r0 = /* 0011 0000 0000 0000 0000 0000 0000 0111 */
PREFETCHCTL_INSTRPREF_EN |
PREFETCHCTL_DATAPREF_EN |
PREFETCHCTL_PREFETCH_OFFSET_7;
const uint32_t aux_val = /* 0111 1100 0100 0111 0000 0000 0000 0001 */
AUXCTL_EARLY_BRESP_EN |
AUXCTL_I_PREFETCH |
AUXCTL_D_PREFETCH |
AUXCTL_NS_INT_ACC_CTL |
AUXCTL_NS_INT_LOCK_EN |
AUXCTL_SHARED_ATT_OVR |
AUXCTL_WAY_SIZE_RSVD7 << 16 | /* why rsvd7 ??? */
AUXCTL_FULL_LINE_WR0;
const uint32_t aux_keepmask = /* 1100 0010 0000 0000 1111 1111 1111 1111 */
AUXCTL_RSVD31 |
AUXCTL_EARLY_BRESP_EN |
AUXCTL_CACHE_REPL_RR |
AUXCTL_SH_ATTR_INV_ENA|
AUXCTL_EXCL_CACHE_CFG |
AUXCTL_ST_BUF_DEV_LIM_EN |
AUXCTL_HIPRO_SO_DEV_EN |
AUXCTL_FULL_LINE_WR0 |
0xffff;
uint32_t prefetch;
/* check the bitmaps are the same as the linux implementation uses */
KASSERT(prefetch4412 == 0x71000007);
KASSERT(prefetch4412_r0 == 0x30000007);
KASSERT(aux_val == 0x7C470001);
KASSERT(aux_keepmask == 0xC200FFFF);
if (IS_EXYNOS4412_R0_P())
prefetch = prefetch4412_r0;
else
prefetch = prefetch4412; /* newer than >= r1_0 */
;
exynos_smc(SMC_CMD_L2X0SETUP1, tag_latency, data_latency, prefetch);
exynos_smc(SMC_CMD_L2X0SETUP2,
POWERCTL_DYNCLKGATE | POWERCTL_STANDBY,
aux_val, aux_keepmask);
exynos_smc(SMC_CMD_L2X0INVALL, 0, 0, 0);
exynos_smc(SMC_CMD_L2X0CTRL, 1, 0, 0);
return 0;
}
#endif
#endif /* ARM_TRUSTZONE_FIRMWARE */
void
exynos_sysctl_cpufreq_init(void)
{
const struct sysctlnode *node, *cpunode, *freqnode;
char *cpos;
int i, val;
int error;
memset(sysctl_cpu_freqs_txt, (int) ' ', sizeof(sysctl_cpu_freqs_txt));
cpos = sysctl_cpu_freqs_txt;
for (i = 0; i < ncpu_freq_settings; i++) {
val = cpu_freq_settings[i].freq;
snprintf(cpos, 6, "%d ", val);
cpos += (val < 1000) ? 4 : 5;
}
*cpos = 0;
error = sysctl_createv(NULL, 0, NULL, &node,
CTLFLAG_PERMANENT, CTLTYPE_NODE, "machdep", NULL,
NULL, 0, NULL, 0, CTL_MACHDEP, CTL_EOL);
if (error)
printf("couldn't create `machdep' node\n");
error = sysctl_createv(NULL, 0, &node, &cpunode,
0, CTLTYPE_NODE, "cpu", NULL,
NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL);
if (error)
printf("couldn't create `cpu' node\n");
error = sysctl_createv(NULL, 0, &cpunode, &freqnode,
0, CTLTYPE_NODE, "frequency", NULL,
NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL);
if (error)
printf("couldn't create `frequency' node\n");
error = sysctl_createv(NULL, 0, &freqnode, &node,
CTLFLAG_READWRITE, CTLTYPE_INT, "target", NULL,
sysctl_cpufreq_target, 0, &cpu_freq_target, 0,
CTL_CREATE, CTL_EOL);
if (error)
printf("couldn't create `target' node\n");
error = sysctl_createv(NULL, 0, &freqnode, &node,
0, CTLTYPE_INT, "current", NULL,
sysctl_cpufreq_current, 0, NULL, 0,
CTL_CREATE, CTL_EOL);
if (error)
printf("couldn't create `current' node\n");
error = sysctl_createv(NULL, 0, &freqnode, &node,
