zircon/system/dev/display/intel-i915/hdmi-display.cpp - fuchsia - Git at Google

 // Copyright 2017 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <ddk/driver.h>
 #include <lib/edid/edid.h>

 #include "intel-i915.h"
 #include "hdmi-display.h"
 #include "macros.h"
 #include "pci-ids.h"
 #include "registers.h"
 #include "registers-ddi.h"
 #include "registers-dpll.h"
 #include "registers-pipe.h"
 #include "registers-transcoder.h"

 // I2c functions

 namespace {
 // Recommended DDI buffer translation programming values

 struct ddi_buf_trans_entry {
     uint32_t high_dword;
     uint32_t low_dword;
 };

 const ddi_buf_trans_entry hdmi_ddi_buf_trans_skl_uhs[11] {
     { 0x000000ac, 0x00000018 },
     { 0x0000009d, 0x00005012 },
     { 0x00000088, 0x00007011 },
     { 0x000000a1, 0x00000018 },
     { 0x00000098, 0x00000018 },
     { 0x00000088, 0x00004013 },
     { 0x000000cd, 0x80006012 },
     { 0x000000df, 0x00000018 },
     { 0x000000cd, 0x80003015 },
     { 0x000000c0, 0x80003015 },
     { 0x000000c0, 0x80000018 },
 };

 const ddi_buf_trans_entry hdmi_ddi_buf_trans_skl_y[11] {
     { 0x000000a1, 0x00000018 },
     { 0x000000df, 0x00005012 },
     { 0x000000cb, 0x80007011 },
     { 0x000000a4, 0x00000018 },
     { 0x0000009d, 0x00000018 },
     { 0x00000080, 0x00004013 },
     { 0x000000c0, 0x80006012 },
     { 0x0000008a, 0x00000018 },
     { 0x000000c0, 0x80003015 },
     { 0x000000c0, 0x80003015 },
     { 0x000000c0, 0x80000018 },
 };

 int ddi_to_pin(registers::Ddi ddi) {
     if (ddi == registers::DDI_B) {
         return registers::GMBus0::kDdiBPin;
     } else if (ddi == registers::DDI_C) {
         return registers::GMBus0::kDdiCPin;
     } else if (ddi == registers::DDI_D) {
         return registers::GMBus0::kDdiDPin;
     }
     return -1;
 }

 void write_gmbus3(ddk::MmioBuffer* mmio_space, const uint8_t* buf, uint32_t size, uint32_t idx) {
     int cur_byte = 0;
     uint32_t val = 0;
     while (idx < size && cur_byte < 4) {
         val |= buf[idx++] << (8 * cur_byte++);
     }
     registers::GMBus3::Get().FromValue(val).WriteTo(mmio_space);
 }

 void read_gmbus3(ddk::MmioBuffer* mmio_space, uint8_t* buf, uint32_t size, uint32_t idx) {
     int cur_byte = 0;
     uint32_t val = registers::GMBus3::Get().ReadFrom(mmio_space).reg_value();
     while (idx < size && cur_byte++ < 4) {
         buf[idx++] = val & 0xff;
         val >>= 8;
     }
 }

 static constexpr uint8_t kDdcSegmentAddress = 0x30;
 static constexpr uint8_t kDdcDataAddress = 0x50;
 static constexpr uint8_t kI2cClockUs = 10; // 100 kHz

 // For bit banging i2c over the gpio pins
 bool i2c_scl(ddk::MmioBuffer* mmio_space, registers::Ddi ddi, bool hi) {
     auto gpio = registers::GpioCtl::Get(ddi).FromValue(0);

     if (!hi) {
         gpio.set_clock_direction_val(1);
         gpio.set_clock_mask(1);
     }
     gpio.set_clock_direction_mask(1);

     gpio.WriteTo(mmio_space);
     gpio.ReadFrom(mmio_space); // Posting read

     // Handle the case where something on the bus is holding the clock
     // low. Timeout after 1ms.
     if (hi) {
         int count = 0;
         do {
             if (count != 0) {
                 zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs)));
             }
             gpio.ReadFrom(mmio_space);
         } while (count++ < 100 && hi != gpio.clock_in());
         if (hi != gpio.clock_in()) {
             return false;
         }
     }
     zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));
     return true;
 }

 // For bit banging i2c over the gpio pins
 void i2c_sda(ddk::MmioBuffer* mmio_space, registers::Ddi ddi, bool hi) {
     auto gpio = registers::GpioCtl::Get(ddi).FromValue(0);

     if (!hi) {
         gpio.set_data_direction_val(1);
         gpio.set_data_mask(1);
     }
     gpio.set_data_direction_mask(1);

     gpio.WriteTo(mmio_space);
     gpio.ReadFrom(mmio_space); // Posting read

     zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));
 }

 // For bit banging i2c over the gpio pins
 bool i2c_send_byte(ddk::MmioBuffer* mmio_space, registers::Ddi ddi, uint8_t byte) {
     // Set the bits from MSB to LSB
     for (int i = 7; i >= 0; i--) {
         i2c_sda(mmio_space, ddi, (byte >> i) & 0x1);

         i2c_scl(mmio_space, ddi, 1);

         // Leave the data line where it is for the rest of the cycle
         zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));

         i2c_scl(mmio_space, ddi, 0);
     }

     // Release the data line and check for an ack
     i2c_sda(mmio_space, ddi, 1);
     i2c_scl(mmio_space, ddi, 1);

     bool ack = !registers::GpioCtl::Get(ddi).ReadFrom(mmio_space).data_in();

     // Sleep for the rest of the cycle
     zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));

     i2c_scl(mmio_space, ddi, 0);

     return ack;
 }

 } // namespace

 namespace i915 {

 // Per the GMBUS Controller Programming Interface section of the Intel docs, GMBUS does not
 // directly support segment pointer addressing. Instead, the segment pointer needs to be
 // set by bit-banging the GPIO pins.
 bool GMBusI2c::SetDdcSegment(uint8_t segment_num) {
     // Reset the clock and data lines
     i2c_scl(mmio_space_, ddi_, 0);
     i2c_sda(mmio_space_, ddi_, 0);

     if (!i2c_scl(mmio_space_, ddi_, 1)) {
         return false;
     }
     i2c_sda(mmio_space_, ddi_, 1);
     // Wait for the rest of the cycle
     zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));

     // Send a start condition
     i2c_sda(mmio_space_, ddi_, 0);
     i2c_scl(mmio_space_, ddi_, 0);

     // Send the segment register index and the segment number
     uint8_t segment_write_command = kDdcSegmentAddress << 1;
     if (!i2c_send_byte(mmio_space_, ddi_, segment_write_command)
             || !i2c_send_byte(mmio_space_, ddi_, segment_num)) {
         return false;
     }

