blob: 500b7dc895d05554e729f8608ce76ec021bcee1f [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (c) 2014, The Linux Foundation. All rights reserved.
* Copyright (C) 2013 Red Hat
* Author: Rob Clark <robdclark@gmail.com>
*/
#include <drm/drm_fourcc.h>
#include <drm/drm_util.h>
#include "mdp5_kms.h"
#include "mdp5_smp.h"
struct mdp5_smp {
struct drm_device *dev;
uint8_t reserved[MAX_CLIENTS]; /* fixed MMBs allocation per client */
int blk_cnt;
int blk_size;
/* register cache */
u32 alloc_w[22];
u32 alloc_r[22];
u32 pipe_reqprio_fifo_wm0[SSPP_MAX];
u32 pipe_reqprio_fifo_wm1[SSPP_MAX];
u32 pipe_reqprio_fifo_wm2[SSPP_MAX];
};
static inline
struct mdp5_kms *get_kms(struct mdp5_smp *smp)
{
struct msm_drm_private *priv = smp->dev->dev_private;
return to_mdp5_kms(to_mdp_kms(priv->kms));
}
static inline u32 pipe2client(enum mdp5_pipe pipe, int plane)
{
#define CID_UNUSED 0
if (WARN_ON(plane >= pipe2nclients(pipe)))
return CID_UNUSED;
/*
* Note on SMP clients:
* For ViG pipes, fetch Y/Cr/Cb-components clients are always
* consecutive, and in that order.
*
* e.g.:
* if mdp5_cfg->smp.clients[SSPP_VIG0] = N,
* Y plane's client ID is N
* Cr plane's client ID is N + 1
* Cb plane's client ID is N + 2
*/
return mdp5_cfg->smp.clients[pipe] + plane;
}
/* allocate blocks for the specified request: */
static int smp_request_block(struct mdp5_smp *smp,
struct mdp5_smp_state *state,
u32 cid, int nblks)
{
void *cs = state->client_state[cid];
int i, avail, cnt = smp->blk_cnt;
uint8_t reserved;
/* we shouldn't be requesting blocks for an in-use client: */
WARN_ON(!bitmap_empty(cs, cnt));
reserved = smp->reserved[cid];
if (reserved) {
nblks = max(0, nblks - reserved);
DBG("%d MMBs allocated (%d reserved)", nblks, reserved);
}
avail = cnt - bitmap_weight(state->state, cnt);
if (nblks > avail) {
DRM_DEV_ERROR(smp->dev->dev, "out of blks (req=%d > avail=%d)\n",
nblks, avail);
return -ENOSPC;
}
for (i = 0; i < nblks; i++) {
int blk = find_first_zero_bit(state->state, cnt);
set_bit(blk, cs);
set_bit(blk, state->state);
}
return 0;
}
static void set_fifo_thresholds(struct mdp5_smp *smp,
enum mdp5_pipe pipe, int nblks)
{
u32 smp_entries_per_blk = smp->blk_size / (128 / BITS_PER_BYTE);
u32 val;
/* 1/4 of SMP pool that is being fetched */
val = (nblks * smp_entries_per_blk) / 4;
smp->pipe_reqprio_fifo_wm0[pipe] = val * 1;
smp->pipe_reqprio_fifo_wm1[pipe] = val * 2;
smp->pipe_reqprio_fifo_wm2[pipe] = val * 3;
}
/*
* NOTE: looks like if horizontal decimation is used (if we supported that)
* then the width used to calculate SMP block requirements is the post-
* decimated width. Ie. SMP buffering sits downstream of decimation (which
* presumably happens during the dma from scanout buffer).
*/
uint32_t mdp5_smp_calculate(struct mdp5_smp *smp,
const struct msm_format *format,
u32 width, bool hdecim)
{
const struct drm_format_info *info = drm_format_info(format->pixel_format);
struct mdp5_kms *mdp5_kms = get_kms(smp);
int rev = mdp5_cfg_get_hw_rev(mdp5_kms->cfg);
int i, hsub, nplanes, nlines;
uint32_t blkcfg = 0;
nplanes = info->num_planes;
hsub = info->hsub;
/* different if BWC (compressed framebuffer?) enabled: */
nlines = 2;
/* Newer MDPs have split/packing logic, which fetches sub-sampled
* U and V components (splits them from Y if necessary) and packs
* them together, writes to SMP using a single client.
