src/devices/lib/amlogic/s905d2-hiu.c - fuchsia - Git at Google

 // Copyright 2018 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 <string.h>
 #include <zircon/assert.h>
 #include <zircon/syscalls.h>
 #include <zircon/types.h>

 #include <ddk/debug.h>
 #include <ddk/mmio-buffer.h>
 #include <hw/reg.h>
 #include <soc/aml-s905d2/s905d2-hiu-regs.h>
 #include <soc/aml-s905d2/s905d2-hiu.h>
 #include <soc/aml-s905d2/s905d2-hw.h>

 static inline uint32_t hiu_clk_get_reg(aml_hiu_dev_t* dev, uint32_t offset) {
   return MmioRead32((MMIO_PTR uint32_t*)(dev->regs_vaddr + offset));
 }

 static inline uint32_t hiu_clk_set_reg(aml_hiu_dev_t* dev, uint32_t offset, uint32_t value) {
   MmioWrite32(value, (MMIO_PTR uint32_t*)(dev->regs_vaddr + offset));
   return hiu_clk_get_reg(dev, offset);
 }

 static inline uint32_t hiu_get_pll_offs(aml_pll_dev_t* pll_dev) {
   switch (pll_dev->pll_num) {
     case GP0_PLL:
       return HHI_GP0_PLL_CNTL0;
     case PCIE_PLL:
       return HHI_PCIE_PLL_CNTL0;
     case HIFI_PLL:
       return HHI_HIFI_PLL_CNTL0;
     case SYS_PLL:
       return HHI_SYS_PLL_CNTL0;
     case SYS1_PLL:
       return HHI_SYS1_PLL_CNTL0;
     default:
       ZX_DEBUG_ASSERT(0);
   }
   return 0;
 }

 zx_status_t s905d2_hiu_init(aml_hiu_dev_t* device) {
   // Please do not use get_root_resource() in new code. See fxbug.dev/31358.
   zx_handle_t resource = get_root_resource();
   zx_status_t status;

   status = mmio_buffer_init_physical(&device->mmio, S905D2_HIU_BASE, S905D2_HIU_LENGTH, resource,
                                      ZX_CACHE_POLICY_UNCACHED_DEVICE);
   if (status != ZX_OK) {
     zxlogf(ERROR, "%s: mmio_buffer_init_physical failed %d", __func__, status);
     return status;
   }
   device->regs_vaddr = device->mmio.vaddr;

   return ZX_OK;
 }

 zx_status_t s905d2_hiu_init_etc(aml_hiu_dev_t* device, MMIO_PTR uint8_t* hiubase) {
   memset(device, 0, sizeof(*device));

   device->mmio.vmo = ZX_HANDLE_INVALID;

   device->regs_vaddr = hiubase;

   return ZX_OK;
 }

 static zx_status_t s905d2_pll_init_regs(aml_pll_dev_t* pll_dev) {
   aml_hiu_dev_t* device = pll_dev->hiu;

   if (pll_dev->pll_num == HIFI_PLL) {
     // write config values
     hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL1, G12A_HIFI_PLL_CNTL1);
     hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL2, G12A_HIFI_PLL_CNTL2);
     hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL3, G12A_HIFI_PLL_CNTL3);
     hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL4, G12A_HIFI_PLL_CNTL4);
     hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL5, G12A_HIFI_PLL_CNTL5);
     hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL6, G12A_HIFI_PLL_CNTL6);
     zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
     return ZX_OK;
   } else if (pll_dev->pll_num == SYS_PLL) {
     // write config values
     hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL1, G12A_SYS_PLL_CNTL1);
     hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL2, G12A_SYS_PLL_CNTL2);
     hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL3, G12A_SYS_PLL_CNTL3);
     hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL4, G12A_SYS_PLL_CNTL4);
     hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL5, G12A_SYS_PLL_CNTL5);
     hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL6, G12A_SYS_PLL_CNTL6);
     zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
     return ZX_OK;
   } else if (pll_dev->pll_num == SYS1_PLL) {
     // write config values
     hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL1, G12A_SYS1_PLL_CNTL1);
     hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL2, G12A_SYS1_PLL_CNTL2);
     hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL3, G12A_SYS1_PLL_CNTL3);
     hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL4, G12A_SYS1_PLL_CNTL4);
     hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL5, G12A_SYS1_PLL_CNTL5);
     hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL6, G12A_SYS1_PLL_CNTL6);
     zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
     return ZX_OK;
   } else if (pll_dev->pll_num == GP0_PLL) {
     // write config values
     hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL1, G12A_GP0_PLL_CNTL1);
     hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL2, G12A_GP0_PLL_CNTL2);
     hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL3, G12A_GP0_PLL_CNTL3);
     hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL4, G12A_GP0_PLL_CNTL4);
     hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL5, G12A_GP0_PLL_CNTL5);
     hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL6, G12A_GP0_PLL_CNTL6);
     zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
     return ZX_OK;
   }
   return ZX_ERR_NOT_SUPPORTED;
 }