CTLFLAG_READONLY, CTLTYPE_STRING, "available", NULL,
NULL, 0, sysctl_cpu_freqs_txt, 0,
CTL_CREATE, CTL_EOL);
if (error)
printf("couldn't create `available' node\b");
}
uint64_t
exynos_get_cpufreq(void)
{
uint32_t regval;
uint32_t freq;
regval = bus_space_read_4(&armv7_generic_bs_tag, exynos_cmu_apll_bsh,
PLL_CON0_OFFSET);
freq = PLL_FREQ(EXYNOS_F_IN_FREQ, regval);
return freq;
}
static void
exynos_set_cpufreq(const struct cpu_freq *freqreq)
{
struct cpu_info *ci;
uint32_t regval;
int M, P, S;
int cii;
M = freqreq->M;
P = freqreq->P;
S = freqreq->S;
regval = __SHIFTIN(M, PLL_CON0_M) |
__SHIFTIN(P, PLL_CON0_P) |
__SHIFTIN(S, PLL_CON0_S);
/* enable PPL and write config */
regval |= PLL_CON0_ENABLE;
bus_space_write_4(&armv7_generic_bs_tag, exynos_cmu_apll_bsh, PLL_CON0_OFFSET,
regval);
/* update our cycle counter i.e. our CPU frequency for all CPUs */
for (CPU_INFO_FOREACH(cii, ci)) {
ci->ci_data.cpu_cc_freq = exynos_get_cpufreq();
}
}
static int
sysctl_cpufreq_target(SYSCTLFN_ARGS)
{
struct sysctlnode node;
uint32_t t, curfreq, minfreq, maxfreq;
int i, best_i, diff;
int error;
curfreq = exynos_get_cpufreq() / (1000*1000);
t = *(int *)rnode->sysctl_data;
if (t == 0)
t = curfreq;
node = *rnode;
node.sysctl_data = &t;
error = sysctl_lookup(SYSCTLFN_CALL(&node));
if (error || newp == NULL)
return error;
minfreq = cpu_freq_settings[0].freq;
maxfreq = cpu_freq_settings[ncpu_freq_settings-1].freq;
if ((t < minfreq) || (t > maxfreq))
return EINVAL;
if (t == curfreq) {
*(int *)rnode->sysctl_data = t;
return 0;
}
diff = maxfreq;
best_i = -1;
for (i = 0; i < ncpu_freq_settings; i++) {
if (abs(t - cpu_freq_settings[i].freq) <= diff) {
diff = labs(t - cpu_freq_settings[i].freq);
best_i = i;
}
}
if (best_i < 0)
return EINVAL;
exynos_set_cpufreq(&cpu_freq_settings[best_i]);
*(int *)rnode->sysctl_data = t;
return 0;
}
static int
sysctl_cpufreq_current(SYSCTLFN_ARGS)
{
struct sysctlnode node = *rnode;
uint32_t freq;
freq = exynos_get_cpufreq() / (1000*1000);
node.sysctl_data = &freq;
return sysctl_lookup(SYSCTLFN_CALL(&node));
}
#ifdef VERBOSE_INIT_ARM
#define VPRINTF(...) printf(__VA_ARGS__)
#define DUMP_PLL(v, var) \
reg = EXYNOS##v##_CMU_##var + PLL_CON0_OFFSET;\
regval = bus_space_read_4(&armv7_generic_bs_tag, exynos_cmu_bsh, reg); \
freq = PLL_FREQ(EXYNOS_F_IN_FREQ, regval); \
printf("%8s at %d Mhz\n", #var, freq/(1000*1000));
static void
exynos_dump_clocks(void)
{
uint32_t reg = 0;
uint32_t regval;
uint32_t freq;
printf("Initial PLL settings\n");
#ifdef SOC_EXYNOS4
DUMP_PLL(4, APLL);
DUMP_PLL(4, MPLL);
DUMP_PLL(4, EPLL);
DUMP_PLL(4, VPLL);
#endif
#ifdef SOC_EXYNOS5
DUMP_PLL(5, APLL);
DUMP_PLL(5, MPLL);
DUMP_PLL(5, KPLL);
DUMP_PLL(5, DPLL);
DUMP_PLL(5, VPLL);
DUMP_PLL(5, CPLL);
