Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Ben Skeggs | 3681 | 99.73% | 92 | 96.84% |
Stephen Chandler Paul | 8 | 0.22% | 2 | 2.11% |
Francisco Jerez | 2 | 0.05% | 1 | 1.05% |
Total | 3691 | 95 |
/* * Copyright 2014 Red Hat Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Authors: Ben Skeggs */ #include "dp.h" #include "conn.h" #include "head.h" #include "ior.h" #include <drm/display/drm_dp.h> #include <subdev/bios.h> #include <subdev/bios/init.h> #include <subdev/gpio.h> #include <subdev/i2c.h> #include <nvif/event.h> /* IED scripts are no longer used by UEFI/RM from Ampere, but have been updated for * the x86 option ROM. However, the relevant VBIOS table versions weren't modified, * so we're unable to detect this in a nice way. */ #define AMPERE_IED_HACK(disp) ((disp)->engine.subdev.device->card_type >= GA100) static int nvkm_dp_mst_id_put(struct nvkm_outp *outp, u32 id) { return 0; } static int nvkm_dp_mst_id_get(struct nvkm_outp *outp, u32 *pid) { *pid = BIT(outp->index); return 0; } static int nvkm_dp_aux_xfer(struct nvkm_outp *outp, u8 type, u32 addr, u8 *data, u8 *size) { int ret = nvkm_i2c_aux_acquire(outp->dp.aux); if (ret) return ret; ret = nvkm_i2c_aux_xfer(outp->dp.aux, false, type, addr, data, size); nvkm_i2c_aux_release(outp->dp.aux); return ret; } static int nvkm_dp_aux_pwr(struct nvkm_outp *outp, bool pu) { outp->dp.enabled = pu; nvkm_dp_enable(outp, outp->dp.enabled); return 0; } struct lt_state { struct nvkm_outp *outp; int repeaters; int repeater; u8 stat[6]; u8 conf[4]; bool pc2; u8 pc2stat; u8 pc2conf[2]; }; static int nvkm_dp_train_sense(struct lt_state *lt, bool pc, u32 delay) { struct nvkm_outp *outp = lt->outp; u32 addr; int ret; usleep_range(delay, delay * 2); if (lt->repeater) addr = DPCD_LTTPR_LANE0_1_STATUS(lt->repeater); else addr = DPCD_LS02; ret = nvkm_rdaux(outp->dp.aux, addr, <->stat[0], 3); if (ret) return ret; if (lt->repeater) addr = DPCD_LTTPR_LANE0_1_ADJUST(lt->repeater); else addr = DPCD_LS06; ret = nvkm_rdaux(outp->dp.aux, addr, <->stat[4], 2); if (ret) return ret; if (pc) { ret = nvkm_rdaux(outp->dp.aux, DPCD_LS0C, <->pc2stat, 1); if (ret) lt->pc2stat = 0x00; OUTP_TRACE(outp, "status %6ph pc2 %02x", lt->stat, lt->pc2stat); } else { OUTP_TRACE(outp, "status %6ph", lt->stat); } return 0; } static int nvkm_dp_train_drive(struct lt_state *lt, bool pc) { struct nvkm_outp *outp = lt->outp; struct nvkm_ior *ior = outp->ior; struct nvkm_bios *bios = ior->disp->engine.subdev.device->bios; struct nvbios_dpout info; struct nvbios_dpcfg ocfg; u8 ver, hdr, cnt, len; u32 addr; u32 data; int ret, i; for (i = 0; i < ior->dp.nr; i++) { u8 lane = (lt->stat[4 + (i >> 1)] >> ((i & 1) * 4)) & 0xf; u8 lpc2 = (lt->pc2stat >> (i * 2)) & 0x3; u8 lpre = (lane & 0x0c) >> 2; u8 lvsw = (lane & 0x03) >> 0; u8 hivs = 3 - lpre; u8 hipe = 3; u8 hipc = 3; if (lpc2 >= hipc) lpc2 = hipc | DPCD_LC0F_LANE0_MAX_POST_CURSOR2_REACHED; if (lpre >= hipe) { lpre = hipe | DPCD_LC03_MAX_SWING_REACHED; /* yes. */ lvsw = hivs = 3 - (lpre & 3); } else if (lvsw >= hivs) { lvsw = hivs | DPCD_LC03_MAX_SWING_REACHED; } lt->conf[i] = (lpre << 3) | lvsw; lt->pc2conf[i >> 1] |= lpc2 << ((i & 1) * 4); OUTP_TRACE(outp, "config lane %d %02x %02x", i, lt->conf[i], lpc2); if (lt->repeater != lt->repeaters) continue; data = nvbios_dpout_match(bios, outp->info.hasht, outp->info.hashm, &ver, &hdr, &cnt, &len, &info); if (!data) continue; data = nvbios_dpcfg_match(bios, data, lpc2 & 3, lvsw & 3, lpre & 3, &ver, &hdr, &cnt, &len, &ocfg); if (!data) continue; ior->func->dp->drive(ior, i, ocfg.pc, ocfg.dc, ocfg.pe, ocfg.tx_pu); } if (lt->repeater) addr = DPCD_LTTPR_LANE0_SET(lt->repeater); else addr = DPCD_LC03(0); ret = nvkm_wraux(outp->dp.aux, addr, lt->conf, 4); if (ret) return ret; if (pc) { ret = nvkm_wraux(outp->dp.aux, DPCD_LC0F, lt->pc2conf, 2); if (ret) return ret; } return 0; } static void nvkm_dp_train_pattern(struct lt_state *lt, u8 pattern) { struct nvkm_outp *outp = lt->outp; u32 addr; u8 sink_tp; OUTP_TRACE(outp, "training pattern %d", pattern); outp->ior->func->dp->pattern(outp->ior, pattern); if (lt->repeater) addr = DPCD_LTTPR_PATTERN_SET(lt->repeater); else addr = DPCD_LC02; nvkm_rdaux(outp->dp.aux, addr, &sink_tp, 1); sink_tp &= ~DPCD_LC02_TRAINING_PATTERN_SET; sink_tp |= (pattern != 4) ? pattern : 7; if (pattern != 0) sink_tp |= DPCD_LC02_SCRAMBLING_DISABLE; else sink_tp &= ~DPCD_LC02_SCRAMBLING_DISABLE; nvkm_wraux(outp->dp.aux, addr, &sink_tp, 1); } static int nvkm_dp_train_eq(struct lt_state *lt) { struct nvkm_i2c_aux *aux = lt->outp->dp.aux; bool eq_done = false, cr_done = true; int tries = 0, usec = 0, i; u8 data; if (lt->repeater) { if (!nvkm_rdaux(aux, DPCD_LTTPR_AUX_RD_INTERVAL(lt->repeater), &data, sizeof(data))) usec = (data & DPCD_RC0E_AUX_RD_INTERVAL) * 4000; nvkm_dp_train_pattern(lt, 4); } else { if (lt->outp->dp.dpcd[DPCD_RC00_DPCD_REV] >= 0x14 && lt->outp->dp.dpcd[DPCD_RC03] & DPCD_RC03_TPS4_SUPPORTED) nvkm_dp_train_pattern(lt, 4); else if (lt->outp->dp.dpcd[DPCD_RC00_DPCD_REV] >= 0x12 && lt->outp->dp.dpcd[DPCD_RC02] & DPCD_RC02_TPS3_SUPPORTED) nvkm_dp_train_pattern(lt, 3); else nvkm_dp_train_pattern(lt, 2); usec = (lt->outp->dp.dpcd[DPCD_RC0E] & DPCD_RC0E_AUX_RD_INTERVAL) * 4000; } do { if ((tries && nvkm_dp_train_drive(lt, lt->pc2)) || nvkm_dp_train_sense(lt, lt->pc2, usec ? usec : 400)) break; eq_done = !!(lt->stat[2] & DPCD_LS04_INTERLANE_ALIGN_DONE); for (i = 0; i < lt->outp->ior->dp.nr && eq_done; i++) { u8 lane = (lt->stat[i >> 1] >> ((i & 1) * 4)) & 0xf; if (!(lane & DPCD_LS02_LANE0_CR_DONE)) cr_done = false; if (!(lane & DPCD_LS02_LANE0_CHANNEL_EQ_DONE) || !(lane & DPCD_LS02_LANE0_SYMBOL_LOCKED)) eq_done = false; } } while (!eq_done && cr_done && ++tries <= 5); return eq_done ? 0 : -1; } static int nvkm_dp_train_cr(struct lt_state *lt) { bool cr_done = false, abort = false; int voltage = lt->conf[0] & DPCD_LC03_VOLTAGE_SWING_SET; int tries = 0, usec = 0, i; nvkm_dp_train_pattern(lt, 1); if (lt->outp->dp.dpcd[DPCD_RC00_DPCD_REV] < 0x14 && !lt->repeater) usec = (lt->outp->dp.dpcd[DPCD_RC0E] & DPCD_RC0E_AUX_RD_INTERVAL) * 4000; do { if (nvkm_dp_train_drive(lt, false) || nvkm_dp_train_sense(lt, false, usec ? usec : 100)) break; cr_done = true; for (i = 0; i < lt->outp->ior->dp.nr; i++) { u8 lane = (lt->stat[i >> 1] >> ((i & 1) * 4)) & 0xf; if (!