     // Set the data and clock lines high to prepare for the GMBus start
     i2c_sda(mmio_space_, ddi_, 1);
     return i2c_scl(mmio_space_, ddi_, 1);
 }

 zx_status_t GMBusI2c::I2cTransact(const i2c_impl_op_t* ops, size_t size) {
     // The GMBus register is a limited interface to the i2c bus - it doesn't support complex
     // transactions like setting the E-DDC segment. For now, providing a special-case interface
     // for reading the E-DDC is good enough.
     fbl::AutoLock lock(&lock_);
     zx_status_t fail_res = ZX_ERR_IO;
     bool gmbus_set = false;
     for (unsigned i = 0; i < size; i++) {
         const i2c_impl_op_t* op = ops + i;
         if (op->address == kDdcSegmentAddress && !op->is_read && op->data_size == 1) {
             registers::GMBus0::Get().FromValue(0).WriteTo(mmio_space_);
             gmbus_set = false;
             if (!SetDdcSegment(*static_cast<uint8_t*>(op->data_buffer))) {
                 goto fail;
             }
         } else if (op->address == kDdcDataAddress) {
             if (!gmbus_set) {
                 auto gmbus0 = registers::GMBus0::Get().FromValue(0);
                 gmbus0.set_pin_pair_select(ddi_to_pin(ddi_));
                 gmbus0.WriteTo(mmio_space_);

                 gmbus_set = true;
             }

             uint8_t* buf = static_cast<uint8_t*>(op->data_buffer);
             uint8_t len = static_cast<uint8_t>(op->data_size);
             if (op->is_read ? GMBusRead(kDdcDataAddress, buf, len)
                     : GMBusWrite(kDdcDataAddress, buf, len)) {
                 if (!WAIT_ON_MS(registers::GMBus2::Get().ReadFrom(mmio_space_).wait(), 10)) {
                     LOG_TRACE("Transition to wait phase timed out\n");
                     goto fail;
                 }
             } else {
                 goto fail;
             }
         } else {
             fail_res = ZX_ERR_NOT_SUPPORTED;
             goto fail;
         }

         if (op->stop) {
             if (!I2cFinish()) {
                 goto fail;
             }
             gmbus_set = false;
         }
     }

     return ZX_OK;
 fail:
     if (!I2cClearNack()) {
         LOG_TRACE("Failed to clear nack\n");
     }
     return fail_res;
 }

 bool GMBusI2c::GMBusWrite(uint8_t addr, const uint8_t* buf, uint8_t size) {
     unsigned idx = 0;
     write_gmbus3(mmio_space_, buf, size, idx);
     idx += 4;

     auto gmbus1 = registers::GMBus1::Get().FromValue(0);
     gmbus1.set_sw_ready(1);
     gmbus1.set_bus_cycle_wait(1);
     gmbus1.set_total_byte_count(size);
     gmbus1.set_slave_register_addr(addr);
     gmbus1.WriteTo(mmio_space_);

     while (idx < size) {
         if (!I2cWaitForHwReady()) {
             return false;
         }

         write_gmbus3(mmio_space_, buf, size, idx);
         idx += 4;
     }
     // One more wait to ensure we're ready when we leave the function
     return I2cWaitForHwReady();
 }

 bool GMBusI2c::GMBusRead(uint8_t addr, uint8_t* buf, uint8_t size) {
     auto gmbus1 = registers::GMBus1::Get().FromValue(0);
     gmbus1.set_sw_ready(1);
     gmbus1.set_bus_cycle_wait(1);
     gmbus1.set_total_byte_count(size);
     gmbus1.set_slave_register_addr(addr);
     gmbus1.set_read_op(1);
     gmbus1.WriteTo(mmio_space_);

     unsigned idx = 0;
     while (idx < size) {
         if (!I2cWaitForHwReady()) {
             return false;
         }

         read_gmbus3(mmio_space_, buf, size, idx);
         idx += 4;
     }

     return true;
 }

 bool GMBusI2c::I2cFinish() {
     auto gmbus1 = registers::GMBus1::Get().FromValue(0);
     gmbus1.set_bus_cycle_stop(1);
     gmbus1.set_sw_ready(1);
     gmbus1.WriteTo(mmio_space_);

     bool idle = WAIT_ON_MS(!registers::GMBus2::Get().ReadFrom(mmio_space_).active(), 100);

     auto gmbus0 = registers::GMBus0::Get().FromValue(0);
     gmbus0.set_pin_pair_select(0);
     gmbus0.WriteTo(mmio_space_);

     if (!idle) {
         LOG_TRACE("hdmi: GMBus i2c failed to go idle\n");
     }
     return idle;
 }

 bool GMBusI2c::I2cWaitForHwReady() {
     auto gmbus2 = registers::GMBus2::Get().FromValue(0);
     if (!WAIT_ON_MS({ gmbus2.ReadFrom(mmio_space_); gmbus2.nack() || gmbus2.hw_ready(); }, 50)) {
         LOG_TRACE("hdmi: GMBus i2c wait for hwready timeout\n");
         return false;
     }
     if (gmbus2.nack()) {
         LOG_TRACE("hdmi: GMBus i2c got nack\n");
         return false;
     }
     return true;
 }

 bool GMBusI2c::I2cClearNack() {
     I2cFinish();

     if (!WAIT_ON_MS(!registers::GMBus2::Get().ReadFrom(mmio_space_).active(), 10)) {
         LOG_TRACE("hdmi: GMBus i2c failed to clear active nack\n");
         return false;
     }

     // Set/clear sw clear int to reset the bus
     auto gmbus1 = registers::GMBus1::Get().FromValue(0);
     gmbus1.set_sw_clear_int(1);
     gmbus1.WriteTo(mmio_space_);
     gmbus1.set_sw_clear_int(0);
     gmbus1.WriteTo(mmio_space_);

     // Reset GMBus0
     auto gmbus0 = registers::GMBus0::Get().FromValue(0);
     gmbus0.WriteTo(mmio_space_);

     return true;
 }

 GMBusI2c::GMBusI2c(registers::Ddi ddi) : ddi_(ddi) {
     ZX_ASSERT(mtx_init(&lock_, mtx_plain) == thrd_success);
 }

 } // namespace i915

 // Modesetting functions

 namespace {

 // See the section on HDMI/DVI programming in intel-gfx-prm-osrc-skl-vol12-display.pdf
 // for documentation on this algorithm.
 static bool calculate_params(uint32_t symbol_clock_khz, uint16_t* dco_int, uint16_t* dco_frac,
                              uint8_t* q, uint8_t* q_mode, uint8_t* k, uint8_t* p, uint8_t* cf) {
     uint8_t even_candidates[36] = {
         4, 6, 8, 10, 12, 14, 16, 18, 20, 24, 28, 30, 32, 36, 40, 42,
         44, 48, 52, 54, 56, 60, 64, 66, 68, 70, 72, 76, 78, 80, 84, 88, 90, 92, 96, 98
     };
     uint8_t odd_candidates[7] = { 3, 5, 7, 9, 15, 21, 35 };
     uint32_t candidate_freqs[3] = { 8400000, 9000000, 9600000 };
     uint32_t chosen_central_freq = 0;
     uint8_t chosen_divisor = 0;
     uint64_t afe_clock = symbol_clock_khz * 5;
     uint32_t best_deviation = 60; // Deviation in .1% intervals

     for (int parity = 0; parity < 2; parity++) {
         uint8_t* candidates;
         uint8_t num_candidates;
         if (parity) {
             candidates = odd_candidates;
             num_candidates = sizeof(odd_candidates) / sizeof(*odd_candidates);
         } else {
             candidates = even_candidates;
             num_candidates = sizeof(even_candidates) / sizeof(*even_candidates);
         }

