linux_dsm_epyc7002/drivers/gpu/drm/vc4/vc4_crtc.c
Chris Wilson 71724f7089 drm/mm: Use helpers for drm_mm_node booleans
In preparation for rearranging the booleans into a flags field, ensure
all the current users are using the inline helpers and not directly
accessing the members.

Signed-off-by: Chris Wilson <chris@chris-wilson.co.uk>
Reviewed-by: Tvrtko Ursulin <tvrtko.ursulin@intel.com>
Link: https://patchwork.freedesktop.org/patch/msgid/20191003210100.22250-3-chris@chris-wilson.co.uk
2019-10-04 13:42:33 +01:00

1278 lines
37 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (C) 2015 Broadcom
*/
/**
* DOC: VC4 CRTC module
*
* In VC4, the Pixel Valve is what most closely corresponds to the
* DRM's concept of a CRTC. The PV generates video timings from the
* encoder's clock plus its configuration. It pulls scaled pixels from
* the HVS at that timing, and feeds it to the encoder.
*
* However, the DRM CRTC also collects the configuration of all the
* DRM planes attached to it. As a result, the CRTC is also
* responsible for writing the display list for the HVS channel that
* the CRTC will use.
*
* The 2835 has 3 different pixel valves. pv0 in the audio power
* domain feeds DSI0 or DPI, while pv1 feeds DS1 or SMI. pv2 in the
* image domain can feed either HDMI or the SDTV controller. The
* pixel valve chooses from the CPRMAN clocks (HSM for HDMI, VEC for
* SDTV, etc.) according to which output type is chosen in the mux.
*
* For power management, the pixel valve's registers are all clocked
* by the AXI clock, while the timings and FIFOs make use of the
* output-specific clock. Since the encoders also directly consume
* the CPRMAN clocks, and know what timings they need, they are the
* ones that set the clock.
*/
#include <linux/clk.h>
#include <linux/component.h>
#include <linux/of_device.h>
#include <drm/drm_atomic.h>
#include <drm/drm_atomic_helper.h>
#include <drm/drm_atomic_uapi.h>
#include <drm/drm_fb_cma_helper.h>
#include <drm/drm_print.h>
#include <drm/drm_probe_helper.h>
#include <drm/drm_vblank.h>
#include "vc4_drv.h"
#include "vc4_regs.h"
struct vc4_crtc_state {
struct drm_crtc_state base;
/* Dlist area for this CRTC configuration. */
struct drm_mm_node mm;
bool feed_txp;
bool txp_armed;
struct {
unsigned int left;
unsigned int right;
unsigned int top;
unsigned int bottom;
} margins;
};
static inline struct vc4_crtc_state *
to_vc4_crtc_state(struct drm_crtc_state *crtc_state)
{
return (struct vc4_crtc_state *)crtc_state;
}
#define CRTC_WRITE(offset, val) writel(val, vc4_crtc->regs + (offset))
#define CRTC_READ(offset) readl(vc4_crtc->regs + (offset))
static const struct debugfs_reg32 crtc_regs[] = {
VC4_REG32(PV_CONTROL),
VC4_REG32(PV_V_CONTROL),
VC4_REG32(PV_VSYNCD_EVEN),
VC4_REG32(PV_HORZA),
VC4_REG32(PV_HORZB),
VC4_REG32(PV_VERTA),
VC4_REG32(PV_VERTB),
VC4_REG32(PV_VERTA_EVEN),
VC4_REG32(PV_VERTB_EVEN),
VC4_REG32(PV_INTEN),
VC4_REG32(PV_INTSTAT),
VC4_REG32(PV_STAT),
VC4_REG32(PV_HACT_ACT),
};
bool vc4_crtc_get_scanoutpos(struct drm_device *dev, unsigned int crtc_id,
bool in_vblank_irq, int *vpos, int *hpos,
ktime_t *stime, ktime_t *etime,
const struct drm_display_mode *mode)
{
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct drm_crtc *crtc = drm_crtc_from_index(dev, crtc_id);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
u32 val;
int fifo_lines;
int vblank_lines;
bool ret = false;
/* preempt_disable_rt() should go right here in PREEMPT_RT patchset. */
/* Get optional system timestamp before query. */
if (stime)
*stime = ktime_get();
/*
* Read vertical scanline which is currently composed for our
* pixelvalve by the HVS, and also the scaler status.
*/
val = HVS_READ(SCALER_DISPSTATX(vc4_crtc->channel));
/* Get optional system timestamp after query. */
if (etime)
*etime = ktime_get();
/* preempt_enable_rt() should go right here in PREEMPT_RT patchset. */
/* Vertical position of hvs composed scanline. */
*vpos = VC4_GET_FIELD(val, SCALER_DISPSTATX_LINE);
*hpos = 0;
if (mode->flags & DRM_MODE_FLAG_INTERLACE) {
*vpos /= 2;
/* Use hpos to correct for field offset in interlaced mode. */
if (VC4_GET_FIELD(val, SCALER_DISPSTATX_FRAME_COUNT) % 2)
*hpos += mode->crtc_htotal / 2;
}
/* This is the offset we need for translating hvs -> pv scanout pos. */
fifo_lines = vc4_crtc->cob_size / mode->crtc_hdisplay;
if (fifo_lines > 0)
ret = true;
/* HVS more than fifo_lines into frame for compositing? */
if (*vpos > fifo_lines) {
/*
* We are in active scanout and can get some meaningful results
* from HVS. The actual PV scanout can not trail behind more
* than fifo_lines as that is the fifo's capacity. Assume that
* in active scanout the HVS and PV work in lockstep wrt. HVS
* refilling the fifo and PV consuming from the fifo, ie.
* whenever the PV consumes and frees up a scanline in the
* fifo, the HVS will immediately refill it, therefore
* incrementing vpos. Therefore we choose HVS read position -
* fifo size in scanlines as a estimate of the real scanout
* position of the PV.
