u-boot/arch/arm/mach-omap2/omap3/sys_info.c

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// SPDX-License-Identifier: GPL-2.0+
/*
* (C) Copyright 2008
* Texas Instruments, <www.ti.com>
*
* Author :
* Manikandan Pillai <mani.pillai@ti.com>
*
* Derived from Beagle Board and 3430 SDP code by
* Richard Woodruff <r-woodruff2@ti.com>
* Syed Mohammed Khasim <khasim@ti.com>
*/
#include <common.h>
#include <asm/io.h>
#include <asm/arch/mem.h> /* get mem tables */
#include <asm/arch/sys_proto.h>
#include <asm/bootm.h>
#include <asm/omap_common.h>
#include <i2c.h>
#include <linux/compiler.h>
extern omap3_sysinfo sysinfo;
static struct ctrl *ctrl_base = (struct ctrl *)OMAP34XX_CTRL_BASE;
#ifdef CONFIG_DISPLAY_CPUINFO
static char *rev_s[CPU_3XX_MAX_REV] = {
"1.0",
"2.0",
"2.1",
"3.0",
"3.1",
"UNKNOWN",
"UNKNOWN",
"3.1.2"};
/* this is the revision table for 37xx CPUs */
static char *rev_s_37xx[CPU_37XX_MAX_REV] = {
"1.0",
"1.1",
"1.2"};
#endif /* CONFIG_DISPLAY_CPUINFO */
void omap_die_id(unsigned int *die_id)
{
struct ctrl_id *id_base = (struct ctrl_id *)OMAP34XX_ID_L4_IO_BASE;
die_id[0] = readl(&id_base->die_id_0);
die_id[1] = readl(&id_base->die_id_1);
die_id[2] = readl(&id_base->die_id_2);
die_id[3] = readl(&id_base->die_id_3);
}
/******************************************
* get_cpu_type(void) - extract cpu info
******************************************/
u32 get_cpu_type(void)
{
return readl(&ctrl_base->ctrl_omap_stat);
}
/******************************************
* get_cpu_id(void) - extract cpu id
* returns 0 for ES1.0, cpuid otherwise
******************************************/
u32 get_cpu_id(void)
{
struct ctrl_id *id_base;
u32 cpuid = 0;
/*
* On ES1.0 the IDCODE register is not exposed on L4
* so using CPU ID to differentiate between ES1.0 and > ES1.0.
*/
__asm__ __volatile__("mrc p15, 0, %0, c0, c0, 0":"=r"(cpuid));
if ((cpuid & 0xf) == 0x0) {
return 0;
} else {
/* Decode the IDs on > ES1.0 */
id_base = (struct ctrl_id *) OMAP34XX_ID_L4_IO_BASE;
cpuid = readl(&id_base->idcode);
}
return cpuid;
}
/******************************************
* get_cpu_family(void) - extract cpu info
******************************************/
u32 get_cpu_family(void)
{
u16 hawkeye;
u32 cpu_family;
u32 cpuid = get_cpu_id();
if (cpuid == 0)
return CPU_OMAP34XX;
hawkeye = (cpuid >> HAWKEYE_SHIFT) & 0xffff;
switch (hawkeye) {
case HAWKEYE_OMAP34XX:
cpu_family = CPU_OMAP34XX;
break;
case HAWKEYE_AM35XX:
cpu_family = CPU_AM35XX;
break;
case HAWKEYE_OMAP36XX:
cpu_family = CPU_OMAP36XX;
break;
default:
cpu_family = CPU_OMAP34XX;
}
return cpu_family;
}
/******************************************
* get_cpu_rev(void) - extract version info
******************************************/
u32 get_cpu_rev(void)
{
u32 cpuid = get_cpu_id();
if (cpuid == 0)
return CPU_3XX_ES10;
else
return (cpuid >> CPU_3XX_ID_SHIFT) & 0xf;
}
/*****************************************************************
* get_sku_id(void) - read sku_id to get info on max clock rate
*****************************************************************/
u32 get_sku_id(void)
{
struct ctrl_id *id_base = (struct ctrl_id *)OMAP34XX_ID_L4_IO_BASE;
return readl(&id_base->sku_id) & SKUID_CLK_MASK;
}
/***************************************************************************
* get_gpmc0_base() - Return current address hardware will be
* fetching from. The below effectively gives what is correct, its a bit
* mis-leading compared to the TRM. For the most general case the mask
* needs to be also taken into account this does work in practice.
