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2022 2023 2024 2025 2026 2027 2028 2029 2030 2031 2032 2033 2034 2035 2036 2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047 2048 2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061 2062 2063 2064 2065 2066 2067 2068 2069 2070 2071 2072 2073 2074 2075 2076 2077 2078 2079 2080 2081 2082 2083 2084 2085 2086 2087 2088 2089 2090 2091 2092 2093 2094 2095 2096 2097 2098 2099 2100 2101 2102 2103 2104 2105 2106 2107 2108 2109 2110 2111 2112 2113 2114 2115 2116 2117 2118 2119 2120 | /* * intelfb * * Linux framebuffer driver for Intel(R) 865G integrated graphics chips. * * Copyright © 2002, 2003 David Dawes <dawes@xfree86.org> * 2004 Sylvain Meyer * * This driver consists of two parts. The first part (intelfbdrv.c) provides * the basic fbdev interfaces, is derived in part from the radeonfb and * vesafb drivers, and is covered by the GPL. The second part (intelfbhw.c) * provides the code to program the hardware. Most of it is derived from * the i810/i830 XFree86 driver. The HW-specific code is covered here * under a dual license (GPL and MIT/XFree86 license). * * Author: David Dawes * */ /* $DHD: intelfb/intelfbhw.c,v 1.9 2003/06/27 15:06:25 dawes Exp $ */ #include <linux/module.h> #include <linux/kernel.h> #include <linux/errno.h> #include <linux/string.h> #include <linux/mm.h> #include <linux/delay.h> #include <linux/fb.h> #include <linux/ioport.h> #include <linux/init.h> #include <linux/pci.h> #include <linux/vmalloc.h> #include <linux/pagemap.h> #include <linux/interrupt.h> #include <asm/io.h> #include "intelfb.h" #include "intelfbhw.h" struct pll_min_max { int min_m, max_m, min_m1, max_m1; int min_m2, max_m2, min_n, max_n; int min_p, max_p, min_p1, max_p1; int min_vco, max_vco, p_transition_clk, ref_clk; int p_inc_lo, p_inc_hi; }; #define PLLS_I8xx 0 #define PLLS_I9xx 1 #define PLLS_MAX 2 static struct pll_min_max plls[PLLS_MAX] = { { 108, 140, 18, 26, 6, 16, 3, 16, 4, 128, 0, 31, 930000, 1400000, 165000, 48000, 4, 2 }, /* I8xx */ { 75, 120, 10, 20, 5, 9, 4, 7, 5, 80, 1, 8, 1400000, 2800000, 200000, 96000, 10, 5 } /* I9xx */ }; int intelfbhw_get_chipset(struct pci_dev *pdev, struct intelfb_info *dinfo) { u32 tmp; if (!pdev || !dinfo) return 1; switch (pdev->device) { case PCI_DEVICE_ID_INTEL_830M: dinfo->name = "Intel(R) 830M"; dinfo->chipset = INTEL_830M; dinfo->mobile = 1; dinfo->pll_index = PLLS_I8xx; return 0; case PCI_DEVICE_ID_INTEL_845G: dinfo->name = "Intel(R) 845G"; dinfo->chipset = INTEL_845G; dinfo->mobile = 0; dinfo->pll_index = PLLS_I8xx; return 0; case PCI_DEVICE_ID_INTEL_854: dinfo->mobile = 1; dinfo->name = "Intel(R) 854"; dinfo->chipset = INTEL_854; return 0; case PCI_DEVICE_ID_INTEL_85XGM: tmp = 0; dinfo->mobile = 1; dinfo->pll_index = PLLS_I8xx; pci_read_config_dword(pdev, INTEL_85X_CAPID, &tmp); switch ((tmp >> INTEL_85X_VARIANT_SHIFT) & INTEL_85X_VARIANT_MASK) { case INTEL_VAR_855GME: dinfo->name = "Intel(R) 855GME"; dinfo->chipset = INTEL_855GME; return 0; case INTEL_VAR_855GM: dinfo->name = "Intel(R) 855GM"; dinfo->chipset = INTEL_855GM; return 0; case INTEL_VAR_852GME: dinfo->name = "Intel(R) 852GME"; dinfo->chipset = INTEL_852GME; return 0; case INTEL_VAR_852GM: dinfo->name = "Intel(R) 852GM"; dinfo->chipset = INTEL_852GM; return 0; default: dinfo->name = "Intel(R) 852GM/855GM"; dinfo->chipset = INTEL_85XGM; return 0; } break; case PCI_DEVICE_ID_INTEL_865G: dinfo->name = "Intel(R) 865G"; dinfo->chipset = INTEL_865G; dinfo->mobile = 0; dinfo->pll_index = PLLS_I8xx; return 0; case PCI_DEVICE_ID_INTEL_915G: dinfo->name = "Intel(R) 915G"; dinfo->chipset = INTEL_915G; dinfo->mobile = 0; dinfo->pll_index = PLLS_I9xx; return 0; case PCI_DEVICE_ID_INTEL_915GM: dinfo->name = "Intel(R) 915GM"; dinfo->chipset = INTEL_915GM; dinfo->mobile = 1; dinfo->pll_index = PLLS_I9xx; return 0; case PCI_DEVICE_ID_INTEL_945G: dinfo->name = "Intel(R) 945G"; dinfo->chipset = INTEL_945G; dinfo->mobile = 0; dinfo->pll_index = PLLS_I9xx; return 0; case PCI_DEVICE_ID_INTEL_945GM: dinfo->name = "Intel(R) 945GM"; dinfo->chipset = INTEL_945GM; dinfo->mobile = 1; dinfo->pll_index = PLLS_I9xx; return 0; case PCI_DEVICE_ID_INTEL_945GME: dinfo->name = "Intel(R) 945GME"; dinfo->chipset = INTEL_945GME; dinfo->mobile = 1; dinfo->pll_index = PLLS_I9xx; return 0; case PCI_DEVICE_ID_INTEL_965G: dinfo->name = "Intel(R) 965G"; dinfo->chipset = INTEL_965G; dinfo->mobile = 0; dinfo->pll_index = PLLS_I9xx; return 0; case PCI_DEVICE_ID_INTEL_965GM: dinfo->name = "Intel(R) 965GM"; dinfo->chipset = INTEL_965GM; dinfo->mobile = 1; dinfo->pll_index = PLLS_I9xx; return 0; default: return 1; } } int intelfbhw_get_memory(struct pci_dev *pdev, int *aperture_size, int *stolen_size) { struct pci_dev *bridge_dev; u16 tmp; int stolen_overhead; if (!pdev || !aperture_size || !stolen_size) return 1; /* Find the bridge device. It is always 0:0.0 */ if (!(bridge_dev = pci_get_bus_and_slot(0, PCI_DEVFN(0, 0)))) { ERR_MSG("cannot find bridge device\n"); return 1; } /* Get the fb aperture size and "stolen" memory amount. */ tmp = 0; pci_read_config_word(bridge_dev, INTEL_GMCH_CTRL, &tmp); pci_dev_put(bridge_dev); switch (pdev->device) { case PCI_DEVICE_ID_INTEL_915G: case PCI_DEVICE_ID_INTEL_915GM: case PCI_DEVICE_ID_INTEL_945G: case PCI_DEVICE_ID_INTEL_945GM: case PCI_DEVICE_ID_INTEL_945GME: case PCI_DEVICE_ID_INTEL_965G: case PCI_DEVICE_ID_INTEL_965GM: /* 915, 945 and 965 chipsets support a 256MB aperture. Aperture size is determined by inspected the base address of the aperture. */ if (pci_resource_start(pdev, 2) & 0x08000000) *aperture_size = MB(128); else *aperture_size = MB(256); break; default: if ((tmp & INTEL_GMCH_MEM_MASK) == INTEL_GMCH_MEM_64M) *aperture_size = MB(64); else *aperture_size = MB(128); break; } /* Stolen memory size is reduced by the GTT and the popup. GTT is 1K per MB of aperture size, and popup is 4K. */ stolen_overhead = (*aperture_size / MB(1)) + 4; switch(pdev->device) { case PCI_DEVICE_ID_INTEL_830M: case PCI_DEVICE_ID_INTEL_845G: switch (tmp & INTEL_830_GMCH_GMS_MASK) { case INTEL_830_GMCH_GMS_STOLEN_512: *stolen_size = KB(512) - KB(stolen_overhead); return 0; case INTEL_830_GMCH_GMS_STOLEN_1024: *stolen_size = MB(1) - KB(stolen_overhead); return 0; case INTEL_830_GMCH_GMS_STOLEN_8192: *stolen_size = MB(8) - KB(stolen_overhead); return 0; case INTEL_830_GMCH_GMS_LOCAL: ERR_MSG("only local memory found\n"); return 1; case INTEL_830_GMCH_GMS_DISABLED: ERR_MSG("video memory is disabled\n"); return 1; default: ERR_MSG("unexpected GMCH_GMS value: 0x%02x\n", tmp & INTEL_830_GMCH_GMS_MASK); return 1; } break; default: switch (tmp & INTEL_855_GMCH_GMS_MASK) { case INTEL_855_GMCH_GMS_STOLEN_1M: *stolen_size = MB(1) - KB(stolen_overhead); return 0; case INTEL_855_GMCH_GMS_STOLEN_4M: *stolen_size = MB(4) - KB(stolen_overhead); return 0; case INTEL_855_GMCH_GMS_STOLEN_8M: *stolen_size = MB(8) - KB(stolen_overhead); return 0; case INTEL_855_GMCH_GMS_STOLEN_16M: *stolen_size = MB(16) - KB(stolen_overhead); return 0; case INTEL_855_GMCH_GMS_STOLEN_32M: *stolen_size = MB(32) - KB(stolen_overhead); return 0; case INTEL_915G_GMCH_GMS_STOLEN_48M: *stolen_size = MB(48) - KB(stolen_overhead); return 0; case INTEL_915G_GMCH_GMS_STOLEN_64M: *stolen_size = MB(64) - KB(stolen_overhead); return 0; case INTEL_855_GMCH_GMS_DISABLED: ERR_MSG("video memory is disabled\n"); return 0; default: ERR_MSG("unexpected GMCH_GMS value: 0x%02x\n", tmp & INTEL_855_GMCH_GMS_MASK); return 1; } } } int intelfbhw_check_non_crt(struct intelfb_info *dinfo) { int dvo = 0; if (INREG(LVDS) & PORT_ENABLE) dvo |= LVDS_PORT; if (INREG(DVOA) & PORT_ENABLE) dvo |= DVOA_PORT; if (INREG(DVOB) & PORT_ENABLE) dvo |= DVOB_PORT; if (INREG(DVOC) & PORT_ENABLE) dvo |= DVOC_PORT; return dvo; } const char * intelfbhw_dvo_to_string(int dvo) { if (dvo & DVOA_PORT) return "DVO port A"; else if (dvo & DVOB_PORT) return "DVO port B"; else if (dvo & DVOC_PORT) return "DVO port C"; else if (dvo & LVDS_PORT) return "LVDS port"; else return NULL; } int intelfbhw_validate_mode(struct intelfb_info *dinfo, struct fb_var_screeninfo *var) { int bytes_per_pixel; int tmp; #if VERBOSE > 0 DBG_MSG("intelfbhw_validate_mode\n"); #endif bytes_per_pixel = var->bits_per_pixel / 8; if (bytes_per_pixel == 3) bytes_per_pixel = 4; /* Check if enough video memory. */ tmp = var->yres_virtual * var->xres_virtual * bytes_per_pixel; if (tmp > dinfo->fb.size) { WRN_MSG("Not enough video ram for mode " "(%d KByte vs %d KByte).\n", BtoKB(tmp), BtoKB(dinfo->fb.size)); return 1; } /* Check if x/y limits are OK. */ if (var->xres - 1 > HACTIVE_MASK) { WRN_MSG("X resolution too large (%d vs %d).\n", var->xres, HACTIVE_MASK + 1); return 1; } if (var->yres - 1 > VACTIVE_MASK) { WRN_MSG("Y resolution too large (%d vs %d).\n", var->yres, VACTIVE_MASK + 1); return 1; } if (var->xres < 4) { WRN_MSG("X resolution too small (%d vs 4).\n", var->xres); return 1; } if (var->yres < 4) { WRN_MSG("Y resolution too small (%d vs 4).\n", var->yres); return 1; } /* Check for doublescan modes. */ if (var->vmode & FB_VMODE_DOUBLE) { WRN_MSG("Mode is double-scan.\n"); return 1; } if ((var->vmode & FB_VMODE_INTERLACED) && (var->yres & 1)) { WRN_MSG("Odd number of lines in interlaced mode\n"); return 1; } /* Check if clock is OK. */ tmp = 1000000000 / var->pixclock; if (tmp < MIN_CLOCK) { WRN_MSG("Pixel clock is too low (%d MHz vs %d MHz).\n", (tmp + 500) / 1000, MIN_CLOCK / 1000); return 1; } if (tmp > MAX_CLOCK) { WRN_MSG("Pixel clock is too high (%d MHz vs %d MHz).\n", (tmp + 500) / 1000, MAX_CLOCK / 1000); return 1; } return 0; } int intelfbhw_pan_display(struct fb_var_screeninfo *var, struct fb_info *info) { struct intelfb_info *dinfo = GET_DINFO(info); u32 offset, xoffset, yoffset; #if VERBOSE > 0 DBG_MSG("intelfbhw_pan_display\n"); #endif xoffset = ROUND_DOWN_TO(var->xoffset, 8); yoffset = var->yoffset; if ((xoffset + info->var.xres > info->var.xres_virtual) || (yoffset + info->var.yres > info->var.yres_virtual)) return -EINVAL; offset = (yoffset * dinfo->pitch) + (xoffset * info->var.bits_per_pixel) / 8; offset += dinfo->fb.offset << 12; dinfo->vsync.pan_offset = offset; if ((var->activate & FB_ACTIVATE_VBL) && !intelfbhw_enable_irq(dinfo)) dinfo->vsync.pan_display = 1; else { dinfo->vsync.pan_display = 0; OUTREG(DSPABASE, offset); } return 0; } /* Blank the screen. */ void intelfbhw_do_blank(int blank, struct fb_info *info) { struct intelfb_info *dinfo = GET_DINFO(info); u32 tmp; #if VERBOSE > 0 DBG_MSG("intelfbhw_do_blank: blank is %d\n", blank); #endif /* Turn plane A on or off */ tmp = INREG(DSPACNTR); if (blank) tmp &= ~DISPPLANE_PLANE_ENABLE; else tmp |= DISPPLANE_PLANE_ENABLE; OUTREG(DSPACNTR, tmp); /* Flush */ tmp = INREG(DSPABASE); OUTREG(DSPABASE, tmp); /* Turn off/on the HW cursor */ #if VERBOSE > 0 DBG_MSG("cursor_on is %d\n", dinfo->cursor_on); #endif if (dinfo->cursor_on) { if (blank) intelfbhw_cursor_hide(dinfo); else intelfbhw_cursor_show(dinfo); dinfo->cursor_on = 1; } dinfo->cursor_blanked = blank; /* Set DPMS level */ tmp = INREG(ADPA) & ~ADPA_DPMS_CONTROL_MASK; switch (blank) { case FB_BLANK_UNBLANK: case FB_BLANK_NORMAL: tmp |= ADPA_DPMS_D0; break; case FB_BLANK_VSYNC_SUSPEND: tmp |= ADPA_DPMS_D1; break; case FB_BLANK_HSYNC_SUSPEND: tmp |= ADPA_DPMS_D2; break; case FB_BLANK_POWERDOWN: tmp |= ADPA_DPMS_D3; break; } OUTREG(ADPA, tmp); return; } /* Check which pipe is connected to an active display plane. */ int intelfbhw_active_pipe(const struct intelfb_hwstate *hw) { int pipe = -1; /* keep old default behaviour - prefer PIPE_A */ if (hw->disp_b_ctrl & DISPPLANE_PLANE_ENABLE) { pipe = (hw->disp_b_ctrl >> DISPPLANE_SEL_PIPE_SHIFT); pipe &= PIPE_MASK; if (unlikely(pipe == PIPE_A)) return PIPE_A; } if (hw->disp_a_ctrl & DISPPLANE_PLANE_ENABLE) { pipe = (hw->disp_a_ctrl >> DISPPLANE_SEL_PIPE_SHIFT); pipe &= PIPE_MASK; if (likely(pipe == PIPE_A)) return PIPE_A; } /* Impossible that no pipe is selected - return PIPE_A */ WARN_ON(pipe == -1); if (unlikely(pipe == -1)) pipe = PIPE_A; return pipe; } void intelfbhw_setcolreg(struct intelfb_info *dinfo, unsigned regno, unsigned red, unsigned green, unsigned blue, unsigned transp) { u32 palette_reg = (dinfo->pipe == PIPE_A) ? PALETTE_A : PALETTE_B; #if VERBOSE > 0 DBG_MSG("intelfbhw_setcolreg: %d: (%d, %d, %d)\n", regno, red, green, blue); #endif OUTREG(palette_reg + (regno << 2), (red << PALETTE_8_RED_SHIFT) | (green << PALETTE_8_GREEN_SHIFT) | (blue << PALETTE_8_BLUE_SHIFT)); } int intelfbhw_read_hw_state(struct intelfb_info *dinfo, struct intelfb_hwstate *hw, int flag) { int i; #if