*/
*vpos -= fifo_lines + 1;
return ret;
}
/*
* Less: This happens when we are in vblank and the HVS, after getting
* the VSTART restart signal from the PV, just started refilling its
* fifo with new lines from the top-most lines of the new framebuffers.
* The PV does not scan out in vblank, so does not remove lines from
* the fifo, so the fifo will be full quickly and the HVS has to pause.
* We can't get meaningful readings wrt. scanline position of the PV
* and need to make things up in a approximative but consistent way.
*/
vblank_lines = mode->vtotal - mode->vdisplay;
if (in_vblank_irq) {
/*
* Assume the irq handler got called close to first
* line of vblank, so PV has about a full vblank
* scanlines to go, and as a base timestamp use the
* one taken at entry into vblank irq handler, so it
* is not affected by random delays due to lock
* contention on event_lock or vblank_time lock in
* the core.
*/
*vpos = -vblank_lines;
if (stime)
*stime = vc4_crtc->t_vblank;
if (etime)
*etime = vc4_crtc->t_vblank;
/*
* If the HVS fifo is not yet full then we know for certain
* we are at the very beginning of vblank, as the hvs just
* started refilling, and the stime and etime timestamps
* truly correspond to start of vblank.
*
* Unfortunately there's no way to report this to upper levels
* and make it more useful.
*/
} else {
/*
* No clue where we are inside vblank. Return a vpos of zero,
* which will cause calling code to just return the etime
* timestamp uncorrected. At least this is no worse than the
* standard fallback.
*/
*vpos = 0;
}
return ret;
}
static void vc4_crtc_destroy(struct drm_crtc *crtc)
{
drm_crtc_cleanup(crtc);
}
static void
vc4_crtc_lut_load(struct drm_crtc *crtc)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
u32 i;
/* The LUT memory is laid out with each HVS channel in order,
* each of which takes 256 writes for R, 256 for G, then 256
* for B.
*/
HVS_WRITE(SCALER_GAMADDR,
SCALER_GAMADDR_AUTOINC |
(vc4_crtc->channel * 3 * crtc->gamma_size));
for (i = 0; i < crtc->gamma_size; i++)
HVS_WRITE(SCALER_GAMDATA, vc4_crtc->lut_r[i]);
for (i = 0; i < crtc->gamma_size; i++)
HVS_WRITE(SCALER_GAMDATA, vc4_crtc->lut_g[i]);
for (i = 0; i < crtc->gamma_size; i++)
HVS_WRITE(SCALER_GAMDATA, vc4_crtc->lut_b[i]);
}
static void
vc4_crtc_update_gamma_lut(struct drm_crtc *crtc)
{
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
struct drm_color_lut *lut = crtc->state->gamma_lut->data;
u32 length = drm_color_lut_size(crtc->state->gamma_lut);
u32 i;
for (i = 0; i < length; i++) {
vc4_crtc->lut_r[i] = drm_color_lut_extract(lut[i].red, 8);
vc4_crtc->lut_g[i] = drm_color_lut_extract(lut[i].green, 8);
vc4_crtc->lut_b[i] = drm_color_lut_extract(lut[i].blue, 8);
}
vc4_crtc_lut_load(crtc);
}
static u32 vc4_get_fifo_full_level(u32 format)
{
static const u32 fifo_len_bytes = 64;
static const u32 hvs_latency_pix = 6;
switch (format) {
case PV_CONTROL_FORMAT_DSIV_16:
case PV_CONTROL_FORMAT_DSIC_16:
return fifo_len_bytes - 2 * hvs_latency_pix;
case PV_CONTROL_FORMAT_DSIV_18:
return fifo_len_bytes - 14;
case PV_CONTROL_FORMAT_24:
case PV_CONTROL_FORMAT_DSIV_24:
default:
return fifo_len_bytes - 3 * hvs_latency_pix;
}
}
/*
* Returns the encoder attached to the CRTC.
*
* VC4 can only scan out to one encoder at a time, while the DRM core
* allows drivers to push pixels to more than one encoder from the
* same CRTC.
*/
static struct drm_encoder *vc4_get_crtc_encoder(struct drm_crtc *crtc)
{
struct drm_connector *connector;
struct drm_connector_list_iter conn_iter;
drm_connector_list_iter_begin(crtc->dev, &conn_iter);
drm_for_each_connector_iter(connector, &conn_iter) {
if (connector->state->crtc == crtc) {
drm_connector_list_iter_end(&conn_iter);
return connector->encoder;
}
}
drm_connector_list_iter_end(&conn_iter);
return NULL;
}
static void vc4_crtc_config_pv(struct drm_crtc *crtc)
{
struct drm_encoder *encoder = vc4_get_crtc_encoder(crtc);
struct vc4_encoder *vc4_encoder = to_vc4_encoder(encoder);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
struct drm_crtc_state *state = crtc->state;
struct drm_display_mode *mode = &state->adjusted_mode;
bool interlace = mode->flags & DRM_MODE_FLAG_INTERLACE;
u32 pixel_rep = (mode->flags & DRM_MODE_FLAG_DBLCLK) ? 2 : 1;
bool is_dsi = (vc4_encoder->type == VC4_ENCODER_TYPE_DSI0 ||
vc4_encoder->type == VC4_ENCODER_TYPE_DSI1);
u32 format = is_dsi ? PV_CONTROL_FORMAT_DSIV_24 : PV_CONTROL_FORMAT_24;
/* Reset the PV fifo. */
CRTC_WRITE(PV_CONTROL, 0);
CRTC_WRITE(PV_CONTROL, PV_CONTROL_FIFO_CLR | PV_CONTROL_EN);
CRTC_WRITE(PV_CONTROL, 0);
CRTC_WRITE(PV_HORZA,
VC4_SET_FIELD((mode->htotal -
mode->hsync_end) * pixel_rep,
PV_HORZA_HBP) |
VC4_SET_FIELD((mode->hsync_end -
mode->hsync_start) * pixel_rep,
PV_HORZA_HSYNC));
CRTC_WRITE(PV_HORZB,
VC4_SET_FIELD((mode->hsync_start -
mode->hdisplay) * pixel_rep,
PV_HORZB_HFP) |
VC4_SET_FIELD(mode->hdisplay * pixel_rep, PV_HORZB_HACTIVE));
CRTC_WRITE(PV_VERTA,
VC4_SET_FIELD(mode->crtc_vtotal - mode->crtc_vsync_end,
PV_VERTA_VBP) |
VC4_SET_FIELD(mode->crtc_vsync_end - mode->crtc_vsync_start,
PV_VERTA_VSYNC));
CRTC_WRITE(PV_VERTB,
VC4_SET_FIELD(mode->crtc_vsync_start - mode->crtc_vdisplay,
PV_VERTB_VFP) |
VC4_SET_FIELD(mode->crtc_vdisplay, PV_VERTB_VACTIVE));
if (interlace) {
CRTC_WRITE(PV_VERTA_EVEN,
VC4_SET_FIELD(mode->crtc_vtotal -
mode->crtc_vsync_end - 1,
PV_VERTA_VBP) |
VC4_SET_FIELD(mode->crtc_vsync_end -
mode->crtc_vsync_start,
PV_VERTA_VSYNC));
CRTC_WRITE(PV_VERTB_EVEN,
VC4_SET_FIELD(mode->crtc_vsync_start -
mode->crtc_vdisplay,
PV_VERTB_VFP) |
VC4_SET_FIELD(mode->crtc_vdisplay, PV_VERTB_VACTIVE));
/* We set up first field even mode for HDMI. VEC's
* NTSC mode would want first field odd instead, once
* we support it (to do so, set ODD_FIRST and put the
* delay in VSYNCD_EVEN instead).