         for (unsigned i = 0; i < sizeof(candidate_freqs) / sizeof(*candidate_freqs); i++) {
             uint32_t candidate_freq = candidate_freqs[i];
             for (unsigned j = 0; j < num_candidates; j++) {
                 uint8_t candidate_divisor = candidates[j];
                 uint64_t dco_freq = candidate_divisor * afe_clock;
                 if (dco_freq > candidate_freq) {
                     uint32_t deviation = static_cast<uint32_t>(
                             1000 * (dco_freq - candidate_freq) / candidate_freq);
                     // positive deviation must be < 1%
                     if (deviation < 10 && deviation < best_deviation) {
                         best_deviation = deviation;
                         chosen_central_freq = candidate_freq;
                         chosen_divisor = candidate_divisor;
                     }
                 } else {
                     uint32_t deviation = static_cast<uint32_t>(
                             1000 * (candidate_freq - dco_freq) / candidate_freq);
                     if (deviation < best_deviation) {
                         best_deviation = deviation;
                         chosen_central_freq = candidate_freq;
                         chosen_divisor = candidate_divisor;
                     }
                 }
             }
         }
         if (chosen_divisor) {
             break;
         }
     }
     if (!chosen_divisor) {
         return false;
     }
     uint8_t p0, p1, p2;
     p0 = p1 = p2 = 1;
     if (chosen_divisor % 2 == 0) {
         uint8_t chosen_divisor1 = chosen_divisor / 2;
         if (chosen_divisor1 == 1 || chosen_divisor1 == 2
                 || chosen_divisor1 == 3 || chosen_divisor1 == 5) {
             p0 = 2;
             p2 = chosen_divisor1;
         } else if (chosen_divisor1 % 2 == 0) {
             p0 = 2;
             p1 = chosen_divisor1 / 2;
             p2 = 2;
         } else if (chosen_divisor1 % 3 == 0) {
             p0 = 3;
             p1 = chosen_divisor1 / 3;
             p2 = 2;
         } else if (chosen_divisor1 % 7 == 0) {
             p0 = 7;
             p1 = chosen_divisor1 / 7;
             p2 = 2;
         }
     } else if (chosen_divisor == 3 || chosen_divisor == 9) {
         p0 = 3;
         p2 = chosen_divisor / 3;
     } else if (chosen_divisor == 5 || chosen_divisor == 7) {
         p0 = chosen_divisor;
     } else if (chosen_divisor == 15) {
         p0 = 3;
         p2 = 5;
     } else if (chosen_divisor == 21) {
         p0 = 7;
         p2 = 3;
     } else if (chosen_divisor == 35) {
         p0 = 7;
         p2 = 5;
     }

     *q = p1;
     *q_mode = p1 != 1;

     if (p2 == 5) {
         *k = registers::DpllConfig2::kKdiv5;
     } else if (p2 == 2) {
         *k = registers::DpllConfig2::kKdiv2;
     } else if (p2 == 3) {
         *k = registers::DpllConfig2::kKdiv3;
     } else { // p2 == 1
         *k = registers::DpllConfig2::kKdiv1;
     }
     if (p0 == 1) {
         *p = registers::DpllConfig2::kPdiv1;
     } else if (p0 == 2) {
         *p = registers::DpllConfig2::kPdiv2;
     } else if (p0 == 3) {
         *p = registers::DpllConfig2::kPdiv3;
     } else { // p0 == 7
         *p = registers::DpllConfig2::kPdiv7;
     }

     uint64_t dco_freq_khz = chosen_divisor * afe_clock;
     *dco_int = static_cast<uint16_t>((dco_freq_khz / 1000) / 24);
     *dco_frac = static_cast<uint16_t>(
             ((dco_freq_khz * (1 << 15) / 24) - ((*dco_int * 1000L) * (1 << 15))) / 1000);

     if (chosen_central_freq == 9600000) {
         *cf = registers::DpllConfig2::k9600Mhz;
     } else if (chosen_central_freq == 9000000) {
         *cf = registers::DpllConfig2::k9000Mhz;
     } else { // chosen_central_freq == 8400000
         *cf = registers::DpllConfig2::k8400Mhz;
     }
     return true;
 }

 } // namespace

 namespace i915 {

 HdmiDisplay::HdmiDisplay(Controller* controller, uint64_t id, registers::Ddi ddi)
         : DisplayDevice(controller, id, ddi) { }

 bool HdmiDisplay::Query() {
     // HDMI isn't supported on these DDIs
     if (ddi_to_pin(ddi()) == -1) {
         return false;
     }

     // Reset the GMBus registers and disable GMBus interrupts
     registers::GMBus0::Get().FromValue(0).WriteTo(mmio_space());
     registers::GMBus4::Get().FromValue(0).WriteTo(mmio_space());

     // The only way to tell if an HDMI monitor is actually connected is
     // to try to read from it over I2C.
     for (unsigned i = 0; i < 3; i++) {
         uint8_t test_data = 0;
         i2c_impl_op_t op = {
             .address = kDdcDataAddress,
             .data_buffer = &test_data,
             .data_size = 1,
             .is_read = true,
             .stop = 1,
         };
         registers::GMBus0::Get().FromValue(0).WriteTo(mmio_space());
         if (controller()->Transact(i2c_bus_id(), &op, 1) == ZX_OK) {
             LOG_TRACE("Found a hdmi/dvi monitor\n");
             return true;
         }
         zx_nanosleep(zx_deadline_after(ZX_MSEC(5)));
     }
     LOG_TRACE("Failed to query hdmi i2c bus\n");
     return false;
 }

 bool HdmiDisplay::InitDdi() {
     // All the init happens during modeset
     return true;
 }

 bool HdmiDisplay::ComputeDpllState(uint32_t pixel_clock_10khz, struct dpll_state* config) {
     config->is_hdmi = true;
     return calculate_params(
             pixel_clock_10khz * 10, &config->hdmi.dco_int, &config->hdmi.dco_frac,
             &config->hdmi.q, &config->hdmi.q_mode, &config->hdmi.k,
             &config->hdmi.p, &config->hdmi.cf);
 }

 bool HdmiDisplay::DdiModeset(const display_mode_t& mode,
                              registers::Pipe pipe, registers::Trans trans) {
     controller()->ResetPipe(pipe);
     controller()->ResetTrans(trans);
     controller()->ResetDdi(ddi());

     // Calculate and the HDMI DPLL parameters
     dpll_state_t state;
     state.is_hdmi = true;
     if (!calculate_params(mode.pixel_clock_10khz * 10,
                           &state.hdmi.dco_int, &state.hdmi.dco_frac, &state.hdmi.q,
                           &state.hdmi.q_mode, &state.hdmi.k, &state.hdmi.p, &state.hdmi.cf)) {
         LOG_ERROR("hdmi: failed to calculate clock params\n");
         return false;
     }

     registers::Dpll dpll = controller()->SelectDpll(false, state);
     if (dpll == registers::DPLL_INVALID) {
         return false;
     }

     auto dpll_enable = registers::DpllEnable::Get(dpll).ReadFrom(mmio_space());
     if (!dpll_enable.enable_dpll()) {
         // Set the DPLL control settings
         auto dpll_ctrl1 = registers::DpllControl1::Get().ReadFrom(mmio_space());
         dpll_ctrl1.dpll_hdmi_mode(dpll).set(1);
         dpll_ctrl1.dpll_override(dpll).set(1);
         dpll_ctrl1.dpll_ssc_enable(dpll).set(0);
         dpll_ctrl1.WriteTo(mmio_space());
         dpll_ctrl1.ReadFrom(mmio_space());