DUMP_PLL(5, GPLL);
DUMP_PLL(5, BPLL);
#endif
}
#undef DUMP_PLL
#else
#define VPRINTF(...) __nothing
#endif
/* XXX clock stuff needs major work XXX */
void
exynos_init_clkout_for_usb(void)
{
/* Select XUSBXTI as source for CLKOUT */
bus_space_write_4(&armv7_generic_bs_tag, exynos_pmu_bsh,
EXYNOS_PMU_DEBUG_CLKOUT, 0x1000);
}
void
exynos_clocks_bootstrap(void)
{
KASSERT(ncpu_freq_settings != 0);
KASSERT(ncpu_freq_settings < NFRQS);
int fsel;
#ifdef VERBOSE_INIT_ARM
exynos_dump_clocks();
#endif
/* set (max) cpufreq */
fsel = ncpu_freq_settings-1;
#ifdef SOC_EXYNOS5
/* XXX BUGFIX selecting freq on E5 goes wrong for now XXX */
fsel = EXYNOS5_DEFAULT_ENTRY;
#endif
exynos_set_cpufreq(&cpu_freq_settings[fsel]);
/* set external USB frequency to XCLKOUT */
exynos_init_clkout_for_usb();
}
void
exynos_bootstrap(int soc)
{
int error;
size_t core_size, audiocore_size;
bus_addr_t audiocore_pbase;
bus_addr_t audiocore_vbase __diagused;
bus_addr_t exynos_wdt_offset;
bus_addr_t exynos_pmu_offset;
bus_addr_t exynos_sysreg_offset;
bus_addr_t exynos_cmu_apll_offset;
switch (soc) {
#ifdef SOC_EXYNOS4
case 4:
core_size = EXYNOS4_CORE_SIZE;
audiocore_size = EXYNOS4_AUDIOCORE_SIZE;
audiocore_pbase = EXYNOS4_AUDIOCORE_PBASE;
audiocore_vbase = EXYNOS4_AUDIOCORE_VBASE;
exynos_wdt_offset = EXYNOS4_WDT_OFFSET;
exynos_pmu_offset = EXYNOS4_PMU_OFFSET;
exynos_sysreg_offset = EXYNOS4_SYSREG_OFFSET;
exynos_cmu_apll_offset = EXYNOS4_CMU_APLL;
cpu_freq_settings = cpu_freq_settings_exynos4;
ncpu_freq_settings = __arraycount(cpu_freq_settings_exynos4);
break;
#endif
#ifdef SOC_EXYNOS5
case 5:
core_size = EXYNOS5_CORE_SIZE;
audiocore_size = EXYNOS5_AUDIOCORE_SIZE;
audiocore_pbase = EXYNOS5_AUDIOCORE_PBASE;
audiocore_vbase = EXYNOS5_AUDIOCORE_VBASE;
exynos_wdt_offset = EXYNOS5_WDT_OFFSET;
exynos_pmu_offset = EXYNOS5_PMU_OFFSET;
exynos_sysreg_offset = EXYNOS5_SYSREG_OFFSET;
exynos_cmu_apll_offset = EXYNOS5_CMU_APLL;
cpu_freq_settings = cpu_freq_settings_exynos5;
ncpu_freq_settings = __arraycount(cpu_freq_settings_exynos5);
break;
#endif
default:
panic("%s: unknown soc version", __func__);
}
/* map in the exynos io registers */
error = bus_space_map(&armv7_generic_bs_tag, EXYNOS_CORE_PBASE,
core_size, 0, &exynos_core_bsh);
if (error)
panic("%s: failed to map in Exynos SFR registers: %d",
__func__, error);
KASSERT(exynos_core_bsh == EXYNOS_CORE_VBASE);
error = bus_space_map(&armv7_generic_bs_tag, audiocore_pbase,
audiocore_size, 0, &exynos_audiocore_bsh);
if (error)
panic("%s: failed to map in Exynos audio SFR registers: %d",
__func__, error);
KASSERT(exynos_audiocore_bsh == audiocore_vbase);
/* map in commonly used subregions and common used register banks */
error = bus_space_subregion(&armv7_generic_bs_tag, exynos_core_bsh,