*/
CRTC_WRITE(PV_V_CONTROL,
PV_VCONTROL_CONTINUOUS |
(is_dsi ? PV_VCONTROL_DSI : 0) |
PV_VCONTROL_INTERLACE |
VC4_SET_FIELD(mode->htotal * pixel_rep / 2,
PV_VCONTROL_ODD_DELAY));
CRTC_WRITE(PV_VSYNCD_EVEN, 0);
} else {
CRTC_WRITE(PV_V_CONTROL,
PV_VCONTROL_CONTINUOUS |
(is_dsi ? PV_VCONTROL_DSI : 0));
}
CRTC_WRITE(PV_HACT_ACT, mode->hdisplay * pixel_rep);
CRTC_WRITE(PV_CONTROL,
VC4_SET_FIELD(format, PV_CONTROL_FORMAT) |
VC4_SET_FIELD(vc4_get_fifo_full_level(format),
PV_CONTROL_FIFO_LEVEL) |
VC4_SET_FIELD(pixel_rep - 1, PV_CONTROL_PIXEL_REP) |
PV_CONTROL_CLR_AT_START |
PV_CONTROL_TRIGGER_UNDERFLOW |
PV_CONTROL_WAIT_HSTART |
VC4_SET_FIELD(vc4_encoder->clock_select,
PV_CONTROL_CLK_SELECT) |
PV_CONTROL_FIFO_CLR |
PV_CONTROL_EN);
}
static void vc4_crtc_mode_set_nofb(struct drm_crtc *crtc)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(crtc->state);
struct drm_display_mode *mode = &crtc->state->adjusted_mode;
bool interlace = mode->flags & DRM_MODE_FLAG_INTERLACE;
bool debug_dump_regs = false;
if (debug_dump_regs) {
struct drm_printer p = drm_info_printer(&vc4_crtc->pdev->dev);
dev_info(&vc4_crtc->pdev->dev, "CRTC %d regs before:\n",
drm_crtc_index(crtc));
drm_print_regset32(&p, &vc4_crtc->regset);
}
if (vc4_crtc->channel == 2) {
u32 dispctrl;
u32 dsp3_mux;
/*
* SCALER_DISPCTRL_DSP3 = X, where X < 2 means 'connect DSP3 to
* FIFO X'.
* SCALER_DISPCTRL_DSP3 = 3 means 'disable DSP 3'.
*
* DSP3 is connected to FIFO2 unless the transposer is
* enabled. In this case, FIFO 2 is directly accessed by the
* TXP IP, and we need to disable the FIFO2 -> pixelvalve1
* route.
*/
if (vc4_state->feed_txp)
dsp3_mux = VC4_SET_FIELD(3, SCALER_DISPCTRL_DSP3_MUX);
else
dsp3_mux = VC4_SET_FIELD(2, SCALER_DISPCTRL_DSP3_MUX);
dispctrl = HVS_READ(SCALER_DISPCTRL) &
~SCALER_DISPCTRL_DSP3_MUX_MASK;
HVS_WRITE(SCALER_DISPCTRL, dispctrl | dsp3_mux);
}
if (!vc4_state->feed_txp)
vc4_crtc_config_pv(crtc);
HVS_WRITE(SCALER_DISPBKGNDX(vc4_crtc->channel),
SCALER_DISPBKGND_AUTOHS |
SCALER_DISPBKGND_GAMMA |
(interlace ? SCALER_DISPBKGND_INTERLACE : 0));
/* Reload the LUT, since the SRAMs would have been disabled if
* all CRTCs had SCALER_DISPBKGND_GAMMA unset at once.