 void s905d2_pll_init_etc(aml_hiu_dev_t* device, aml_pll_dev_t* pll_dev, hhi_plls_t pll_num) {
   ZX_DEBUG_ASSERT(device);
   ZX_DEBUG_ASSERT(pll_dev);

   pll_dev->hiu = device;

   pll_dev->rate_table = s905d2_pll_get_rate_table(pll_num);
   pll_dev->rate_idx = 0;
   pll_dev->frequency = 0;
   pll_dev->pll_num = pll_num;
   pll_dev->rate_count = s905d2_get_rate_table_count(pll_num);

   ZX_DEBUG_ASSERT(pll_dev->rate_table);
   ZX_DEBUG_ASSERT(pll_dev->rate_count);
 }

 zx_status_t s905d2_pll_init(aml_hiu_dev_t* device, aml_pll_dev_t* pll_dev, hhi_plls_t pll_num) {
   ZX_DEBUG_ASSERT(device);
   ZX_DEBUG_ASSERT(pll_dev);

   s905d2_pll_init_etc(device, pll_dev, pll_num);

   // Disable and reset the pll
   s905d2_pll_disable(pll_dev);
   // Write configuration registers
   return s905d2_pll_init_regs(pll_dev);
 }

 bool s905d2_pll_disable(aml_pll_dev_t* pll_dev) {
   uint32_t offs = hiu_get_pll_offs(pll_dev);
   uint32_t ctl0 = hiu_clk_get_reg(pll_dev->hiu, offs);

   bool retval = ctl0 & HHI_PLL_CNTL0_EN;

   ctl0 = (ctl0 & ~HHI_PLL_CNTL0_EN) | HHI_PLL_CNTL0_RESET;
   hiu_clk_set_reg(pll_dev->hiu, offs, ctl0);

   return retval;
 }

 zx_status_t s905d2_pll_ena(aml_pll_dev_t* pll_dev) {
   ZX_DEBUG_ASSERT(pll_dev);

   uint32_t offs = hiu_get_pll_offs(pll_dev);
   uint32_t reg_val = hiu_clk_get_reg(pll_dev->hiu, offs);

   // Set Enable bit
   reg_val |= HHI_PLL_CNTL0_EN;
   hiu_clk_set_reg(pll_dev->hiu, offs, reg_val);
   zx_nanosleep(zx_deadline_after(ZX_USEC(50)));

   // Clear Reset bit
   reg_val &= ~HHI_PLL_CNTL0_RESET;
   hiu_clk_set_reg(pll_dev->hiu, offs, reg_val);

   uint32_t wait_count = 100;
   while (wait_count) {
     if (hiu_clk_get_reg(pll_dev->hiu, offs) & HHI_PLL_LOCK) {
       return ZX_OK;
     }
     zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
     wait_count--;
   }

   return ZX_ERR_TIMED_OUT;
 }

 /* Notes:
     -VCO needs to be between 3-6GHz per the datasheet. It appears that if you
     provide values which would result in a VCO outside of this range, it will
     still oscillate, but at unknown (but likely close to target) frequency.
 */
 zx_status_t s905d2_pll_set_rate(aml_pll_dev_t* pll_dev, uint64_t freq) {
   ZX_DEBUG_ASSERT(pll_dev);

   const hhi_pll_rate_t* pll_rate;

   zx_status_t status = s905d2_pll_fetch_rate(pll_dev, freq, &pll_rate);
   if (status != ZX_OK) {
     return status;
   }
   // Disable/reset the pll, save previous state
   bool ena = s905d2_pll_disable(pll_dev);

   // Initialize the registers to defaults (may not be retained after reset)
   s905d2_pll_init_regs(pll_dev);

   uint32_t offs = hiu_get_pll_offs(pll_dev);
   uint32_t ctl0 = hiu_clk_get_reg(pll_dev->hiu, offs);

   ctl0 &= ~HHI_PLL_CNTL0_M;
   ctl0 |= pll_rate->m << HHI_PLL_CNTL0_M_SHIFT;

   ctl0 &= ~HHI_PLL_CNTL0_N;
   ctl0 |= pll_rate->n << HHI_PLL_CNTL0_N_SHIFT;

   ctl0 &= ~HHI_PLL_CNTL0_OD;
   ctl0 |= pll_rate->od << HHI_PLL_CNTL0_OD_SHIFT;

   hiu_clk_set_reg(pll_dev->hiu, offs, ctl0);

   hiu_clk_set_reg(pll_dev->hiu, offs + 4, pll_rate->frac);

   if (ena) {
     return s905d2_pll_ena(pll_dev);
   }

   return ZX_OK;
 }
	// Copyright 2018 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 <string.h>
	#include <zircon/assert.h>
	#include <zircon/syscalls.h>
	#include <zircon/types.h>

