openwrt/target/linux/bcm27xx/patches-6.6/950-1179-drm-rp1-rp1-dsi-Switch-to-PLL_SYS-source-for-DPI-whe.patch
Álvaro Fernández Rojas 0171157d45 bcm27xx: update to latest RPi patches
The patches were generated from the RPi repo with the following command:
git format-patch v6.6.44..rpi-6.6.y

Signed-off-by: Álvaro Fernández Rojas <noltari@gmail.com>
2024-08-06 18:38:00 +02:00

314 lines
12 KiB
Diff

From f5de8d46da4b40f2180be502c1e547fe8c9b2ac2 Mon Sep 17 00:00:00 2001
From: Nick Hollinghurst <nick.hollinghurst@raspberrypi.com>
Date: Fri, 10 May 2024 15:48:15 +0100
Subject: [PATCH 1179/1215] drm: rp1: rp1-dsi: Switch to PLL_SYS source for DPI
when 8 * lanes > bpp
To support 4 lanes, re-parent DPI clock source between DSI byteclock
(using the new "variable sources" defined in clk-rp1) and PLL_SYS.
This is to cover cases in which byteclock < pixclock <= 200MHz.
Tidying: All frequencies now in Hz (not kHz), where DSI speed is now
represented by byteclock to simplify arithmetic. Clamp DPI and byte
clocks to their legal ranges; fix up HSTX timeout to avoid an unsafe
assumption that it would return to LP state for every scanline.
Because of RP1's clock topology, the ratio between DSI and DPI clocks
may not be exact with 3 or 4 lanes, leading to slightly irregular
timings each time DSI switches between HS and LP states. Tweak to
inhibit LP during Horizontal BP when sync pulses were requested.
Signed-off-by: Nick Hollinghurst <nick.hollinghurst@raspberrypi.com>
---
drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi.c | 3 +-
drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi.h | 3 +-
drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi_dsi.c | 130 +++++++++++++---------
3 files changed, 80 insertions(+), 56 deletions(-)
--- a/drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi.c
+++ b/drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi.c
@@ -54,6 +54,7 @@ static void rp1_dsi_bridge_pre_enable(st
struct rp1_dsi *dsi = bridge_to_rp1_dsi(bridge);
rp1dsi_dsi_setup(dsi, &dsi->pipe.crtc.state->adjusted_mode);
+ dsi->dsi_running = true;
}
static void rp1_dsi_bridge_enable(struct drm_bridge *bridge,
@@ -443,7 +444,7 @@ static int rp1dsi_platform_probe(struct
/* Hardware resources */
for (i = 0; i < RP1DSI_NUM_CLOCKS; i++) {
static const char * const myclocknames[RP1DSI_NUM_CLOCKS] = {
- "cfgclk", "dpiclk", "byteclk", "refclk"
+ "cfgclk", "dpiclk", "byteclk", "refclk", "pllsys"
};
dsi->clocks[i] = devm_clk_get(dev, myclocknames[i]);
if (IS_ERR(dsi->clocks[i])) {
--- a/drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi.h
+++ b/drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi.h
@@ -30,7 +30,8 @@
#define RP1DSI_CLOCK_DPI 1
#define RP1DSI_CLOCK_BYTE 2
#define RP1DSI_CLOCK_REF 3
-#define RP1DSI_NUM_CLOCKS 4
+#define RP1DSI_CLOCK_PLLSYS 4
+#define RP1DSI_NUM_CLOCKS 5
/* ---------------------------------------------------------------------- */
--- a/drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi_dsi.c
+++ b/drivers/gpu/drm/rp1/rp1-dsi/rp1_dsi_dsi.c
@@ -7,6 +7,7 @@
#include <linux/delay.h>
#include <linux/errno.h>
+#include <linux/math64.h>
#include <linux/platform_device.h>
#include <linux/rp1_platform.h>
#include "drm/drm_print.h"
@@ -1111,7 +1112,7 @@ static void dphy_transaction(struct rp1_
DSI_WRITE(DSI_PHY_TST_CTRL0, DPHY_CTRL0_PHY_TESTCLK_BITS);
}
-static uint8_t dphy_get_div(u32 refclk_khz, u32 vco_freq_khz, u32 *ptr_m, u32 *ptr_n)
+static u64 dphy_get_div(u32 refclk, u64 vco_freq, u32 *ptr_m, u32 *ptr_n)
{
/*
* See pg 77-78 of dphy databook
@@ -1124,19 +1125,23 @@ static uint8_t dphy_get_div(u32 refclk_k
* In practice, given a 50MHz reference clock, it can produce any
* multiple of 10MHz, 11.1111MHz, 12.5MHz, 14.286MHz or 16.667MHz
* with < 1% error for all frequencies above 495MHz.
