drivers/gpu/drm/gma500/psb_intel_display.c - kernel/bruno - Git at Google

 /*
  * Copyright Â© 2006-2011 Intel Corporation
  *
  * This program is free software; you can redistribute it and/or modify it
  * under the terms and conditions of the GNU General Public License,
  * version 2, as published by the Free Software Foundation.
  *
  * This program is distributed in the hope it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
  * more details.
  *
  * You should have received a copy of the GNU General Public License along with
  * this program; if not, write to the Free Software Foundation, Inc.,
  * 51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Authors:
  *	Eric Anholt <eric@anholt.net>
  */

 #include <linux/i2c.h>

 #include <drm/drmP.h>
 #include <drm/drm_plane_helper.h>
 #include "framebuffer.h"
 #include "psb_drv.h"
 #include "psb_intel_drv.h"
 #include "psb_intel_reg.h"
 #include "gma_display.h"
 #include "power.h"

 #define INTEL_LIMIT_I9XX_SDVO_DAC   0
 #define INTEL_LIMIT_I9XX_LVDS	    1

 static const struct gma_limit_t psb_intel_limits[] = {
 	{			/* INTEL_LIMIT_I9XX_SDVO_DAC */
 	 .dot = {.min = 20000, .max = 400000},
 	 .vco = {.min = 1400000, .max = 2800000},
 	 .n = {.min = 1, .max = 6},
 	 .m = {.min = 70, .max = 120},
 	 .m1 = {.min = 8, .max = 18},
 	 .m2 = {.min = 3, .max = 7},
 	 .p = {.min = 5, .max = 80},
 	 .p1 = {.min = 1, .max = 8},
 	 .p2 = {.dot_limit = 200000, .p2_slow = 10, .p2_fast = 5},
 	 .find_pll = gma_find_best_pll,
 	 },
 	{			/* INTEL_LIMIT_I9XX_LVDS */
 	 .dot = {.min = 20000, .max = 400000},
 	 .vco = {.min = 1400000, .max = 2800000},
 	 .n = {.min = 1, .max = 6},
 	 .m = {.min = 70, .max = 120},
 	 .m1 = {.min = 8, .max = 18},
 	 .m2 = {.min = 3, .max = 7},
 	 .p = {.min = 7, .max = 98},
 	 .p1 = {.min = 1, .max = 8},
 	 /* The single-channel range is 25-112Mhz, and dual-channel
 	  * is 80-224Mhz.  Prefer single channel as much as possible.
 	  */
 	 .p2 = {.dot_limit = 112000, .p2_slow = 14, .p2_fast = 7},
 	 .find_pll = gma_find_best_pll,
 	 },
 };

 static const struct gma_limit_t *psb_intel_limit(struct drm_crtc *crtc,
 						 int refclk)
 {
 	const struct gma_limit_t *limit;

 	if (gma_pipe_has_type(crtc, INTEL_OUTPUT_LVDS))
 		limit = &psb_intel_limits[INTEL_LIMIT_I9XX_LVDS];
 	else
 		limit = &psb_intel_limits[INTEL_LIMIT_I9XX_SDVO_DAC];
 	return limit;
 }

 static void psb_intel_clock(int refclk, struct gma_clock_t *clock)
 {
 	clock->m = 5 * (clock->m1 + 2) + (clock->m2 + 2);
 	clock->p = clock->p1 * clock->p2;
 	clock->vco = refclk * clock->m / (clock->n + 2);
 	clock->dot = clock->vco / clock->p;
 }

 /**
  * Return the pipe currently connected to the panel fitter,
  * or -1 if the panel fitter is not present or not in use
  */
 static int psb_intel_panel_fitter_pipe(struct drm_device *dev)
 {
 	u32 pfit_control;

 	pfit_control = REG_READ(PFIT_CONTROL);

 	/* See if the panel fitter is in use */
 	if ((pfit_control & PFIT_ENABLE) == 0)
 		return -1;
 	/* Must be on PIPE 1 for PSB */
 	return 1;
 }

 static int psb_intel_crtc_mode_set(struct drm_crtc *crtc,
 			       struct drm_display_mode *mode,
 			       struct drm_display_mode *adjusted_mode,
 			       int x, int y,
 			       struct drm_framebuffer *old_fb)
 {
 	struct drm_device *dev = crtc->dev;
 	struct drm_psb_private *dev_priv = dev->dev_private;
 	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
 	const struct drm_crtc_helper_funcs *crtc_funcs = crtc->helper_private;
 	int pipe = gma_crtc->pipe;
 	const struct psb_offset *map = &dev_priv->regmap[pipe];
 	int refclk;
 	struct gma_clock_t clock;
 	u32 dpll = 0, fp = 0, dspcntr, pipeconf;
 	bool ok, is_sdvo = false;
 	bool is_lvds = false, is_tv = false;
 	struct drm_mode_config *mode_config = &dev->mode_config;
 	struct drm_connector *connector;
 	const struct gma_limit_t *limit;

