/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include static void dmi_recipe(void) { const u32 cpuid = cpu_get_cpuid(); int i; /* The DMI recipe is only needed on Ivy Bridge */ if (!IS_IVY_CPU(cpuid)) return; for (i = 0; i < 2; i++) { dmibar_setbits32(0x0914 + (i << 5), 1 << 31); } for (i = 0; i < 4; i++) { dmibar_clrbits32(0x0a00 + (i << 4), 3 << 26); dmibar_setbits32(0x0a04 + (i << 4), 1 << 11); } dmibar_clrsetbits32(0x0c30, 0xf << 28, 1 << 30); for (i = 0; i < 2; i++) { dmibar_clrbits32(0x0904 + (i << 5), 7 << 22); dmibar_clrbits32(0x090c + (i << 5), 7 << 17); } for (i = 0; i < 2; i++) { dmibar_clrbits32(0x090c + (i << 5), 0xf << 21); } for (i = 0; i < 2; i++) { dmibar_read32(0x0904 + (i << 5)); // !!! = 0x7a1842ec dmibar_write32(0x0904 + (i << 5), 0x7a1842ec); dmibar_read32(0x090c + (i << 5)); // !!! = 0x00000208 dmibar_write32(0x090c + (i << 5), 0x00000128); } for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x46139008 dmibar_write32(0x0700 + (i << 5), 0x46139008); } dmibar_read32(0x0c04); // !!! = 0x2e680008 dmibar_write32(0x0c04, 0x2e680008); for (i = 0; i < 2; i++) { dmibar_read32(0x0904 + (i << 5)); // !!! = 0x7a1842ec dmibar_write32(0x0904 + (i << 5), 0x3a1842ec); } for (i = 0; i < 2; i++) { dmibar_read32(0x0910 + (i << 5)); // !!! = 0x00006300 dmibar_write32(0x0910 + (i << 5), 0x00004300); } for (i = 0; i < 4; i++) { dmibar_read32(0x0a00 + (i << 4)); // !!! = 0x03042010 dmibar_write32(0x0a00 + (i << 4), 0x03042018); } dmibar_read32(0x0c00); // !!! = 0x29700c08 dmibar_write32(0x0c00, 0x29700c08); for (i = 0; i < 4; i++) { dmibar_read32(0x0a04 + (i << 4)); // !!! = 0x0c0708f0 dmibar_write32(0x0a04 + (i << 4), 0x0c0718f0); } for (i = 0; i < 2; i++) { dmibar_read32(0x0900 + (i << 5)); // !!! = 0x50000000 dmibar_write32(0x0900 + (i << 5), 0x50000000); } for (i = 0; i < 2; i++) { dmibar_read32(0x0908 + (i << 5)); // !!! = 0x51ffffff dmibar_write32(0x0908 + (i << 5), 0x51ffffff); } for (i = 0; i < 4; i++) { dmibar_read32(0x0a00 + (i << 4)); // !!! = 0x03042018 dmibar_write32(0x0a00 + (i << 4), 0x03042018); } for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x46139008 dmibar_write32(0x0700 + (i << 5), 0x46139008); } for (i = 0; i < 2; i++) { dmibar_read32(0x0904 + (i << 5)); // !!! = 0x3a1842ec dmibar_write32(0x0904 + (i << 5), 0x3a1846ec); } for (i = 0; i < 4; i++) { dmibar_read32(0x0a00 + (i << 4)); // !!! = 0x03042018 dmibar_write32(0x0a00 + (i << 4), 0x03042018); } for (i = 0; i < 2; i++) { dmibar_read32(0x0908 + (i << 5)); // !!! = 0x51ffffff dmibar_write32(0x0908 + (i << 5), 0x51ffffff); } dmibar_read32(0x0c00); // !!! = 0x29700c08 dmibar_write32(0x0c00, 0x29700c08); dmibar_read32(0x0c0c); // !!! = 0x16063400 dmibar_write32(0x0c0c, 0x00063400); for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x46139008 dmibar_write32(0x0700 + (i << 5), 0x46339008); } for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x46339008 dmibar_write32(0x0700 + (i << 5), 0x45339008); } for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x45339008 dmibar_write32(0x0700 + (i << 5), 0x453b9008); } for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x453b9008 dmibar_write32(0x0700 + (i << 5), 0x45bb9008); } for (i = 0; i < 2; i++) { dmibar_read32(0x0700 + (i << 5)); // !!! = 0x45bb9008 dmibar_write32(0x0700 + (i << 5), 0x45fb9008); } for (i = 0; i < 2; i++) { dmibar_read32(0x0914 + (i << 5)); // !!! = 0x9021a080 dmibar_write32(0x0914 + (i << 5), 0x9021a280); } for (i = 0; i < 2; i++) { dmibar_read32(0x0914 + (i << 5)); // !!! = 0x9021a080 dmibar_write32(0x0914 + (i << 5), 0x9821a280); } for (i = 0; i < 4; i++) { dmibar_read32(0x0a00 + (i << 4)); // !!! = 0x03042018 dmibar_write32(0x0a00 + (i << 4), 0x03242018); } dmibar_read32(0x0258); // !!! = 0x40000600 dmibar_write32(0x0258, 0x60000600); for (i = 0; i < 2; i++) { dmibar_read32(0x0904 + (i << 5)); // !!! = 0x3a1846ec dmibar_write32(0x0904 + (i << 5), 0x2a1846ec); dmibar_read32(0x0914 + (i << 5)); // !!! = 0x9821a280 dmibar_write32(0x0914 + (i << 5), 0x98200280); } dmibar_read32(DMIL0SLAT); // !!! = 0x00c26460 dmibar_write32(DMIL0SLAT, 0x00c2403c); } void early_init_dmi(void) { dmi_recipe(); early_pch_init_native_dmi_pre(); /* Write once settings */ dmibar_clrsetbits32(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 dmibar_setbits8(DMILCTL, 1 << 5); // Retrain link while (dmibar_read16(DMILSTS) & TXTRN) ; dmibar_setbits8(DMILCTL, 1 << 5); // Retrain link while (dmibar_read16(DMILSTS) & TXTRN) ; const u8 w = (dmibar_read16(DMILSTS) >> 4) & 0x1f; const u16 t = (dmibar_read16(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 0: Enable, Set ID to 0, map TC0 and TC3 and TC4 to VC0. */ dmibar_write32(DMIVC0RCTL, 1 << 31 | 0 << 24 | 0x0c << 1 | 1); /* Channel 1: Enable, Set ID to 1, map TC1 and TC5 to VC1. */ dmibar_write32(DMIVC1RCTL, 1 << 31 | 1 << 24 | 0x11 << 1); /* Channel p: Enable, Set ID to 2, map TC2 and TC6 to VCp */ dmibar_write32(DMIVCPRCTL, 1 << 31 | 2 << 24 | 0x22 << 1); /* Channel m: Enable, Set ID to 0, map TC7 to VCm */ dmibar_write32(DMIVCMRCTL, 1 << 31 | 7 << 24 | 0x40 << 1); /* Set Extended VC Count (EVCC) to 1 as Channel 1 is active. */ dmibar_setbits8(DMIPVCCAP1, 1 << 0); early_pch_init_native_dmi_post(); /* * BIOS Requirement: Check if DMI VC Negotiation was successful. * Wait for virtual channels negotiation pending. */ while (dmibar_read16(DMIVC0RSTS) & VC0NP) ; while (dmibar_read16(DMIVC1RSTS) & VC1NP) ; while (dmibar_read16(DMIVCPRSTS) & VCPNP) ; while (dmibar_read16(DMIVCMRSTS) & VCMNP) ; }