+ *
+ * vco_freq should be set to the lane bit rate (not the MIPI clock
+ * which is half of this). These frequencies are now measured in Hz.
+ * They should fit within u32, but u64 is needed for calculations.
*/
- static const u32 REF_DIVN_MAX = 40000u;
- static const u32 REF_DIVN_MIN = 5000u;
- u32 best_n, best_m, best_err = 0x7fffffff;
- unsigned int n;
+ static const u32 REF_DIVN_MAX = 40000000;
+ static const u32 REF_DIVN_MIN = 5000000;
+ u32 n, best_n, best_m;
+ u64 best_err = vco_freq;
- for (n = 1 + refclk_khz / REF_DIVN_MAX; n * REF_DIVN_MIN <= refclk_khz && n < 100; ++n) {
- u32 half_m = (n * vco_freq_khz + refclk_khz) / (2 * refclk_khz);
+ for (n = 1 + refclk / REF_DIVN_MAX; n * REF_DIVN_MIN <= refclk && n < 100; ++n) {
+ u32 half_m = DIV_U64_ROUND_CLOSEST(n * vco_freq, 2 * refclk);
if (half_m < 150) {
- u32 f = (2 * half_m * refclk_khz) / n;
- u32 err = (f > vco_freq_khz) ? f - vco_freq_khz : vco_freq_khz - f;
+ u64 f = div_u64(mul_u32_u32(2 * half_m, refclk), n);
+ u64 err = (f > vco_freq) ? f - vco_freq : vco_freq - f;
if (err < best_err) {
best_n = n;
@@ -1148,12 +1153,12 @@ static uint8_t dphy_get_div(u32 refclk_k
}
}
- if (64 * best_err < vco_freq_khz) { /* tolerate small error */
- *ptr_n = best_n;
- *ptr_m = best_m;
- return 1;
- }
- return 0;
+ if (64 * best_err >= vco_freq)
+ return 0;
+
+ *ptr_n = best_n;
+ *ptr_m = best_m;
+ return div_u64(mul_u32_u32(best_m, refclk), best_n);
}
struct hsfreq_range {
@@ -1226,13 +1231,14 @@ static void dphy_set_hsfreqrange(struct
hsfreq_table[i].hsfreqrange << 1);
}
-static void dphy_configure_pll(struct rp1_dsi *dsi, u32 refclk_khz, u32 vco_freq_khz)
+static u32 dphy_configure_pll(struct rp1_dsi *dsi, u32 refclk, u32 vco_freq)
{
u32 m = 0;
u32 n = 0;
+ u32 actual_vco_freq = dphy_get_div(refclk, vco_freq, &m, &n);
- if (dphy_get_div(refclk_khz, vco_freq_khz, &m, &n)) {
- dphy_set_hsfreqrange(dsi, vco_freq_khz / 1000);
+ if (actual_vco_freq) {
+ dphy_set_hsfreqrange(dsi, actual_vco_freq / 1000000);
/* Program m,n from registers */
dphy_transaction(dsi, DPHY_PLL_DIV_CTRL_OFFSET, 0x30);
/* N (program N-1) */
@@ -1242,18 +1248,21 @@ static void dphy_configure_pll(struct rp
/* M[4:0] (program M-1) */
dphy_transaction(dsi, DPHY_PLL_LOOP_DIV_OFFSET, ((m - 1) & 0x1F));
drm_dbg_driver(dsi->drm,
- "DPHY: vco freq want %dkHz got %dkHz = %d * (%dkHz / %d), hsfreqrange = 0x%02x\r\n",
- vco_freq_khz, refclk_khz * m / n, m, refclk_khz,
- n, hsfreq_table[dsi->hsfreq_index].hsfreqrange);
+ "DPHY: vco freq want %uHz got %uHz = %d * (%uHz / %d), hsfreqrange = 0x%02x\n",
+ vco_freq, actual_vco_freq, m, refclk, n,
+ hsfreq_table[dsi->hsfreq_index].hsfreqrange);
} else {
- drm_info(dsi->drm,
- "rp1dsi: Error configuring DPHY PLL! %dkHz = %d * (%dkHz / %d)\r\n",
- vco_freq_khz, m, refclk_khz, n);
+ drm_warn(dsi->drm,
+ "rp1dsi: Error configuring DPHY PLL %uHz\n", vco_freq);