 	/* No scan out no play */
 	if (crtc->primary->fb == NULL) {
 		crtc_funcs->mode_set_base(crtc, x, y, old_fb);
 		return 0;
 	}

 	list_for_each_entry(connector, &mode_config->connector_list, head) {
 		struct gma_encoder *gma_encoder = gma_attached_encoder(connector);

 		if (!connector->encoder
 		    || connector->encoder->crtc != crtc)
 			continue;

 		switch (gma_encoder->type) {
 		case INTEL_OUTPUT_LVDS:
 			is_lvds = true;
 			break;
 		case INTEL_OUTPUT_SDVO:
 			is_sdvo = true;
 			break;
 		case INTEL_OUTPUT_TVOUT:
 			is_tv = true;
 			break;
 		}
 	}

 	refclk = 96000;

 	limit = gma_crtc->clock_funcs->limit(crtc, refclk);

 	ok = limit->find_pll(limit, crtc, adjusted_mode->clock, refclk,
 				 &clock);
 	if (!ok) {
 		DRM_ERROR("Couldn't find PLL settings for mode! target: %d, actual: %d",
 			  adjusted_mode->clock, clock.dot);
 		return 0;
 	}

 	fp = clock.n << 16 | clock.m1 << 8 | clock.m2;

 	dpll = DPLL_VGA_MODE_DIS;
 	if (is_lvds) {
 		dpll |= DPLLB_MODE_LVDS;
 		dpll |= DPLL_DVO_HIGH_SPEED;
 	} else
 		dpll |= DPLLB_MODE_DAC_SERIAL;
 	if (is_sdvo) {
 		int sdvo_pixel_multiply =
 			    adjusted_mode->clock / mode->clock;
 		dpll |= DPLL_DVO_HIGH_SPEED;
 		dpll |=
 		    (sdvo_pixel_multiply - 1) << SDVO_MULTIPLIER_SHIFT_HIRES;
 	}

 	/* compute bitmask from p1 value */
 	dpll |= (1 << (clock.p1 - 1)) << 16;
 	switch (clock.p2) {
 	case 5:
 		dpll |= DPLL_DAC_SERIAL_P2_CLOCK_DIV_5;
 		break;
 	case 7:
 		dpll |= DPLLB_LVDS_P2_CLOCK_DIV_7;
 		break;
 	case 10:
 		dpll |= DPLL_DAC_SERIAL_P2_CLOCK_DIV_10;
 		break;
 	case 14:
 		dpll |= DPLLB_LVDS_P2_CLOCK_DIV_14;
 		break;
 	}

 	if (is_tv) {
 		/* XXX: just matching BIOS for now */
 /*	dpll |= PLL_REF_INPUT_TVCLKINBC; */
 		dpll |= 3;
 	}
 	dpll |= PLL_REF_INPUT_DREFCLK;

 	/* setup pipeconf */
 	pipeconf = REG_READ(map->conf);

 	/* Set up the display plane register */
 	dspcntr = DISPPLANE_GAMMA_ENABLE;

 	if (pipe == 0)
 		dspcntr |= DISPPLANE_SEL_PIPE_A;
 	else
 		dspcntr |= DISPPLANE_SEL_PIPE_B;

 	dspcntr |= DISPLAY_PLANE_ENABLE;
 	pipeconf |= PIPEACONF_ENABLE;
 	dpll |= DPLL_VCO_ENABLE;


 	/* Disable the panel fitter if it was on our pipe */
 	if (psb_intel_panel_fitter_pipe(dev) == pipe)
 		REG_WRITE(PFIT_CONTROL, 0);

 	drm_mode_debug_printmodeline(mode);

 	if (dpll & DPLL_VCO_ENABLE) {
 		REG_WRITE(map->fp0, fp);
 		REG_WRITE(map->dpll, dpll & ~DPLL_VCO_ENABLE);
 		REG_READ(map->dpll);
 		udelay(150);
 	}

 	/* The LVDS pin pair needs to be on before the DPLLs are enabled.
 	 * This is an exception to the general rule that mode_set doesn't turn
 	 * things on.
 	 */
 	if (is_lvds) {
 		u32 lvds = REG_READ(LVDS);

 		lvds &= ~LVDS_PIPEB_SELECT;
 		if (pipe == 1)
 			lvds |= LVDS_PIPEB_SELECT;

 		lvds |= LVDS_PORT_EN | LVDS_A0A2_CLKA_POWER_UP;
 		/* Set the B0-B3 data pairs corresponding to
 		 * whether we're going to
 		 * set the DPLLs for dual-channel mode or not.
 		 */
 		lvds &= ~(LVDS_B0B3_POWER_UP | LVDS_CLKB_POWER_UP);
 		if (clock.p2 == 7)
 			lvds |= LVDS_B0B3_POWER_UP | LVDS_CLKB_POWER_UP;

 		/* It would be nice to set 24 vs 18-bit mode (LVDS_A3_POWER_UP)
 		 * appropriately here, but we need to look more
 		 * thoroughly into how panels behave in the two modes.
 		 */

 		REG_WRITE(LVDS, lvds);
 		REG_READ(LVDS);
 	}

 	REG_WRITE(map->fp0, fp);
 	REG_WRITE(map->dpll, dpll);
 	REG_READ(map->dpll);
 	/* Wait for the clocks to stabilize. */
 	udelay(150);

 	/* write it again -- the BIOS does, after all */
 	REG_WRITE(map->dpll, dpll);

 	REG_READ(map->dpll);
 	/* Wait for the clocks to stabilize. */
 	udelay(150);

 	REG_WRITE(map->htotal, (adjusted_mode->crtc_hdisplay - 1) |
 		  ((adjusted_mode->crtc_htotal - 1) << 16));
 	REG_WRITE(map->hblank, (adjusted_mode->crtc_hblank_start - 1) |
 		  ((adjusted_mode->crtc_hblank_end - 1) << 16));
 	REG_WRITE(map->hsync, (adjusted_mode->crtc_hsync_start - 1) |
 		  ((adjusted_mode->crtc_hsync_end - 1) << 16));
 	REG_WRITE(map->vtotal, (adjusted_mode->crtc_vdisplay - 1) |
 		  ((adjusted_mode->crtc_vtotal - 1) << 16));
 	REG_WRITE(map->vblank, (adjusted_mode->crtc_vblank_start - 1) |
 		  ((adjusted_mode->crtc_vblank_end - 1) << 16));
 	REG_WRITE(map->vsync, (adjusted_mode->crtc_vsync_start - 1) |
 		  ((adjusted_mode->crtc_vsync_end - 1) << 16));
 	/* pipesrc and dspsize control the size that is scaled from,
 	 * which should always be the user's requested size.
 	 */
 	REG_WRITE(map->size,
 		  ((mode->vdisplay - 1) << 16) | (mode->hdisplay - 1));
 	REG_WRITE(map->pos, 0);
 	REG_WRITE(map->src,
 		  ((mode->hdisplay - 1) << 16) | (mode->vdisplay - 1));
 	REG_WRITE(map->conf, pipeconf);
 	REG_READ(map->conf);

 	gma_wait_for_vblank(dev);

