Merge remote-tracking branch 'u-boot/master' into test

[karo-tx-uboot.git] / board / freescale / qemu-ppce500 / qemu-ppce500.c

/*
 * Copyright 2007,2009-2014 Freescale Semiconductor, Inc.
 *
 * SPDX-License-Identifier:     GPL-2.0+
 */

#include <common.h>
#include <command.h>
#include <pci.h>
#include <asm/processor.h>
#include <asm/mmu.h>
#include <asm/fsl_pci.h>
#include <asm/io.h>
#include <libfdt.h>
#include <fdt_support.h>
#include <netdev.h>
#include <fdtdec.h>
#include <errno.h>
#include <malloc.h>

DECLARE_GLOBAL_DATA_PTR;

static void *get_fdt_virt(void)
{
        return (void *)CONFIG_SYS_TMPVIRT;
}

static uint64_t get_fdt_phys(void)
{
        return (uint64_t)(uintptr_t)gd->fdt_blob;
}

static void map_fdt_as(int esel)
{
        u32 mas0, mas1, mas2, mas3, mas7;
        uint64_t fdt_phys = get_fdt_phys();
        unsigned long fdt_phys_tlb = fdt_phys & ~0xffffful;
        unsigned long fdt_virt_tlb = (ulong)get_fdt_virt() & ~0xffffful;

        mas0 = MAS0_TLBSEL(1) | MAS0_ESEL(esel);
        mas1 = MAS1_VALID | MAS1_TID(0) | MAS1_TS | MAS1_TSIZE(BOOKE_PAGESZ_1M);
        mas2 = FSL_BOOKE_MAS2(fdt_virt_tlb, 0);
        mas3 = FSL_BOOKE_MAS3(fdt_phys_tlb, 0, MAS3_SW|MAS3_SR);
        mas7 = FSL_BOOKE_MAS7(fdt_phys_tlb);

        write_tlb(mas0, mas1, mas2, mas3, mas7);
}

uint64_t get_phys_ccsrbar_addr_early(void)
{
        void *fdt = get_fdt_virt();
        uint64_t r;

        /*
         * To be able to read the FDT we need to create a temporary TLB
         * map for it.
         */
        map_fdt_as(10);
        r = fdt_get_base_address(fdt, fdt_path_offset(fdt, "/soc"));
        disable_tlb(10);

        return r;
}

int board_early_init_f(void)
{
        return 0;
}

int checkboard(void)
{
        return 0;
}

static int pci_map_region(void *fdt, int pci_node, int range_id,
                          phys_size_t *ppaddr, pci_addr_t *pvaddr,
                          pci_size_t *psize, ulong *pmap_addr)
{
        uint64_t addr;
        uint64_t size;
        ulong map_addr;
        int r;

        r = fdt_read_range(fdt, pci_node, 0, NULL, &addr, &size);
        if (r)
                return r;

        if (ppaddr)
                *ppaddr = addr;
        if (psize)
                *psize = size;

        if (!pmap_addr)
                return 0;

        map_addr = *pmap_addr;

        /* Align map_addr */
        map_addr += size - 1;
        map_addr &= ~(size - 1);

        if (map_addr + size >= CONFIG_SYS_PCI_MAP_END)
                return -1;

        /* Map virtual memory for range */
        assert(!tlb_map_range(map_addr, addr, size, TLB_MAP_IO));
        *pmap_addr = map_addr + size;

        if (pvaddr)
                *pvaddr = map_addr;

        return 0;
}

void pci_init_board(void)
{
        struct pci_controller *pci_hoses;
        void *fdt = get_fdt_virt();
        int pci_node = -1;
        int pci_num = 0;
        int pci_count = 0;
        ulong map_addr;

        puts("\n");

        /* Start MMIO and PIO range maps above RAM */
        map_addr = CONFIG_SYS_PCI_MAP_START;

        /* Count and allocate PCI buses */
        pci_node = fdt_node_offset_by_prop_value(fdt, pci_node,
                        "device_type", "pci", 4);
        while (pci_node != -FDT_ERR_NOTFOUND) {
                pci_node = fdt_node_offset_by_prop_value(fdt, pci_node,
                                "device_type", "pci", 4);
                pci_count++;
        }

        if (pci_count) {
                pci_hoses = malloc(sizeof(struct pci_controller) * pci_count);
        } else {
                printf("PCI: disabled\n\n");
                return;
        }

        /* Spawn PCI buses based on device tree */
        pci_node = fdt_node_offset_by_prop_value(fdt, pci_node,
                        "device_type", "pci", 4);
        while (pci_node != -FDT_ERR_NOTFOUND) {
                struct fsl_pci_info pci_info = { };
                const fdt32_t *reg;
                int r;

                reg = fdt_getprop(fdt, pci_node, "reg", NULL);
                pci_info.regs = fdt_translate_address(fdt, pci_node, reg);

                /* Map MMIO range */
                r = pci_map_region(fdt, pci_node, 0, &pci_info.mem_phys, NULL,
                                   &pci_info.mem_size, &map_addr);
                if (r)
                        break;

                /* Map PIO range */
                r = pci_map_region(fdt, pci_node, 1, &pci_info.io_phys, NULL,
                                   &pci_info.io_size, &map_addr);
                if (r)
                        break;

                /*
                 * The PCI framework finds virtual addresses for the buses
                 * through our address map, so tell it the physical addresses.
                 */
                pci_info.mem_bus = pci_info.mem_phys;
                pci_info.io_bus = pci_info.io_phys;