}
+
+ return actual_vco_freq;
}
-static void dphy_init_khz(struct rp1_dsi *dsi, u32 ref_freq, u32 vco_freq)
+static u32 dphy_init(struct rp1_dsi *dsi, u32 ref_freq, u32 vco_freq)
{
+ u32 actual_vco_freq;
+
/* Reset the PHY */
DSI_WRITE(DSI_PHYRSTZ, 0);
DSI_WRITE(DSI_PHY_TST_CTRL0, DPHY_CTRL0_PHY_TESTCLK_BITS);
@@ -1263,13 +1272,15 @@ static void dphy_init_khz(struct rp1_dsi
DSI_WRITE(DSI_PHY_TST_CTRL0, DPHY_CTRL0_PHY_TESTCLK_BITS);
udelay(1);
/* Since we are in DSI (not CSI2) mode here, start the PLL */
- dphy_configure_pll(dsi, ref_freq, vco_freq);
+ actual_vco_freq = dphy_configure_pll(dsi, ref_freq, vco_freq);
udelay(1);
/* Unreset */
DSI_WRITE(DSI_PHYRSTZ, DSI_PHYRSTZ_SHUTDOWNZ_BITS);
udelay(1);
DSI_WRITE(DSI_PHYRSTZ, (DSI_PHYRSTZ_SHUTDOWNZ_BITS | DSI_PHYRSTZ_RSTZ_BITS));
udelay(1); /* so we can see PLL coming up? */
+
+ return actual_vco_freq;
}
void rp1dsi_mipicfg_setup(struct rp1_dsi *dsi)
@@ -1290,23 +1301,30 @@ static unsigned long rp1dsi_refclk_freq(
return u;
}
-static void rp1dsi_dpiclk_start(struct rp1_dsi *dsi, unsigned int bpp, unsigned int lanes)
+static void rp1dsi_dpiclk_start(struct rp1_dsi *dsi, u32 byte_clock,
+ unsigned int bpp, unsigned int lanes)
{
- unsigned long u;
-
- if (dsi->clocks[RP1DSI_CLOCK_DPI]) {
- u = (dsi->clocks[RP1DSI_CLOCK_BYTE]) ?
- clk_get_rate(dsi->clocks[RP1DSI_CLOCK_BYTE]) : 0;
- drm_info(dsi->drm,
- "rp1dsi: Nominal byte clock %lu; scale by %u/%u",
- u, 4 * lanes, (bpp >> 1));
- if (u < 1 || u >= (1ul << 28))
- u = 72000000ul; /* default DUMMY frequency for byteclock */
+ /* Dummy clk_set_rate() to declare the actual DSI byte-clock rate */
+ clk_set_rate(dsi->clocks[RP1DSI_CLOCK_BYTE], byte_clock);
+ /*
+ * Prefer the DSI byte-clock source where possible, so that DSI and DPI
+ * clocks will be in an exact ratio and downstream devices can recover
+ * perfect timings. But when DPI clock is faster, fall back on PLL_SYS.
+ * To defeat rounding errors, specify explicitly which source to use.
+ */
+ if (bpp >= 8 * lanes)
clk_set_parent(dsi->clocks[RP1DSI_CLOCK_DPI], dsi->clocks[RP1DSI_CLOCK_BYTE]);
- clk_set_rate(dsi->clocks[RP1DSI_CLOCK_DPI], (4 * lanes * u) / (bpp >> 1));
- clk_prepare_enable(dsi->clocks[RP1DSI_CLOCK_DPI]);
- }
+ else if (dsi->clocks[RP1DSI_CLOCK_PLLSYS])
+ clk_set_parent(dsi->clocks[RP1DSI_CLOCK_DPI], dsi->clocks[RP1DSI_CLOCK_PLLSYS]);
+
+ clk_set_rate(dsi->clocks[RP1DSI_CLOCK_DPI], (4 * lanes * byte_clock) / (bpp >> 1));
+ clk_prepare_enable(dsi->clocks[RP1DSI_CLOCK_DPI]);
+ drm_info(dsi->drm,
+ "rp1dsi: Nominal Byte clock %u DPI clock %lu (parent rate %lu)",
+ byte_clock,
+ clk_get_rate(dsi->clocks[RP1DSI_CLOCK_DPI]),
+ clk_get_rate(clk_get_parent(dsi->clocks[RP1DSI_CLOCK_DPI])));
}
static void rp1dsi_dpiclk_stop(struct rp1_dsi *dsi)
@@ -1336,18 +1354,21 @@ static u32 get_colorcode(enum mipi_dsi_p
return 0x005;
}