*/
if ((rev > 0) && (format->chroma_sample > CHROMA_FULL)) {
nplanes = 2;
/* if decimation is enabled, HW decimates less on the
* sub sampled chroma components
*/
if (hdecim && (hsub > 1))
hsub = 1;
}
for (i = 0; i < nplanes; i++) {
int n, fetch_stride, cpp;
cpp = info->cpp[i];
fetch_stride = width * cpp / (i ? hsub : 1);
n = DIV_ROUND_UP(fetch_stride * nlines, smp->blk_size);
/* for hw rev v1.00 */
if (rev == 0)
n = roundup_pow_of_two(n);
blkcfg |= (n << (8 * i));
}
return blkcfg;
}
int mdp5_smp_assign(struct mdp5_smp *smp, struct mdp5_smp_state *state,
enum mdp5_pipe pipe, uint32_t blkcfg)
{
struct mdp5_kms *mdp5_kms = get_kms(smp);
struct drm_device *dev = mdp5_kms->dev;
int i, ret;
for (i = 0; i < pipe2nclients(pipe); i++) {
u32 cid = pipe2client(pipe, i);
int n = blkcfg & 0xff;
if (!n)
continue;
DBG("%s[%d]: request %d SMP blocks", pipe2name(pipe), i, n);
ret = smp_request_block(smp, state, cid, n);
if (ret) {
DRM_DEV_ERROR(dev->dev, "Cannot allocate %d SMP blocks: %d\n",
n, ret);
return ret;
}
blkcfg >>= 8;
}
state->assigned |= (1 << pipe);
return 0;
}
/* Release SMP blocks for all clients of the pipe */
void mdp5_smp_release(struct mdp5_smp *smp, struct mdp5_smp_state *state,
enum mdp5_pipe pipe)
{
int i;
int cnt = smp->blk_cnt;
for (i = 0; i < pipe2nclients(pipe); i++) {
u32 cid = pipe2client(pipe, i);
void *cs = state->client_state[cid];
/* update global state: */
bitmap_andnot(state->state, state->state, cs, cnt);
/* clear client's state */
bitmap_zero(cs, cnt);
}
state->released |= (1 << pipe);
}
/* NOTE: SMP_ALLOC_* regs are *not* double buffered, so release has to
* happen after scanout completes.
*/
static unsigned update_smp_state(struct mdp5_smp *smp,
u32 cid, mdp5_smp_state_t *assigned)
{
int cnt = smp->blk_cnt;
unsigned nblks = 0;
u32 blk, val;
for_each_set_bit(blk, *assigned, cnt) {
int idx = blk / 3;
int fld = blk % 3;
val = smp->alloc_w[idx];
switch (fld) {
case 0:
val &= ~MDP5_SMP_ALLOC_W_REG_CLIENT0__MASK;
val |= MDP5_SMP_ALLOC_W_REG_CLIENT0(cid);
break;
case 1:
val &= ~MDP5_SMP_ALLOC_W_REG_CLIENT1__MASK;
val |= MDP5_SMP_ALLOC_W_REG_CLIENT1(cid);
break;
case 2:
val &= ~MDP5_SMP_ALLOC_W_REG_CLIENT2__MASK;
val |= MDP5_SMP_ALLOC_W_REG_CLIENT2(cid);
break;
}
smp->alloc_w[idx] = val;
smp->alloc_r[idx] = val;
nblks++;
}
return nblks;
}
static void write_smp_alloc_regs(struct mdp5_smp *smp)
{
struct mdp5_kms *mdp5_kms = get_kms(smp);
int i, num_regs;
num_regs = smp->blk_cnt / 3 + 1;
for (i = 0; i < num_regs; i++) {
mdp5_write(mdp5_kms, REG_MDP5_SMP_ALLOC_W_REG(i),
smp->alloc_w[i]);
mdp5_write(mdp5_kms, REG_MDP5_SMP_ALLOC_R_REG(i),
smp->alloc_r[i]);
}
}
static void write_smp_fifo_regs(struct mdp5_smp *smp)
{
struct mdp5_kms *mdp5_kms = get_kms(smp);
int i;
for (i = 0; i < mdp5_kms->num_hwpipes; i++) {
struct mdp5_hw_pipe *hwpipe = mdp5_kms->hwpipes[i];
enum mdp5_pipe pipe = hwpipe->pipe;