*/
vc4_crtc_lut_load(crtc);
if (debug_dump_regs) {
struct drm_printer p = drm_info_printer(&vc4_crtc->pdev->dev);
dev_info(&vc4_crtc->pdev->dev, "CRTC %d regs after:\n",
drm_crtc_index(crtc));
drm_print_regset32(&p, &vc4_crtc->regset);
}
}
static void require_hvs_enabled(struct drm_device *dev)
{
struct vc4_dev *vc4 = to_vc4_dev(dev);
WARN_ON_ONCE((HVS_READ(SCALER_DISPCTRL) & SCALER_DISPCTRL_ENABLE) !=
SCALER_DISPCTRL_ENABLE);
}
static void vc4_crtc_atomic_disable(struct drm_crtc *crtc,
struct drm_crtc_state *old_state)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
u32 chan = vc4_crtc->channel;
int ret;
require_hvs_enabled(dev);
/* Disable vblank irq handling before crtc is disabled. */
drm_crtc_vblank_off(crtc);
CRTC_WRITE(PV_V_CONTROL,
CRTC_READ(PV_V_CONTROL) & ~PV_VCONTROL_VIDEN);
ret = wait_for(!(CRTC_READ(PV_V_CONTROL) & PV_VCONTROL_VIDEN), 1);
WARN_ONCE(ret, "Timeout waiting for !PV_VCONTROL_VIDEN\n");
if (HVS_READ(SCALER_DISPCTRLX(chan)) &
SCALER_DISPCTRLX_ENABLE) {
HVS_WRITE(SCALER_DISPCTRLX(chan),
SCALER_DISPCTRLX_RESET);
/* While the docs say that reset is self-clearing, it
* seems it doesn't actually.
*/
HVS_WRITE(SCALER_DISPCTRLX(chan), 0);
}
/* Once we leave, the scaler should be disabled and its fifo empty. */
WARN_ON_ONCE(HVS_READ(SCALER_DISPCTRLX(chan)) & SCALER_DISPCTRLX_RESET);
WARN_ON_ONCE(VC4_GET_FIELD(HVS_READ(SCALER_DISPSTATX(chan)),
SCALER_DISPSTATX_MODE) !=
SCALER_DISPSTATX_MODE_DISABLED);
WARN_ON_ONCE((HVS_READ(SCALER_DISPSTATX(chan)) &
(SCALER_DISPSTATX_FULL | SCALER_DISPSTATX_EMPTY)) !=
SCALER_DISPSTATX_EMPTY);
/*
* Make sure we issue a vblank event after disabling the CRTC if
* someone was waiting it.
*/
if (crtc->state->event) {
unsigned long flags;
spin_lock_irqsave(&dev->event_lock, flags);
drm_crtc_send_vblank_event(crtc, crtc->state->event);
crtc->state->event = NULL;
spin_unlock_irqrestore(&dev->event_lock, flags);
}
}
void vc4_crtc_txp_armed(struct drm_crtc_state *state)
{
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(state);
vc4_state->txp_armed = true;
}
static void vc4_crtc_update_dlist(struct drm_crtc *crtc)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(crtc->state);
if (crtc->state->event) {
unsigned long flags;
crtc->state->event->pipe = drm_crtc_index(crtc);
WARN_ON(drm_crtc_vblank_get(crtc) != 0);
spin_lock_irqsave(&dev->event_lock, flags);
if (!vc4_state->feed_txp || vc4_state->txp_armed) {
vc4_crtc->event = crtc->state->event;
crtc->state->event = NULL;
}
HVS_WRITE(SCALER_DISPLISTX(vc4_crtc->channel),
vc4_state->mm.start);
spin_unlock_irqrestore(&dev->event_lock, flags);
} else {
HVS_WRITE(SCALER_DISPLISTX(vc4_crtc->channel),
vc4_state->mm.start);
}
}
static void vc4_crtc_atomic_enable(struct drm_crtc *crtc,
struct drm_crtc_state *old_state)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(crtc->state);
struct drm_display_mode *mode = &crtc->state->adjusted_mode;
require_hvs_enabled(dev);
/* Enable vblank irq handling before crtc is started otherwise
* drm_crtc_get_vblank() fails in vc4_crtc_update_dlist().
*/
drm_crtc_vblank_on(crtc);
vc4_crtc_update_dlist(crtc);
/* Turn on the scaler, which will wait for vstart to start
* compositing.
* When feeding the transposer, we should operate in oneshot
* mode.
*/
HVS_WRITE(SCALER_DISPCTRLX(vc4_crtc->channel),
VC4_SET_FIELD(mode->hdisplay, SCALER_DISPCTRLX_WIDTH) |
VC4_SET_FIELD(mode->vdisplay, SCALER_DISPCTRLX_HEIGHT) |
SCALER_DISPCTRLX_ENABLE |
(vc4_state->feed_txp ? SCALER_DISPCTRLX_ONESHOT : 0));
/* When feeding the transposer block the pixelvalve is unneeded and
* should not be enabled.
*/
if (!vc4_state->feed_txp)
CRTC_WRITE(PV_V_CONTROL,
CRTC_READ(PV_V_CONTROL) | PV_VCONTROL_VIDEN);
}
static enum drm_mode_status vc4_crtc_mode_valid(struct drm_crtc *crtc,
const struct drm_display_mode *mode)
{
/* Do not allow doublescan modes from user space */
if (mode->flags & DRM_MODE_FLAG_DBLSCAN) {
DRM_DEBUG_KMS("[CRTC:%d] Doublescan mode rejected.\n",
crtc->base.id);
return MODE_NO_DBLESCAN;
}
return MODE_OK;
}
void vc4_crtc_get_margins(struct drm_crtc_state *state,
unsigned int *left, unsigned int *right,
unsigned int *top, unsigned int *bottom)
{
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(state);
struct drm_connector_state *conn_state;
struct drm_connector *conn;
int i;
*left = vc4_state->margins.left;
*right = vc4_state->margins.right;
*top = vc4_state->margins.top;
*bottom = vc4_state->margins.bottom;
/* We have to interate over all new connector states because
* vc4_crtc_get_margins() might be called before
* vc4_crtc_atomic_check() which means margins info in vc4_crtc_state
* might be outdated.