* - for u-boot we currently map:
* -- 0 to nothing,
* -- 4 to flash
* -- 8 to enent
* -- c to wifi
****************************************************************************/
u32 get_gpmc0_base(void)
{
u32 b;
b = readl(&gpmc_cfg->cs[0].config7);
b &= 0x1F; /* keep base [5:0] */
b = b << 24; /* ret 0x0b000000 */
return b;
}
/*******************************************************************
* get_gpmc0_width() - See if bus is in x8 or x16 (mainly for nand)
*******************************************************************/
u32 get_gpmc0_width(void)
{
return WIDTH_16BIT;
}
/*************************************************************************
* get_board_rev() - setup to pass kernel board revision information
* returns:(bit[0-3] sub version, higher bit[7-4] is higher version)
*************************************************************************/
#ifdef CONFIG_REVISION_TAG
u32 __weak get_board_rev(void)
{
return 0x20;
}
#endif
/********************************************************
* get_base(); get upper addr of current execution
*******************************************************/
static u32 get_base(void)
{
u32 val;
__asm__ __volatile__("mov %0, pc \n":"=r"(val)::"memory");
val &= 0xF0000000;
val >>= 28;
return val;
}
/********************************************************
* is_running_in_flash() - tell if currently running in
* FLASH.
*******************************************************/
u32 is_running_in_flash(void)
{
if (get_base() < 4)
return 1; /* in FLASH */
return 0; /* running in SRAM or SDRAM */
}
/********************************************************
* is_running_in_sram() - tell if currently running in
* SRAM.
*******************************************************/
u32 is_running_in_sram(void)
{
if (get_base() == 4)
return 1; /* in SRAM */
return 0; /* running in FLASH or SDRAM */
}
/********************************************************
* is_running_in_sdram() - tell if currently running in
* SDRAM.
*******************************************************/
u32 is_running_in_sdram(void)
{
if (get_base() > 4)
return 1; /* in SDRAM */
return 0; /* running in SRAM or FLASH */
}
/***************************************************************
* get_boot_type() - Is this an XIP type device or a stream one
* bits 4-0 specify type. Bit 5 says mem/perif
***************************************************************/
u32 get_boot_type(void)
{
return (readl(&ctrl_base->status) & SYSBOOT_MASK);
}
#ifdef CONFIG_DISPLAY_CPUINFO
/**
* Print CPU information
*/
int print_cpuinfo (void)
{
char *cpu_family_s, *cpu_s, *sec_s, *max_clk;
switch (get_cpu_family()) {
case CPU_OMAP34XX:
cpu_family_s = "OMAP";
switch (get_cpu_type()) {
case OMAP3503:
cpu_s = "3503";
break;
case OMAP3515:
cpu_s = "3515";
break;
case OMAP3525:
cpu_s = "3525";
break;
case OMAP3530:
cpu_s = "3530";
break;
default:
cpu_s = "35XX";
break;
}
if ((get_cpu_rev() >= CPU_3XX_ES31) &&
(get_sku_id() == SKUID_CLK_720MHZ))
max_clk = "720 MHz";
else
max_clk = "600 MHz";
break;
case CPU_AM35XX:
cpu_family_s = "AM";
switch (get_cpu_type()) {
case AM3505:
cpu_s = "3505";
break;
case AM3517:
cpu_s = "3517";
break;
default:
cpu_s = "35XX";
break;
}
max_clk = "600 MHz";
break;
case CPU_OMAP36XX:
switch (get_cpu_type()) {
case AM3703:
cpu_family_s = "AM";
cpu_s = "3703";
max_clk = "800 MHz";
break;
case AM3703_1GHZ:
cpu_family_s = "AM";
cpu_s = "3703";
max_clk = "1 GHz";
break;
case AM3715:
cpu_family_s = "AM";
cpu_s = "3715";
max_clk = "800 MHz";
break;
case AM3715_1GHZ:
cpu_family_s = "AM";
cpu_s = "3715";
max_clk = "1 GHz";
break;
case OMAP3725:
cpu_family_s = "OMAP";
cpu_s = "3625/3725";
max_clk = "800 MHz";
break;
case OMAP3725_1GHZ:
cpu_family_s = "OMAP";
cpu_s = "3625/3725";
max_clk = "1 GHz";
break;
case OMAP3730:
cpu_family_s = "OMAP";
cpu_s = "3630/3730";
max_clk = "800 MHz";
break;
case OMAP3730_1GHZ:
cpu_family_s = "OMAP";
cpu_s = "3630/3730";
max_clk = "1 GHz";
break;
default:
cpu_family_s = "OMAP/AM";
cpu_s = "36XX/37XX";
max_clk = "1 GHz";
break;
}
break;
default:
cpu_family_s = "OMAP";
cpu_s = "35XX";
max_clk = "600 MHz";
}
switch (get_device_type()) {
case TST_DEVICE:
sec_s = "TST";
break;
case EMU_DEVICE:
sec_s = "EMU";
break;
case HS_DEVICE:
sec_s = "HS";
break;
case GP_DEVICE:
sec_s = "GP";
break;
default:
sec_s = "?";
}
if (CPU_OMAP36XX == get_cpu_family())
printf("%s%s-%s ES%s, CPU-OPP2, L3-200MHz, Max CPU Clock %s\n",
cpu_family_s, cpu_s, sec_s,
rev_s_37xx[get_cpu_rev()], max_clk);
else
printf("%s%s-%s ES%s, CPU-OPP2, L3-165MHz, Max CPU Clock %s\n",
cpu_family_s, cpu_s, sec_s,
rev_s[get_cpu_rev()], max_clk);
return 0;
}
#endif /* CONFIG_DISPLAY_CPUINFO */