 	REG_WRITE(map->cntr, dspcntr);

 	/* Flush the plane changes */
 	crtc_funcs->mode_set_base(crtc, x, y, old_fb);

 	gma_wait_for_vblank(dev);

 	return 0;
 }

 /* Returns the clock of the currently programmed mode of the given pipe. */
 static int psb_intel_crtc_clock_get(struct drm_device *dev,
 				struct drm_crtc *crtc)
 {
 	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
 	struct drm_psb_private *dev_priv = dev->dev_private;
 	int pipe = gma_crtc->pipe;
 	const struct psb_offset *map = &dev_priv->regmap[pipe];
 	u32 dpll;
 	u32 fp;
 	struct gma_clock_t clock;
 	bool is_lvds;
 	struct psb_pipe *p = &dev_priv->regs.pipe[pipe];

 	if (gma_power_begin(dev, false)) {
 		dpll = REG_READ(map->dpll);
 		if ((dpll & DISPLAY_RATE_SELECT_FPA1) == 0)
 			fp = REG_READ(map->fp0);
 		else
 			fp = REG_READ(map->fp1);
 		is_lvds = (pipe == 1) && (REG_READ(LVDS) & LVDS_PORT_EN);
 		gma_power_end(dev);
 	} else {
 		dpll = p->dpll;

 		if ((dpll & DISPLAY_RATE_SELECT_FPA1) == 0)
 			fp = p->fp0;
 		else
 		        fp = p->fp1;

 		is_lvds = (pipe == 1) && (dev_priv->regs.psb.saveLVDS &
 								LVDS_PORT_EN);
 	}

 	clock.m1 = (fp & FP_M1_DIV_MASK) >> FP_M1_DIV_SHIFT;
 	clock.m2 = (fp & FP_M2_DIV_MASK) >> FP_M2_DIV_SHIFT;
 	clock.n = (fp & FP_N_DIV_MASK) >> FP_N_DIV_SHIFT;

 	if (is_lvds) {
 		clock.p1 =
 		    ffs((dpll &
 			 DPLL_FPA01_P1_POST_DIV_MASK_I830_LVDS) >>
 			DPLL_FPA01_P1_POST_DIV_SHIFT);
 		clock.p2 = 14;

 		if ((dpll & PLL_REF_INPUT_MASK) ==
 		    PLLB_REF_INPUT_SPREADSPECTRUMIN) {
 			/* XXX: might not be 66MHz */
 			psb_intel_clock(66000, &clock);
 		} else
 			psb_intel_clock(48000, &clock);
 	} else {
 		if (dpll & PLL_P1_DIVIDE_BY_TWO)
 			clock.p1 = 2;
 		else {
 			clock.p1 =
 			    ((dpll &
 			      DPLL_FPA01_P1_POST_DIV_MASK_I830) >>
 			     DPLL_FPA01_P1_POST_DIV_SHIFT) + 2;
 		}
 		if (dpll & PLL_P2_DIVIDE_BY_4)
 			clock.p2 = 4;
 		else
 			clock.p2 = 2;

 		psb_intel_clock(48000, &clock);
 	}

 	/* XXX: It would be nice to validate the clocks, but we can't reuse
 	 * i830PllIsValid() because it relies on the xf86_config connector
 	 * configuration being accurate, which it isn't necessarily.
 	 */

 	return clock.dot;
 }

 /** Returns the currently programmed mode of the given pipe. */
 struct drm_display_mode *psb_intel_crtc_mode_get(struct drm_device *dev,
 					     struct drm_crtc *crtc)
 {
 	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
 	int pipe = gma_crtc->pipe;
 	struct drm_display_mode *mode;
 	int htot;
 	int hsync;
 	int vtot;
 	int vsync;
 	struct drm_psb_private *dev_priv = dev->dev_private;
 	struct psb_pipe *p = &dev_priv->regs.pipe[pipe];
 	const struct psb_offset *map = &dev_priv->regmap[pipe];

 	if (gma_power_begin(dev, false)) {
 		htot = REG_READ(map->htotal);
 		hsync = REG_READ(map->hsync);
 		vtot = REG_READ(map->vtotal);
 		vsync = REG_READ(map->vsync);
 		gma_power_end(dev);
 	} else {
 		htot = p->htotal;
 		hsync = p->hsync;
 		vtot = p->vtotal;
 		vsync = p->vsync;
 	}

 	mode = kzalloc(sizeof(*mode), GFP_KERNEL);
 	if (!mode)
 		return NULL;

 	mode->clock = psb_intel_crtc_clock_get(dev, crtc);
 	mode->hdisplay = (htot & 0xffff) + 1;
 	mode->htotal = ((htot & 0xffff0000) >> 16) + 1;
 	mode->hsync_start = (hsync & 0xffff) + 1;
 	mode->hsync_end = ((hsync & 0xffff0000) >> 16) + 1;
 	mode->vdisplay = (vtot & 0xffff) + 1;
 	mode->vtotal = ((vtot & 0xffff0000) >> 16) + 1;
 	mode->vsync_start = (vsync & 0xffff) + 1;
 	mode->vsync_end = ((vsync & 0xffff0000) >> 16) + 1;

 	drm_mode_set_name(mode);
 	drm_mode_set_crtcinfo(mode, 0);