         // Set the DCO frequency
         auto dpll_cfg1 = registers::DpllConfig1::Get(dpll).FromValue(0);
         dpll_cfg1.set_frequency_enable(1);
         dpll_cfg1.set_dco_integer(state.hdmi.dco_int);
         dpll_cfg1.set_dco_fraction(state.hdmi.dco_frac);
         dpll_cfg1.WriteTo(mmio_space());
         dpll_cfg1.ReadFrom(mmio_space());

         // Set the divisors and central frequency
         auto dpll_cfg2 = registers::DpllConfig2::Get(dpll).FromValue(0);
         dpll_cfg2.set_qdiv_ratio(state.hdmi.q);
         dpll_cfg2.set_qdiv_mode(state.hdmi.q_mode);
         dpll_cfg2.set_kdiv_ratio(state.hdmi.k);
         dpll_cfg2.set_pdiv_ratio(state.hdmi.p);
         dpll_cfg2.set_central_freq(state.hdmi.cf);
         dpll_cfg2.WriteTo(mmio_space());
         dpll_cfg2.ReadFrom(mmio_space()); // Posting read

         // Enable and wait for the DPLL
         dpll_enable.set_enable_dpll(1);
         dpll_enable.WriteTo(mmio_space());
         if (!WAIT_ON_MS(registers::DpllStatus
                 ::Get().ReadFrom(mmio_space()).dpll_lock(dpll).get(), 5)) {
             LOG_ERROR("hdmi: DPLL failed to lock\n");
             return false;
         }
     }

     // Direct the DPLL to the DDI
     auto dpll_ctrl2 = registers::DpllControl2::Get().ReadFrom(mmio_space());
     dpll_ctrl2.ddi_select_override(ddi()).set(1);
     dpll_ctrl2.ddi_clock_off(ddi()).set(0);
     dpll_ctrl2.ddi_clock_select(ddi()).set(dpll);
     dpll_ctrl2.WriteTo(mmio_space());

     // Enable DDI IO power and wait for it
     auto pwc2 = registers::PowerWellControl2::Get().ReadFrom(mmio_space());
     pwc2.ddi_io_power_request(ddi()).set(1);
     pwc2.WriteTo(mmio_space());
     if (!WAIT_ON_US(registers::PowerWellControl2
             ::Get().ReadFrom(mmio_space()).ddi_io_power_state(ddi()).get(), 20)) {
         LOG_ERROR("hdmi: failed to enable IO power for ddi\n");
         return false;
     }

     return true;
 }

 bool HdmiDisplay::PipeConfigPreamble(const display_mode_t& mode,
                                      registers::Pipe pipe, registers::Trans trans) {
     registers::TranscoderRegs trans_regs(trans);

     // Configure Transcoder Clock Select
     auto trans_clk_sel = trans_regs.ClockSelect().ReadFrom(mmio_space());
     trans_clk_sel.set_trans_clock_select(ddi() + 1);
     trans_clk_sel.WriteTo(mmio_space());

     return true;
 }

 bool HdmiDisplay::PipeConfigEpilogue(const display_mode_t& mode,
                                      registers::Pipe pipe, registers::Trans trans) {
     registers::TranscoderRegs trans_regs(trans);

     auto ddi_func = trans_regs.DdiFuncControl().ReadFrom(mmio_space());
     ddi_func.set_trans_ddi_function_enable(1);
     ddi_func.set_ddi_select(ddi());
     ddi_func.set_trans_ddi_mode_select(is_hdmi() ? ddi_func.kModeHdmi : ddi_func.kModeDvi);
     ddi_func.set_bits_per_color(ddi_func.k8bbc);
     ddi_func.set_sync_polarity((!!(mode.flags & MODE_FLAG_VSYNC_POSITIVE)) << 1
                                 | (!!(mode.flags & MODE_FLAG_HSYNC_POSITIVE)));
     ddi_func.set_port_sync_mode_enable(0);
     ddi_func.set_dp_vc_payload_allocate(0);
     ddi_func.WriteTo(mmio_space());

     auto trans_conf = trans_regs.Conf().ReadFrom(mmio_space());
     trans_conf.set_transcoder_enable(1);
     trans_conf.set_interlaced_mode(!!(mode.flags & MODE_FLAG_INTERLACED));
     trans_conf.WriteTo(mmio_space());

     // Configure voltage swing and related IO settings.
     registers::DdiRegs ddi_regs(ddi());
     auto ddi_buf_trans_hi = ddi_regs.DdiBufTransHi(9).ReadFrom(mmio_space());
     auto ddi_buf_trans_lo = ddi_regs.DdiBufTransLo(9).ReadFrom(mmio_space());
     auto disio_cr_tx_bmu = registers::DisplayIoCtrlRegTxBmu::Get().ReadFrom(mmio_space());

     // kUseDefaultIdx always fails the idx-in-bounds check, so no additional handling is needed
     uint8_t idx = controller()->igd_opregion().GetHdmiBufferTranslationIndex(ddi());
     uint8_t i_boost_override = controller()->igd_opregion().GetIBoost(ddi(), false /* is_dp */);

     const ddi_buf_trans_entry* entries;
     uint8_t default_iboost;
     if (is_skl_y(controller()->device_id()) || is_kbl_y(controller()->device_id())) {
         entries = hdmi_ddi_buf_trans_skl_y;
         if (idx >= fbl::count_of(hdmi_ddi_buf_trans_skl_y)) {
             idx = 8; // Default index
         }
         default_iboost = 3;
     } else {
         entries = hdmi_ddi_buf_trans_skl_uhs;
         if (idx >= fbl::count_of(hdmi_ddi_buf_trans_skl_uhs)) {
             idx = 8; // Default index
         }
         default_iboost = 1;
     }

     ddi_buf_trans_hi.set_reg_value(entries[idx].high_dword);
     ddi_buf_trans_lo.set_reg_value(entries[idx].low_dword);
     if (i_boost_override) {
         ddi_buf_trans_lo.set_balance_leg_enable(1);
     }
     disio_cr_tx_bmu.set_disable_balance_leg(0);
     disio_cr_tx_bmu.tx_balance_leg_select(ddi()).set(
             i_boost_override ? i_boost_override : default_iboost);

     ddi_buf_trans_hi.WriteTo(mmio_space());
     ddi_buf_trans_lo.WriteTo(mmio_space());
     disio_cr_tx_bmu.WriteTo(mmio_space());

     // Configure and enable DDI_BUF_CTL
     auto ddi_buf_ctl = ddi_regs.DdiBufControl().ReadFrom(mmio_space());
     ddi_buf_ctl.set_ddi_buffer_enable(1);
     ddi_buf_ctl.WriteTo(mmio_space());

     return true;
 }

 bool HdmiDisplay::CheckPixelRate(uint64_t pixel_rate) {
     // Pixel rates of 300M/165M pixels per second for HDMI/DVI. The Intel docs state
     // that the maximum link bit rate of an HDMI port is 3GHz, not 3.4GHz that would
     // be expected  based on the HDMI spec.
     if ((is_hdmi() ? 300000000 : 165000000) < pixel_rate) {
         return false;
     }

     dpll_state_t test_state;
     return ComputeDpllState(static_cast<uint32_t>(pixel_rate / 10000 /* 10khz */), &test_state);
 }

