#include #include #include #include #include #include #include #include #include #include #include #include "chip.h" #include "cpu.h" #define RAM_BASE_KB (CONFIG_SYS_SDRAM_BASE >> 10) #define RAM_SIZE_KB (CONFIG_DRAM_SIZE_MB << 10UL) /* we distinguish a display port device from a raw graphics device * because there are dramatic differences in startup depending on * graphics usage. To make startup fast and easier to understand and * debug we explicitly name this common case. The alternate approach, * involving lots of machine and callbacks, is hard to debug and * verify. */ static void exynos_displayport_init(device_t dev) { int ret; struct cpu_samsung_exynos5250_config *conf = dev->chip_info; /* put these on the stack. If, at some point, we want to move * this code to a pre-ram stage, it will be much easier. */ vidinfo_t vi; struct exynos5_fimd_panel panel; unsigned long int fb_size; u32 lcdbase; memset(&vi, 0, sizeof(vi)); memset(&panel, 0, sizeof(panel)); panel.is_dp = 1; /* Display I/F is eDP */ /* while it is true that we did a memset to zero, * we leave some 'set to zero' entries here to make * it clear what's going on. Graphics is confusing. */ panel.is_mipi = 0; panel.fixvclk = 0; panel.ivclk = 0; panel.clkval_f = conf->clkval_f; panel.upper_margin = conf->upper_margin; panel.lower_margin = conf->lower_margin; panel.vsync = conf->vsync; panel.left_margin = conf->left_margin; panel.right_margin = conf->right_margin; panel.hsync = conf->hsync; panel.xres = conf->xres; panel.yres = conf->yres; vi.vl_col = conf->xres; vi.vl_row = conf->yres; vi.vl_bpix = conf->bpp; /* * The size is a magic number from hardware. Allocate enough for the * frame buffer and color map. */ fb_size = conf->xres * conf->yres * (conf->bpp / 8); lcdbase = (uintptr_t)cbmem_add(CBMEM_ID_CONSOLE, fb_size + 64*KiB); printk(BIOS_SPEW, "lcd colormap base is %p\n", (void *)(lcdbase)); mmio_resource(dev, 0, lcdbase/KiB, 64); vi.cmap = (void *)lcdbase; /* * We need to clean and invalidate the framebuffer region and disable * caching as well. We assume that our dcache <--> memory address * space is identity-mapped in 1MB chunks, so align accordingly. * * Note: We may want to do something clever to ensure the framebuffer * region is aligned such that we don't change dcache policy for other * stuff inadvertantly. * * FIXME: Is disabling/re-enabling the MMU entirely necessary? */ uint32_t lower = ALIGN_DOWN(lcdbase, MiB); uint32_t upper = ALIGN_UP(lcdbase + fb_size + 64*KiB, MiB); dcache_clean_invalidate_by_mva(lower, upper - lower); dcache_mmu_disable(); mmu_config_range(lower/MiB, (upper - lower)/MiB, DCACHE_OFF); dcache_mmu_enable(); lcdbase += 64*KiB; mmio_resource(dev, 1, lcdbase/KiB, (fb_size + KiB - 1)/KiB); printk(BIOS_DEBUG, "Initializing exynos VGA, base %p\n", (void *)lcdbase); memset((void *)lcdbase, 0, fb_size); /* clear the framebuffer */ ret = lcd_ctrl_init(&vi, &panel, (void *)lcdbase); } static void cpu_init(device_t dev) { exynos_displayport_init(dev); ram_resource(dev, 0, RAM_BASE_KB, RAM_SIZE_KB); arch_cpu_init(); } static void cpu_noop(device_t dev) { } static struct device_operations cpu_ops = { .read_resources = cpu_noop, .set_resources = cpu_noop, .enable_resources = cpu_init, .init = cpu_noop, .scan_bus = 0, }; static void enable_exynos5250_dev(device_t dev) { dev->ops = &cpu_ops; } struct chip_operations cpu_samsung_exynos5250_ops = { CHIP_NAME("CPU Samsung Exynos 5250") .enable_dev = enable_exynos5250_dev, }; void exynos5250_config_l2_cache(void) { uint32_t val; /* * Bit 9 - L2 tag RAM setup (1 cycle) * Bits 8:6 - L2 tag RAM latency (3 cycles) * Bit 5 - L2 data RAM setup (1 cycle) * Bits 2:0 - L2 data RAM latency (3 cycles) */ val = (1 << 9) | (0x2 << 6) | (1 << 5) | (0x2); write_l2ctlr(val); }