 	return mode;
 }

 const struct drm_crtc_helper_funcs psb_intel_helper_funcs = {
 	.dpms = gma_crtc_dpms,
 	.mode_fixup = gma_crtc_mode_fixup,
 	.mode_set = psb_intel_crtc_mode_set,
 	.mode_set_base = gma_pipe_set_base,
 	.prepare = gma_crtc_prepare,
 	.commit = gma_crtc_commit,
 	.disable = gma_crtc_disable,
 };

 const struct drm_crtc_funcs psb_intel_crtc_funcs = {
 	.save = gma_crtc_save,
 	.restore = gma_crtc_restore,
 	.cursor_set = gma_crtc_cursor_set,
 	.cursor_move = gma_crtc_cursor_move,
 	.gamma_set = gma_crtc_gamma_set,
 	.set_config = gma_crtc_set_config,
 	.destroy = gma_crtc_destroy,
 };

 const struct gma_clock_funcs psb_clock_funcs = {
 	.clock = psb_intel_clock,
 	.limit = psb_intel_limit,
 	.pll_is_valid = gma_pll_is_valid,
 };

 /*
  * Set the default value of cursor control and base register
  * to zero. This is a workaround for h/w defect on Oaktrail
  */
 static void psb_intel_cursor_init(struct drm_device *dev,
 				  struct gma_crtc *gma_crtc)
 {
 	struct drm_psb_private *dev_priv = dev->dev_private;
 	u32 control[3] = { CURACNTR, CURBCNTR, CURCCNTR };
 	u32 base[3] = { CURABASE, CURBBASE, CURCBASE };
 	struct gtt_range *cursor_gt;

 	if (dev_priv->ops->cursor_needs_phys) {
 		/* Allocate 4 pages of stolen mem for a hardware cursor. That
 		 * is enough for the 64 x 64 ARGB cursors we support.
 		 */
 		cursor_gt = psb_gtt_alloc_range(dev, 4 * PAGE_SIZE, "cursor", 1,
 						PAGE_SIZE);
 		if (!cursor_gt) {
 			gma_crtc->cursor_gt = NULL;
 			goto out;
 		}
 		gma_crtc->cursor_gt = cursor_gt;
 		gma_crtc->cursor_addr = dev_priv->stolen_base +
 							cursor_gt->offset;
 	} else {
 		gma_crtc->cursor_gt = NULL;
 	}

 out:
 	REG_WRITE(control[gma_crtc->pipe], 0);
 	REG_WRITE(base[gma_crtc->pipe], 0);
 }

 void psb_intel_crtc_init(struct drm_device *dev, int pipe,
 		     struct psb_intel_mode_device *mode_dev)
 {
 	struct drm_psb_private *dev_priv = dev->dev_private;
 	struct gma_crtc *gma_crtc;
 	int i;
 	uint16_t *r_base, *g_base, *b_base;

 	/* We allocate a extra array of drm_connector pointers
 	 * for fbdev after the crtc */
 	gma_crtc = kzalloc(sizeof(struct gma_crtc) +
 			(INTELFB_CONN_LIMIT * sizeof(struct drm_connector *)),
 			GFP_KERNEL);
 	if (gma_crtc == NULL)
 		return;

 	gma_crtc->crtc_state =
 		kzalloc(sizeof(struct psb_intel_crtc_state), GFP_KERNEL);
 	if (!gma_crtc->crtc_state) {
 		dev_err(dev->dev, "Crtc state error: No memory\n");
 		kfree(gma_crtc);
 		return;
 	}

 	/* Set the CRTC operations from the chip specific data */
 	drm_crtc_init(dev, &gma_crtc->base, dev_priv->ops->crtc_funcs);

 	/* Set the CRTC clock functions from chip specific data */
 	gma_crtc->clock_funcs = dev_priv->ops->clock_funcs;

 	drm_mode_crtc_set_gamma_size(&gma_crtc->base, 256);
 	gma_crtc->pipe = pipe;
 	gma_crtc->plane = pipe;

 	r_base = gma_crtc->base.gamma_store;
 	g_base = r_base + 256;
 	b_base = g_base + 256;
 	for (i = 0; i < 256; i++) {
 		gma_crtc->lut_r[i] = i;
 		gma_crtc->lut_g[i] = i;
 		gma_crtc->lut_b[i] = i;
 		r_base[i] = i << 8;
 		g_base[i] = i << 8;
 		b_base[i] = i << 8;

 		gma_crtc->lut_adj[i] = 0;
 	}

 	gma_crtc->mode_dev = mode_dev;
 	gma_crtc->cursor_addr = 0;

 	drm_crtc_helper_add(&gma_crtc->base,
 						dev_priv->ops->crtc_helper);

 	/* Setup the array of drm_connector pointer array */
 	gma_crtc->mode_set.crtc = &gma_crtc->base;
 	BUG_ON(pipe >= ARRAY_SIZE(dev_priv->plane_to_crtc_mapping) ||
 	       dev_priv->plane_to_crtc_mapping[gma_crtc->plane] != NULL);
 	dev_priv->plane_to_crtc_mapping[gma_crtc->plane] = &gma_crtc->base;
 	dev_priv->pipe_to_crtc_mapping[gma_crtc->pipe] = &gma_crtc->base;
 	gma_crtc->mode_set.connectors = (struct drm_connector **)(gma_crtc + 1);
 	gma_crtc->mode_set.num_connectors = 0;
 	psb_intel_cursor_init(dev, gma_crtc);