*/
for_each_new_connector_in_state(state->state, conn, conn_state, i) {
if (conn_state->crtc != state->crtc)
continue;
*left = conn_state->tv.margins.left;
*right = conn_state->tv.margins.right;
*top = conn_state->tv.margins.top;
*bottom = conn_state->tv.margins.bottom;
break;
}
}
static int vc4_crtc_atomic_check(struct drm_crtc *crtc,
struct drm_crtc_state *state)
{
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(state);
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct drm_plane *plane;
unsigned long flags;
const struct drm_plane_state *plane_state;
struct drm_connector *conn;
struct drm_connector_state *conn_state;
u32 dlist_count = 0;
int ret, i;
/* The pixelvalve can only feed one encoder (and encoders are
* 1:1 with connectors.)
*/
if (hweight32(state->connector_mask) > 1)
return -EINVAL;
drm_atomic_crtc_state_for_each_plane_state(plane, plane_state, state)
dlist_count += vc4_plane_dlist_size(plane_state);
dlist_count++; /* Account for SCALER_CTL0_END. */
spin_lock_irqsave(&vc4->hvs->mm_lock, flags);
ret = drm_mm_insert_node(&vc4->hvs->dlist_mm, &vc4_state->mm,
dlist_count);
spin_unlock_irqrestore(&vc4->hvs->mm_lock, flags);
if (ret)
return ret;
for_each_new_connector_in_state(state->state, conn, conn_state, i) {
if (conn_state->crtc != crtc)
continue;
/* The writeback connector is implemented using the transposer
* block which is directly taking its data from the HVS FIFO.
*/
if (conn->connector_type == DRM_MODE_CONNECTOR_WRITEBACK) {
state->no_vblank = true;
vc4_state->feed_txp = true;
} else {
state->no_vblank = false;
vc4_state->feed_txp = false;
}
vc4_state->margins.left = conn_state->tv.margins.left;
vc4_state->margins.right = conn_state->tv.margins.right;
vc4_state->margins.top = conn_state->tv.margins.top;
vc4_state->margins.bottom = conn_state->tv.margins.bottom;
break;
}
return 0;
}
static void vc4_crtc_atomic_flush(struct drm_crtc *crtc,
struct drm_crtc_state *old_state)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(crtc->state);
struct drm_plane *plane;
struct vc4_plane_state *vc4_plane_state;
bool debug_dump_regs = false;
bool enable_bg_fill = false;
u32 __iomem *dlist_start = vc4->hvs->dlist + vc4_state->mm.start;
u32 __iomem *dlist_next = dlist_start;
if (debug_dump_regs) {
DRM_INFO("CRTC %d HVS before:\n", drm_crtc_index(crtc));
vc4_hvs_dump_state(dev);
}
/* Copy all the active planes' dlist contents to the hardware dlist. */
drm_atomic_crtc_for_each_plane(plane, crtc) {
/* Is this the first active plane? */
if (dlist_next == dlist_start) {
/* We need to enable background fill when a plane
* could be alpha blending from the background, i.e.
* where no other plane is underneath. It suffices to
* consider the first active plane here since we set
* needs_bg_fill such that either the first plane
* already needs it or all planes on top blend from
* the first or a lower plane.
*/
vc4_plane_state = to_vc4_plane_state(plane->state);
enable_bg_fill = vc4_plane_state->needs_bg_fill;
}
dlist_next += vc4_plane_write_dlist(plane, dlist_next);
}
writel(SCALER_CTL0_END, dlist_next);
dlist_next++;
WARN_ON_ONCE(dlist_next - dlist_start != vc4_state->mm.size);
if (enable_bg_fill)
/* This sets a black background color fill, as is the case
* with other DRM drivers.
*/
HVS_WRITE(SCALER_DISPBKGNDX(vc4_crtc->channel),
HVS_READ(SCALER_DISPBKGNDX(vc4_crtc->channel)) |
SCALER_DISPBKGND_FILL);
/* Only update DISPLIST if the CRTC was already running and is not
* being disabled.
* vc4_crtc_enable() takes care of updating the dlist just after
* re-enabling VBLANK interrupts and before enabling the engine.
* If the CRTC is being disabled, there's no point in updating this
* information.
*/
if (crtc->state->active && old_state->active)
vc4_crtc_update_dlist(crtc);
if (crtc->state->color_mgmt_changed) {
u32 dispbkgndx = HVS_READ(SCALER_DISPBKGNDX(vc4_crtc->channel));
if (crtc->state->gamma_lut) {
vc4_crtc_update_gamma_lut(crtc);
dispbkgndx |= SCALER_DISPBKGND_GAMMA;
} else {
/* Unsetting DISPBKGND_GAMMA skips the gamma lut step
* in hardware, which is the same as a linear lut that
* DRM expects us to use in absence of a user lut.
*/
dispbkgndx &= ~SCALER_DISPBKGND_GAMMA;
}
HVS_WRITE(SCALER_DISPBKGNDX(vc4_crtc->channel), dispbkgndx);
}
if (debug_dump_regs) {
DRM_INFO("CRTC %d HVS after:\n", drm_crtc_index(crtc));
vc4_hvs_dump_state(dev);
}
}
static int vc4_enable_vblank(struct drm_crtc *crtc)
{
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
CRTC_WRITE(PV_INTEN, PV_INT_VFP_START);
return 0;
}
static void vc4_disable_vblank(struct drm_crtc *crtc)
{
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
CRTC_WRITE(PV_INTEN, 0);
}
static void vc4_crtc_handle_page_flip(struct vc4_crtc *vc4_crtc)
{
struct drm_crtc *crtc = &vc4_crtc->base;
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(crtc->state);
u32 chan = vc4_crtc->channel;
unsigned long flags;
spin_lock_irqsave(&dev->event_lock, flags);
if (vc4_crtc->event &&
(vc4_state->mm.start == HVS_READ(SCALER_DISPLACTX(chan)) ||
vc4_state->feed_txp)) {
drm_crtc_send_vblank_event(crtc, vc4_crtc->event);
vc4_crtc->event = NULL;
drm_crtc_vblank_put(crtc);
/* Wait for the page flip to unmask the underrun to ensure that
* the display list was updated by the hardware. Before that
* happens, the HVS will be using the previous display list with
* the CRTC and encoder already reconfigured, leading to
* underruns. This can be seen when reconfiguring the CRTC.