exynos_wdt_offset, EXYNOS_BLOCK_SIZE, &exynos_wdt_bsh);
if (error)
panic("%s: failed to subregion wdt registers: %d",
__func__, error);
error = bus_space_subregion(&armv7_generic_bs_tag, exynos_core_bsh,
exynos_pmu_offset, EXYNOS_BLOCK_SIZE, &exynos_pmu_bsh);
if (error)
panic("%s: failed to subregion pmu registers: %d",
__func__, error);
exynos_cmu_bsh = exynos_core_bsh;
bus_space_subregion(&armv7_generic_bs_tag, exynos_core_bsh,
exynos_sysreg_offset, EXYNOS_BLOCK_SIZE,
&exynos_sysreg_bsh);
if (error)
panic("%s: failed to subregion sysreg registers: %d",
__func__, error);
error = bus_space_subregion(&armv7_generic_bs_tag, exynos_cmu_bsh,
exynos_cmu_apll_offset, 0xfff, &exynos_cmu_apll_bsh);
if (error)
panic("%s: failed to subregion cmu apll registers: %d",
__func__, error);
/* gpio bootstrapping delayed */
}
void
exynos_device_register(device_t self, void *aux)
{
if (device_is_a(self, "armperiph")
&& device_is_a(device_parent(self), "mainbus")) {
/*
* XXX KLUDGE ALERT XXX
* The iot mainbus supplies is completely wrong since it scales
* addresses by 2. The simplest remedy is to replace with our
* bus space used for the armcore registers (which armperiph uses).
*/
struct mainbus_attach_args * const mb = aux;
mb->mb_iot = &armv7_generic_bs_tag;
return;
}
if (device_is_a(self, "armgic")
&& device_is_a(device_parent(self), "armperiph")) {
/*
* The Exynos4420 armgic is located at a different location!
*/
extern uint32_t exynos_soc_id;
switch (EXYNOS_PRODUCT_ID(exynos_soc_id)) {
#ifdef SOC_EXYNOS5
case 0xe5410:
/* offsets not changed on matt's request */
#if 0
mpcaa->mpcaa_memh = EXYNOS_CORE_VBASE;
mpcaa->mpcaa_off1 = EXYNOS5_GIC_IOP_DISTRIBUTOR_OFFSET;
mpcaa->mpcaa_off2 = EXYNOS5_GIC_IOP_CONTROLLER_OFFSET;
#endif
break;
case 0xe5422: {
struct mpcore_attach_args * const mpcaa = aux;
mpcaa->mpcaa_memh = EXYNOS_CORE_VBASE;
mpcaa->mpcaa_off1 = EXYNOS5_GIC_IOP_DISTRIBUTOR_OFFSET;
mpcaa->mpcaa_off2 = EXYNOS5_GIC_IOP_CONTROLLER_OFFSET;
break;
}
#endif
#ifdef SOC_EXYNOS4
case 0xe4410:
case 0xe4412: {
struct mpcore_attach_args * const mpcaa = aux;
mpcaa->mpcaa_memh = EXYNOS_CORE_VBASE;
mpcaa->mpcaa_off1 = EXYNOS4_GIC_DISTRIBUTOR_OFFSET;
mpcaa->mpcaa_off2 = EXYNOS4_GIC_CNTR_OFFSET;
break;
}
#endif
default:
panic("%s: unknown SoC product id %#x", __func__,
(u_int)EXYNOS_PRODUCT_ID(exynos_soc_id));
}
return;
}
if (device_is_a(self, "armgtmr") || device_is_a(self, "mct")) {
#ifdef SOC_EXYNOS5
/*
* The global timer is dependent on the MCT running.
*/
bus_size_t o = EXYNOS5_MCT_OFFSET + MCT_G_TCON;
uint32_t v = bus_space_read_4(&armv7_generic_bs_tag, exynos_core_bsh,
o);
v |= G_TCON_START;
bus_space_write_4(&armv7_generic_bs_tag, exynos_core_bsh, o, v);
#endif
/*
* The frequencies of the timers are the reference
* frequency.