 } // namespace i915
	// Copyright 2017 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <ddk/driver.h>
	#include <lib/edid/edid.h>

	#include "intel-i915.h"
	#include "hdmi-display.h"
	#include "macros.h"
	#include "pci-ids.h"
	#include "registers.h"
	#include "registers-ddi.h"
	#include "registers-dpll.h"
	#include "registers-pipe.h"
	#include "registers-transcoder.h"

	// I2c functions

	namespace {
	// Recommended DDI buffer translation programming values

	struct ddi_buf_trans_entry {
	uint32_t high_dword;
	uint32_t low_dword;
	};

	const ddi_buf_trans_entry hdmi_ddi_buf_trans_skl_uhs[11] {
	{ 0x000000ac, 0x00000018 },
	{ 0x0000009d, 0x00005012 },
	{ 0x00000088, 0x00007011 },
	{ 0x000000a1, 0x00000018 },
	{ 0x00000098, 0x00000018 },
	{ 0x00000088, 0x00004013 },
	{ 0x000000cd, 0x80006012 },
	{ 0x000000df, 0x00000018 },
	{ 0x000000cd, 0x80003015 },
	{ 0x000000c0, 0x80003015 },
	{ 0x000000c0, 0x80000018 },
	};

	const ddi_buf_trans_entry hdmi_ddi_buf_trans_skl_y[11] {
	{ 0x000000a1, 0x00000018 },
	{ 0x000000df, 0x00005012 },
	{ 0x000000cb, 0x80007011 },
	{ 0x000000a4, 0x00000018 },
	{ 0x0000009d, 0x00000018 },
	{ 0x00000080, 0x00004013 },
	{ 0x000000c0, 0x80006012 },
	{ 0x0000008a, 0x00000018 },
	{ 0x000000c0, 0x80003015 },
	{ 0x000000c0, 0x80003015 },
	{ 0x000000c0, 0x80000018 },
	};

	int ddi_to_pin(registers::Ddi ddi) {
	if (ddi == registers::DDI_B) {
	return registers::GMBus0::kDdiBPin;
	} else if (ddi == registers::DDI_C) {
	return registers::GMBus0::kDdiCPin;
	} else if (ddi == registers::DDI_D) {
	return registers::GMBus0::kDdiDPin;
	}
	return -1;
	}

	void write_gmbus3(ddk::MmioBuffer* mmio_space, const uint8_t* buf, uint32_t size, uint32_t idx) {
	int cur_byte = 0;
	uint32_t val = 0;
	while (idx < size && cur_byte < 4) {
	val \|= buf[idx++] << (8 * cur_byte++);
	}
	registers::GMBus3::Get().FromValue(val).WriteTo(mmio_space);
	}

	void read_gmbus3(ddk::MmioBuffer* mmio_space, uint8_t* buf, uint32_t size, uint32_t idx) {
	int cur_byte = 0;
	uint32_t val = registers::GMBus3::Get().ReadFrom(mmio_space).reg_value();
	while (idx < size && cur_byte++ < 4) {
	buf[idx++] = val & 0xff;
	val >>= 8;
	}
	}

	static constexpr uint8_t kDdcSegmentAddress = 0x30;
	static constexpr uint8_t kDdcDataAddress = 0x50;
	static constexpr uint8_t kI2cClockUs = 10; // 100 kHz

	// For bit banging i2c over the gpio pins
	bool i2c_scl(ddk::MmioBuffer* mmio_space, registers::Ddi ddi, bool hi) {
	auto gpio = registers::GpioCtl::Get(ddi).FromValue(0);

	if (!hi) {
	gpio.set_clock_direction_val(1);
	gpio.set_clock_mask(1);
	}
	gpio.set_clock_direction_mask(1);

	gpio.WriteTo(mmio_space);
	gpio.ReadFrom(mmio_space); // Posting read

	// Handle the case where something on the bus is holding the clock
	// low. Timeout after 1ms.
	if (hi) {
	int count = 0;
	do {
	if (count != 0) {
	zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs)));
	}
	gpio.ReadFrom(mmio_space);
	} while (count++ < 100 && hi != gpio.clock_in());
	if (hi != gpio.clock_in()) {
	return false;
	}
	}
	zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));
	return true;
	}

	// For bit banging i2c over the gpio pins
	void i2c_sda(ddk::MmioBuffer* mmio_space, registers::Ddi ddi, bool hi) {
	auto gpio = registers::GpioCtl::Get(ddi).FromValue(0);

	if (!hi) {
	gpio.set_data_direction_val(1);
	gpio.set_data_mask(1);
	}
	gpio.set_data_direction_mask(1);

	gpio.WriteTo(mmio_space);
	gpio.ReadFrom(mmio_space); // Posting read

	zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));
	}

	// For bit banging i2c over the gpio pins
	bool i2c_send_byte(ddk::MmioBuffer* mmio_space, registers::Ddi ddi, uint8_t byte) {
	// Set the bits from MSB to LSB
	for (int i = 7; i >= 0; i--) {
	i2c_sda(mmio_space, ddi, (byte >> i) & 0x1);

	i2c_scl(mmio_space, ddi, 1);

	// Leave the data line where it is for the rest of the cycle
	zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));

	i2c_scl(mmio_space, ddi, 0);
	}

	// Release the data line and check for an ack
	i2c_sda(mmio_space, ddi, 1);
	i2c_scl(mmio_space, ddi, 1);

	bool ack = !registers::GpioCtl::Get(ddi).ReadFrom(mmio_space).data_in();

	// Sleep for the rest of the cycle
	zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));

	i2c_scl(mmio_space, ddi, 0);

	return ack;
	}

	} // namespace

	namespace i915 {

	// Per the GMBUS Controller Programming Interface section of the Intel docs, GMBUS does not
	// directly support segment pointer addressing. Instead, the segment pointer needs to be
	// set by bit-banging the GPIO pins.
	bool GMBusI2c::SetDdcSegment(uint8_t segment_num) {
	// Reset the clock and data lines
	i2c_scl(mmio_space_, ddi_, 0);
	i2c_sda(mmio_space_, ddi_, 0);

	if (!i2c_scl(mmio_space_, ddi_, 1)) {
	return false;
	}
	i2c_sda(mmio_space_, ddi_, 1);
	// Wait for the rest of the cycle
	zx_nanosleep(zx_deadline_after(ZX_USEC(kI2cClockUs / 2)));

	// Send a start condition
	i2c_sda(mmio_space_, ddi_, 0);
	i2c_scl(mmio_space_, ddi_, 0);

	// Send the segment register index and the segment number
	uint8_t segment_write_command = kDdcSegmentAddress << 1;
	if (!i2c_send_byte(mmio_space_, ddi_, segment_write_command)
	\|\| !i2c_send_byte(mmio_space_, ddi_, segment_num)) {
	return false;
	}