VERBOSE > 0 DBG_MSG("intelfbhw_read_hw_state\n"); #endif if (!hw || !dinfo) return -1; /* Read in as much of the HW state as possible. */ hw->vga0_divisor = INREG(VGA0_DIVISOR); hw->vga1_divisor = INREG(VGA1_DIVISOR); hw->vga_pd = INREG(VGAPD); hw->dpll_a = INREG(DPLL_A); hw->dpll_b = INREG(DPLL_B); hw->fpa0 = INREG(FPA0); hw->fpa1 = INREG(FPA1); hw->fpb0 = INREG(FPB0); hw->fpb1 = INREG(FPB1); if (flag == 1) return flag; #if 0 /* This seems to be a problem with the 852GM/855GM */ for (i = 0; i < PALETTE_8_ENTRIES; i++) { hw->palette_a[i] = INREG(PALETTE_A + (i << 2)); hw->palette_b[i] = INREG(PALETTE_B + (i << 2)); } #endif if (flag == 2) return flag; hw->htotal_a = INREG(HTOTAL_A); hw->hblank_a = INREG(HBLANK_A); hw->hsync_a = INREG(HSYNC_A); hw->vtotal_a = INREG(VTOTAL_A); hw->vblank_a = INREG(VBLANK_A); hw->vsync_a = INREG(VSYNC_A); hw->src_size_a = INREG(SRC_SIZE_A); hw->bclrpat_a = INREG(BCLRPAT_A); hw->htotal_b = INREG(HTOTAL_B); hw->hblank_b = INREG(HBLANK_B); hw->hsync_b = INREG(HSYNC_B); hw->vtotal_b = INREG(VTOTAL_B); hw->vblank_b = INREG(VBLANK_B); hw->vsync_b = INREG(VSYNC_B); hw->src_size_b = INREG(SRC_SIZE_B); hw->bclrpat_b = INREG(BCLRPAT_B); if (flag == 3) return flag; hw->adpa = INREG(ADPA); hw->dvoa = INREG(DVOA); hw->dvob = INREG(DVOB); hw->dvoc = INREG(DVOC); hw->dvoa_srcdim = INREG(DVOA_SRCDIM); hw->dvob_srcdim = INREG(DVOB_SRCDIM); hw->dvoc_srcdim = INREG(DVOC_SRCDIM); hw->lvds = INREG(LVDS); if (flag == 4) return flag; hw->pipe_a_conf = INREG(PIPEACONF); hw->pipe_b_conf = INREG(PIPEBCONF); hw->disp_arb = INREG(DISPARB); if (flag == 5) return flag; hw->cursor_a_control = INREG(CURSOR_A_CONTROL); hw->cursor_b_control = INREG(CURSOR_B_CONTROL); hw->cursor_a_base = INREG(CURSOR_A_BASEADDR); hw->cursor_b_base = INREG(CURSOR_B_BASEADDR); if (flag == 6) return flag; for (i = 0; i < 4; i++) { hw->cursor_a_palette[i] = INREG(CURSOR_A_PALETTE0 + (i << 2)); hw->cursor_b_palette[i] = INREG(CURSOR_B_PALETTE0 + (i << 2)); } if (flag == 7) return flag; hw->cursor_size = INREG(CURSOR_SIZE); if (flag == 8) return flag; hw->disp_a_ctrl = INREG(DSPACNTR); hw->disp_b_ctrl = INREG(DSPBCNTR); hw->disp_a_base = INREG(DSPABASE); hw->disp_b_base = INREG(DSPBBASE); hw->disp_a_stride = INREG(DSPASTRIDE); hw->disp_b_stride = INREG(DSPBSTRIDE); if (flag == 9) return flag; hw->vgacntrl = INREG(VGACNTRL); if (flag == 10) return flag; hw->add_id = INREG(ADD_ID); if (flag == 11) return flag; for (i = 0; i < 7; i++) { hw->swf0x[i] = INREG(SWF00 + (i << 2)); hw->swf1x[i] = INREG(SWF10 + (i << 2)); if (i < 3) hw->swf3x[i] = INREG(SWF30 + (i << 2)); } for (i = 0; i < 8; i++) hw->fence[i] = INREG(FENCE + (i << 2)); hw->instpm = INREG(INSTPM); hw->mem_mode = INREG(MEM_MODE); hw->fw_blc_0 = INREG(FW_BLC_0); hw->fw_blc_1 = INREG(FW_BLC_1); hw->hwstam = INREG16(HWSTAM); hw->ier = INREG16(IER); hw->iir = INREG16(IIR); hw->imr = INREG16(IMR); return 0; } static int calc_vclock3(int index, int m, int n, int p) { if (p == 0 || n == 0) return 0; return plls[index].ref_clk * m / n / p; } static int calc_vclock(int index, int m1, int m2, int n, int p1, int p2, int lvds) { struct pll_min_max *pll = &plls[index]; u32 m, vco, p; m = (5 * (m1 + 2)) + (m2 + 2); n += 2; vco = pll->ref_clk * m / n; if (index == PLLS_I8xx) p = ((p1 + 2) * (1 << (p2 + 1))); else p = ((p1) * (p2 ? 5 : 10)); return vco / p; } #if REGDUMP static void intelfbhw_get_p1p2(struct intelfb_info *dinfo, int dpll, int *o_p1, int *o_p2) { int p1, p2; if (IS_I9XX(dinfo)) { if (dpll & DPLL_P1_FORCE_DIV2) p1 = 1; else p1 = (dpll >> DPLL_P1_SHIFT) & 0xff; p1 = ffs(p1); p2 = (dpll >> DPLL_I9XX_P2_SHIFT) & DPLL_P2_MASK; } else { if (dpll & DPLL_P1_FORCE_DIV2) p1 = 0; else p1 = (dpll >> DPLL_P1_SHIFT) & DPLL_P1_MASK; p2 = (dpll >> DPLL_P2_SHIFT) & DPLL_P2_MASK; } *o_p1 = p1; *o_p2 = p2; } #endif void intelfbhw_print_hw_state(struct intelfb_info *dinfo, struct intelfb_hwstate *hw) { #if REGDUMP int i, m1, m2, n, p1, p2; int index = dinfo->pll_index; DBG_MSG("intelfbhw_print_hw_state\n"); if (!hw) return; /* Read in as much of the HW state as possible. */ printk("hw state dump start\n"); printk(" VGA0_DIVISOR: 0x%08x\n", hw->vga0_divisor); printk(" VGA1_DIVISOR: 0x%08x\n", hw->vga1_divisor); printk(" VGAPD: 0x%08x\n", hw->vga_pd); n = (hw->vga0_divisor >> FP_N_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m1 = (hw->vga0_divisor >> FP_M1_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m2 = (hw->vga0_divisor >> FP_M2_DIVISOR_SHIFT) & FP_DIVISOR_MASK; intelfbhw_get_p1p2(dinfo, hw->vga_pd, &p1, &p2); printk(" VGA0: (m1, m2, n, p1, p2) = (%d, %d, %d, %d, %d)\n", m1, m2, n, p1, p2); printk(" VGA0: clock is %d\n", calc_vclock(index, m1, m2, n, p1, p2, 0)); n = (hw->vga1_divisor >> FP_N_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m1 = (hw->vga1_divisor >> FP_M1_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m2 = (hw->vga1_divisor >> FP_M2_DIVISOR_SHIFT) & FP_DIVISOR_MASK; intelfbhw_get_p1p2(dinfo, hw->vga_pd, &p1, &p2); printk(" VGA1: (m1, m2, n, p1, p2) = (%d, %d, %d, %d, %d)\n", m1, m2, n, p1, p2); printk(" VGA1: clock is %d\n", calc_vclock(index, m1, m2, n, p1, p2, 0)); printk(" DPLL_A: 0x%08x\n", hw->dpll_a); printk(" DPLL_B: 0x%08x\n", hw->dpll_b); printk(" FPA0: 0x%08x\n", hw->fpa0); printk(" FPA1: 0x%08x\n", hw->fpa1); printk(" FPB0: 0x%08x\n", hw->fpb0); printk(" FPB1: 0x%08x\n", hw->fpb1); n = (hw->fpa0 >> FP_N_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m1 = (hw->fpa0 >> FP_M1_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m2 = (hw->fpa0 >> FP_M2_DIVISOR_SHIFT) & FP_DIVISOR_MASK; intelfbhw_get_p1p2(dinfo, hw->dpll_a, &p1, &p2); printk(" PLLA0: (m1, m2, n, p1, p2) = (%d, %d, %d, %d, %d)\n", m1, m2, n, p1, p2); printk(" PLLA0: clock is %d\n", calc_vclock(index, m1, m2, n, p1, p2, 0)); n = (hw->fpa1 >> FP_N_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m1 = (hw->fpa1 >> FP_M1_DIVISOR_SHIFT) & FP_DIVISOR_MASK; m2 = (hw->fpa1 >> FP_M2_DIVISOR_SHIFT) & FP_DIVISOR_MASK; intelfbhw_get_p1p2(dinfo, hw->dpll_a, &p1, &p2); printk(" PLLA1: (m1, m2, n, p1, p2) = (%d, %d, %d, %d, %d)\n", m1, m2, n, p1, p2); printk(" PLLA1: clock is %d\n", calc_vclock(index, m1, m2, n, p1, p2, 0)); #if 0 printk(" PALETTE_A:\n"); for (i = 0; i < PALETTE_8_ENTRIES) printk(" %3d: 