-/* Maximum frequency for LP escape clock (20MHz), and some magic numbers */
-#define RP1DSI_ESC_CLK_KHZ 20000
-#define RP1DSI_TO_CLK_DIV 5
-#define RP1DSI_HSTX_TO_MIN 0x200
-#define RP1DSI_LPRX_TO_VAL 0x400
+/* Frequency limits for DPI, HS and LP clocks, and some magic numbers */
+#define RP1DSI_DPI_MAX_KHZ 200000
+#define RP1DSI_BYTE_CLK_MIN 10000000
+#define RP1DSI_BYTE_CLK_MAX 187500000
+#define RP1DSI_ESC_CLK_MAX 20000000
+#define RP1DSI_TO_CLK_DIV 0x50
+#define RP1DSI_LPRX_TO_VAL 0x40
#define RP1DSI_BTA_TO_VAL 0xd00
void rp1dsi_dsi_setup(struct rp1_dsi *dsi, struct drm_display_mode const *mode)
{
u32 timeout, mask, vid_mode_cfg;
- int lane_kbps;
unsigned int bpp = mipi_dsi_pixel_format_to_bpp(dsi->display_format);
+ u32 byte_clock = clamp((bpp * 125 * min(mode->clock, RP1DSI_DPI_MAX_KHZ)) / dsi->lanes,
+ RP1DSI_BYTE_CLK_MIN, RP1DSI_BYTE_CLK_MAX);
DSI_WRITE(DSI_PHY_IF_CFG, dsi->lanes - 1);
DSI_WRITE(DSI_DPI_CFG_POL, 0);
@@ -1360,6 +1381,8 @@ void rp1dsi_dsi_setup(struct rp1_dsi *ds
vid_mode_cfg = 0xbf00;
if (!(dsi->display_flags & MIPI_DSI_MODE_VIDEO_SYNC_PULSE))
vid_mode_cfg |= 0x01;
+ else if (8 * dsi->lanes > bpp)
+ vid_mode_cfg &= ~0x400; /* PULSE && inexact DPICLK => fix HBP time */
if (dsi->display_flags & MIPI_DSI_MODE_VIDEO_BURST)
vid_mode_cfg |= 0x02;
DSI_WRITE(DSI_VID_MODE_CFG, vid_mode_cfg);
@@ -1369,15 +1392,14 @@ void rp1dsi_dsi_setup(struct rp1_dsi *ds
DSI_WRITE(DSI_MODE_CFG, 1);
/* Set timeouts and clock dividers */
- DSI_WRITE(DSI_TO_CNT_CFG,
- (max((bpp * mode->htotal) / (7 * RP1DSI_TO_CLK_DIV * dsi->lanes),
- RP1DSI_HSTX_TO_MIN) << 16) |
- RP1DSI_LPRX_TO_VAL);
+ timeout = (bpp * mode->htotal * mode->vdisplay) / (7 * RP1DSI_TO_CLK_DIV * dsi->lanes);
+ if (timeout > 0xFFFFu)
+ timeout = 0;
+ DSI_WRITE(DSI_TO_CNT_CFG, (timeout << 16) | RP1DSI_LPRX_TO_VAL);
DSI_WRITE(DSI_BTA_TO_CNT, RP1DSI_BTA_TO_VAL);
- lane_kbps = (bpp * mode->clock) / dsi->lanes;
DSI_WRITE(DSI_CLKMGR_CFG,
(RP1DSI_TO_CLK_DIV << 8) |
- max(2, lane_kbps / (8 * RP1DSI_ESC_CLK_KHZ) + 1));
+ max(2u, 1u + byte_clock / RP1DSI_ESC_CLK_MAX));
/* Configure video timings */
DSI_WRITE(DSI_VID_PKT_SIZE, mode->hdisplay);
@@ -1394,7 +1416,7 @@ void rp1dsi_dsi_setup(struct rp1_dsi *ds
DSI_WRITE(DSI_VID_VACTIVE_LINES, mode->vdisplay);
/* Init PHY */
- dphy_init_khz(dsi, rp1dsi_refclk_freq(dsi) / 1000, lane_kbps);
+ byte_clock = dphy_init(dsi, rp1dsi_refclk_freq(dsi), 8 * byte_clock) >> 3;
DSI_WRITE(DSI_PHY_TMR_LPCLK_CFG,
(hsfreq_table[dsi->hsfreq_index].clk_lp2hs << DSI_PHY_TMR_LP2HS_LSB) |
@@ -1418,7 +1440,7 @@ void rp1dsi_dsi_setup(struct rp1_dsi *ds
DSI_WRITE(DSI_PWR_UP, 0x1); /* power up */
/* Now it should be safe to start the external DPI clock divider */
- rp1dsi_dpiclk_start(dsi, bpp, dsi->lanes);
+ rp1dsi_dpiclk_start(dsi, byte_clock, bpp, dsi->lanes);
/* Wait for all lane(s) to be in Stopstate */
mask = (1 << 4);