	// Set the data and clock lines high to prepare for the GMBus start
	i2c_sda(mmio_space_, ddi_, 1);
	return i2c_scl(mmio_space_, ddi_, 1);
	}

	zx_status_t GMBusI2c::I2cTransact(const i2c_impl_op_t* ops, size_t size) {
	// The GMBus register is a limited interface to the i2c bus - it doesn't support complex
	// transactions like setting the E-DDC segment. For now, providing a special-case interface
	// for reading the E-DDC is good enough.
	fbl::AutoLock lock(&lock_);
	zx_status_t fail_res = ZX_ERR_IO;
	bool gmbus_set = false;
	for (unsigned i = 0; i < size; i++) {
	const i2c_impl_op_t* op = ops + i;
	if (op->address == kDdcSegmentAddress && !op->is_read && op->data_size == 1) {
	registers::GMBus0::Get().FromValue(0).WriteTo(mmio_space_);
	gmbus_set = false;
	if (!SetDdcSegment(static_cast<uint8_t>(op->data_buffer))) {
	goto fail;
	}
	} else if (op->address == kDdcDataAddress) {
	if (!gmbus_set) {
	auto gmbus0 = registers::GMBus0::Get().FromValue(0);
	gmbus0.set_pin_pair_select(ddi_to_pin(ddi_));
	gmbus0.WriteTo(mmio_space_);

	gmbus_set = true;
	}

	uint8_t* buf = static_cast<uint8_t*>(op->data_buffer);
	uint8_t len = static_cast<uint8_t>(op->data_size);
	if (op->is_read ? GMBusRead(kDdcDataAddress, buf, len)
	: GMBusWrite(kDdcDataAddress, buf, len)) {
	if (!WAIT_ON_MS(registers::GMBus2::Get().ReadFrom(mmio_space_).wait(), 10)) {
	LOG_TRACE("Transition to wait phase timed out\n");
	goto fail;
	}
	} else {
	goto fail;
	}
	} else {
	fail_res = ZX_ERR_NOT_SUPPORTED;
	goto fail;
	}

	if (op->stop) {
	if (!I2cFinish()) {
	goto fail;
	}
	gmbus_set = false;
	}
	}

	return ZX_OK;
	fail:
	if (!I2cClearNack()) {
	LOG_TRACE("Failed to clear nack\n");
	}
	return fail_res;
	}

	bool GMBusI2c::GMBusWrite(uint8_t addr, const uint8_t* buf, uint8_t size) {
	unsigned idx = 0;
	write_gmbus3(mmio_space_, buf, size, idx);
	idx += 4;

	auto gmbus1 = registers::GMBus1::Get().FromValue(0);
	gmbus1.set_sw_ready(1);
	gmbus1.set_bus_cycle_wait(1);
	gmbus1.set_total_byte_count(size);
	gmbus1.set_slave_register_addr(addr);
	gmbus1.WriteTo(mmio_space_);

	while (idx < size) {
	if (!I2cWaitForHwReady()) {
	return false;
	}

	write_gmbus3(mmio_space_, buf, size, idx);
	idx += 4;
	}
	// One more wait to ensure we're ready when we leave the function
	return I2cWaitForHwReady();
	}

	bool GMBusI2c::GMBusRead(uint8_t addr, uint8_t* buf, uint8_t size) {
	auto gmbus1 = registers::GMBus1::Get().FromValue(0);
	gmbus1.set_sw_ready(1);
	gmbus1.set_bus_cycle_wait(1);
	gmbus1.set_total_byte_count(size);
	gmbus1.set_slave_register_addr(addr);
	gmbus1.set_read_op(1);
	gmbus1.WriteTo(mmio_space_);

	unsigned idx = 0;
	while (idx < size) {
	if (!I2cWaitForHwReady()) {
	return false;
	}

	read_gmbus3(mmio_space_, buf, size, idx);
	idx += 4;
	}

	return true;
	}

	bool GMBusI2c::I2cFinish() {
	auto gmbus1 = registers::GMBus1::Get().FromValue(0);
	gmbus1.set_bus_cycle_stop(1);
	gmbus1.set_sw_ready(1);
	gmbus1.WriteTo(mmio_space_);

	bool idle = WAIT_ON_MS(!registers::GMBus2::Get().ReadFrom(mmio_space_).active(), 100);

	auto gmbus0 = registers::GMBus0::Get().FromValue(0);
	gmbus0.set_pin_pair_select(0);
	gmbus0.WriteTo(mmio_space_);

	if (!idle) {
	LOG_TRACE("hdmi: GMBus i2c failed to go idle\n");
	}
	return idle;
	}

	bool GMBusI2c::I2cWaitForHwReady() {
	auto gmbus2 = registers::GMBus2::Get().FromValue(0);
	if (!WAIT_ON_MS({ gmbus2.ReadFrom(mmio_space_); gmbus2.nack() \|\| gmbus2.hw_ready(); }, 50)) {
	LOG_TRACE("hdmi: GMBus i2c wait for hwready timeout\n");
	return false;
	}
	if (gmbus2.nack()) {
	LOG_TRACE("hdmi: GMBus i2c got nack\n");
	return false;
	}
	return true;
	}

	bool GMBusI2c::I2cClearNack() {
	I2cFinish();

	if (!WAIT_ON_MS(!registers::GMBus2::Get().ReadFrom(mmio_space_).active(), 10)) {
	LOG_TRACE("hdmi: GMBus i2c failed to clear active nack\n");
	return false;
	}

	// Set/clear sw clear int to reset the bus
	auto gmbus1 = registers::GMBus1::Get().FromValue(0);
	gmbus1.set_sw_clear_int(1);
	gmbus1.WriteTo(mmio_space_);
	gmbus1.set_sw_clear_int(0);
	gmbus1.WriteTo(mmio_space_);

	// Reset GMBus0
	auto gmbus0 = registers::GMBus0::Get().FromValue(0);
	gmbus0.WriteTo(mmio_space_);

	return true;
	}

	GMBusI2c::GMBusI2c(registers::Ddi ddi) : ddi_(ddi) {
	ZX_ASSERT(mtx_init(&lock_, mtx_plain) == thrd_success);
	}

	} // namespace i915

	// Modesetting functions

	namespace {

	// See the section on HDMI/DVI programming in intel-gfx-prm-osrc-skl-vol12-display.pdf
	// for documentation on this algorithm.
	static bool calculate_params(uint32_t symbol_clock_khz, uint16_t* dco_int, uint16_t* dco_frac,
	uint8_t* q, uint8_t* q_mode, uint8_t* k, uint8_t* p, uint8_t* cf) {
	uint8_t even_candidates[36] = {
	4, 6, 8, 10, 12, 14, 16, 18, 20, 24, 28, 30, 32, 36, 40, 42,
	44, 48, 52, 54, 56, 60, 64, 66, 68, 70, 72, 76, 78, 80, 84, 88, 90, 92, 96, 98
	};
	uint8_t odd_candidates[7] = { 3, 5, 7, 9, 15, 21, 35 };
	uint32_t candidate_freqs[3] = { 8400000, 9000000, 9600000 };
	uint32_t chosen_central_freq = 0;
	uint8_t chosen_divisor = 0;
	uint64_t afe_clock = symbol_clock_khz * 5;
	uint32_t best_deviation = 60; // Deviation in .1% intervals

	for (int parity = 0; parity < 2; parity++) {
	uint8_t* candidates;
	uint8_t num_candidates;
	if (parity) {
	candidates = odd_candidates;
	num_candidates = sizeof(odd_candidates) / sizeof(*odd_candidates);
	} else {
	candidates = even_candidates;
	num_candidates = sizeof(even_candidates) / sizeof(*even_candidates);
	}