0x%08x\n", i, hw->palette_a[i]); printk(" PALETTE_B:\n"); for (i = 0; i < PALETTE_8_ENTRIES) printk(" %3d: 0x%08x\n", i, hw->palette_b[i]); #endif printk(" HTOTAL_A: 0x%08x\n", hw->htotal_a); printk(" HBLANK_A: 0x%08x\n", hw->hblank_a); printk(" HSYNC_A: 0x%08x\n", hw->hsync_a); printk(" VTOTAL_A: 0x%08x\n", hw->vtotal_a); printk(" VBLANK_A: 0x%08x\n", hw->vblank_a); printk(" VSYNC_A: 0x%08x\n", hw->vsync_a); printk(" SRC_SIZE_A: 0x%08x\n", hw->src_size_a); printk(" BCLRPAT_A: 0x%08x\n", hw->bclrpat_a); printk(" HTOTAL_B: 0x%08x\n", hw->htotal_b); printk(" HBLANK_B: 0x%08x\n", hw->hblank_b); printk(" HSYNC_B: 0x%08x\n", hw->hsync_b); printk(" VTOTAL_B: 0x%08x\n", hw->vtotal_b); printk(" VBLANK_B: 0x%08x\n", hw->vblank_b); printk(" VSYNC_B: 0x%08x\n", hw->vsync_b); printk(" SRC_SIZE_B: 0x%08x\n", hw->src_size_b); printk(" BCLRPAT_B: 0x%08x\n", hw->bclrpat_b); printk(" ADPA: 0x%08x\n", hw->adpa); printk(" DVOA: 0x%08x\n", hw->dvoa); printk(" DVOB: 0x%08x\n", hw->dvob); printk(" DVOC: 0x%08x\n", hw->dvoc); printk(" DVOA_SRCDIM: 0x%08x\n", hw->dvoa_srcdim); printk(" DVOB_SRCDIM: 0x%08x\n", hw->dvob_srcdim); printk(" DVOC_SRCDIM: 0x%08x\n", hw->dvoc_srcdim); printk(" LVDS: 0x%08x\n", hw->lvds); printk(" PIPEACONF: 0x%08x\n", hw->pipe_a_conf); printk(" PIPEBCONF: 0x%08x\n", hw->pipe_b_conf); printk(" DISPARB: 0x%08x\n", hw->disp_arb); printk(" CURSOR_A_CONTROL: 0x%08x\n", hw->cursor_a_control); printk(" CURSOR_B_CONTROL: 0x%08x\n", hw->cursor_b_control); printk(" CURSOR_A_BASEADDR: 0x%08x\n", hw->cursor_a_base); printk(" CURSOR_B_BASEADDR: 0x%08x\n", hw->cursor_b_base); printk(" CURSOR_A_PALETTE: "); for (i = 0; i < 4; i++) { printk("0x%08x", hw->cursor_a_palette[i]); if (i < 3) printk(", "); } printk("\n"); printk(" CURSOR_B_PALETTE: "); for (i = 0; i < 4; i++) { printk("0x%08x", hw->cursor_b_palette[i]); if (i < 3) printk(", "); } printk("\n"); printk(" CURSOR_SIZE: 0x%08x\n", hw->cursor_size); printk(" DSPACNTR: 0x%08x\n", hw->disp_a_ctrl); printk(" DSPBCNTR: 0x%08x\n", hw->disp_b_ctrl); printk(" DSPABASE: 0x%08x\n", hw->disp_a_base); printk(" DSPBBASE: 0x%08x\n", hw->disp_b_base); printk(" DSPASTRIDE: 0x%08x\n", hw->disp_a_stride); printk(" DSPBSTRIDE: 0x%08x\n", hw->disp_b_stride); printk(" VGACNTRL: 0x%08x\n", hw->vgacntrl); printk(" ADD_ID: 0x%08x\n", hw->add_id); for (i = 0; i < 7; i++) { printk(" SWF0%d 0x%08x\n", i, hw->swf0x[i]); } for (i = 0; i < 7; i++) { printk(" SWF1%d 0x%08x\n", i, hw->swf1x[i]); } for (i = 0; i < 3; i++) { printk(" SWF3%d 0x%08x\n", i, hw->swf3x[i]); } for (i = 0; i < 8; i++) printk(" FENCE%d 0x%08x\n", i, hw->fence[i]); printk(" INSTPM 0x%08x\n", hw->instpm); printk(" MEM_MODE 0x%08x\n", hw->mem_mode); printk(" FW_BLC_0 0x%08x\n", hw->fw_blc_0); printk(" FW_BLC_1 0x%08x\n", hw->fw_blc_1); printk(" HWSTAM 0x%04x\n", hw->hwstam); printk(" IER 0x%04x\n", hw->ier); printk(" IIR 0x%04x\n", hw->iir); printk(" IMR 0x%04x\n", hw->imr); printk("hw state dump end\n"); #endif } /* Split the M parameter into M1 and M2. */ static int splitm(int index, unsigned int m, unsigned int *retm1, unsigned int *retm2) { int m1, m2; int testm; struct pll_min_max *pll = &plls[index]; /* no point optimising too much - brute force m */ for (m1 = pll->min_m1; m1 < pll->max_m1 + 1; m1++) { for (m2 = pll->min_m2; m2 < pll->max_m2 + 1; m2++) { testm = (5 * (m1 + 2)) + (m2 + 2); if (testm == m) { *retm1 = (unsigned int)m1; *retm2 = (unsigned int)m2; return 0; } } } return 1; } /* Split the P parameter into P1 and P2. */ static int splitp(int index, unsigned int p, unsigned int *retp1, unsigned int *retp2) { int p1, p2; struct pll_min_max *pll = &plls[index]; if (index == PLLS_I9xx) { p2 = (p % 10) ? 1 : 0; p1 = p / (p2 ? 5 : 10); *retp1 = (unsigned int)p1; *retp2 = (unsigned int)p2; return 0; } if (p % 4 == 0) p2 = 1; else p2 = 0; p1 = (p / (1 << (p2 + 1))) - 2; if (p % 4 == 0 && p1 < pll->min_p1) { p2 = 0; p1 = (p / (1 << (p2 + 1))) - 2; } if (p1 < pll->min_p1 || p1 > pll->max_p1 || (p1 + 2) * (1 << (p2 + 1)) != p) { return 1; } else { *retp1 = (unsigned int)p1; *retp2 = (unsigned int)p2; return 0; } } static int calc_pll_params(int index, int clock, u32 *retm1, u32 *retm2, u32 *retn, u32 *retp1, u32 *retp2, u32 *retclock) { u32 m1, m2, n, p1, p2, n1, testm; u32 f_vco, p, p_best = 0, m, f_out = 0; u32 err_max, err_target, err_best = 10000000; u32 n_best = 0, m_best = 0, f_best, f_err; u32 p_min, p_max, p_inc, div_max; struct pll_min_max *pll = &plls[index]; /* Accept 0.5% difference, but aim for 0.1% */ err_max = 5 * clock / 1000; err_target = clock / 1000; DBG_MSG("Clock is %d\n", clock); div_max = pll->max_vco / clock; p_inc = (clock <= pll->p_transition_clk) ? pll->p_inc_lo : pll->p_inc_hi; p_min = p_inc; p_max = ROUND_DOWN_TO(div_max, p_inc); if (p_min < pll->min_p) p_min = pll->min_p; if (p_max > pll->max_p) p_max = pll->max_p; DBG_MSG("p range is %d-%d (%d)\n", p_min, p_max, p_inc); p = p_min; do { if (splitp(index, p, &p1, &p2)) { WRN_MSG("cannot split p = %d\n", p); p += p_inc; continue; } n = pll->min_n; f_vco = clock * p; do { m = ROUND_UP_TO(f_vco * n, pll->ref_clk) / pll->ref_clk; if (m < pll->min_m) m = pll->min_m + 1; if (m > pll->max_m) m = pll->max_m - 1; for (testm = m - 1; testm <= m; testm++) { f_out = calc_vclock3(index, testm, n, p); if (splitm(index, testm, &m1, &m2)) { WRN_MSG("cannot split m = %d\n", testm); continue; } if (clock > f_out) f_err = clock - f_out; else/* slightly bias the error for bigger clocks */ f_err = f_out - clock + 1; if (f_err < err_best) { m_best = testm; n_best = n; p_best = p; f_best = f_out; err_best = f_err; } } n++; } while ((n <= pll->max_n) && (f_out >= clock)); p += p_inc; } while ((p <= p_max)); if (!m_best) { WRN_MSG("cannot find parameters for clock %d\n", clock); return 1; } m = m_best; n = n_best; p = p_best; splitm(index, m, &m1, &m2); splitp(index, p, &p1, &p2); n1 = n - 2; DBG_MSG("m, n, p: %d (%d,%d), %d (%d), %d (%d,%d), " "f: %d (%d), VCO: %d\n", m, m1, m2, n, n1, p, p1, p2, calc_vclock3(index, m, n, p), calc_vclock(index, m1, m2, n1, p1, p2, 0), calc_vclock3(index, m, n, p) * p); *retm1 = m1; *retm2 = m2; *retn = n1; *retp1 = p1; *retp2 = p2; *retclock = calc_vclock(index, m1, m2, n1, p1, p2, 0); return 0; } static __inline__ int check_overflow(u32 value, u32 limit, const char *description) { if (value > limit) { WRN_MSG("%s value %d exceeds limit %d\n", description, value, limit); return 1; } return 0; } /* It is assumed that hw is filled in with the initial state information. */ int intelfbhw_mode_to_hw(struct intelfb_info *dinfo, struct intelfb_hwstate *hw, struct fb_var_screeninfo *var) { int pipe = intelfbhw_active_pipe(hw); u32 *dpll, *fp0, *fp1; u32 m1, m2, n, p1, p2, clock_target, clock; u32 hsync_start, hsync_end, hblank_start, hblank_end, htotal, hactive; u32 vsync_start, vsync_end, vblank_start, vblank_end, vtotal, vactive; u32 vsync_pol, hsync_pol; u32 *vs, *vb, *vt, *hs, *hb, *ht, *ss, *pipe_conf; u32 stride_alignment; DBG_MSG("intelfbhw_mode_to_hw\n"); /* Disable VGA */ hw->vgacntrl |= VGA_DISABLE; /* Set which pipe's registers will be set. */ if (pipe == PIPE_B) { dpll = &hw->dpll_b; fp0 = &hw->fpb0; fp1 = &hw->fpb1; hs = &hw->hsync_b; hb = &hw->hblank_b; ht = &hw->htotal_b; vs = &hw->vsync_b; vb = &hw->vblank_b; vt = &hw->vtotal_b; ss = &hw->src_size_b; pipe_conf = &hw->pipe_b_conf; } else { dpll = &hw->dpll_a; fp0 = &hw->fpa0; fp1 = &hw->fpa1; hs = &hw->hsync_a; hb = &hw->hblank_a; ht = &hw->htotal_a; vs = &hw->vsync_a; vb = &hw->vblank_a; vt = &hw->vtotal_a; ss = &hw->src_size_a; pipe_conf = &hw->pipe_a_conf; } /* Use ADPA register for sync control. */ hw->adpa &= ~ADPA_USE_VGA_HVPOLARITY; /* sync polarity */ hsync_pol = (var->sync & FB_SYNC_HOR_HIGH_ACT) ? ADPA_SYNC_ACTIVE_HIGH : ADPA_SYNC_ACTIVE_LOW; vsync_pol = (var->sync & FB_SYNC_VERT_HIGH_ACT) ? ADPA_SYNC_ACTIVE_HIGH : ADPA_SYNC_ACTIVE_LOW; hw->adpa &= ~((ADPA_SYNC_ACTIVE_MASK << ADPA_VSYNC_ACTIVE_SHIFT) | (ADPA_SYNC_ACTIVE_MASK << ADPA_HSYNC_ACTIVE_SHIFT)); hw->adpa |= (hsync_pol << ADPA_HSYNC_ACTIVE_SHIFT) | (vsync_pol << ADPA_VSYNC_ACTIVE_SHIFT); /* Connect correct pipe to the analog port DAC */ hw->adpa &= ~(PIPE_MASK << ADPA_PIPE_SELECT_SHIFT); hw->adpa |= (pipe << ADPA_PIPE_SELECT_SHIFT); /* Set DPMS state to D0 (on) */ hw->adpa &= ~ADPA_DPMS_CONTROL_MASK; hw->adpa |= ADPA_DPMS_D0; hw->adpa |= ADPA_DAC_ENABLE; *dpll |= (DPLL_VCO_ENABLE | DPLL_VGA_MODE_DISABLE); *dpll &= ~(DPLL_RATE_SELECT_MASK | DPLL_REFERENCE_SELECT_MASK); *dpll |= (DPLL_REFERENCE_DEFAULT | DPLL_RATE_SELECT_FP0); /* Desired clock in kHz */ clock_target = 1000000000 / var->pixclock; if (calc_pll_params(dinfo->pll_index, clock_target, &m1, &m2, &n, &p1, &p2, &clock)) { WRN_MSG("calc_pll_params failed\n"); return 1; } /* Check for overflow. */ if (check_overflow(p1, DPLL_P1_MASK, "PLL P1 parameter")) return 1; if (check_overflow(p2, DPLL_P2_MASK, "PLL P2 parameter")) return 1; if (check_overflow(m1, FP_DIVISOR_MASK, "PLL M1 parameter")) return 1; if (check_overflow(m2, FP_DIVISOR_MASK, "PLL M2 parameter")) return 1; if (check_overflow(n, FP_DIVISOR_MASK, "PLL N parameter")) return 1; *dpll &= ~DPLL_P1_FORCE_DIV2; *dpll &= ~((DPLL_P2_MASK << DPLL_P2_SHIFT) | (DPLL_P1_MASK << DPLL_P1_SHIFT)); if (IS_I9XX(dinfo)) { *dpll |= (p2 << DPLL_I9XX_P2_SHIFT); *dpll |= (1 << (p1 - 1)) << DPLL_P1_SHIFT; } else *dpll |= (p2 << DPLL_P2_SHIFT) | (p1 << DPLL_P1_SHIFT); *fp0 = (n << FP_N_DIVISOR_SHIFT) | (m1 << FP_M1_DIVISOR_SHIFT) | (m2 << FP_M2_DIVISOR_SHIFT); *fp1 = *fp0; hw->dvob &= ~PORT_ENABLE; hw->dvoc &= ~PORT_ENABLE; /* Use display plane A. */ hw->disp_a_ctrl |= DISPPLANE_PLANE_ENABLE; hw->disp_a_ctrl &= ~DISPPLANE_GAMMA_ENABLE; hw->disp_a_ctrl &= ~DISPPLANE_PIXFORMAT_MASK; switch (intelfb_var_to_depth(var)) { case 8: hw->disp_a_ctrl |= DISPPLANE_8BPP | DISPPLANE_GAMMA_ENABLE; break; case 15: hw->disp_a_ctrl |= DISPPLANE_15_16BPP; break; case 16: hw->disp_a_ctrl |= DISPPLANE_16BPP; break; case 24: hw->disp_a_ctrl |= DISPPLANE_32BPP_NO_ALPHA; break; } hw->disp_a_ctrl &= ~(PIPE_MASK << DISPPLANE_SEL_PIPE_SHIFT); hw->disp_a_ctrl |= (pipe << DISPPLANE_SEL_PIPE_SHIFT); /* Set CRTC registers. */ hactive = var->xres; hsync_start = hactive + var->right_margin; hsync_end = hsync_start + var->hsync_len; htotal = hsync_end + var->left_margin; hblank_start = hactive; hblank_end = htotal; DBG_MSG("H: act %d, ss %d, se %d, tot %d bs %d, be %d\n", hactive, hsync_start, hsync_end, htotal, hblank_start, hblank_end); vactive = var->yres; if (var->vmode & FB_VMODE_INTERLACED) vactive--; /* the chip adds 2 halflines automatically */ vsync_start = vactive + var->lower_margin; vsync_end = vsync_start + var->vsync_len; vtotal = vsync_end + var->upper_margin; vblank_start = vactive; vblank_end = vsync_end + 1; DBG_MSG("V: act %d, ss %d, se %d, tot %d bs %d, be %d\n", vactive, vsync_start, vsync_end, vtotal, vblank_start, vblank_end); /* Adjust for register values, and check for overflow. */ hactive--; if (check_overflow(hactive, HACTIVE_MASK, "CRTC hactive")) return 1; hsync_start--; if (check_overflow(hsync_start, HSYNCSTART_MASK, "CRTC hsync_start")) return 1; hsync_end--; if (check_overflow(hsync_end, HSYNCEND_MASK, "CRTC hsync_end")) return 1; htotal--; if (check_overflow(htotal, HTOTAL_MASK, "CRTC htotal")) return 1; hblank_start--; if (check_overflow(hblank_start, HBLANKSTART_MASK, "CRTC hblank_start")) return 1; hblank_end--; if (check_overflow(hblank_end, HBLANKEND_MASK, "CRTC hblank_end")) return 1; vactive--; if (check_overflow(vactive, VACTIVE_MASK, "CRTC vactive")) return 1; vsync_start--; if (check_overflow(vsync_start, VSYNCSTART_MASK, "CRTC vsync_start")) return 1; vsync_end--; if (check_overflow(vsync_end, VSYNCEND_MASK, "CRTC vsync_end")) return 1; vtotal--; if (check_overflow(vtotal, VTOTAL_MASK, "CRTC vtotal")) return 1; vblank_start--; if (check_overflow(vblank_start, VBLANKSTART_MASK, "CRTC vblank_start")) return 1; vblank_end--; if (check_overflow(vblank_end, VBLANKEND_MASK, "CRTC vblank_end")) return 1; *ht = (htotal << HTOTAL_SHIFT) | (hactive << HACTIVE_SHIFT); *hb = (hblank_start << HBLANKSTART_SHIFT) | (hblank_end << HSYNCEND_SHIFT); *hs = (hsync_start << HSYNCSTART_SHIFT) | (hsync_end << HSYNCEND_SHIFT); *vt = (vtotal << VTOTAL_SHIFT) | (vactive << VACTIVE_SHIFT); *vb = (vblank_start << VBLANKSTART_SHIFT) | (vblank_end << VSYNCEND_SHIFT); *vs = (vsync_start << VSYNCSTART_SHIFT) | (vsync_end << VSYNCEND_SHIFT); *ss = (hactive << SRC_SIZE_HORIZ_SHIFT) | (vactive << SRC_SIZE_VERT_SHIFT); hw->disp_a_stride = dinfo->pitch; DBG_MSG("pitch is %d\n", hw->disp_a_stride); hw->disp_a_base = hw->disp_a_stride * var->yoffset + var->xoffset * var->bits_per_pixel / 8; hw->disp_a_base += dinfo->fb.offset << 12; /* Check stride alignment. */ stride_alignment = IS_I9XX(dinfo) ? STRIDE_ALIGNMENT_I9XX : STRIDE_ALIGNMENT; if (hw->disp_a_stride % stride_alignment != 0) { WRN_MSG("display stride %d has bad alignment %d\n", hw->disp_a_stride, stride_alignment); return 1; } /* Set the palette to 8-bit mode. */ *pipe_conf &= ~PIPECONF_GAMMA; if (var->vmode & FB_VMODE_INTERLACED) *pipe_conf |= PIPECONF_INTERLACE_W_FIELD_INDICATION; else *pipe_conf &= ~PIPECONF_INTERLACE_MASK; return 0; } /* Program a (non-VGA) video mode. */ int intelfbhw_program_mode(struct intelfb_info *dinfo, const struct intelfb_hwstate *hw, int blank) { u32 tmp; const u32 *dpll, *fp0, *fp1, *pipe_conf; const u32 *hs, *ht, *hb, *vs, *vt, *vb, *ss; u32 dpll_reg, fp0_reg, fp1_reg, pipe_conf_reg, pipe_stat_reg; u32 hsync_reg, htotal_reg, hblank_reg; u32 vsync_reg, vtotal_reg, vblank_reg; u32 src_size_reg; u32 count, tmp_val[3]; /* Assume single pipe */ #if VERBOSE > 0 DBG_MSG("intelfbhw_program_mode\n"); #endif /* Disable VGA */ tmp = INREG(VGACNTRL); tmp |= VGA_DISABLE; OUTREG(VGACNTRL, tmp); dinfo->pipe = intelfbhw_active_pipe(hw); if (dinfo->pipe == PIPE_B) { dpll = &hw->dpll_b; fp0 = &hw->fpb0; fp1 = &hw->fpb1; pipe_conf = &hw->pipe_b_conf; hs = &hw->hsync_b; hb = &hw->hblank_b; ht = &hw->htotal_b; vs = &hw->vsync_b; vb = &hw->vblank_b; vt = &hw->vtotal_b; ss = &hw->src_size_b; dpll_reg = DPLL_B; fp0_reg = FPB0; fp1_reg = FPB1; pipe_conf_reg = PIPEBCONF; pipe_stat_reg = PIPEBSTAT; hsync_reg = HSYNC_B; htotal_reg = HTOTAL_B; hblank_reg = HBLANK_B; vsync_reg = VSYNC_B; vtotal_reg = VTOTAL_B; vblank_reg = VBLANK_B; src_size_reg = SRC_SIZE_B; } else { dpll = &hw->dpll_a; fp0 = &hw->fpa0; fp1 = &hw->fpa1; pipe_conf = &hw->pipe_a_conf; hs = &hw->hsync_a; hb = &hw->hblank_a; ht = &hw->htotal_a; vs = &hw->vsync_a; vb = &hw->vblank_a; vt = &hw->vtotal_a; ss = &hw->src_size_a; dpll_reg = DPLL_A; fp0_reg = FPA0; fp1_reg = FPA1; pipe_conf_reg = PIPEACONF; pipe_stat_reg = PIPEASTAT; hsync_reg = HSYNC_A; htotal_reg = HTOTAL_A; hblank_reg = HBLANK_A; vsync_reg = VSYNC_A; vtotal_reg = VTOTAL_A; vblank_reg = VBLANK_A; src_size_reg = SRC_SIZE_A; } /* turn off pipe */ tmp = INREG(pipe_conf_reg); tmp &= ~PIPECONF_ENABLE; OUTREG(pipe_conf_reg, tmp); count = 0; do { tmp_val[count % 3] = INREG(PIPEA_DSL); if ((tmp_val[0] == tmp_val[1]) && (tmp_val[1] == tmp_val[2])) break; count++; udelay(1); if (count % 200 == 0) { tmp = INREG(pipe_conf_reg); tmp &= ~PIPECONF_ENABLE; OUTREG(pipe_conf_reg, tmp); } } while (count < 2000); OUTREG(ADPA, INREG(ADPA) & ~ADPA_DAC_ENABLE); /* Disable planes A and B. */ tmp = INREG(DSPACNTR); tmp &= ~DISPPLANE_PLANE_ENABLE; OUTREG(DSPACNTR, tmp); tmp = INREG(DSPBCNTR); tmp &= ~DISPPLANE_PLANE_ENABLE; OUTREG(DSPBCNTR, tmp); /* Wait for vblank. For now, just wait for a 50Hz cycle (20ms)) */ mdelay(20); OUTREG(DVOB, INREG(DVOB) & ~PORT_ENABLE); OUTREG(DVOC, INREG(DVOC) & ~PORT_ENABLE); OUTREG(ADPA, INREG(ADPA) & ~ADPA_DAC_ENABLE); /* Disable Sync */ tmp = INREG(ADPA); tmp &= ~ADPA_DPMS_CONTROL_MASK; tmp |= ADPA_DPMS_D3; OUTREG(ADPA, tmp); /* do some funky magic - xyzzy */ OUTREG(0x61204, 0xabcd0000); /* turn off PLL */ tmp = INREG(dpll_reg); tmp &= ~DPLL_VCO_ENABLE; OUTREG(dpll_reg, tmp); /* Set PLL parameters */ OUTREG(fp0_reg, *fp0); OUTREG(fp1_reg, *fp1); /* Enable PLL */ OUTREG(dpll_reg, *dpll); /* Set DVOs B/C */ OUTREG(DVOB, hw->dvob); OUTREG(DVOC, hw->dvoc); /* undo funky magic */ OUTREG(0x61204, 0x00000000); /* Set ADPA */ OUTREG(ADPA, INREG(ADPA) | ADPA_DAC_ENABLE); OUTREG(ADPA, (hw->adpa & ~(ADPA_DPMS_CONTROL_MASK)) | ADPA_DPMS_D3); /* Set pipe parameters */ OUTREG(hsync_reg, *hs); OUTREG(hblank_reg, *hb); OUTREG(htotal_reg, *ht); OUTREG(vsync_reg, *vs); OUTREG(vblank_reg, *vb); OUTREG(vtotal_reg, *vt); OUTREG(src_size_reg, *ss); switch (dinfo->info->var.vmode & (FB_VMODE_INTERLACED | FB_VMODE_ODD_FLD_FIRST)) { case FB_VMODE_INTERLACED | FB_VMODE_ODD_FLD_FIRST: OUTREG(pipe_stat_reg, 0xFFFF | PIPESTAT_FLD_EVT_ODD_EN); break; case FB_VMODE_INTERLACED: /* even lines first */ OUTREG(pipe_stat_reg, 0xFFFF | PIPESTAT_FLD_EVT_EVEN_EN); break; default: /* non-interlaced */ OUTREG(pipe_stat_reg, 0xFFFF); /* clear all status bits only */ } /* Enable pipe */ OUTREG(pipe_conf_reg, *pipe_conf | PIPECONF_ENABLE); /* Enable sync */ tmp = INREG(ADPA); tmp &= ~ADPA_DPMS_CONTROL_MASK; tmp |= ADPA_DPMS_D0; OUTREG(ADPA, tmp); /* setup display plane */ if (dinfo->pdev->device == PCI_DEVICE_ID_INTEL_830M) { /* * i830M errata: the display plane must be enabled * to allow writes to the other bits in the plane * control register. */ tmp = INREG(DSPACNTR); if ((tmp & DISPPLANE_PLANE_ENABLE) != DISPPLANE_PLANE_ENABLE) { tmp |= DISPPLANE_PLANE_ENABLE; OUTREG(DSPACNTR, tmp); OUTREG(DSPACNTR, hw->disp_a_ctrl|DISPPLANE_PLANE_ENABLE); mdelay(1); } } OUTREG(DSPACNTR, hw->disp_a_ctrl & ~DISPPLANE_PLANE_ENABLE); OUTREG(DSPASTRIDE, hw->disp_a_stride); OUTREG(DSPABASE, hw->disp_a_base); /* Enable plane */ if (!blank) { tmp = INREG(DSPACNTR); tmp |= DISPPLANE_PLANE_ENABLE; OUTREG(DSPACNTR, tmp); OUTREG(DSPABASE, hw->disp_a_base); } return 0; } /* forward declarations */ static void refresh_ring(struct intelfb_info *dinfo); static void reset_state(struct intelfb_info *dinfo); static void do_flush(struct intelfb_info *dinfo); static u32 get_ring_space(struct intelfb_info *dinfo) { u32 ring_space; if (dinfo->ring_tail >= dinfo->ring_head) ring_space = dinfo->ring.size - (dinfo->ring_tail - dinfo->ring_head); else ring_space = dinfo->ring_head - dinfo->ring_tail; if (ring_space > RING_MIN_FREE) ring_space -= RING_MIN_FREE; else ring_space = 0; return ring_space; } static int wait_ring(struct intelfb_info *dinfo, int n) { int i = 0; unsigned long end; u32 last_head = INREG(PRI_RING_HEAD) & RING_HEAD_MASK; #if VERBOSE > 0 DBG_MSG("wait_ring: %d\n", n); #endif end = jiffies + (HZ * 3); while (dinfo->ring_space < n) { dinfo->ring_head = INREG(PRI_RING_HEAD) & RING_HEAD_MASK; dinfo->ring_space = get_ring_space(dinfo); if (dinfo->ring_head != last_head) { end = jiffies + (HZ * 3); last_head = dinfo->ring_head; } i++; if (time_before(end, jiffies)) { if (!i) { /* Try again */ reset_state(dinfo); refresh_ring(dinfo); do_flush(dinfo); end = jiffies + (HZ * 3); i = 1; } else { WRN_MSG("ring buffer : space: %d wanted %d\n", dinfo->ring_space, n); WRN_MSG("lockup - turning off hardware " "acceleration\n"); dinfo->ring_lockup = 1; break; } } udelay(1); } return i; } static void do_flush(struct intelfb_info *dinfo) { START_RING(2); OUT_RING(MI_FLUSH | MI_WRITE_DIRTY_STATE | MI_INVALIDATE_MAP_CACHE); OUT_RING(MI_NOOP); ADVANCE_RING(); } void intelfbhw_do_sync(struct intelfb_info *dinfo) { #if VERBOSE > 0 DBG_MSG("intelfbhw_do_sync\n"); #endif if (!dinfo->accel) return; /* * Send a flush, then wait until the ring is empty. This is what * the XFree86 driver does, and actually it doesn't seem a lot worse * than the recommended method (both have problems). */ do_flush(dinfo); wait_ring(dinfo, dinfo->ring.size - RING_MIN_FREE); dinfo->ring_space = dinfo->ring.size - RING_MIN_FREE; } static void refresh_ring(struct intelfb_info *dinfo) { #if VERBOSE > 0 DBG_MSG("refresh_ring\n"); #endif dinfo->ring_head = INREG(PRI_RING_HEAD) & RING_HEAD_MASK; dinfo->ring_tail = INREG(PRI_RING_TAIL) & RING_TAIL_MASK; dinfo->ring_space = get_ring_space(dinfo); } static void reset_state(struct intelfb_info *dinfo) { int i; u32 tmp; #if VERBOSE > 0 DBG_MSG("reset_state\n"); #endif for (i = 0; i < FENCE_NUM; i++) OUTREG(FENCE + (i << 2), 0); /* Flush the ring buffer if it's enabled. */ tmp = INREG(PRI_RING_LENGTH); if (tmp & RING_ENABLE) { #if VERBOSE > 0 DBG_MSG("reset_state: ring was enabled\n"); #endif refresh_ring(dinfo); intelfbhw_do_sync(dinfo); DO_RING_IDLE(); } OUTREG(PRI_RING_LENGTH, 0); OUTREG(PRI_RING_HEAD, 0); OUTREG(PRI_RING_TAIL, 0); OUTREG(PRI_RING_START, 0); } /* Stop the 2D engine, and turn off the ring buffer. */ void intelfbhw_2d_stop(struct intelfb_info *dinfo) { #if VERBOSE > 0 DBG_MSG("intelfbhw_2d_stop: accel: %d, ring_active: %d\n", dinfo->accel, dinfo->ring_active); #endif if (!dinfo->accel) return; dinfo->ring_active = 0; reset_state(dinfo); } /* * Enable the ring buffer, and initialise the 2D engine. * It is assumed that the graphics engine has been stopped by previously * calling intelfb_2d_stop(). */ void intelfbhw_2d_start(struct intelfb_info *dinfo) { #if VERBOSE > 0 DBG_MSG("intelfbhw_2d_start: accel: %d, ring_active: %d\n", dinfo->accel, dinfo->ring_active); #endif if (!dinfo->accel) return; /* Initialise the primary ring buffer. */ OUTREG(PRI_RING_LENGTH, 0); OUTREG(PRI_RING_TAIL, 0); OUTREG(PRI_RING_HEAD, 0); OUTREG(PRI_RING_START, dinfo->ring.physical & RING_START_MASK); OUTREG(PRI_RING_LENGTH, ((dinfo->ring.size - GTT_PAGE_SIZE) & RING_LENGTH_MASK) | RING_NO_REPORT | RING_ENABLE); refresh_ring(dinfo); dinfo->ring_active = 1; } /* 2D fillrect (solid fill or invert) */ void intelfbhw_do_fillrect(struct intelfb_info *dinfo, u32 x, u32 y, u32 w, u32 h, u32 color, u32 pitch, u32 bpp, u32 rop) { u32 br00, br09, br13, br14, br16; #if VERBOSE > 0 DBG_MSG("intelfbhw_do_fillrect: (%d,%d) %dx%d, c 0x%06x, p %d bpp %d, " "rop 0x%02x\n", x, y, w, h, color, pitch, bpp, rop); #endif br00 = COLOR_BLT_CMD; br09 = dinfo->fb_start + (y * pitch + x * (bpp / 8)); br13 = (rop << ROP_SHIFT) | pitch; br14 = (h << HEIGHT_SHIFT) | ((w * (bpp / 8)) << WIDTH_SHIFT); br16 = color; switch (bpp) { case 8: br13 |= COLOR_DEPTH_8; break; case 16: br13 |= COLOR_DEPTH_16; break; case 32: br13 |= COLOR_DEPTH_32; br00 |= WRITE_ALPHA | WRITE_RGB; break; } START_RING(6); OUT_RING(br00); OUT_RING(br13); OUT_RING(br14); OUT_RING(br09); OUT_RING(br16); OUT_RING(MI_NOOP); ADVANCE_RING(); #if VERBOSE > 0 DBG_MSG("ring = 0x%08x, 0x%08x (%d)\n", dinfo->ring_head, dinfo->ring_tail, dinfo->ring_space); #endif } void intelfbhw_do_bitblt(struct intelfb_info *dinfo, u32 curx, u32 cury, u32 dstx, u32 dsty, u32 w, u32 h, u32 pitch, u32 bpp) { u32 br00, br09, br11, br12, br13, br22, br23, br26; #if VERBOSE > 0 DBG_MSG("intelfbhw_do_bitblt: (%d,%d)->(%d,%d) %dx%d, p %d bpp %d\n", curx, cury, dstx, dsty, w, h, pitch, bpp); #endif br00 = XY_SRC_COPY_BLT_CMD; br09 = dinfo->fb_start; br11 = (pitch << PITCH_SHIFT); br12 = dinfo->fb_start; br13 = (SRC_ROP_GXCOPY << ROP_SHIFT) | (pitch << PITCH_SHIFT); br22 = (dstx << WIDTH_SHIFT) | (dsty << HEIGHT_SHIFT); br23 = ((dstx + w) << WIDTH_SHIFT) | ((dsty + h) << HEIGHT_SHIFT); br26 = (curx << WIDTH_SHIFT) | (cury << HEIGHT_SHIFT); switch (bpp) { case 8: br13 |= COLOR_DEPTH_8; break; case 16: br13 |= COLOR_DEPTH_16; break; case 32: br13 |= COLOR_DEPTH_32; br00 |= WRITE_ALPHA | WRITE_RGB; break; } START_RING(8); OUT_RING(br00); OUT_RING(br13); OUT_RING(br22); OUT_RING(br23); OUT_RING(br09); OUT_RING(br26); OUT_RING(br11); OUT_RING(br12); ADVANCE_RING(); } int intelfbhw_do_drawglyph(struct intelfb_info *dinfo, u32 fg, u32 bg, u32 w, u32 h, const u8* cdat, u32 x, u32 y, u32 pitch, u32 bpp) { int nbytes, ndwords, pad, tmp; u32 br00, br09, br13, br18, br19, br22, br23; int dat, ix, iy, iw; int i, j; #if VERBOSE > 0 DBG_MSG("intelfbhw_do_drawglyph: (%d,%d) %dx%d\n", x, y, w, h); #endif /* size in bytes of a padded scanline */ nbytes = ROUND_UP_TO(w, 16) / 8; /* Total bytes of padded scanline data to write out. */ nbytes = nbytes * h; /* * Check if the glyph data exceeds the immediate mode limit. * It would take a large font (1K pixels) to hit this limit. */ if (nbytes > MAX_MONO_IMM_SIZE) return 0; /* Src data is packaged a dword (32-bit) at a time. */ ndwords = ROUND_UP_TO(nbytes, 4) / 4; /* * Ring has to be padded to a quad word. But because the command starts with 7 bytes, pad only if there is an even number of ndwords */ pad = !