 	/* Set to true so that the pipe is forced off on initial config. */
 	gma_crtc->active = true;
 }

 struct drm_crtc *psb_intel_get_crtc_from_pipe(struct drm_device *dev, int pipe)
 {
 	struct drm_crtc *crtc = NULL;

 	list_for_each_entry(crtc, &dev->mode_config.crtc_list, head) {
 		struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
 		if (gma_crtc->pipe == pipe)
 			break;
 	}
 	return crtc;
 }

 int gma_connector_clones(struct drm_device *dev, int type_mask)
 {
 	int index_mask = 0;
 	struct drm_connector *connector;
 	int entry = 0;

 	list_for_each_entry(connector, &dev->mode_config.connector_list,
 			    head) {
 		struct gma_encoder *gma_encoder = gma_attached_encoder(connector);
 		if (type_mask & (1 << gma_encoder->type))
 			index_mask |= (1 << entry);
 		entry++;
 	}
 	return index_mask;
 }
	/*
	* Copyright Â© 2006-2011 Intel Corporation
	*
	* This program is free software; you can redistribute it and/or modify it
	* under the terms and conditions of the GNU General Public License,
	* version 2, as published by the Free Software Foundation.
	*
	* This program is distributed in the hope it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
	* more details.
	*
	* You should have received a copy of the GNU General Public License along with
	* this program; if not, write to the Free Software Foundation, Inc.,
	* 51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Authors:
	* Eric Anholt <eric@anholt.net>
	*/

	#include <linux/i2c.h>

	#include <drm/drmP.h>
	#include <drm/drm_plane_helper.h>
	#include "framebuffer.h"
	#include "psb_drv.h"
	#include "psb_intel_drv.h"
	#include "psb_intel_reg.h"
	#include "gma_display.h"
	#include "power.h"

	#define INTEL_LIMIT_I9XX_SDVO_DAC 0
	#define INTEL_LIMIT_I9XX_LVDS 1

	static const struct gma_limit_t psb_intel_limits[] = {
	{ /* INTEL_LIMIT_I9XX_SDVO_DAC */
	.dot = {.min = 20000, .max = 400000},
	.vco = {.min = 1400000, .max = 2800000},
	.n = {.min = 1, .max = 6},
	.m = {.min = 70, .max = 120},
	.m1 = {.min = 8, .max = 18},
	.m2 = {.min = 3, .max = 7},
	.p = {.min = 5, .max = 80},
	.p1 = {.min = 1, .max = 8},
	.p2 = {.dot_limit = 200000, .p2_slow = 10, .p2_fast = 5},
	.find_pll = gma_find_best_pll,
	},
	{ /* INTEL_LIMIT_I9XX_LVDS */
	.dot = {.min = 20000, .max = 400000},
	.vco = {.min = 1400000, .max = 2800000},
	.n = {.min = 1, .max = 6},
	.m = {.min = 70, .max = 120},
	.m1 = {.min = 8, .max = 18},
	.m2 = {.min = 3, .max = 7},
	.p = {.min = 7, .max = 98},
	.p1 = {.min = 1, .max = 8},
	/* The single-channel range is 25-112Mhz, and dual-channel
	* is 80-224Mhz. Prefer single channel as much as possible.
	*/
	.p2 = {.dot_limit = 112000, .p2_slow = 14, .p2_fast = 7},
	.find_pll = gma_find_best_pll,
	},
	};

	static const struct gma_limit_t psb_intel_limit(struct drm_crtc crtc,
	int refclk)
	{
	const struct gma_limit_t *limit;

	if (gma_pipe_has_type(crtc, INTEL_OUTPUT_LVDS))
	limit = &psb_intel_limits[INTEL_LIMIT_I9XX_LVDS];
	else
	limit = &psb_intel_limits[INTEL_LIMIT_I9XX_SDVO_DAC];
	return limit;
	}

	static void psb_intel_clock(int refclk, struct gma_clock_t *clock)
	{
	clock->m = 5 * (clock->m1 + 2) + (clock->m2 + 2);
	clock->p = clock->p1 * clock->p2;
	clock->vco = refclk * clock->m / (clock->n + 2);
	clock->dot = clock->vco / clock->p;
	}

	/**
	* Return the pipe currently connected to the panel fitter,
	* or -1 if the panel fitter is not present or not in use
	*/
	static int psb_intel_panel_fitter_pipe(struct drm_device *dev)
	{
	u32 pfit_control;

	pfit_control = REG_READ(PFIT_CONTROL);

	/* See if the panel fitter is in use */
	if ((pfit_control & PFIT_ENABLE) == 0)
	return -1;
	/* Must be on PIPE 1 for PSB */
	return 1;
	}

	static int psb_intel_crtc_mode_set(struct drm_crtc *crtc,
	struct drm_display_mode *mode,
	struct drm_display_mode *adjusted_mode,
	int x, int y,
	struct drm_framebuffer *old_fb)
	{
	struct drm_device *dev = crtc->dev;
	struct drm_psb_private *dev_priv = dev->dev_private;
	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
	const struct drm_crtc_helper_funcs *crtc_funcs = crtc->helper_private;
	int pipe = gma_crtc->pipe;
	const struct psb_offset *map = &dev_priv->regmap[pipe];
	int refclk;
	struct gma_clock_t clock;
	u32 dpll = 0, fp = 0, dspcntr, pipeconf;
	bool ok, is_sdvo = false;
	bool is_lvds = false, is_tv = false;
	struct drm_mode_config *mode_config = &dev->mode_config;
	struct drm_connector *connector;
	const struct gma_limit_t *limit;