(lane & DPCD_LS02_LANE0_CR_DONE)) { cr_done = false; if (lt->conf[i] & DPCD_LC03_MAX_SWING_REACHED) abort = true; break; } } if ((lt->conf[0] & DPCD_LC03_VOLTAGE_SWING_SET) != voltage) { voltage = lt->conf[0] & DPCD_LC03_VOLTAGE_SWING_SET; tries = 0; } } while (!cr_done && !abort && ++tries < 5); return cr_done ? 0 : -1; } static int nvkm_dp_train_link(struct nvkm_outp *outp, int rate) { struct nvkm_ior *ior = outp->ior; struct lt_state lt = { .outp = outp, .pc2 = outp->dp.dpcd[DPCD_RC02] & DPCD_RC02_TPS3_SUPPORTED, .repeaters = outp->dp.lttprs, }; u8 sink[2]; int ret; OUTP_DBG(outp, "training %dx%02x", ior->dp.nr, ior->dp.bw); /* Set desired link configuration on the sink. */ sink[0] = (outp->dp.rate[rate].dpcd < 0) ? ior->dp.bw : 0; sink[1] = ior->dp.nr; if (ior->dp.ef) sink[1] |= DPCD_LC01_ENHANCED_FRAME_EN; if (outp->dp.lt.post_adj) sink[1] |= 0x20; ret = nvkm_wraux(outp->dp.aux, DPCD_LC00_LINK_BW_SET, sink, 2); if (ret) return ret; if (outp->dp.rate[rate].dpcd >= 0) { ret = nvkm_rdaux(outp->dp.aux, DPCD_LC15_LINK_RATE_SET, &sink[0], sizeof(sink[0])); if (ret) return ret; sink[0] &= ~DPCD_LC15_LINK_RATE_SET_MASK; sink[0] |= outp->dp.rate[rate].dpcd; ret = nvkm_wraux(outp->dp.aux, DPCD_LC15_LINK_RATE_SET, &sink[0], sizeof(sink[0])); if (ret) return ret; } /* Attempt to train the link in this configuration. */ for (lt.repeater = lt.repeaters; lt.repeater >= 0; lt.repeater--) { if (lt.repeater) OUTP_DBG(outp, "training LTTPR%d", lt.repeater); else OUTP_DBG(outp, "training sink"); memset(lt.stat, 0x00, sizeof(lt.stat)); ret = nvkm_dp_train_cr(<); if (ret == 0) ret = nvkm_dp_train_eq(<); nvkm_dp_train_pattern(<, 0); } return ret; } static int nvkm_dp_train_links(struct nvkm_outp *outp, int rate) { struct nvkm_ior *ior = outp->ior; struct nvkm_disp *disp = outp->disp; struct nvkm_subdev *subdev = &disp->engine.subdev; struct nvkm_bios *bios = subdev->device->bios; u32 lnkcmp; int ret; OUTP_DBG(outp, "programming link for %dx%02x", ior->dp.nr, ior->dp.bw); /* Intersect misc. capabilities of the OR and sink. */ if (disp->engine.subdev.device->chipset < 0x110) outp->dp.dpcd[DPCD_RC03] &= ~DPCD_RC03_TPS4_SUPPORTED; if (disp->engine.subdev.device->chipset < 0xd0) outp->dp.dpcd[DPCD_RC02] &= ~DPCD_RC02_TPS3_SUPPORTED; if (AMPERE_IED_HACK(disp) && (lnkcmp = outp->dp.info.script[0])) { /* Execute BeforeLinkTraining script from DP Info table. */ while (ior->dp.bw < nvbios_rd08(bios, lnkcmp)) lnkcmp += 3; lnkcmp = nvbios_rd16(bios, lnkcmp + 1); nvbios_init(&outp->disp->engine.subdev, lnkcmp, init.outp = &outp->info; init.or = ior->id; init.link = ior->asy.link; ); } /* Set desired link configuration on the source. */ if ((lnkcmp = outp->dp.info.lnkcmp)) { if (outp->dp.version < 0x30) { while ((ior->dp.bw * 2700) < nvbios_rd16(bios, lnkcmp)) lnkcmp += 4; lnkcmp = nvbios_rd16(bios, lnkcmp + 2); } else { while (ior->dp.bw < nvbios_rd08(bios, lnkcmp)) lnkcmp += 3; lnkcmp = nvbios_rd16(bios, lnkcmp + 1); } nvbios_init(subdev, lnkcmp, init.outp = &outp->info; init.or = ior->id; init.link = ior->asy.link; ); } ret = ior->func->dp->links(ior, outp->dp.aux); if (ret) { if (ret < 0) { OUTP_ERR(outp, "train failed with %d", ret); return ret; } return 0; } ior->func->dp->power(ior, ior->dp.nr); /* Attempt to train the link in this configuration. */ return nvkm_dp_train_link(outp, rate); } static void nvkm_dp_train_fini(struct nvkm_outp *outp) { /* Execute AfterLinkTraining script from DP Info table. */ nvbios_init(&outp->disp->engine.subdev, outp->dp.info.script[1], init.outp = &outp->info; init.or = outp->ior->id; init.link = outp->ior->asy.link; ); } static void nvkm_dp_train_init(struct nvkm_outp *outp) { /* Execute EnableSpread/DisableSpread script from DP Info table. */ if (outp->dp.dpcd[DPCD_RC03] & DPCD_RC03_MAX_DOWNSPREAD) { nvbios_init(&outp->disp->engine.subdev, outp->dp.info.script[2], init.outp = &outp->info; init.or = outp->ior->id; init.link = outp->ior->asy.link; ); } else { nvbios_init(&outp->disp->engine.subdev, outp->dp.info.script[3], init.outp = &outp->info; init.or = outp->ior->id; init.link = outp->ior->asy.link; ); } if (!AMPERE_IED_HACK(outp->disp)) { /* Execute BeforeLinkTraining script from DP Info table. */ nvbios_init(&outp->disp->engine.subdev, outp->dp.info.script[0], init.outp = &outp->info; init.or = outp->ior->id; init.link = outp->ior->asy.link; ); } } static int nvkm_dp_drive(struct nvkm_outp *outp, u8 lanes, u8 pe[4], u8 vs[4]) { struct lt_state lt = { .outp = outp, .stat[4] = (pe[0] << 2) | (vs[0] << 0) | (pe[1] << 6) | (vs[1] << 4), .stat[5] = (pe[2] << 2) | (vs[2] << 0) | (pe[3] << 6) | (vs[3] << 4), }; return nvkm_dp_train_drive(<, false); } static int nvkm_dp_train(struct nvkm_outp *outp, bool retrain) { struct nvkm_ior *ior = outp->ior; int ret, rate; for (rate = 0; rate < outp->dp.rates; rate++) { if (outp->dp.rate[rate].rate == (retrain ? ior->dp.bw : outp->dp.lt.bw) * 27000) break; } if (WARN_ON(rate == outp->dp.rates)) return -EINVAL; /* Retraining link? Skip source configuration, it can mess up the active modeset. */ if (retrain) { mutex_lock(&outp->dp.mutex); ret = nvkm_dp_train_link(outp, rate); mutex_unlock(&outp->dp.mutex); return ret; } mutex_lock(&outp->dp.mutex); OUTP_DBG(outp, "training"); ior->dp.mst = outp->dp.lt.mst; ior->dp.ef = outp->dp.dpcd[DPCD_RC02] & DPCD_RC02_ENHANCED_FRAME_CAP; ior->dp.bw = outp->dp.lt.bw; ior->dp.nr = outp->dp.lt.nr; nvkm_dp_train_init(outp); ret = nvkm_dp_train_links(outp, rate); nvkm_dp_train_fini(outp); if (ret < 0) OUTP_ERR(outp, "training failed"); else OUTP_DBG(outp, "training done"); mutex_unlock(&outp->dp.mutex); return ret; } void nvkm_dp_disable(struct nvkm_outp *outp, struct nvkm_ior *ior) { /* Execute DisableLT script from DP Info Table. */ nvbios_init(&ior->disp->engine.subdev, outp->dp.info.script[4], init.outp = &outp->info; init.or = ior->id; init.link = ior->arm.link; ); } static void nvkm_dp_release(struct nvkm_outp *outp) { outp->ior->dp.nr = 0; nvkm_dp_disable(outp, outp->ior); nvkm_outp_release(outp); } void nvkm_dp_enable(struct nvkm_outp *outp, bool auxpwr) { struct nvkm_gpio *gpio = outp->disp->engine.subdev.device->gpio; struct nvkm_i2c_aux *aux = outp->dp.aux; if (auxpwr && !outp->dp.aux_pwr) { /* eDP panels