/* * P1022DS board specific routines * * Authors: Travis Wheatley * Dave Liu * Timur Tabi * * Copyright 2010 Freescale Semiconductor, Inc. * * This file is taken from the Freescale P1022DS BSP, with modifications: * 2) No AMP support * 3) No PCI endpoint support * * This file is licensed under the terms of the GNU General Public License * version 2. This program is licensed "as is" without any warranty of any * kind, whether express or implied. */ #include #include #include #include #include #include #include #include #include #include #include "smp.h" #include "mpc85xx.h" #if defined(CONFIG_FB_FSL_DIU) || defined(CONFIG_FB_FSL_DIU_MODULE) #define PMUXCR_ELBCDIU_MASK 0xc0000000 #define PMUXCR_ELBCDIU_NOR16 0x80000000 #define PMUXCR_ELBCDIU_DIU 0x40000000 /* * Board-specific initialization of the DIU. This code should probably be * executed when the DIU is opened, rather than in arch code, but the DIU * driver does not have a mechanism for this (yet). * * This is especially problematic on the P1022DS because the local bus (eLBC) * and the DIU video signals share the same pins, which means that enabling the * DIU will disable access to NOR flash. */ /* DIU Pixel Clock bits of the CLKDVDR Global Utilities register */ #define CLKDVDR_PXCKEN 0x80000000 #define CLKDVDR_PXCKINV 0x10000000 #define CLKDVDR_PXCKDLY 0x06000000 #define CLKDVDR_PXCLK_MASK 0x00FF0000 /* Some ngPIXIS register definitions */ #define PX_CTL 3 #define PX_BRDCFG0 8 #define PX_BRDCFG1 9 #define PX_BRDCFG0_ELBC_SPI_MASK 0xc0 #define PX_BRDCFG0_ELBC_SPI_ELBC 0x00 #define PX_BRDCFG0_ELBC_SPI_NULL 0xc0 #define PX_BRDCFG0_ELBC_DIU 0x02 #define PX_BRDCFG1_DVIEN 0x80 #define PX_BRDCFG1_DFPEN 0x40 #define PX_BRDCFG1_BACKLIGHT 0x20 #define PX_BRDCFG1_DDCEN 0x10 #define PX_CTL_ALTACC 0x80 /* * DIU Area Descriptor * * Note that we need to byte-swap the value before it's written to the AD * register. So even though the registers don't look like they're in the same * bit positions as they are on the MPC8610, the same value is written to the * AD register on the MPC8610 and on the P1022. */ #define AD_BYTE_F 0x10000000 #define AD_ALPHA_C_MASK 0x0E000000 #define AD_ALPHA_C_SHIFT 25 #define AD_BLUE_C_MASK 0x01800000 #define AD_BLUE_C_SHIFT 23 #define AD_GREEN_C_MASK 0x00600000 #define AD_GREEN_C_SHIFT 21 #define AD_RED_C_MASK 0x00180000 #define AD_RED_C_SHIFT 19 #define AD_PALETTE 0x00040000 #define AD_PIXEL_S_MASK 0x00030000 #define AD_PIXEL_S_SHIFT 16 #define AD_COMP_3_MASK 0x0000F000 #define AD_COMP_3_SHIFT 12 #define AD_COMP_2_MASK 0x00000F00 #define AD_COMP_2_SHIFT 8 #define AD_COMP_1_MASK 0x000000F0 #define AD_COMP_1_SHIFT 4 #define AD_COMP_0_MASK 0x0000000F #define AD_COMP_0_SHIFT 0 #define MAKE_AD(alpha, red, blue, green, size, c0, c1, c2, c3) \ cpu_to_le32(AD_BYTE_F | (alpha << AD_ALPHA_C_SHIFT) | \ (blue << AD_BLUE_C_SHIFT) | (green << AD_GREEN_C_SHIFT) | \ (red << AD_RED_C_SHIFT) | (c3 << AD_COMP_3_SHIFT) | \ (c2 << AD_COMP_2_SHIFT) | (c1 << AD_COMP_1_SHIFT) | \ (c0 << AD_COMP_0_SHIFT) | (size << AD_PIXEL_S_SHIFT)) struct fsl_law { u32 lawbar; u32 reserved1; u32 lawar; u32 reserved[5]; }; #define LAWBAR_MASK 0x00F00000 #define LAWBAR_SHIFT 12 #define LAWAR_EN 0x80000000 #define LAWAR_TGT_MASK 0x01F00000 #define LAW_TRGT_IF_LBC (0x04 << 20) #define LAWAR_MASK (LAWAR_EN | LAWAR_TGT_MASK) #define LAWAR_MATCH (LAWAR_EN | LAW_TRGT_IF_LBC) #define BR_BA 0xFFFF8000 /* * Map a BRx value to a physical address * * The localbus BRx registers only store the lower 32 bits of the address. To * obtain the upper