mdp5_write(mdp5_kms, REG_MDP5_PIPE_REQPRIO_FIFO_WM_0(pipe),
smp->pipe_reqprio_fifo_wm0[pipe]);
mdp5_write(mdp5_kms, REG_MDP5_PIPE_REQPRIO_FIFO_WM_1(pipe),
smp->pipe_reqprio_fifo_wm1[pipe]);
mdp5_write(mdp5_kms, REG_MDP5_PIPE_REQPRIO_FIFO_WM_2(pipe),
smp->pipe_reqprio_fifo_wm2[pipe]);
}
}
void mdp5_smp_prepare_commit(struct mdp5_smp *smp, struct mdp5_smp_state *state)
{
enum mdp5_pipe pipe;
for_each_set_bit(pipe, &state->assigned, sizeof(state->assigned) * 8) {
unsigned i, nblks = 0;
for (i = 0; i < pipe2nclients(pipe); i++) {
u32 cid = pipe2client(pipe, i);
void *cs = state->client_state[cid];
nblks += update_smp_state(smp, cid, cs);
DBG("assign %s:%u, %u blks",
pipe2name(pipe), i, nblks);
}
set_fifo_thresholds(smp, pipe, nblks);
}
write_smp_alloc_regs(smp);
write_smp_fifo_regs(smp);
state->assigned = 0;
}
void mdp5_smp_complete_commit(struct mdp5_smp *smp, struct mdp5_smp_state *state)
{
enum mdp5_pipe pipe;
for_each_set_bit(pipe, &state->released, sizeof(state->released) * 8) {
DBG("release %s", pipe2name(pipe));
set_fifo_thresholds(smp, pipe, 0);
}
write_smp_fifo_regs(smp);
state->released = 0;
}
void mdp5_smp_dump(struct mdp5_smp *smp, struct drm_printer *p,
struct mdp5_global_state *global_state)
{
struct mdp5_kms *mdp5_kms = get_kms(smp);
struct mdp5_hw_pipe_state *hwpstate;
struct mdp5_smp_state *state;
int total = 0, i, j;
drm_printf(p, "name\tinuse\tplane\n");
drm_printf(p, "----\t-----\t-----\n");
/* grab these *after* we hold the state_lock */
hwpstate = &global_state->hwpipe;
state = &global_state->smp;
for (i = 0; i < mdp5_kms->num_hwpipes; i++) {
struct mdp5_hw_pipe *hwpipe = mdp5_kms->hwpipes[i];
struct drm_plane *plane = hwpstate->hwpipe_to_plane[hwpipe->idx];
enum mdp5_pipe pipe = hwpipe->pipe;
for (j = 0; j < pipe2nclients(pipe); j++) {
u32 cid = pipe2client(pipe, j);
void *cs = state->client_state[cid];
int inuse = bitmap_weight(cs, smp->blk_cnt);
drm_printf(p, "%s:%d\t%d\t%s\n",
pipe2name(pipe), j, inuse,
plane ? plane->name : "(null)");
total += inuse;
}
}
drm_printf(p, "TOTAL:\t%d\t(of %d)\n", total, smp->blk_cnt);
drm_printf(p, "AVAIL:\t%d\n", smp->blk_cnt -
bitmap_weight(state->state, smp->blk_cnt));
}
struct mdp5_smp *mdp5_smp_init(struct mdp5_kms *mdp5_kms, const struct mdp5_smp_block *cfg)
{
struct drm_device *dev = mdp5_kms->dev;
struct mdp5_smp_state *state;
struct mdp5_global_state *global_state;
struct mdp5_smp *smp;
smp = devm_kzalloc(dev->dev, sizeof(*smp), GFP_KERNEL);
if (unlikely(!smp))
return ERR_PTR(-ENOMEM);
smp->dev = mdp5_kms->dev;
smp->blk_cnt = cfg->mmb_count;
smp->blk_size = cfg->mmb_size;
global_state = mdp5_get_existing_global_state(mdp5_kms);
state = &global_state->smp;
/* statically tied MMBs cannot be re-allocated: */
bitmap_copy(state->state, cfg->reserved_state, smp->blk_cnt);
memcpy(smp->reserved, cfg->reserved, sizeof(smp->reserved));
return smp;
}