                /* Instantiate */
                pci_info.pci_num = pci_num + 1;

                fsl_setup_hose(&pci_hoses[pci_num], pci_info.regs);
                printf("PCI: base address %lx\n", pci_info.regs);

                fsl_pci_init_port(&pci_info, &pci_hoses[pci_num], pci_num);

                /* Jump to next PCI node */
                pci_node = fdt_node_offset_by_prop_value(fdt, pci_node,
                                "device_type", "pci", 4);
                pci_num++;
        }

        puts("\n");
}

int last_stage_init(void)
{
        void *fdt = get_fdt_virt();
        int len = 0;
        const uint64_t *prop;
        int chosen;

        chosen = fdt_path_offset(fdt, "/chosen");
        if (chosen < 0) {
                printf("Couldn't find /chosen node in fdt\n");
                return -EIO;
        }

        /* -kernel boot */
        prop = fdt_getprop(fdt, chosen, "qemu,boot-kernel", &len);
        if (prop && (len >= 8))
                setenv_hex("qemu_kernel_addr", *prop);

        /* Give the user a variable for the host fdt */
        setenv_hex("fdt_addr_r", (ulong)fdt);

        return 0;
}

static uint64_t get_linear_ram_size(void)
{
        void *fdt = get_fdt_virt();
        const void *prop;
        int memory;
        int len;

        memory = fdt_path_offset(fdt, "/memory");
        prop = fdt_getprop(fdt, memory, "reg", &len);

        if (prop && len >= 16)
                return *(uint64_t *)(prop+8);

        panic("Couldn't determine RAM size");
}

int board_eth_init(bd_t *bis)
{
        return pci_eth_init(bis);
}

#if defined(CONFIG_OF_BOARD_SETUP)
void ft_board_setup(void *blob, bd_t *bd)
{
        FT_FSL_PCI_SETUP;
}
#endif

void print_laws(void)
{
        /* We don't emulate LAWs yet */
}

phys_size_t fixed_sdram(void)
{
        return get_linear_ram_size();
}

phys_size_t fsl_ddr_sdram_size(void)
{
        return get_linear_ram_size();
}

void init_tlbs(void)
{
        phys_size_t ram_size;

        /*
         * Create a temporary AS=1 map for the fdt
         *
         * We use ESEL=0 here to overwrite the previous AS=0 map for ourselves
         * which was only 4k big. This way we don't have to clear any other maps.
         */
        map_fdt_as(0);

        /* Fetch RAM size from the fdt */
        ram_size = get_linear_ram_size();

        /* And remove our fdt map again */
        disable_tlb(0);

        /* Create an internal map of manually created TLB maps */
        init_used_tlb_cams();

        /* Create a dynamic AS=0 CCSRBAR mapping */
        assert(!tlb_map_range(CONFIG_SYS_CCSRBAR, CONFIG_SYS_CCSRBAR_PHYS,
                              1024 * 1024, TLB_MAP_IO));

        /* Create a RAM map that spans all accessible RAM */
        setup_ddr_tlbs(ram_size >> 20);

        /* Create a map for the TLB */
        assert(!tlb_map_range((ulong)get_fdt_virt(), get_fdt_phys(),
                              1024 * 1024, TLB_MAP_RAM));
}

void init_laws(void)
{
        /* We don't emulate LAWs yet */
}

static uint32_t get_cpu_freq(void)
{
        void *fdt = get_fdt_virt();
        int cpus_node = fdt_path_offset(fdt, "/cpus");
        int cpu_node = fdt_first_subnode(fdt, cpus_node);
        const char *prop = "clock-frequency";
        return fdt_getprop_u32_default_node(fdt, cpu_node, 0, prop, 0);
}

void get_sys_info(sys_info_t *sys_info)
{
        int freq = get_cpu_freq();

        memset(sys_info, 0, sizeof(sys_info_t));
        sys_info->freq_systembus = freq;
        sys_info->freq_ddrbus = freq;
        sys_info->freq_processor[0] = freq;
}

int get_clocks (void)
{
        sys_info_t sys_info;

        get_sys_info(&sys_info);

        gd->cpu_clk = sys_info.freq_processor[0];
        gd->bus_clk = sys_info.freq_systembus;
        gd->mem_clk = sys_info.freq_ddrbus;
        gd->arch.lbc_clk = sys_info.freq_ddrbus;

        return 0;
}

unsigned long get_tbclk (void)
{
        void *fdt = get_fdt_virt();
        int cpus_node = fdt_path_offset(fdt, "/cpus");
        int cpu_node = fdt_first_subnode(fdt, cpus_node);
        const char *prop = "timebase-frequency";
        return fdt_getprop_u32_default_node(fdt, cpu_node, 0, prop, 0);
}

/********************************************
 * get_bus_freq
 * return system bus freq in Hz
 *********************************************/
ulong get_bus_freq (ulong dummy)
{
        sys_info_t sys_info;
        get_sys_info(&sys_info);
        return sys_info.freq_systembus;
}

/*
 * Return the number of cores on this SOC.
 */
int cpu_numcores(void)
{
        /*
         * The QEMU u-boot target only needs to drive the first core,
         * spinning and device tree nodes get driven by QEMU itself
         */
        return 1;
}

/*
 * Return a 32-bit mask indicating which cores are present on this SOC.
 */
u32 cpu_mask(void)
{
        return (1 << cpu_numcores()) - 1;
}