	for (unsigned i = 0; i < sizeof(candidate_freqs) / sizeof(*candidate_freqs); i++) {
	uint32_t candidate_freq = candidate_freqs[i];
	for (unsigned j = 0; j < num_candidates; j++) {
	uint8_t candidate_divisor = candidates[j];
	uint64_t dco_freq = candidate_divisor * afe_clock;
	if (dco_freq > candidate_freq) {
	uint32_t deviation = static_cast<uint32_t>(
	1000 * (dco_freq - candidate_freq) / candidate_freq);
	// positive deviation must be < 1%
	if (deviation < 10 && deviation < best_deviation) {
	best_deviation = deviation;
	chosen_central_freq = candidate_freq;
	chosen_divisor = candidate_divisor;
	}
	} else {
	uint32_t deviation = static_cast<uint32_t>(
	1000 * (candidate_freq - dco_freq) / candidate_freq);
	if (deviation < best_deviation) {
	best_deviation = deviation;
	chosen_central_freq = candidate_freq;
	chosen_divisor = candidate_divisor;
	}
	}
	}
	}
	if (chosen_divisor) {
	break;
	}
	}
	if (!chosen_divisor) {
	return false;
	}
	uint8_t p0, p1, p2;
	p0 = p1 = p2 = 1;
	if (chosen_divisor % 2 == 0) {
	uint8_t chosen_divisor1 = chosen_divisor / 2;
	if (chosen_divisor1 == 1 \|\| chosen_divisor1 == 2
	\|\| chosen_divisor1 == 3 \|\| chosen_divisor1 == 5) {
	p0 = 2;
	p2 = chosen_divisor1;
	} else if (chosen_divisor1 % 2 == 0) {
	p0 = 2;
	p1 = chosen_divisor1 / 2;
	p2 = 2;
	} else if (chosen_divisor1 % 3 == 0) {
	p0 = 3;
	p1 = chosen_divisor1 / 3;
	p2 = 2;
	} else if (chosen_divisor1 % 7 == 0) {
	p0 = 7;
	p1 = chosen_divisor1 / 7;
	p2 = 2;
	}
	} else if (chosen_divisor == 3 \|\| chosen_divisor == 9) {
	p0 = 3;
	p2 = chosen_divisor / 3;
	} else if (chosen_divisor == 5 \|\| chosen_divisor == 7) {
	p0 = chosen_divisor;
	} else if (chosen_divisor == 15) {
	p0 = 3;
	p2 = 5;
	} else if (chosen_divisor == 21) {
	p0 = 7;
	p2 = 3;
	} else if (chosen_divisor == 35) {
	p0 = 7;
	p2 = 5;
	}

	*q = p1;
	*q_mode = p1 != 1;

	if (p2 == 5) {
	*k = registers::DpllConfig2::kKdiv5;
	} else if (p2 == 2) {
	*k = registers::DpllConfig2::kKdiv2;
	} else if (p2 == 3) {
	*k = registers::DpllConfig2::kKdiv3;
	} else { // p2 == 1
	*k = registers::DpllConfig2::kKdiv1;
	}
	if (p0 == 1) {
	*p = registers::DpllConfig2::kPdiv1;
	} else if (p0 == 2) {
	*p = registers::DpllConfig2::kPdiv2;
	} else if (p0 == 3) {
	*p = registers::DpllConfig2::kPdiv3;
	} else { // p0 == 7
	*p = registers::DpllConfig2::kPdiv7;
	}

	uint64_t dco_freq_khz = chosen_divisor * afe_clock;
	*dco_int = static_cast<uint16_t>((dco_freq_khz / 1000) / 24);
	*dco_frac = static_cast<uint16_t>(
	((dco_freq_khz * (1 << 15) / 24) - ((dco_int 1000L) * (1 << 15))) / 1000);

	if (chosen_central_freq == 9600000) {
	*cf = registers::DpllConfig2::k9600Mhz;
	} else if (chosen_central_freq == 9000000) {
	*cf = registers::DpllConfig2::k9000Mhz;
	} else { // chosen_central_freq == 8400000
	*cf = registers::DpllConfig2::k8400Mhz;
	}
	return true;
	}

	} // namespace

	namespace i915 {

	HdmiDisplay::HdmiDisplay(Controller* controller, uint64_t id, registers::Ddi ddi)
	: DisplayDevice(controller, id, ddi) { }

	bool HdmiDisplay::Query() {
	// HDMI isn't supported on these DDIs
	if (ddi_to_pin(ddi()) == -1) {
	return false;
	}

	// Reset the GMBus registers and disable GMBus interrupts
	registers::GMBus0::Get().FromValue(0).WriteTo(mmio_space());
	registers::GMBus4::Get().FromValue(0).WriteTo(mmio_space());

	// The only way to tell if an HDMI monitor is actually connected is
	// to try to read from it over I2C.
	for (unsigned i = 0; i < 3; i++) {
	uint8_t test_data = 0;
	i2c_impl_op_t op = {
	.address = kDdcDataAddress,
	.data_buffer = &test_data,
	.data_size = 1,
	.is_read = true,
	.stop = 1,
	};
	registers::GMBus0::Get().FromValue(0).WriteTo(mmio_space());
	if (controller()->Transact(i2c_bus_id(), &op, 1) == ZX_OK) {
	LOG_TRACE("Found a hdmi/dvi monitor\n");
	return true;
	}
	zx_nanosleep(zx_deadline_after(ZX_MSEC(5)));
	}
	LOG_TRACE("Failed to query hdmi i2c bus\n");
	return false;
	}

	bool HdmiDisplay::InitDdi() {
	// All the init happens during modeset
	return true;
	}

	bool HdmiDisplay::ComputeDpllState(uint32_t pixel_clock_10khz, struct dpll_state* config) {
	config->is_hdmi = true;
	return calculate_params(
	pixel_clock_10khz * 10, &config->hdmi.dco_int, &config->hdmi.dco_frac,
	&config->hdmi.q, &config->hdmi.q_mode, &config->hdmi.k,
	&config->hdmi.p, &config->hdmi.cf);
	}

	bool HdmiDisplay::DdiModeset(const display_mode_t& mode,
	registers::Pipe pipe, registers::Trans trans) {
	controller()->ResetPipe(pipe);
	controller()->ResetTrans(trans);
	controller()->ResetDdi(ddi());

	// Calculate and the HDMI DPLL parameters
	dpll_state_t state;
	state.is_hdmi = true;
	if (!calculate_params(mode.pixel_clock_10khz * 10,
	&state.hdmi.dco_int, &state.hdmi.dco_frac, &state.hdmi.q,
	&state.hdmi.q_mode, &state.hdmi.k, &state.hdmi.p, &state.hdmi.cf)) {
	LOG_ERROR("hdmi: failed to calculate clock params\n");
	return false;
	}

	registers::Dpll dpll = controller()->SelectDpll(false, state);
	if (dpll == registers::DPLL_INVALID) {
	return false;
	}

	auto dpll_enable = registers::DpllEnable::Get(dpll).ReadFrom(mmio_space());
	if (!dpll_enable.enable_dpll()) {
	// Set the DPLL control settings
	auto dpll_ctrl1 = registers::DpllControl1::Get().ReadFrom(mmio_space());
	dpll_ctrl1.dpll_hdmi_mode(dpll).set(1);
	dpll_ctrl1.dpll_override(dpll).set(1);
	dpll_ctrl1.dpll_ssc_enable(dpll).set(0);
	dpll_ctrl1.WriteTo(mmio_space());
	dpll_ctrl1.ReadFrom(mmio_space());