*/
vc4_hvs_unmask_underrun(dev, vc4_crtc->channel);
}
spin_unlock_irqrestore(&dev->event_lock, flags);
}
void vc4_crtc_handle_vblank(struct vc4_crtc *crtc)
{
crtc->t_vblank = ktime_get();
drm_crtc_handle_vblank(&crtc->base);
vc4_crtc_handle_page_flip(crtc);
}
static irqreturn_t vc4_crtc_irq_handler(int irq, void *data)
{
struct vc4_crtc *vc4_crtc = data;
u32 stat = CRTC_READ(PV_INTSTAT);
irqreturn_t ret = IRQ_NONE;
if (stat & PV_INT_VFP_START) {
CRTC_WRITE(PV_INTSTAT, PV_INT_VFP_START);
vc4_crtc_handle_vblank(vc4_crtc);
ret = IRQ_HANDLED;
}
return ret;
}
struct vc4_async_flip_state {
struct drm_crtc *crtc;
struct drm_framebuffer *fb;
struct drm_framebuffer *old_fb;
struct drm_pending_vblank_event *event;
struct vc4_seqno_cb cb;
};
/* Called when the V3D execution for the BO being flipped to is done, so that
* we can actually update the plane's address to point to it.
*/
static void
vc4_async_page_flip_complete(struct vc4_seqno_cb *cb)
{
struct vc4_async_flip_state *flip_state =
container_of(cb, struct vc4_async_flip_state, cb);
struct drm_crtc *crtc = flip_state->crtc;
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct drm_plane *plane = crtc->primary;
vc4_plane_async_set_fb(plane, flip_state->fb);
if (flip_state->event) {
unsigned long flags;
spin_lock_irqsave(&dev->event_lock, flags);
drm_crtc_send_vblank_event(crtc, flip_state->event);
spin_unlock_irqrestore(&dev->event_lock, flags);
}
drm_crtc_vblank_put(crtc);
drm_framebuffer_put(flip_state->fb);
/* Decrement the BO usecnt in order to keep the inc/dec calls balanced
* when the planes are updated through the async update path.
* FIXME: we should move to generic async-page-flip when it's
* available, so that we can get rid of this hand-made cleanup_fb()
* logic.
*/
if (flip_state->old_fb) {
struct drm_gem_cma_object *cma_bo;
struct vc4_bo *bo;
cma_bo = drm_fb_cma_get_gem_obj(flip_state->old_fb, 0);
bo = to_vc4_bo(&cma_bo->base);
vc4_bo_dec_usecnt(bo);
drm_framebuffer_put(flip_state->old_fb);
}
kfree(flip_state);
up(&vc4->async_modeset);
}
/* Implements async (non-vblank-synced) page flips.
*
* The page flip ioctl needs to return immediately, so we grab the
* modeset semaphore on the pipe, and queue the address update for
* when V3D is done with the BO being flipped to.
*/
static int vc4_async_page_flip(struct drm_crtc *crtc,
struct drm_framebuffer *fb,
struct drm_pending_vblank_event *event,
uint32_t flags)
{
struct drm_device *dev = crtc->dev;
struct vc4_dev *vc4 = to_vc4_dev(dev);
struct drm_plane *plane = crtc->primary;
int ret = 0;
struct vc4_async_flip_state *flip_state;
struct drm_gem_cma_object *cma_bo = drm_fb_cma_get_gem_obj(fb, 0);
struct vc4_bo *bo = to_vc4_bo(&cma_bo->base);
/* Increment the BO usecnt here, so that we never end up with an
* unbalanced number of vc4_bo_{dec,inc}_usecnt() calls when the
* plane is later updated through the non-async path.
* FIXME: we should move to generic async-page-flip when it's
* available, so that we can get rid of this hand-made prepare_fb()
* logic.
*/
ret = vc4_bo_inc_usecnt(bo);
if (ret)
return ret;
flip_state = kzalloc(sizeof(*flip_state), GFP_KERNEL);
if (!flip_state) {
vc4_bo_dec_usecnt(bo);
return -ENOMEM;
}
drm_framebuffer_get(fb);
flip_state->fb = fb;
flip_state->crtc = crtc;
flip_state->event = event;
/* Make sure all other async modesetes have landed. */
ret = down_interruptible(&vc4->async_modeset);
if (ret) {
drm_framebuffer_put(fb);
vc4_bo_dec_usecnt(bo);
kfree(flip_state);
return ret;
}
/* Save the current FB before it's replaced by the new one in
* drm_atomic_set_fb_for_plane(). We'll need the old FB in
* vc4_async_page_flip_complete() to decrement the BO usecnt and keep
* it consistent.
* FIXME: we should move to generic async-page-flip when it's
* available, so that we can get rid of this hand-made cleanup_fb()
* logic.
*/
flip_state->old_fb = plane->state->fb;
if (flip_state->old_fb)
drm_framebuffer_get(flip_state->old_fb);
WARN_ON(drm_crtc_vblank_get(crtc) != 0);
/* Immediately update the plane's legacy fb pointer, so that later
* modeset prep sees the state that will be present when the semaphore
* is released.