*/
prop_dictionary_set_uint32(device_properties(self),
"frequency", EXYNOS_F_IN_FREQ);
return;
}
}
void
exynos_device_register_post_config(device_t self, void *aux)
{
}
void
exynos_usb_soc_powerup(void)
{
/* XXX 5422 XXX */
}
/*
* USB Phy SoC dependent handling
*/
/* XXX 5422 not handled since its unknown how it handles this XXX*/
static void
exynos_usb2_set_isolation(bool on)
{
uint32_t en_mask, regval;
bus_addr_t reg;
/* enable PHY */
reg = EXYNOS_PMU_USB_PHY_CTRL;
if (IS_EXYNOS5_P() || IS_EXYNOS4410_P()) {
/* set usbhost mode */
regval = on ? 0 : USB20_PHY_HOST_LINK_EN;
bus_space_write_4(&armv7_generic_bs_tag, exynos_sysreg_bsh,
EXYNOS5_SYSREG_USB20_PHY_TYPE, regval);
reg = EXYNOS_PMU_USBHOST_PHY_CTRL;
}
/* do enable PHY */
en_mask = PMU_PHY_ENABLE;
regval = bus_space_read_4(&armv7_generic_bs_tag, exynos_pmu_bsh, reg);
regval = on ? regval & ~en_mask : regval | en_mask;
bus_space_write_4(&armv7_generic_bs_tag, exynos_pmu_bsh,
reg, regval);
if (IS_EXYNOS4X12_P()) {
bus_space_write_4(&armv7_generic_bs_tag, exynos_pmu_bsh,
EXYNOS_PMU_USB_HSIC_1_PHY_CTRL, regval);
bus_space_write_4(&armv7_generic_bs_tag, exynos_pmu_bsh,
EXYNOS_PMU_USB_HSIC_2_PHY_CTRL, regval);
}
}
#ifdef SOC_EXYNOS4
static void
exynos4_usb2phy_enable(bus_space_handle_t usb2phy_bsh)
{
uint32_t phypwr, rstcon, clkreg;
/* write clock value */
clkreg = FSEL_CLKSEL_24M;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHYCLK, clkreg);
/* set device and host to normal */
phypwr = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHYPWR);
/* enable analog, enable otg, unsleep phy0 (host) */
phypwr &= ~PHYPWR_NORMAL_MASK_PHY0;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHYPWR, phypwr);
if (IS_EXYNOS4X12_P()) {
/* enable hsic0 (host), enable hsic1 and phy1 (otg) */
phypwr = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHYPWR);
phypwr &= ~(PHYPWR_NORMAL_MASK_HSIC0 |
PHYPWR_NORMAL_MASK_HSIC1 |
PHYPWR_NORMAL_MASK_PHY1);
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHYPWR, phypwr);
}
/* reset both phy and link of device */
rstcon = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_RSTCON);
rstcon |= RSTCON_DEVPHY_SWRST;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_RSTCON, rstcon);
DELAY(10000);
rstcon &= ~RSTCON_DEVPHY_SWRST;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_RSTCON, rstcon);
if (IS_EXYNOS4X12_P()) {
/* reset both phy and link of host */
rstcon = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_RSTCON);
rstcon |= RSTCON_HOSTPHY_SWRST | RSTCON_HOSTPHYLINK_SWRST;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_RSTCON, rstcon);
DELAY(10000);
rstcon &= ~(RSTCON_HOSTPHY_SWRST | RSTCON_HOSTPHYLINK_SWRST);
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_RSTCON, rstcon);
}
/* wait for everything to be initialized */
DELAY(80000);
}
#endif
#ifdef SOC_EXYNOS5
static void
exynos5410_usb2phy_enable(bus_space_handle_t usb2phy_bsh)
{
uint32_t phyhost; //, phyotg;
uint32_t phyhsic;
uint32_t ehcictrl, ohcictrl;
/* host configuration: */
phyhost = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_HOST_CTRL0);
/* host phy reference clock; assumption its 24 MHz now */
phyhost &= ~HOST_CTRL0_FSEL_MASK;