four bits, we need to scan the LAW table. The entry which * maps to the localbus will contain the upper four bits. */ static phys_addr_t lbc_br_to_phys(const void *ecm, unsigned int count, u32 br) { #ifndef CONFIG_PHYS_64BIT /* * If we only have 32-bit addressing, then the BRx address *is* the * physical address. */ return br & BR_BA; #else const struct fsl_law *law = ecm + 0xc08; unsigned int i; for (i = 0; i < count; i++) { u64 lawbar = in_be32(&law[i].lawbar); u32 lawar = in_be32(&law[i].lawar); if ((lawar & LAWAR_MASK) == LAWAR_MATCH) /* Extract the upper four bits */ return (br & BR_BA) | ((lawbar & LAWBAR_MASK) << 12); } return 0; #endif } /** * p1022ds_set_monitor_port: switch the output to a different monitor port */ static void p1022ds_set_monitor_port(enum fsl_diu_monitor_port port) { struct device_node *guts_node; struct device_node *lbc_node = NULL; struct device_node *law_node = NULL; struct ccsr_guts __iomem *guts; struct fsl_lbc_regs *lbc = NULL; void *ecm = NULL; u8 __iomem *lbc_lcs0_ba = NULL; u8 __iomem *lbc_lcs1_ba = NULL; phys_addr_t cs0_addr, cs1_addr; u32 br0, or0, br1, or1; const __be32 *iprop; unsigned int num_laws; u8 b; /* Map the global utilities registers. */ guts_node = of_find_compatible_node(NULL, NULL, "fsl,p1022-guts"); if (!guts_node) { pr_err("p1022ds: missing global utilities device node\n"); return; } guts = of_iomap(guts_node, 0); if (!guts) { pr_err("p1022ds: could not map global utilities device\n"); goto exit; } lbc_node = of_find_compatible_node(NULL, NULL, "fsl,p1022-elbc"); if (!lbc_node) { pr_err("p1022ds: missing localbus node\n"); goto exit; } lbc = of_iomap(lbc_node, 0); if (!lbc) { pr_err("p1022ds: could not map localbus node\n"); goto exit; } law_node = of_find_compatible_node(NULL, NULL, "fsl,ecm-law"); if (!law_node) { pr_err("p1022ds: missing local access window node\n"); goto exit; } ecm = of_iomap(law_node, 0); if (!ecm) { pr_err("p1022ds: could not map local access window node\n"); goto exit; } iprop = of_get_property(law_node, "fsl,num-laws", NULL); if (!iprop) { pr_err("p1022ds: LAW node is missing fsl,num-laws property\n"); goto exit; } num_laws = be32_to_cpup(iprop); /* * Indirect mode requires both BR0 and BR1 to be set to "GPCM", * otherwise writes to these addresses won't actually appear on the * local bus, and so the PIXIS won't see them. * * In FCM mode, writes go to the NAND controller, which does not pass * them to the localbus directly. So we force BR0 and BR1 into GPCM * mode, since we don't care about what's behind the localbus any * more. */ br0 = in_be32(&lbc->bank[0].br); br1 = in_be32(&lbc->bank[1].br); or0 = in_be32(&lbc->bank[0].or); or1 = in_be32(&lbc->bank[1].or); /* Make sure CS0 and CS1 are programmed */ if (!(br0 & BR_V) || !(br1 & BR_V)) { pr_err("p1022ds: CS0 and/or CS1 is not programmed\n"); goto exit; } /* * Use the existing BRx/ORx values if it's already GPCM. Otherwise, * force the values to simple 32KB GPCM windows with the most * conservative timing. */ if ((br0 & BR_MSEL) != BR_MS_GPCM) { br0 = (br0 & BR_BA) | BR_V; or0 = 0xFFFF8000 | 0xFF7; out_be32(&lbc->bank[0].br, br0); out_be32(&lbc->bank[0].or, or0); } if ((br1 & BR_MSEL) != BR_MS_GPCM) { br1 = (br1 & BR_BA) | BR_V; or1 = 0xFFFF8000 | 0xFF7; out_be32(&lbc->bank[1].br, br1); out_be32(&lbc->bank[1].or, or1); } cs0_addr = lbc_br_to_phys(ecm, num_laws, br0); if (!cs0_addr) { pr_err("p1022ds: could not determine physical address for CS0" " (BR0=%08x)\n", br0); goto exit; } cs1_addr = lbc_br_to_phys(ecm, num_laws, br1); if (!cs1_addr) { pr_err("p1022ds: could not determine physical address for CS1" " (BR1=%08x)\n", br1); goto exit; } lbc_lcs0_ba = ioremap(cs0_addr, 1); if (!lbc_lcs0_ba) { pr_err("p1022ds: could not ioremap CS0 address %llx\n", (unsigned long long)cs0_addr); goto exit; } lbc_lcs1_ba = ioremap(cs1_addr, 1); if (!lbc_lcs1_ba) { pr_err("p1022ds: could not ioremap CS1 address %llx\n", (unsigned long long)cs1_addr); goto exit; } /* Make sure we're in indirect mode first. */ if ((in_be32(&guts->pmuxcr) & PMUXCR_ELBCDIU_MASK) != PMUXCR_ELBCDIU_DIU) { struct device_node *pixis_node; void __iomem *pixis; pixis_node = of_find_compatible_node(NULL, NULL, "fsl,p1022ds-fpga"); if (!pixis_node) { pr_err("p1022ds: missing pixis node\n"); goto exit; } pixis = of_iomap(pixis_node, 0); of_node_put(pixis_node); if (!pixis) { pr_err("p1022ds: could not map pixis registers\n"); goto exit; } /* Enable indirect PIXIS mode. */ setbits8(pixis + PX_CTL, PX_CTL_ALTACC); iounmap(pixis); /* Switch the board mux to the DIU */ out_8(lbc_lcs0_ba, PX_BRDCFG0); /* BRDCFG0 */ b = in_8(lbc_lcs1_ba); b |= PX_BRDCFG0_ELBC_DIU; out_8(lbc_lcs1_ba, b); /* Set the chip mux to DIU mode. */ clrsetbits_be32(&guts->pmuxcr, PMUXCR_ELBCDIU_MASK, PMUXCR_ELBCDIU_DIU); in_be32(&guts->pmuxcr); } switch (port) { case FSL_DIU_PORT_DVI: /* Enable the DVI port, disable the DFP and the backlight */ out_8(lbc_lcs0_ba, PX_BRDCFG1); b = in_8(lbc_lcs1_ba); b &= ~(PX_BRDCFG1_DFPEN | PX_BRDCFG1_BACKLIGHT); b |= PX_BRDCFG1_DVIEN; out_8(lbc_lcs1_ba, b); break; case FSL_DIU_PORT_LVDS: /* * LVDS also needs backlight enabled, otherwise the display * will be blank. */ /* Enable the DFP port, disable the DVI and the backlight */ out_8(lbc_lcs0_ba, PX_BRDCFG1); b = in_8(lbc_lcs1_ba); b &= ~PX_BRDCFG1_DVIEN; b |= PX_BRDCFG1_DFPEN | PX_BRDCFG1_BACKLIGHT; out_8(lbc_lcs1_ba, b); break; default: pr_err("p1022ds: unsupported monitor port %i\n", port); } exit: if (lbc_lcs1_ba) iounmap(lbc_lcs1_ba); if (lbc_lcs0_ba) iounmap(lbc_lcs0_ba); if (lbc) iounmap(lbc); if (ecm) iounmap(ecm); if (guts) iounmap(guts); of_node_put(law_node); of_node_put(lbc_node); of_node_put(guts_node); } /** * p1022ds_set_pixel_clock: program the DIU's clock * * @pixclock: the wavelength, in picoseconds, of the clock */ void p1022ds_set_pixel_clock(unsigned int pixclock) { struct device_node *guts_np = NULL; struct ccsr_guts __iomem *guts; unsigned long freq; u64 temp; u32 pxclk; /* Map the global utilities registers. */ guts_np = of_find_compatible_node(NULL, NULL, "fsl,p1022-guts"); if (!guts_np) { pr_err("p1022ds: missing global utilities device node\n"); return; } guts = of_iomap(guts_np, 0); of_node_put(guts_np); if (!guts) { pr_err("p1022ds: could not map global utilities device\n"); return; } /* Convert pixclock from a wavelength to a frequency */ temp = 1000000000000ULL; do_div(temp, pixclock); freq = temp; /* * 'pxclk' is the ratio of the platform clock to the pixel clock. * This number is programmed into the CLKDVDR register, and the valid * range of values is 2-255. */ pxclk = DIV_ROUND_CLOSEST(fsl_get_sys_freq(), freq); pxclk = clamp_t(u32, pxclk, 2, 255); /* Disable the pixel clock, and set it to non-inverted and no delay */ clrbits32(&guts->clkdvdr, CLKDVDR_PXCKEN | CLKDVDR_PXCKDLY | CLKDVDR_PXCLK_MASK); /* Enable the clock and set the pxclk */ setbits32(&guts->clkdvdr, CLKDVDR_PXCKEN | (pxclk << 16)); iounmap(guts); } /** * p1022ds_valid_monitor_port: set the monitor port for sysfs */ enum fsl_diu_monitor_port p1022ds_valid_monitor_port(enum