(ndwords % 2); tmp = (XY_MONO_SRC_IMM_BLT_CMD & DW_LENGTH_MASK) + ndwords; br00 = (XY_MONO_SRC_IMM_BLT_CMD & ~DW_LENGTH_MASK) | tmp; br09 = dinfo->fb_start; br13 = (SRC_ROP_GXCOPY << ROP_SHIFT) | (pitch << PITCH_SHIFT); br18 = bg; br19 = fg; br22 = (x << WIDTH_SHIFT) | (y << HEIGHT_SHIFT); br23 = ((x + w) << WIDTH_SHIFT) | ((y + h) << HEIGHT_SHIFT); switch (bpp) { case 8: br13 |= COLOR_DEPTH_8; break; case 16: br13 |= COLOR_DEPTH_16; break; case 32: br13 |= COLOR_DEPTH_32; br00 |= WRITE_ALPHA | WRITE_RGB; break; } START_RING(8 + ndwords); OUT_RING(br00); OUT_RING(br13); OUT_RING(br22); OUT_RING(br23); OUT_RING(br09); OUT_RING(br18); OUT_RING(br19); ix = iy = 0; iw = ROUND_UP_TO(w, 8) / 8; while (ndwords--) { dat = 0; for (j = 0; j < 2; ++j) { for (i = 0; i < 2; ++i) { if (ix != iw || i == 0) dat |= cdat[iy*iw + ix++] << (i+j*2)*8; } if (ix == iw && iy != (h-1)) { ix = 0; ++iy; } } OUT_RING(dat); } if (pad) OUT_RING(MI_NOOP); ADVANCE_RING(); return 1; } /* HW cursor functions. */ void intelfbhw_cursor_init(struct intelfb_info *dinfo) { u32 tmp; #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_init\n"); #endif if (dinfo->mobile || IS_I9XX(dinfo)) { if (!dinfo->cursor.physical) return; tmp = INREG(CURSOR_A_CONTROL); tmp &= ~(CURSOR_MODE_MASK | CURSOR_MOBILE_GAMMA_ENABLE | CURSOR_MEM_TYPE_LOCAL | (1 << CURSOR_PIPE_SELECT_SHIFT)); tmp |= CURSOR_MODE_DISABLE; OUTREG(CURSOR_A_CONTROL, tmp); OUTREG(CURSOR_A_BASEADDR, dinfo->cursor.physical); } else { tmp = INREG(CURSOR_CONTROL); tmp &= ~(CURSOR_FORMAT_MASK | CURSOR_GAMMA_ENABLE | CURSOR_ENABLE | CURSOR_STRIDE_MASK); tmp |= CURSOR_FORMAT_3C; OUTREG(CURSOR_CONTROL, tmp); OUTREG(CURSOR_A_BASEADDR, dinfo->cursor.offset << 12); tmp = (64 << CURSOR_SIZE_H_SHIFT) | (64 << CURSOR_SIZE_V_SHIFT); OUTREG(CURSOR_SIZE, tmp); } } void intelfbhw_cursor_hide(struct intelfb_info *dinfo) { u32 tmp; #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_hide\n"); #endif dinfo->cursor_on = 0; if (dinfo->mobile || IS_I9XX(dinfo)) { if (!dinfo->cursor.physical) return; tmp = INREG(CURSOR_A_CONTROL); tmp &= ~CURSOR_MODE_MASK; tmp |= CURSOR_MODE_DISABLE; OUTREG(CURSOR_A_CONTROL, tmp); /* Flush changes */ OUTREG(CURSOR_A_BASEADDR, dinfo->cursor.physical); } else { tmp = INREG(CURSOR_CONTROL); tmp &= ~CURSOR_ENABLE; OUTREG(CURSOR_CONTROL, tmp); } } void intelfbhw_cursor_show(struct intelfb_info *dinfo) { u32 tmp; #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_show\n"); #endif dinfo->cursor_on = 1; if (dinfo->cursor_blanked) return; if (dinfo->mobile || IS_I9XX(dinfo)) { if (!dinfo->cursor.physical) return; tmp = INREG(CURSOR_A_CONTROL); tmp &= ~CURSOR_MODE_MASK; tmp |= CURSOR_MODE_64_4C_AX; OUTREG(CURSOR_A_CONTROL, tmp); /* Flush changes */ OUTREG(CURSOR_A_BASEADDR, dinfo->cursor.physical); } else { tmp = INREG(CURSOR_CONTROL); tmp |= CURSOR_ENABLE; OUTREG(CURSOR_CONTROL, tmp); } } void intelfbhw_cursor_setpos(struct intelfb_info *dinfo, int x, int y) { u32 tmp; #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_setpos: (%d, %d)\n", x, y); #endif /* * Sets the position. The coordinates are assumed to already * have any offset adjusted. Assume that the cursor is never * completely off-screen, and that x, y are always >= 0. */ tmp = ((x & CURSOR_POS_MASK) << CURSOR_X_SHIFT) | ((y & CURSOR_POS_MASK) << CURSOR_Y_SHIFT); OUTREG(CURSOR_A_POSITION, tmp); if (IS_I9XX(dinfo)) OUTREG(CURSOR_A_BASEADDR, dinfo->cursor.physical); } void intelfbhw_cursor_setcolor(struct intelfb_info *dinfo, u32 bg, u32 fg) { #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_setcolor\n"); #endif OUTREG(CURSOR_A_PALETTE0, bg & CURSOR_PALETTE_MASK); OUTREG(CURSOR_A_PALETTE1, fg & CURSOR_PALETTE_MASK); OUTREG(CURSOR_A_PALETTE2, fg & CURSOR_PALETTE_MASK); OUTREG(CURSOR_A_PALETTE3, bg & CURSOR_PALETTE_MASK); } void intelfbhw_cursor_load(struct intelfb_info *dinfo, int width, int height, u8 *data) { u8 __iomem *addr = (u8 __iomem *)dinfo->cursor.virtual; int i, j, w = width / 8; int mod = width % 8, t_mask, d_mask; #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_load\n"); #endif if (!dinfo->cursor.virtual) return; t_mask = 0xff >> mod; d_mask = ~(0xff >> mod); for (i = height; i--; ) { for (j = 0; j < w; j++) { writeb(0x00, addr + j); writeb(*(data++), addr + j+8); } if (mod) { writeb(t_mask, addr + j); writeb(*(data++) & d_mask, addr + j+8); } addr += 16; } } void intelfbhw_cursor_reset(struct intelfb_info *dinfo) { u8 __iomem *addr = (u8 __iomem *)dinfo->cursor.virtual; int i, j; #if VERBOSE > 0 DBG_MSG("intelfbhw_cursor_reset\n"); #endif if (!dinfo->cursor.virtual) return; for (i = 64; i--; ) { for (j = 0; j < 8; j++) { writeb(0xff, addr + j+0); writeb(0x00, addr + j+8); } addr += 16; } } static irqreturn_t intelfbhw_irq(int irq, void *dev_id) { u16 tmp; struct intelfb_info *dinfo = dev_id; spin_lock(&dinfo->int_lock); tmp = INREG16(IIR); if (dinfo->info->var.vmode & FB_VMODE_INTERLACED) tmp &= PIPE_A_EVENT_INTERRUPT; else tmp &= VSYNC_PIPE_A_INTERRUPT; /* non-interlaced */ if (tmp == 0) { spin_unlock(&dinfo->int_lock); return IRQ_RETVAL(0); /* not us */ } /* clear status bits 0-15 ASAP and don't touch bits 16-31 */ OUTREG(PIPEASTAT, INREG(PIPEASTAT)); OUTREG16(IIR, tmp); if (dinfo->vsync.pan_display) { dinfo->vsync.pan_display = 0; OUTREG(DSPABASE, dinfo->vsync.pan_offset); } dinfo->vsync.count++; wake_up_interruptible(&dinfo->vsync.wait); spin_unlock(&dinfo->int_lock); return IRQ_RETVAL(1); } int intelfbhw_enable_irq(struct intelfb_info *dinfo) { u16 tmp; if (!test_and_set_bit(0, &dinfo->irq_flags)) { if (request_irq(dinfo->pdev->irq, intelfbhw_irq, IRQF_SHARED, "intelfb", dinfo)) { clear_bit(0, &dinfo->irq_flags); return -EINVAL; } spin_lock_irq(&dinfo->int_lock); OUTREG16(HWSTAM, 0xfffe); /* i830 DRM uses ffff */ OUTREG16(IMR, 0); } else spin_lock_irq(&dinfo->int_lock); if (dinfo->info->var.vmode & FB_VMODE_INTERLACED) tmp = PIPE_A_EVENT_INTERRUPT; else tmp = VSYNC_PIPE_A_INTERRUPT; /* non-interlaced */ if (tmp != INREG16(IER)) { DBG_MSG("changing IER to 0x%X\n", tmp); OUTREG16(IER, tmp); } spin_unlock_irq(&dinfo->int_lock); return 0; } void intelfbhw_disable_irq(struct intelfb_info *dinfo) { if (test_and_clear_bit(0, &dinfo->irq_flags)) { if (dinfo->vsync.pan_display) { dinfo->vsync.pan_display = 0; OUTREG(DSPABASE, dinfo->vsync.pan_offset); } spin_lock_irq(&dinfo->int_lock); OUTREG16(HWSTAM, 0xffff); OUTREG16(IMR, 0xffff); OUTREG16(IER, 0x0); OUTREG16(IIR, INREG16(IIR)); /* clear IRQ requests */ spin_unlock_irq(&dinfo->int_lock); free_irq(dinfo->pdev->irq, dinfo); } } int intelfbhw_wait_for_vsync(struct intelfb_info *dinfo, u32 pipe) { struct intelfb_vsync *vsync; unsigned int count; int ret; switch (pipe) { case 0: vsync = &dinfo->vsync; break; default: return -ENODEV; } ret = intelfbhw_enable_irq(dinfo); if (ret) return ret; count = vsync->count; ret = wait_event_interruptible_timeout(vsync->wait, count != vsync->count, HZ / 10); if (ret < 0) return ret; if (ret == 0) { DBG_MSG("wait_for_vsync timed out!\n"); return -ETIMEDOUT; } return 0; } |