	/* No scan out no play */
	if (crtc->primary->fb == NULL) {
	crtc_funcs->mode_set_base(crtc, x, y, old_fb);
	return 0;
	}

	list_for_each_entry(connector, &mode_config->connector_list, head) {
	struct gma_encoder *gma_encoder = gma_attached_encoder(connector);

	if (!connector->encoder
	\|\| connector->encoder->crtc != crtc)
	continue;

	switch (gma_encoder->type) {
	case INTEL_OUTPUT_LVDS:
	is_lvds = true;
	break;
	case INTEL_OUTPUT_SDVO:
	is_sdvo = true;
	break;
	case INTEL_OUTPUT_TVOUT:
	is_tv = true;
	break;
	}
	}

	refclk = 96000;

	limit = gma_crtc->clock_funcs->limit(crtc, refclk);

	ok = limit->find_pll(limit, crtc, adjusted_mode->clock, refclk,
	&clock);
	if (!ok) {
	DRM_ERROR("Couldn't find PLL settings for mode! target: %d, actual: %d",
	adjusted_mode->clock, clock.dot);
	return 0;
	}

	fp = clock.n << 16 \| clock.m1 << 8 \| clock.m2;

	dpll = DPLL_VGA_MODE_DIS;
	if (is_lvds) {
	dpll \|= DPLLB_MODE_LVDS;
	dpll \|= DPLL_DVO_HIGH_SPEED;
	} else
	dpll \|= DPLLB_MODE_DAC_SERIAL;
	if (is_sdvo) {
	int sdvo_pixel_multiply =
	adjusted_mode->clock / mode->clock;
	dpll \|= DPLL_DVO_HIGH_SPEED;
	dpll \|=
	(sdvo_pixel_multiply - 1) << SDVO_MULTIPLIER_SHIFT_HIRES;
	}

	/* compute bitmask from p1 value */
	dpll \|= (1 << (clock.p1 - 1)) << 16;
	switch (clock.p2) {
	case 5:
	dpll \|= DPLL_DAC_SERIAL_P2_CLOCK_DIV_5;
	break;
	case 7:
	dpll \|= DPLLB_LVDS_P2_CLOCK_DIV_7;
	break;
	case 10:
	dpll \|= DPLL_DAC_SERIAL_P2_CLOCK_DIV_10;
	break;
	case 14:
	dpll \|= DPLLB_LVDS_P2_CLOCK_DIV_14;
	break;
	}

	if (is_tv) {
	/* XXX: just matching BIOS for now */
	/* dpll \|= PLL_REF_INPUT_TVCLKINBC; */
	dpll \|= 3;
	}
	dpll \|= PLL_REF_INPUT_DREFCLK;

	/* setup pipeconf */
	pipeconf = REG_READ(map->conf);

	/* Set up the display plane register */
	dspcntr = DISPPLANE_GAMMA_ENABLE;

	if (pipe == 0)
	dspcntr \|= DISPPLANE_SEL_PIPE_A;
	else
	dspcntr \|= DISPPLANE_SEL_PIPE_B;

	dspcntr \|= DISPLAY_PLANE_ENABLE;
	pipeconf \|= PIPEACONF_ENABLE;
	dpll \|= DPLL_VCO_ENABLE;


	/* Disable the panel fitter if it was on our pipe */
	if (psb_intel_panel_fitter_pipe(dev) == pipe)
	REG_WRITE(PFIT_CONTROL, 0);

	drm_mode_debug_printmodeline(mode);

	if (dpll & DPLL_VCO_ENABLE) {
	REG_WRITE(map->fp0, fp);
	REG_WRITE(map->dpll, dpll & ~DPLL_VCO_ENABLE);
	REG_READ(map->dpll);
	udelay(150);
	}

	/* The LVDS pin pair needs to be on before the DPLLs are enabled.
	* This is an exception to the general rule that mode_set doesn't turn
	* things on.
	*/
	if (is_lvds) {
	u32 lvds = REG_READ(LVDS);

	lvds &= ~LVDS_PIPEB_SELECT;
	if (pipe == 1)
	lvds \|= LVDS_PIPEB_SELECT;

	lvds \|= LVDS_PORT_EN \| LVDS_A0A2_CLKA_POWER_UP;
	/* Set the B0-B3 data pairs corresponding to
	* whether we're going to
	* set the DPLLs for dual-channel mode or not.
	*/
	lvds &= ~(LVDS_B0B3_POWER_UP \| LVDS_CLKB_POWER_UP);
	if (clock.p2 == 7)
	lvds \|= LVDS_B0B3_POWER_UP \| LVDS_CLKB_POWER_UP;

	/* It would be nice to set 24 vs 18-bit mode (LVDS_A3_POWER_UP)
	* appropriately here, but we need to look more
	* thoroughly into how panels behave in the two modes.
	*/

	REG_WRITE(LVDS, lvds);
	REG_READ(LVDS);
	}

	REG_WRITE(map->fp0, fp);
	REG_WRITE(map->dpll, dpll);
	REG_READ(map->dpll);
	/* Wait for the clocks to stabilize. */
	udelay(150);

	/* write it again -- the BIOS does, after all */
	REG_WRITE(map->dpll, dpll);

	REG_READ(map->dpll);
	/* Wait for the clocks to stabilize. */
	udelay(150);

	REG_WRITE(map->htotal, (adjusted_mode->crtc_hdisplay - 1) \|
	((adjusted_mode->crtc_htotal - 1) << 16));
	REG_WRITE(map->hblank, (adjusted_mode->crtc_hblank_start - 1) \|
	((adjusted_mode->crtc_hblank_end - 1) << 16));
	REG_WRITE(map->hsync, (adjusted_mode->crtc_hsync_start - 1) \|
	((adjusted_mode->crtc_hsync_end - 1) << 16));
	REG_WRITE(map->vtotal, (adjusted_mode->crtc_vdisplay - 1) \|
	((adjusted_mode->crtc_vtotal - 1) << 16));
	REG_WRITE(map->vblank, (adjusted_mode->crtc_vblank_start - 1) \|
	((adjusted_mode->crtc_vblank_end - 1) << 16));
	REG_WRITE(map->vsync, (adjusted_mode->crtc_vsync_start - 1) \|
	((adjusted_mode->crtc_vsync_end - 1) << 16));
	/* pipesrc and dspsize control the size that is scaled from,
	* which should always be the user's requested size.
	*/
	REG_WRITE(map->size,
	((mode->vdisplay - 1) << 16) \| (mode->hdisplay - 1));
	REG_WRITE(map->pos, 0);
	REG_WRITE(map->src,
	((mode->hdisplay - 1) << 16) \| (mode->vdisplay - 1));
	REG_WRITE(map->conf, pipeconf);
	REG_READ(map->conf);

	gma_wait_for_vblank(dev);