	// Set the DCO frequency
	auto dpll_cfg1 = registers::DpllConfig1::Get(dpll).FromValue(0);
	dpll_cfg1.set_frequency_enable(1);
	dpll_cfg1.set_dco_integer(state.hdmi.dco_int);
	dpll_cfg1.set_dco_fraction(state.hdmi.dco_frac);
	dpll_cfg1.WriteTo(mmio_space());
	dpll_cfg1.ReadFrom(mmio_space());

	// Set the divisors and central frequency
	auto dpll_cfg2 = registers::DpllConfig2::Get(dpll).FromValue(0);
	dpll_cfg2.set_qdiv_ratio(state.hdmi.q);
	dpll_cfg2.set_qdiv_mode(state.hdmi.q_mode);
	dpll_cfg2.set_kdiv_ratio(state.hdmi.k);
	dpll_cfg2.set_pdiv_ratio(state.hdmi.p);
	dpll_cfg2.set_central_freq(state.hdmi.cf);
	dpll_cfg2.WriteTo(mmio_space());
	dpll_cfg2.ReadFrom(mmio_space()); // Posting read

	// Enable and wait for the DPLL
	dpll_enable.set_enable_dpll(1);
	dpll_enable.WriteTo(mmio_space());
	if (!WAIT_ON_MS(registers::DpllStatus
	::Get().ReadFrom(mmio_space()).dpll_lock(dpll).get(), 5)) {
	LOG_ERROR("hdmi: DPLL failed to lock\n");
	return false;
	}
	}

	// Direct the DPLL to the DDI
	auto dpll_ctrl2 = registers::DpllControl2::Get().ReadFrom(mmio_space());
	dpll_ctrl2.ddi_select_override(ddi()).set(1);
	dpll_ctrl2.ddi_clock_off(ddi()).set(0);
	dpll_ctrl2.ddi_clock_select(ddi()).set(dpll);
	dpll_ctrl2.WriteTo(mmio_space());

	// Enable DDI IO power and wait for it
	auto pwc2 = registers::PowerWellControl2::Get().ReadFrom(mmio_space());
	pwc2.ddi_io_power_request(ddi()).set(1);
	pwc2.WriteTo(mmio_space());
	if (!WAIT_ON_US(registers::PowerWellControl2
	::Get().ReadFrom(mmio_space()).ddi_io_power_state(ddi()).get(), 20)) {
	LOG_ERROR("hdmi: failed to enable IO power for ddi\n");
	return false;
	}

	return true;
	}

	bool HdmiDisplay::PipeConfigPreamble(const display_mode_t& mode,
	registers::Pipe pipe, registers::Trans trans) {
	registers::TranscoderRegs trans_regs(trans);

	// Configure Transcoder Clock Select
	auto trans_clk_sel = trans_regs.ClockSelect().ReadFrom(mmio_space());
	trans_clk_sel.set_trans_clock_select(ddi() + 1);
	trans_clk_sel.WriteTo(mmio_space());

	return true;
	}

	bool HdmiDisplay::PipeConfigEpilogue(const display_mode_t& mode,
	registers::Pipe pipe, registers::Trans trans) {
	registers::TranscoderRegs trans_regs(trans);

	auto ddi_func = trans_regs.DdiFuncControl().ReadFrom(mmio_space());
	ddi_func.set_trans_ddi_function_enable(1);
	ddi_func.set_ddi_select(ddi());
	ddi_func.set_trans_ddi_mode_select(is_hdmi() ? ddi_func.kModeHdmi : ddi_func.kModeDvi);
	ddi_func.set_bits_per_color(ddi_func.k8bbc);
	ddi_func.set_sync_polarity((!!(mode.flags & MODE_FLAG_VSYNC_POSITIVE)) << 1
	\| (!!(mode.flags & MODE_FLAG_HSYNC_POSITIVE)));
	ddi_func.set_port_sync_mode_enable(0);
	ddi_func.set_dp_vc_payload_allocate(0);
	ddi_func.WriteTo(mmio_space());

	auto trans_conf = trans_regs.Conf().ReadFrom(mmio_space());
	trans_conf.set_transcoder_enable(1);
	trans_conf.set_interlaced_mode(!!(mode.flags & MODE_FLAG_INTERLACED));
	trans_conf.WriteTo(mmio_space());

	// Configure voltage swing and related IO settings.
	registers::DdiRegs ddi_regs(ddi());
	auto ddi_buf_trans_hi = ddi_regs.DdiBufTransHi(9).ReadFrom(mmio_space());
	auto ddi_buf_trans_lo = ddi_regs.DdiBufTransLo(9).ReadFrom(mmio_space());
	auto disio_cr_tx_bmu = registers::DisplayIoCtrlRegTxBmu::Get().ReadFrom(mmio_space());

	// kUseDefaultIdx always fails the idx-in-bounds check, so no additional handling is needed
	uint8_t idx = controller()->igd_opregion().GetHdmiBufferTranslationIndex(ddi());
	uint8_t i_boost_override = controller()->igd_opregion().GetIBoost(ddi(), false /* is_dp */);

	const ddi_buf_trans_entry* entries;
	uint8_t default_iboost;
	if (is_skl_y(controller()->device_id()) \|\| is_kbl_y(controller()->device_id())) {
	entries = hdmi_ddi_buf_trans_skl_y;
	if (idx >= fbl::count_of(hdmi_ddi_buf_trans_skl_y)) {
	idx = 8; // Default index
	}
	default_iboost = 3;
	} else {
	entries = hdmi_ddi_buf_trans_skl_uhs;
	if (idx >= fbl::count_of(hdmi_ddi_buf_trans_skl_uhs)) {
	idx = 8; // Default index
	}
	default_iboost = 1;
	}

	ddi_buf_trans_hi.set_reg_value(entries[idx].high_dword);
	ddi_buf_trans_lo.set_reg_value(entries[idx].low_dword);
	if (i_boost_override) {
	ddi_buf_trans_lo.set_balance_leg_enable(1);
	}
	disio_cr_tx_bmu.set_disable_balance_leg(0);
	disio_cr_tx_bmu.tx_balance_leg_select(ddi()).set(
	i_boost_override ? i_boost_override : default_iboost);

	ddi_buf_trans_hi.WriteTo(mmio_space());
	ddi_buf_trans_lo.WriteTo(mmio_space());
	disio_cr_tx_bmu.WriteTo(mmio_space());

	// Configure and enable DDI_BUF_CTL
	auto ddi_buf_ctl = ddi_regs.DdiBufControl().ReadFrom(mmio_space());
	ddi_buf_ctl.set_ddi_buffer_enable(1);
	ddi_buf_ctl.WriteTo(mmio_space());

	return true;
	}

	bool HdmiDisplay::CheckPixelRate(uint64_t pixel_rate) {
	// Pixel rates of 300M/165M pixels per second for HDMI/DVI. The Intel docs state
	// that the maximum link bit rate of an HDMI port is 3GHz, not 3.4GHz that would
	// be expected based on the HDMI spec.
	if ((is_hdmi() ? 300000000 : 165000000) < pixel_rate) {
	return false;
	}

	dpll_state_t test_state;
	return ComputeDpllState(static_cast<uint32_t>(pixel_rate / 10000 /* 10khz */), &test_state);
	}

	} // namespace i915