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authorAngel Pons <th3fanbus@gmail.com>2020-03-18 13:09:39 +0100
committerPatrick Georgi <pgeorgi@google.com>2020-03-19 12:04:08 +0000
commite82b02c004e94c4f6016543088f99120be415ff3 (patch)
tree017cf5dc3d375f6c8190875e66246a65e2346d85 /src/northbridge/intel/sandybridge
parent44eeed0e5cbb1d449d2398671b29bb36b661ac6f (diff)
downloadcoreboot-e82b02c004e94c4f6016543088f99120be415ff3.tar.xz
nb/intel/sandybridge: Use loops on DMI register groups
The DMI link consists of four lanes, grouped in two bundles. Therefore, some DMI registers may be organized as "per-lane" or "per-bundle". This can be seen in the DMI initialization sequence as series of equidistant offsets being programmed with the same value. Make this more obvious by factoring out the register groups using loops. With BUILD_TIMELESS=1, the binary of ASUS P8Z77-V LX2 remains identical. Change-Id: Iebf40b2a5b37ed9060a6660840ea6cdff7eb3fc3 Signed-off-by: Angel Pons <th3fanbus@gmail.com> Reviewed-on: https://review.coreboot.org/c/coreboot/+/39631 Tested-by: build bot (Jenkins) <no-reply@coreboot.org> Reviewed-by: Arthur Heymans <arthur@aheymans.xyz>
Diffstat (limited to 'src/northbridge/intel/sandybridge')
-rw-r--r--src/northbridge/intel/sandybridge/early_dmi.c279
1 files changed, 142 insertions, 137 deletions
diff --git a/src/northbridge/intel/sandybridge/early_dmi.c b/src/northbridge/intel/sandybridge/early_dmi.c
index 99705bb358..dec371fd15 100644
--- a/src/northbridge/intel/sandybridge/early_dmi.c
+++ b/src/northbridge/intel/sandybridge/early_dmi.c
@@ -20,179 +20,184 @@ void early_init_dmi(void)
{
int i;
- DMIBAR32(0x0914) |= 0x80000000;
- DMIBAR32(0x0934) |= 0x80000000;
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0914 + (i << 5)) |= (1 << 31);
+ }
for (i = 0; i < 4; i++) {
- DMIBAR32(0x0a00 + (i << 4)) &= 0xf3ffffff;
- DMIBAR32(0x0a04 + (i << 4)) |= 0x800;
+ DMIBAR32(0x0a00 + (i << 4)) &= ~0x0c000000;
+ DMIBAR32(0x0a04 + (i << 4)) |= (1 << 11);
+ }
+ DMIBAR32(0x0c30) = (DMIBAR32(0x0c30) & 0x0fffffff) | (1 << 30);
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0904 + (i << 5)) &= ~0x01c00000;
+ DMIBAR32(0x090c + (i << 5)) &= ~0x000e0000;
}
- DMIBAR32(0x0c30) = (DMIBAR32(0x0c30) & 0xfffffff) | 0x40000000;
+
for (i = 0; i < 2; i++) {
- DMIBAR32(0x0904 + (i << 5)) &= 0xfe3fffff;
- DMIBAR32(0x090c + (i << 5)) &= 0xfff1ffff;
+ DMIBAR32(0x090c + (i << 5)) &= ~0x01e00000;
}
- DMIBAR32(0x090c) &= 0xfe1fffff;
- DMIBAR32(0x092c) &= 0xfe1fffff;
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0904 + (i << 5)); // !!! = 0x7a1842ec
+ DMIBAR32(0x0904 + (i << 5)) = 0x7a1842ec;
+ DMIBAR32(0x090c + (i << 5)); // !!! = 0x00000208
+ DMIBAR32(0x090c + (i << 5)) = 0x00000128;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x46139008
+ DMIBAR32(0x0700 + (i << 5)) = 0x46139008;
+ }
- DMIBAR32(0x0904); // !!! = 0x7a1842ec