	REG_WRITE(map->cntr, dspcntr);

	/* Flush the plane changes */
	crtc_funcs->mode_set_base(crtc, x, y, old_fb);

	gma_wait_for_vblank(dev);

	return 0;
	}

	/* Returns the clock of the currently programmed mode of the given pipe. */
	static int psb_intel_crtc_clock_get(struct drm_device *dev,
	struct drm_crtc *crtc)
	{
	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
	struct drm_psb_private *dev_priv = dev->dev_private;
	int pipe = gma_crtc->pipe;
	const struct psb_offset *map = &dev_priv->regmap[pipe];
	u32 dpll;
	u32 fp;
	struct gma_clock_t clock;
	bool is_lvds;
	struct psb_pipe *p = &dev_priv->regs.pipe[pipe];

	if (gma_power_begin(dev, false)) {
	dpll = REG_READ(map->dpll);
	if ((dpll & DISPLAY_RATE_SELECT_FPA1) == 0)
	fp = REG_READ(map->fp0);
	else
	fp = REG_READ(map->fp1);
	is_lvds = (pipe == 1) && (REG_READ(LVDS) & LVDS_PORT_EN);
	gma_power_end(dev);
	} else {
	dpll = p->dpll;

	if ((dpll & DISPLAY_RATE_SELECT_FPA1) == 0)
	fp = p->fp0;
	else
	fp = p->fp1;

	is_lvds = (pipe == 1) && (dev_priv->regs.psb.saveLVDS &
	LVDS_PORT_EN);
	}

	clock.m1 = (fp & FP_M1_DIV_MASK) >> FP_M1_DIV_SHIFT;
	clock.m2 = (fp & FP_M2_DIV_MASK) >> FP_M2_DIV_SHIFT;
	clock.n = (fp & FP_N_DIV_MASK) >> FP_N_DIV_SHIFT;

	if (is_lvds) {
	clock.p1 =
	ffs((dpll &
	DPLL_FPA01_P1_POST_DIV_MASK_I830_LVDS) >>
	DPLL_FPA01_P1_POST_DIV_SHIFT);
	clock.p2 = 14;

	if ((dpll & PLL_REF_INPUT_MASK) ==
	PLLB_REF_INPUT_SPREADSPECTRUMIN) {
	/* XXX: might not be 66MHz */
	psb_intel_clock(66000, &clock);
	} else
	psb_intel_clock(48000, &clock);
	} else {
	if (dpll & PLL_P1_DIVIDE_BY_TWO)
	clock.p1 = 2;
	else {
	clock.p1 =
	((dpll &
	DPLL_FPA01_P1_POST_DIV_MASK_I830) >>
	DPLL_FPA01_P1_POST_DIV_SHIFT) + 2;
	}
	if (dpll & PLL_P2_DIVIDE_BY_4)
	clock.p2 = 4;
	else
	clock.p2 = 2;

	psb_intel_clock(48000, &clock);
	}

	/* XXX: It would be nice to validate the clocks, but we can't reuse
	* i830PllIsValid() because it relies on the xf86_config connector
	* configuration being accurate, which it isn't necessarily.
	*/

	return clock.dot;
	}

	/** Returns the currently programmed mode of the given pipe. */
	struct drm_display_mode psb_intel_crtc_mode_get(struct drm_device dev,
	struct drm_crtc *crtc)
	{
	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
	int pipe = gma_crtc->pipe;
	struct drm_display_mode *mode;
	int htot;
	int hsync;
	int vtot;
	int vsync;
	struct drm_psb_private *dev_priv = dev->dev_private;
	struct psb_pipe *p = &dev_priv->regs.pipe[pipe];
	const struct psb_offset *map = &dev_priv->regmap[pipe];

	if (gma_power_begin(dev, false)) {
	htot = REG_READ(map->htotal);
	hsync = REG_READ(map->hsync);
	vtot = REG_READ(map->vtotal);
	vsync = REG_READ(map->vsync);
	gma_power_end(dev);
	} else {
	htot = p->htotal;
	hsync = p->hsync;
	vtot = p->vtotal;
	vsync = p->vsync;
	}

	mode = kzalloc(sizeof(*mode), GFP_KERNEL);
	if (!mode)
	return NULL;

	mode->clock = psb_intel_crtc_clock_get(dev, crtc);
	mode->hdisplay = (htot & 0xffff) + 1;
	mode->htotal = ((htot & 0xffff0000) >> 16) + 1;
	mode->hsync_start = (hsync & 0xffff) + 1;
	mode->hsync_end = ((hsync & 0xffff0000) >> 16) + 1;
	mode->vdisplay = (vtot & 0xffff) + 1;
	mode->vtotal = ((vtot & 0xffff0000) >> 16) + 1;
	mode->vsync_start = (vsync & 0xffff) + 1;
	mode->vsync_end = ((vsync & 0xffff0000) >> 16) + 1;

	drm_mode_set_name(mode);
	drm_mode_set_crtcinfo(mode, 0);

	return mode;
	}

	const struct drm_crtc_helper_funcs psb_intel_helper_funcs = {
	.dpms = gma_crtc_dpms,
	.mode_fixup = gma_crtc_mode_fixup,
	.mode_set = psb_intel_crtc_mode_set,
	.mode_set_base = gma_pipe_set_base,
	.prepare = gma_crtc_prepare,
	.commit = gma_crtc_commit,
	.disable = gma_crtc_disable,
	};

	const struct drm_crtc_funcs psb_intel_crtc_funcs = {
	.save = gma_crtc_save,
	.restore = gma_crtc_restore,
	.cursor_set = gma_crtc_cursor_set,
	.cursor_move = gma_crtc_cursor_move,
	.gamma_set = gma_crtc_gamma_set,
	.set_config = gma_crtc_set_config,
	.destroy = gma_crtc_destroy,
	};

	const struct gma_clock_funcs psb_clock_funcs = {
	.clock = psb_intel_clock,
	.limit = psb_intel_limit,
	.pll_is_valid = gma_pll_is_valid,
	};