phyhost |= __SHIFTIN(FSEL_CLKSEL_24M, HOST_CTRL0_FSEL_MASK);
/* enable normal mode of operation */
phyhost &= ~(HOST_CTRL0_FORCESUSPEND | HOST_CTRL0_FORCESLEEP);
/* host phy reset */
phyhost &= ~(HOST_CTRL0_PHY_SWRST | HOST_CTRL0_PHY_SWRST_ALL |
HOST_CTRL0_SIDDQ | HOST_CTRL0_FORCESUSPEND |
HOST_CTRL0_FORCESLEEP);
/* host link reset */
phyhost |= HOST_CTRL0_LINK_SWRST | HOST_CTRL0_UTMI_SWRST |
HOST_CTRL0_COMMONON_N;
/* do the reset */
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh, USB_PHY_HOST_CTRL0,
phyhost);
DELAY(10000);
phyhost &= ~(HOST_CTRL0_LINK_SWRST | HOST_CTRL0_UTMI_SWRST);
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh, USB_PHY_HOST_CTRL0,
phyhost);
/* HSIC control */
phyhsic =
__SHIFTIN(HSIC_CTRL_REFCLKDIV_12, HSIC_CTRL_REFCLKDIV_MASK) |
__SHIFTIN(HSIC_CTRL_REFCLKSEL_DEFAULT, HSIC_CTRL_REFCLKSEL_MASK) |
HSIC_CTRL_PHY_SWRST;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh, USB_PHY_HSIC_CTRL1,
phyhsic);
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh, USB_PHY_HSIC_CTRL2,
phyhsic);
DELAY(10);
phyhsic &= ~HSIC_CTRL_PHY_SWRST;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh, USB_PHY_HSIC_CTRL1,
phyhsic);
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh, USB_PHY_HSIC_CTRL2,
phyhsic);
DELAY(80);
#if 0
/* otg configuration: */
phyotg = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_OTG_SYS);
/* otg phy reference clock: assumption its 24 Mhz now */
phyotg &= ~OTG_SYS_FSEL_MASK;
phyotg |= __SHIFTIN(OTG_SYS_FSEL_MASK, FSEL_CLKSEL_24M);
/* enable normal mode of operation */
phyotg &= ~(OTG_SYS_FORCESUSPEND | OTG_SYS_FORCESLEEP |
OTG_SYS_SIDDQ_UOTG | OTG_SYS_REFCLKSEL_MASK |
OTG_SYS_COMMON_ON);
/* OTG phy and link reset */
phyotg |= OTG_SYS_PHY0_SWRST | OTG_SYS_PHYLINK_SWRST |
OTG_SYS_OTGDISABLE | OTG_SYS_REFCLKSEL_MASK;
/* do the reset */
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_OTG_SYS, phyotg);
DELAY(10000);
phyotg &= ~(OTG_SYS_PHY0_SWRST | OTG_SYS_LINK_SWRST_UOTG |
OTG_SYS_PHYLINK_SWRST);
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_OTG_SYS, phyotg);
#endif
/* enable EHCI DMA burst: */
ehcictrl = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_HOST_EHCICTRL);
ehcictrl |= HOST_EHCICTRL_ENA_INCRXALIGN |
HOST_EHCICTRL_ENA_INCR4 | HOST_EHCICTRL_ENA_INCR8 |
HOST_EHCICTRL_ENA_INCR16;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_HOST_EHCICTRL, ehcictrl);
/* Set OHCI suspend */
ohcictrl = bus_space_read_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_HOST_OHCICTRL);
ohcictrl |= HOST_OHCICTRL_SUSPLGCY;
bus_space_write_4(&armv7_generic_bs_tag, usb2phy_bsh,
USB_PHY_HOST_OHCICTRL, ohcictrl);
}
static void
exynos5422_usb2phy_enable(bus_space_handle_t usb2phy_bsh)
{
aprint_error("%s not implemented\n", __func__);
}
#endif
void
exynos_usb_phy_init(bus_space_handle_t usb2phy_bsh)
{
/* disable phy isolation */
exynos_usb2_set_isolation(false);
#ifdef SOC_EXYNOS4
exynos4_usb2phy_enable(usb2phy_bsh);
#endif
#ifdef SOC_EXYNOS5
if (IS_EXYNOS5410_P()) {
exynos5410_usb2phy_enable(usb2phy_bsh);
/* TBD: USB3 phy init */
} else if (IS_EXYNOS5422_P()) {
exynos5422_usb2phy_enable(usb2phy_bsh);
/* TBD: USB3 phy init */
}
#endif
}