fsl_diu_monitor_port port) { switch (port) { case FSL_DIU_PORT_DVI: case FSL_DIU_PORT_LVDS: return port; default: return FSL_DIU_PORT_DVI; /* Dual-link LVDS is not supported */ } } #endif void __init p1022_ds_pic_init(void) { struct mpic *mpic = mpic_alloc(NULL, 0, MPIC_BIG_ENDIAN | MPIC_SINGLE_DEST_CPU, 0, 256, " OpenPIC "); BUG_ON(mpic == NULL); mpic_init(mpic); } #if defined(CONFIG_FB_FSL_DIU) || defined(CONFIG_FB_FSL_DIU_MODULE) /* TRUE if there is a "video=fslfb" command-line parameter. */ static bool fslfb; /* * Search for a "video=fslfb" command-line parameter, and set 'fslfb' to * true if we find it. * * We need to use early_param() instead of __setup() because the normal * __setup() gets called to late. However, early_param() gets called very * early, before the device tree is unflattened, so all we can do now is set a * global variable. Later on, p1022_ds_setup_arch() will use that variable * to determine if we need to update the device tree. */ static int __init early_video_setup(char *options) { fslfb = (strncmp(options, "fslfb:", 6) == 0); return 0; } early_param("video", early_video_setup); #endif /* * Setup the architecture */ static void __init p1022_ds_setup_arch(void) { if (ppc_md.progress) ppc_md.progress("p1022_ds_setup_arch()", 0); #if defined(CONFIG_FB_FSL_DIU) || defined(CONFIG_FB_FSL_DIU_MODULE) diu_ops.set_monitor_port = p1022ds_set_monitor_port; diu_ops.set_pixel_clock = p1022ds_set_pixel_clock; diu_ops.valid_monitor_port = p1022ds_valid_monitor_port; /* * Disable the NOR and NAND flash nodes if there is video=fslfb... * command-line parameter. When the DIU is active, the localbus is * unavailable, so we have to disable these nodes before the MTD * driver loads. */ if (fslfb) { struct device_node *np = of_find_compatible_node(NULL, NULL, "fsl,p1022-elbc"); if (np) { struct device_node *np2; of_node_get(np); np2 = of_find_compatible_node(np, NULL, "cfi-flash"); if (np2) { static struct property nor_status = { .name = "status", .value = "disabled", .length = sizeof("disabled"), }; /* * of_update_property() is called before * kmalloc() is available, so the 'new' object * should be allocated in the global area. * The easiest way is to do that is to * allocate one static local variable for each * call to this function. */ pr_info("p1022ds: disabling %s node", np2->full_name); of_update_property(np2, &nor_status); of_node_put(np2); } of_node_get(np); np2 = of_find_compatible_node(np, NULL, "fsl,elbc-fcm-nand"); if (np2) { static struct property nand_status = { .name = "status", .value = "disabled", .length = sizeof("disabled"), }; pr_info("p1022ds: disabling %s node", np2->full_name); of_update_property(np2, &nand_status); of_node_put(np2); } of_node_put(np); } } #endif mpc85xx_smp_init(); fsl_pci_assign_primary(); swiotlb_detect_4g(); pr_info("Freescale P1022 DS reference board\n"); } machine_arch_initcall(p1022_ds, mpc85xx_common_publish_devices); machine_arch_initcall(p1022_ds, swiotlb_setup_bus_notifier); /* * Called very early, device-tree isn't unflattened */ static int __init p1022_ds_probe(void) { unsigned long root = of_get_flat_dt_root(); return of_flat_dt_is_compatible(root, "fsl,p1022ds"); } define_machine(p1022_ds) { .name = "P1022 DS", .probe = p1022_ds_probe, .setup_arch = p1022_ds_setup_arch, .init_IRQ = p1022_ds_pic_init, #ifdef CONFIG_PCI .pcibios_fixup_bus = fsl_pcibios_fixup_bus, #endif .get_irq = mpic_get_irq, .restart = fsl_rstcr_restart, .calibrate_decr = generic_calibrate_decr, .progress = udbg_progress, };