- DMIBAR32(0x0904) = 0x7a1842ec;
- DMIBAR32(0x090c); // !!! = 0x00000208
- DMIBAR32(0x090c) = 0x00000128;
- DMIBAR32(0x0924); // !!! = 0x7a1842ec
- DMIBAR32(0x0924) = 0x7a1842ec;
- DMIBAR32(0x092c); // !!! = 0x00000208
- DMIBAR32(0x092c) = 0x00000128;
- DMIBAR32(0x0700); // !!! = 0x46139008
- DMIBAR32(0x0700) = 0x46139008;
- DMIBAR32(0x0720); // !!! = 0x46139008
- DMIBAR32(0x0720) = 0x46139008;
DMIBAR32(0x0c04); // !!! = 0x2e680008
DMIBAR32(0x0c04) = 0x2e680008;
- DMIBAR32(0x0904); // !!! = 0x7a1842ec
- DMIBAR32(0x0904) = 0x3a1842ec;
- DMIBAR32(0x0924); // !!! = 0x7a1842ec
- DMIBAR32(0x0924) = 0x3a1842ec;
- DMIBAR32(0x0910); // !!! = 0x00006300
- DMIBAR32(0x0910) = 0x00004300;
- DMIBAR32(0x0930); // !!! = 0x00006300
- DMIBAR32(0x0930) = 0x00004300;
- DMIBAR32(0x0a00); // !!! = 0x03042010
- DMIBAR32(0x0a00) = 0x03042018;
- DMIBAR32(0x0a10); // !!! = 0x03042010
- DMIBAR32(0x0a10) = 0x03042018;
- DMIBAR32(0x0a20); // !!! = 0x03042010
- DMIBAR32(0x0a20) = 0x03042018;
- DMIBAR32(0x0a30); // !!! = 0x03042010
- DMIBAR32(0x0a30) = 0x03042018;
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0904 + (i << 5)); // !!! = 0x7a1842ec
+ DMIBAR32(0x0904 + (i << 5)) = 0x3a1842ec;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0910 + (i << 5)); // !!! = 0x00006300
+ DMIBAR32(0x0910 + (i << 5)) = 0x00004300;
+ }
+
+ for (i = 0; i < 4; i++) {
+ DMIBAR32(0x0a00 + (i << 4)); // !!! = 0x03042010
+ DMIBAR32(0x0a00 + (i << 4)) = 0x03042018;
+ }
+
DMIBAR32(0x0c00); // !!! = 0x29700c08
DMIBAR32(0x0c00) = 0x29700c08;
- DMIBAR32(0x0a04); // !!! = 0x0c0708f0
- DMIBAR32(0x0a04) = 0x0c0718f0;
- DMIBAR32(0x0a14); // !!! = 0x0c0708f0
- DMIBAR32(0x0a14) = 0x0c0718f0;
- DMIBAR32(0x0a24); // !!! = 0x0c0708f0
- DMIBAR32(0x0a24) = 0x0c0718f0;
- DMIBAR32(0x0a34); // !!! = 0x0c0708f0
- DMIBAR32(0x0a34) = 0x0c0718f0;
- DMIBAR32(0x0900); // !!! = 0x50000000
- DMIBAR32(0x0900) = 0x50000000;
- DMIBAR32(0x0920); // !!! = 0x50000000
- DMIBAR32(0x0920) = 0x50000000;
- DMIBAR32(0x0908); // !!! = 0x51ffffff
- DMIBAR32(0x0908) = 0x51ffffff;
- DMIBAR32(0x0928); // !!! = 0x51ffffff
- DMIBAR32(0x0928) = 0x51ffffff;
- DMIBAR32(0x0a00); // !!! = 0x03042018
- DMIBAR32(0x0a00) = 0x03042018;
- DMIBAR32(0x0a10); // !!! = 0x03042018
- DMIBAR32(0x0a10) = 0x03042018;
- DMIBAR32(0x0a20); // !!! = 0x03042018
- DMIBAR32(0x0a20) = 0x03042018;
- DMIBAR32(0x0a30); // !!! = 0x03042018
- DMIBAR32(0x0a30) = 0x03042018;
- DMIBAR32(0x0700); // !!! = 0x46139008
- DMIBAR32(0x0700) = 0x46139008;
- DMIBAR32(0x0720); // !!! = 0x46139008
- DMIBAR32(0x0720) = 0x46139008;
- DMIBAR32(0x0904); // !!! = 0x3a1842ec
- DMIBAR32(0x0904) = 0x3a1846ec;
- DMIBAR32(0x0924); // !!! = 0x3a1842ec
- DMIBAR32(0x0924) = 0x3a1846ec;
- DMIBAR32(0x0a00); // !!! = 0x03042018
- DMIBAR32(0x0a00) = 0x03042018;
- DMIBAR32(0x0a10); // !!! = 0x03042018
- DMIBAR32(0x0a10) = 0x03042018;
- DMIBAR32(0x0a20); // !!! = 0x03042018