	/*
	* Set the default value of cursor control and base register
	* to zero. This is a workaround for h/w defect on Oaktrail
	*/
	static void psb_intel_cursor_init(struct drm_device *dev,
	struct gma_crtc *gma_crtc)
	{
	struct drm_psb_private *dev_priv = dev->dev_private;
	u32 control[3] = { CURACNTR, CURBCNTR, CURCCNTR };
	u32 base[3] = { CURABASE, CURBBASE, CURCBASE };
	struct gtt_range *cursor_gt;

	if (dev_priv->ops->cursor_needs_phys) {
	/* Allocate 4 pages of stolen mem for a hardware cursor. That
	* is enough for the 64 x 64 ARGB cursors we support.
	*/
	cursor_gt = psb_gtt_alloc_range(dev, 4 * PAGE_SIZE, "cursor", 1,
	PAGE_SIZE);
	if (!cursor_gt) {
	gma_crtc->cursor_gt = NULL;
	goto out;
	}
	gma_crtc->cursor_gt = cursor_gt;
	gma_crtc->cursor_addr = dev_priv->stolen_base +
	cursor_gt->offset;
	} else {
	gma_crtc->cursor_gt = NULL;
	}

	out:
	REG_WRITE(control[gma_crtc->pipe], 0);
	REG_WRITE(base[gma_crtc->pipe], 0);
	}

	void psb_intel_crtc_init(struct drm_device *dev, int pipe,
	struct psb_intel_mode_device *mode_dev)
	{
	struct drm_psb_private *dev_priv = dev->dev_private;
	struct gma_crtc *gma_crtc;
	int i;
	uint16_t r_base, g_base, *b_base;

	/* We allocate a extra array of drm_connector pointers
	* for fbdev after the crtc */
	gma_crtc = kzalloc(sizeof(struct gma_crtc) +
	(INTELFB_CONN_LIMIT * sizeof(struct drm_connector *)),
	GFP_KERNEL);
	if (gma_crtc == NULL)
	return;

	gma_crtc->crtc_state =
	kzalloc(sizeof(struct psb_intel_crtc_state), GFP_KERNEL);
	if (!gma_crtc->crtc_state) {
	dev_err(dev->dev, "Crtc state error: No memory\n");
	kfree(gma_crtc);
	return;
	}

	/* Set the CRTC operations from the chip specific data */
	drm_crtc_init(dev, &gma_crtc->base, dev_priv->ops->crtc_funcs);

	/* Set the CRTC clock functions from chip specific data */
	gma_crtc->clock_funcs = dev_priv->ops->clock_funcs;

	drm_mode_crtc_set_gamma_size(&gma_crtc->base, 256);
	gma_crtc->pipe = pipe;
	gma_crtc->plane = pipe;

	r_base = gma_crtc->base.gamma_store;
	g_base = r_base + 256;
	b_base = g_base + 256;
	for (i = 0; i < 256; i++) {
	gma_crtc->lut_r[i] = i;
	gma_crtc->lut_g[i] = i;
	gma_crtc->lut_b[i] = i;
	r_base[i] = i << 8;
	g_base[i] = i << 8;
	b_base[i] = i << 8;

	gma_crtc->lut_adj[i] = 0;
	}

	gma_crtc->mode_dev = mode_dev;
	gma_crtc->cursor_addr = 0;

	drm_crtc_helper_add(&gma_crtc->base,
	dev_priv->ops->crtc_helper);

	/* Setup the array of drm_connector pointer array */
	gma_crtc->mode_set.crtc = &gma_crtc->base;
	BUG_ON(pipe >= ARRAY_SIZE(dev_priv->plane_to_crtc_mapping) \|\|
	dev_priv->plane_to_crtc_mapping[gma_crtc->plane] != NULL);
	dev_priv->plane_to_crtc_mapping[gma_crtc->plane] = &gma_crtc->base;
	dev_priv->pipe_to_crtc_mapping[gma_crtc->pipe] = &gma_crtc->base;
	gma_crtc->mode_set.connectors = (struct drm_connector **)(gma_crtc + 1);
	gma_crtc->mode_set.num_connectors = 0;
	psb_intel_cursor_init(dev, gma_crtc);

	/* Set to true so that the pipe is forced off on initial config. */
	gma_crtc->active = true;
	}

	struct drm_crtc psb_intel_get_crtc_from_pipe(struct drm_device dev, int pipe)
	{
	struct drm_crtc *crtc = NULL;

	list_for_each_entry(crtc, &dev->mode_config.crtc_list, head) {
	struct gma_crtc *gma_crtc = to_gma_crtc(crtc);
	if (gma_crtc->pipe == pipe)
	break;
	}
	return crtc;
	}

	int gma_connector_clones(struct drm_device *dev, int type_mask)
	{
	int index_mask = 0;
	struct drm_connector *connector;
	int entry = 0;

	list_for_each_entry(connector, &dev->mode_config.connector_list,
	head) {
	struct gma_encoder *gma_encoder = gma_attached_encoder(connector);
	if (type_mask & (1 << gma_encoder->type))
	index_mask \|= (1 << entry);
	entry++;
	}
	return index_mask;
	}