*/
drm_atomic_set_fb_for_plane(plane->state, fb);
vc4_queue_seqno_cb(dev, &flip_state->cb, bo->seqno,
vc4_async_page_flip_complete);
/* Driver takes ownership of state on successful async commit. */
return 0;
}
static int vc4_page_flip(struct drm_crtc *crtc,
struct drm_framebuffer *fb,
struct drm_pending_vblank_event *event,
uint32_t flags,
struct drm_modeset_acquire_ctx *ctx)
{
if (flags & DRM_MODE_PAGE_FLIP_ASYNC)
return vc4_async_page_flip(crtc, fb, event, flags);
else
return drm_atomic_helper_page_flip(crtc, fb, event, flags, ctx);
}
static struct drm_crtc_state *vc4_crtc_duplicate_state(struct drm_crtc *crtc)
{
struct vc4_crtc_state *vc4_state, *old_vc4_state;
vc4_state = kzalloc(sizeof(*vc4_state), GFP_KERNEL);
if (!vc4_state)
return NULL;
old_vc4_state = to_vc4_crtc_state(crtc->state);
vc4_state->feed_txp = old_vc4_state->feed_txp;
vc4_state->margins = old_vc4_state->margins;
__drm_atomic_helper_crtc_duplicate_state(crtc, &vc4_state->base);
return &vc4_state->base;
}
static void vc4_crtc_destroy_state(struct drm_crtc *crtc,
struct drm_crtc_state *state)
{
struct vc4_dev *vc4 = to_vc4_dev(crtc->dev);
struct vc4_crtc_state *vc4_state = to_vc4_crtc_state(state);
if (drm_mm_node_allocated(&vc4_state->mm)) {
unsigned long flags;
spin_lock_irqsave(&vc4->hvs->mm_lock, flags);
drm_mm_remove_node(&vc4_state->mm);
spin_unlock_irqrestore(&vc4->hvs->mm_lock, flags);
}
drm_atomic_helper_crtc_destroy_state(crtc, state);
}
static void
vc4_crtc_reset(struct drm_crtc *crtc)
{
if (crtc->state)
vc4_crtc_destroy_state(crtc, crtc->state);
crtc->state = kzalloc(sizeof(struct vc4_crtc_state), GFP_KERNEL);
if (crtc->state)
crtc->state->crtc = crtc;
}
static const struct drm_crtc_funcs vc4_crtc_funcs = {
.set_config = drm_atomic_helper_set_config,
.destroy = vc4_crtc_destroy,
.page_flip = vc4_page_flip,
.set_property = NULL,
.cursor_set = NULL, /* handled by drm_mode_cursor_universal */
.cursor_move = NULL, /* handled by drm_mode_cursor_universal */
.reset = vc4_crtc_reset,
.atomic_duplicate_state = vc4_crtc_duplicate_state,
.atomic_destroy_state = vc4_crtc_destroy_state,
.gamma_set = drm_atomic_helper_legacy_gamma_set,
.enable_vblank = vc4_enable_vblank,
.disable_vblank = vc4_disable_vblank,
};
static const struct drm_crtc_helper_funcs vc4_crtc_helper_funcs = {
.mode_set_nofb = vc4_crtc_mode_set_nofb,
.mode_valid = vc4_crtc_mode_valid,
.atomic_check = vc4_crtc_atomic_check,
.atomic_flush = vc4_crtc_atomic_flush,
.atomic_enable = vc4_crtc_atomic_enable,
.atomic_disable = vc4_crtc_atomic_disable,
};
static const struct vc4_crtc_data pv0_data = {
.hvs_channel = 0,
.debugfs_name = "crtc0_regs",
.encoder_types = {
[PV_CONTROL_CLK_SELECT_DSI] = VC4_ENCODER_TYPE_DSI0,
[PV_CONTROL_CLK_SELECT_DPI_SMI_HDMI] = VC4_ENCODER_TYPE_DPI,
},
};
static const struct vc4_crtc_data pv1_data = {
.hvs_channel = 2,
.debugfs_name = "crtc1_regs",
.encoder_types = {
[PV_CONTROL_CLK_SELECT_DSI] = VC4_ENCODER_TYPE_DSI1,
[PV_CONTROL_CLK_SELECT_DPI_SMI_HDMI] = VC4_ENCODER_TYPE_SMI,
},
};
static const struct vc4_crtc_data pv2_data = {
.hvs_channel = 1,
.debugfs_name = "crtc2_regs",
.encoder_types = {
[PV_CONTROL_CLK_SELECT_DPI_SMI_HDMI] = VC4_ENCODER_TYPE_HDMI,
[PV_CONTROL_CLK_SELECT_VEC] = VC4_ENCODER_TYPE_VEC,
},
};
static const struct of_device_id vc4_crtc_dt_match[] = {
{ .compatible = "brcm,bcm2835-pixelvalve0", .data = &pv0_data },
{ .compatible = "brcm,bcm2835-pixelvalve1", .data = &pv1_data },
{ .compatible = "brcm,bcm2835-pixelvalve2", .data = &pv2_data },
{}
};
static void vc4_set_crtc_possible_masks(struct drm_device *drm,
struct drm_crtc *crtc)
{
struct vc4_crtc *vc4_crtc = to_vc4_crtc(crtc);
const struct vc4_crtc_data *crtc_data = vc4_crtc->data;
const enum vc4_encoder_type *encoder_types = crtc_data->encoder_types;
struct drm_encoder *encoder;
drm_for_each_encoder(encoder, drm) {
struct vc4_encoder *vc4_encoder;
int i;
/* HVS FIFO2 can feed the TXP IP. */
if (crtc_data->hvs_channel == 2 &&
encoder->encoder_type == DRM_MODE_ENCODER_VIRTUAL) {
encoder->possible_crtcs |= drm_crtc_mask(crtc);
continue;
}
vc4_encoder = to_vc4_encoder(encoder);
for (i = 0; i < ARRAY_SIZE(crtc_data->encoder_types); i++) {
if (vc4_encoder->type == encoder_types[i]) {
vc4_encoder->clock_select = i;
encoder->possible_crtcs |= drm_crtc_mask(crtc);
break;
}
}
}
}
static void
vc4_crtc_get_cob_allocation(struct vc4_crtc *vc4_crtc)
{
struct drm_device *drm = vc4_crtc->base.dev;
struct vc4_dev *vc4 = to_vc4_dev(drm);
u32 dispbase = HVS_READ(SCALER_DISPBASEX(vc4_crtc->channel));
/* Top/base are supposed to be 4-pixel aligned, but the
* Raspberry Pi firmware fills the low bits (which are
* presumably ignored).