- DMIBAR32(0x0a20) = 0x03042018;
- DMIBAR32(0x0a30); // !!! = 0x03042018
- DMIBAR32(0x0a30) = 0x03042018;
- DMIBAR32(0x0908); // !!! = 0x51ffffff
- DMIBAR32(0x0908) = 0x51ffffff;
- DMIBAR32(0x0928); // !!! = 0x51ffffff
- DMIBAR32(0x0928) = 0x51ffffff;
+
+ for (i = 0; i < 4; i++) {
+ DMIBAR32(0x0a04 + (i << 4)); // !!! = 0x0c0708f0
+ DMIBAR32(0x0a04 + (i << 4)) = 0x0c0718f0;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0900 + (i << 5)); // !!! = 0x50000000
+ DMIBAR32(0x0900 + (i << 5)) = 0x50000000;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0908 + (i << 5)); // !!! = 0x51ffffff
+ DMIBAR32(0x0908 + (i << 5)) = 0x51ffffff;
+ }
+
+ for (i = 0; i < 4; i++) {
+ DMIBAR32(0x0a00 + (i << 4)); // !!! = 0x03042018
+ DMIBAR32(0x0a00 + (i << 4)) = 0x03042018;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x46139008
+ DMIBAR32(0x0700 + (i << 5)) = 0x46139008;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0904 + (i << 5)); // !!! = 0x3a1842ec
+ DMIBAR32(0x0904 + (i << 5)) = 0x3a1846ec;
+ }
+
+ for (i = 0; i < 4; i++) {
+ DMIBAR32(0x0a00 + (i << 4)); // !!! = 0x03042018
+ DMIBAR32(0x0a00 + (i << 4)) = 0x03042018;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0908 + (i << 5)); // !!! = 0x51ffffff
+ DMIBAR32(0x0908 + (i << 5)) = 0x51ffffff;
+ }
+
DMIBAR32(0x0c00); // !!! = 0x29700c08
DMIBAR32(0x0c00) = 0x29700c08;
+
DMIBAR32(0x0c0c); // !!! = 0x16063400
DMIBAR32(0x0c0c) = 0x00063400;
- DMIBAR32(0x0700); // !!! = 0x46139008
- DMIBAR32(0x0700) = 0x46339008;
- DMIBAR32(0x0720); // !!! = 0x46139008
- DMIBAR32(0x0720) = 0x46339008;
- DMIBAR32(0x0700); // !!! = 0x46339008
- DMIBAR32(0x0700) = 0x45339008;
- DMIBAR32(0x0720); // !!! = 0x46339008
- DMIBAR32(0x0720) = 0x45339008;
- DMIBAR32(0x0700); // !!! = 0x45339008
- DMIBAR32(0x0700) = 0x453b9008;
- DMIBAR32(0x0720); // !!! = 0x45339008
- DMIBAR32(0x0720) = 0x453b9008;
- DMIBAR32(0x0700); // !!! = 0x453b9008
- DMIBAR32(0x0700) = 0x45bb9008;
- DMIBAR32(0x0720); // !!! = 0x453b9008
- DMIBAR32(0x0720) = 0x45bb9008;
- DMIBAR32(0x0700); // !!! = 0x45bb9008
- DMIBAR32(0x0700) = 0x45fb9008;
- DMIBAR32(0x0720); // !!! = 0x45bb9008
- DMIBAR32(0x0720) = 0x45fb9008;
- DMIBAR32(0x0914); // !!! = 0x9021a080
- DMIBAR32(0x0914) = 0x9021a280;
- DMIBAR32(0x0934); // !!! = 0x9021a080
- DMIBAR32(0x0934) = 0x9021a280;
- DMIBAR32(0x0914); // !!! = 0x9021a280
- DMIBAR32(0x0914) = 0x9821a280;
- DMIBAR32(0x0934); // !!! = 0x9021a280
- DMIBAR32(0x0934) = 0x9821a280;
- DMIBAR32(0x0a00); // !!! = 0x03042018
- DMIBAR32(0x0a00) = 0x03242018;
- DMIBAR32(0x0a10); // !!! = 0x03042018
- DMIBAR32(0x0a10) = 0x03242018;
- DMIBAR32(0x0a20); // !!! = 0x03042018
- DMIBAR32(0x0a20) = 0x03242018;
- DMIBAR32(0x0a30); // !!! = 0x03042018
- DMIBAR32(0x0a30) = 0x03242018;
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x46139008
+ DMIBAR32(0x0700 + (i << 5)) = 0x46339008;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x46339008