need powering on by us (if the VBIOS doesn't default it * to on) before doing any AUX channel transactions. LVDS panel power * is handled by the SOR itself, and not required for LVDS DDC. */ if (outp->conn->info.type == DCB_CONNECTOR_eDP) { int power = nvkm_gpio_get(gpio, 0, DCB_GPIO_PANEL_POWER, 0xff); if (power == 0) { nvkm_gpio_set(gpio, 0, DCB_GPIO_PANEL_POWER, 0xff, 1); outp->dp.aux_pwr_pu = true; } /* We delay here unconditionally, even if already powered, * because some laptop panels having a significant resume * delay before the panel begins responding. * * This is likely a bit of a hack, but no better idea for * handling this at the moment. */ msleep(300); } OUTP_DBG(outp, "aux power -> always"); nvkm_i2c_aux_monitor(aux, true); outp->dp.aux_pwr = true; } else if (!auxpwr && outp->dp.aux_pwr) { OUTP_DBG(outp, "aux power -> demand"); nvkm_i2c_aux_monitor(aux, false); outp->dp.aux_pwr = false; /* Restore eDP panel GPIO to its prior state if we changed it, as * it could potentially interfere with other outputs. */ if (outp->conn->info.type == DCB_CONNECTOR_eDP) { if (outp->dp.aux_pwr_pu) { nvkm_gpio_set(gpio, 0, DCB_GPIO_PANEL_POWER, 0xff, 0); outp->dp.aux_pwr_pu = false; } } } } static void nvkm_dp_fini(struct nvkm_outp *outp) { nvkm_dp_enable(outp, false); } static void nvkm_dp_init(struct nvkm_outp *outp) { nvkm_outp_init(outp); nvkm_dp_enable(outp, outp->dp.enabled); } static void * nvkm_dp_dtor(struct nvkm_outp *outp) { return outp; } static const struct nvkm_outp_func nvkm_dp_func = { .dtor = nvkm_dp_dtor, .init = nvkm_dp_init, .fini = nvkm_dp_fini, .detect = nvkm_outp_detect, .inherit = nvkm_outp_inherit, .acquire = nvkm_outp_acquire, .release = nvkm_dp_release, .bl.get = nvkm_outp_bl_get, .bl.set = nvkm_outp_bl_set, .dp.aux_pwr = nvkm_dp_aux_pwr, .dp.aux_xfer = nvkm_dp_aux_xfer, .dp.train = nvkm_dp_train, .dp.drive = nvkm_dp_drive, .dp.mst_id_get = nvkm_dp_mst_id_get, .dp.mst_id_put = nvkm_dp_mst_id_put, }; int nvkm_dp_new(struct nvkm_disp *disp, int index, struct dcb_output *dcbE, struct nvkm_outp **poutp) { struct nvkm_device *device = disp->engine.subdev.device; struct nvkm_bios *bios = device->bios; struct nvkm_i2c *i2c = device->i2c; struct nvkm_outp *outp; u8 ver, hdr, cnt, len; u32 data; int ret; ret = nvkm_outp_new_(&nvkm_dp_func, disp, index, dcbE, poutp); outp = *poutp; if (ret) return ret; if (dcbE->location == 0) outp->dp.aux = nvkm_i2c_aux_find(i2c, NVKM_I2C_AUX_CCB(dcbE->i2c_index)); else outp->dp.aux = nvkm_i2c_aux_find(i2c, NVKM_I2C_AUX_EXT(dcbE->extdev)); if (!outp->dp.aux) { OUTP_ERR(outp, "no aux"); return -EINVAL; } /* bios data is not optional */ data = nvbios_dpout_match(bios, outp->info.hasht, outp->info.hashm, &outp->dp.version, &hdr, &cnt, &len, &outp->dp.info); if (!data) { OUTP_ERR(outp, "no bios dp data"); return -EINVAL; } OUTP_DBG(outp, "bios dp %02x %02x %02x %02x", outp->dp.version, hdr, cnt, len); data = nvbios_dp_table(bios, &ver, &hdr, &cnt, &len); outp->dp.mst = data && ver >= 0x40 && (nvbios_rd08(bios, data + 0x08) & 0x04); mutex_init(&outp->dp.mutex); return 0; }
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