*/
u32 top = VC4_GET_FIELD(dispbase, SCALER_DISPBASEX_TOP) & ~3;
u32 base = VC4_GET_FIELD(dispbase, SCALER_DISPBASEX_BASE) & ~3;
vc4_crtc->cob_size = top - base + 4;
}
static int vc4_crtc_bind(struct device *dev, struct device *master, void *data)
{
struct platform_device *pdev = to_platform_device(dev);
struct drm_device *drm = dev_get_drvdata(master);
struct vc4_crtc *vc4_crtc;
struct drm_crtc *crtc;
struct drm_plane *primary_plane, *cursor_plane, *destroy_plane, *temp;
const struct of_device_id *match;
int ret, i;
vc4_crtc = devm_kzalloc(dev, sizeof(*vc4_crtc), GFP_KERNEL);
if (!vc4_crtc)
return -ENOMEM;
crtc = &vc4_crtc->base;
match = of_match_device(vc4_crtc_dt_match, dev);
if (!match)
return -ENODEV;
vc4_crtc->data = match->data;
vc4_crtc->pdev = pdev;
vc4_crtc->regs = vc4_ioremap_regs(pdev, 0);
if (IS_ERR(vc4_crtc->regs))
return PTR_ERR(vc4_crtc->regs);
vc4_crtc->regset.base = vc4_crtc->regs;
vc4_crtc->regset.regs = crtc_regs;
vc4_crtc->regset.nregs = ARRAY_SIZE(crtc_regs);
/* For now, we create just the primary and the legacy cursor
* planes. We should be able to stack more planes on easily,
* but to do that we would need to compute the bandwidth
* requirement of the plane configuration, and reject ones
* that will take too much.
*/
primary_plane = vc4_plane_init(drm, DRM_PLANE_TYPE_PRIMARY);
if (IS_ERR(primary_plane)) {
dev_err(dev, "failed to construct primary plane\n");
ret = PTR_ERR(primary_plane);
goto err;
}
drm_crtc_init_with_planes(drm, crtc, primary_plane, NULL,
&vc4_crtc_funcs, NULL);
drm_crtc_helper_add(crtc, &vc4_crtc_helper_funcs);
vc4_crtc->channel = vc4_crtc->data->hvs_channel;
drm_mode_crtc_set_gamma_size(crtc, ARRAY_SIZE(vc4_crtc->lut_r));
drm_crtc_enable_color_mgmt(crtc, 0, false, crtc->gamma_size);
/* We support CTM, but only for one CRTC at a time. It's therefore
* implemented as private driver state in vc4_kms, not here.
*/
drm_crtc_enable_color_mgmt(crtc, 0, true, crtc->gamma_size);
/* Set up some arbitrary number of planes. We're not limited
* by a set number of physical registers, just the space in
* the HVS (16k) and how small an plane can be (28 bytes).
* However, each plane we set up takes up some memory, and
* increases the cost of looping over planes, which atomic
* modesetting does quite a bit. As a result, we pick a
* modest number of planes to expose, that should hopefully
* still cover any sane usecase.
*/
for (i = 0; i < 8; i++) {
struct drm_plane *plane =
vc4_plane_init(drm, DRM_PLANE_TYPE_OVERLAY);
if (IS_ERR(plane))
continue;
plane->possible_crtcs = drm_crtc_mask(crtc);
}
/* Set up the legacy cursor after overlay initialization,
* since we overlay planes on the CRTC in the order they were
* initialized.
*/
cursor_plane = vc4_plane_init(drm, DRM_PLANE_TYPE_CURSOR);
if (!IS_ERR(cursor_plane)) {
cursor_plane->possible_crtcs = drm_crtc_mask(crtc);
crtc->cursor = cursor_plane;
}
vc4_crtc_get_cob_allocation(vc4_crtc);
CRTC_WRITE(PV_INTEN, 0);
CRTC_WRITE(PV_INTSTAT, PV_INT_VFP_START);
ret = devm_request_irq(dev, platform_get_irq(pdev, 0),
vc4_crtc_irq_handler, 0, "vc4 crtc", vc4_crtc);
if (ret)
goto err_destroy_planes;
vc4_set_crtc_possible_masks(drm, crtc);
for (i = 0; i < crtc->gamma_size; i++) {
vc4_crtc->lut_r[i] = i;
vc4_crtc->lut_g[i] = i;
vc4_crtc->lut_b[i] = i;
}
platform_set_drvdata(pdev, vc4_crtc);
vc4_debugfs_add_regset32(drm, vc4_crtc->data->debugfs_name,
&vc4_crtc->regset);
return 0;
err_destroy_planes:
list_for_each_entry_safe(destroy_plane, temp,
&drm->mode_config.plane_list, head) {
if (destroy_plane->possible_crtcs == drm_crtc_mask(crtc))
destroy_plane->funcs->destroy(destroy_plane);
}
err:
return ret;
}
static void vc4_crtc_unbind(struct device *dev, struct device *master,
void *data)
{
struct platform_device *pdev = to_platform_device(dev);
struct vc4_crtc *vc4_crtc = dev_get_drvdata(dev);
vc4_crtc_destroy(&vc4_crtc->base);
CRTC_WRITE(PV_INTEN, 0);
platform_set_drvdata(pdev, NULL);
}
static const struct component_ops vc4_crtc_ops = {
.bind = vc4_crtc_bind,
.unbind = vc4_crtc_unbind,
};
static int vc4_crtc_dev_probe(struct platform_device *pdev)
{
return component_add(&pdev->dev, &vc4_crtc_ops);
}
static int vc4_crtc_dev_remove(struct platform_device *pdev)
{
component_del(&pdev->dev, &vc4_crtc_ops);
return 0;
}
struct platform_driver vc4_crtc_driver = {
.probe = vc4_crtc_dev_probe,
.remove = vc4_crtc_dev_remove,
.driver = {
.name = "vc4_crtc",
.of_match_table = vc4_crtc_dt_match,
},
};