+ DMIBAR32(0x0700 + (i << 5)) = 0x45339008;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x45339008
+ DMIBAR32(0x0700 + (i << 5)) = 0x453b9008;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x453b9008
+ DMIBAR32(0x0700 + (i << 5)) = 0x45bb9008;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0700 + (i << 5)); // !!! = 0x45bb9008
+ DMIBAR32(0x0700 + (i << 5)) = 0x45fb9008;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0914 + (i << 5)); // !!! = 0x9021a080
+ DMIBAR32(0x0914 + (i << 5)) = 0x9021a280;
+ }
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0914 + (i << 5)); // !!! = 0x9021a080
+ DMIBAR32(0x0914 + (i << 5)) = 0x9821a280;
+ }
+
+ for (i = 0; i < 4; i++) {
+ DMIBAR32(0x0a00 + (i << 4)); // !!! = 0x03042018
+ DMIBAR32(0x0a00 + (i << 4)) = 0x03242018;
+ }
+
DMIBAR32(0x0258); // !!! = 0x40000600
DMIBAR32(0x0258) = 0x60000600;
- DMIBAR32(0x0904); // !!! = 0x3a1846ec
- DMIBAR32(0x0904) = 0x2a1846ec;
- DMIBAR32(0x0914); // !!! = 0x9821a280
- DMIBAR32(0x0914) = 0x98200280;
- DMIBAR32(0x0924); // !!! = 0x3a1846ec
- DMIBAR32(0x0924) = 0x2a1846ec;
- DMIBAR32(0x0934); // !!! = 0x9821a280
- DMIBAR32(0x0934) = 0x98200280;
+
+ for (i = 0; i < 2; i++) {
+ DMIBAR32(0x0904 + (i << 5)); // !!! = 0x3a1846ec
+ DMIBAR32(0x0904 + (i << 5)) = 0x2a1846ec;
+ DMIBAR32(0x0914 + (i << 5)); // !!! = 0x9821a280
+ DMIBAR32(0x0914 + (i << 5)) = 0x98200280;
+ }
+
DMIBAR32(0x022c); // !!! = 0x00c26460
DMIBAR32(0x022c) = 0x00c2403c;
early_pch_init_native_dmi_pre();
- /* Write once settings. */
+ /* Write once settings */
DMIBAR32(DMILCAP) = (DMIBAR32(DMILCAP) & ~0x3f00f) |
- (2 << 0) | // 5GT/s
- (2 << 12) | // L0s 128 ns to less than 256 ns
- (2 << 15); // L1 2 us to less than 4 us
+ (2 << 0) | // 5GT/s
+ (2 << 12) | // L0s 128 ns to less than 256 ns
+ (2 << 15); // L1 2 us to less than 4 us
- DMIBAR8(DMILCTL) |= 0x20; // Retrain link
+ DMIBAR8(DMILCTL) |= (1 << 5); // Retrain link
while (DMIBAR16(DMILSTS) & TXTRN)
;
- DMIBAR8(DMILCTL) |= 0x20; // Retrain link
+ DMIBAR8(DMILCTL) |= (1 << 5); // Retrain link
while (DMIBAR16(DMILSTS) & TXTRN)
;
- const u8 w = (DMIBAR16(DMILSTS) >> 4) & 0x1f;
- const u16 t = (DMIBAR16(DMILSTS) & 0xf) * 2500;
+ const u8 w = (DMIBAR16(DMILSTS) >> 4) & 0x1f;
+ const u16 t = (DMIBAR16(DMILSTS) & 0x0f) * 2500;
printk(BIOS_DEBUG, "DMI: Running at X%x @ %dMT/s\n", w, t);
/*
* Virtual Channel resources must match settings in RCBA!
*
- * Channel Vp and Vm are documented in
- * "Desktop 4th Generation Intel Core Processor Family, Desktop Intel
- * Pentium Processor Family, and Desktop Intel Celeron Processor Family
- * Vol. 2"
+ * Channel Vp and Vm are documented in:
+ * "Desktop 4th Generation Intel Core Processor Family, Desktop Intel Pentium
+ * Processor Family, and Desktop Intel Celeron Processor Family Vol. 2"
*/
/* Channel 0: Enable, Set ID to 0, map TC0 and TC3 and TC4 to VC0. */