	#include <ddk/debug.h>
	#include <ddk/mmio-buffer.h>
	#include <hw/reg.h>
	#include <soc/aml-s905d2/s905d2-hiu-regs.h>
	#include <soc/aml-s905d2/s905d2-hiu.h>
	#include <soc/aml-s905d2/s905d2-hw.h>

	static inline uint32_t hiu_clk_get_reg(aml_hiu_dev_t* dev, uint32_t offset) {
	return MmioRead32((MMIO_PTR uint32_t*)(dev->regs_vaddr + offset));
	}

	static inline uint32_t hiu_clk_set_reg(aml_hiu_dev_t* dev, uint32_t offset, uint32_t value) {
	MmioWrite32(value, (MMIO_PTR uint32_t*)(dev->regs_vaddr + offset));
	return hiu_clk_get_reg(dev, offset);
	}

	static inline uint32_t hiu_get_pll_offs(aml_pll_dev_t* pll_dev) {
	switch (pll_dev->pll_num) {
	case GP0_PLL:
	return HHI_GP0_PLL_CNTL0;
	case PCIE_PLL:
	return HHI_PCIE_PLL_CNTL0;
	case HIFI_PLL:
	return HHI_HIFI_PLL_CNTL0;
	case SYS_PLL:
	return HHI_SYS_PLL_CNTL0;
	case SYS1_PLL:
	return HHI_SYS1_PLL_CNTL0;
	default:
	ZX_DEBUG_ASSERT(0);
	}
	return 0;
	}

	zx_status_t s905d2_hiu_init(aml_hiu_dev_t* device) {
	// Please do not use get_root_resource() in new code. See fxbug.dev/31358.
	zx_handle_t resource = get_root_resource();
	zx_status_t status;

	status = mmio_buffer_init_physical(&device->mmio, S905D2_HIU_BASE, S905D2_HIU_LENGTH, resource,
	ZX_CACHE_POLICY_UNCACHED_DEVICE);
	if (status != ZX_OK) {
	zxlogf(ERROR, "%s: mmio_buffer_init_physical failed %d", __func__, status);
	return status;
	}
	device->regs_vaddr = device->mmio.vaddr;

	return ZX_OK;
	}

	zx_status_t s905d2_hiu_init_etc(aml_hiu_dev_t* device, MMIO_PTR uint8_t* hiubase) {
	memset(device, 0, sizeof(*device));

	device->mmio.vmo = ZX_HANDLE_INVALID;

	device->regs_vaddr = hiubase;

	return ZX_OK;
	}

	static zx_status_t s905d2_pll_init_regs(aml_pll_dev_t* pll_dev) {
	aml_hiu_dev_t* device = pll_dev->hiu;

	if (pll_dev->pll_num == HIFI_PLL) {
	// write config values
	hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL1, G12A_HIFI_PLL_CNTL1);
	hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL2, G12A_HIFI_PLL_CNTL2);
	hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL3, G12A_HIFI_PLL_CNTL3);
	hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL4, G12A_HIFI_PLL_CNTL4);
	hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL5, G12A_HIFI_PLL_CNTL5);
	hiu_clk_set_reg(device, HHI_HIFI_PLL_CNTL6, G12A_HIFI_PLL_CNTL6);
	zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
	return ZX_OK;
	} else if (pll_dev->pll_num == SYS_PLL) {
	// write config values
	hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL1, G12A_SYS_PLL_CNTL1);
	hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL2, G12A_SYS_PLL_CNTL2);
	hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL3, G12A_SYS_PLL_CNTL3);
	hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL4, G12A_SYS_PLL_CNTL4);
	hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL5, G12A_SYS_PLL_CNTL5);
	hiu_clk_set_reg(device, HHI_SYS_PLL_CNTL6, G12A_SYS_PLL_CNTL6);
	zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
	return ZX_OK;
	} else if (pll_dev->pll_num == SYS1_PLL) {
	// write config values
	hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL1, G12A_SYS1_PLL_CNTL1);
	hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL2, G12A_SYS1_PLL_CNTL2);
	hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL3, G12A_SYS1_PLL_CNTL3);
	hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL4, G12A_SYS1_PLL_CNTL4);
	hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL5, G12A_SYS1_PLL_CNTL5);
	hiu_clk_set_reg(device, HHI_SYS1_PLL_CNTL6, G12A_SYS1_PLL_CNTL6);
	zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
	return ZX_OK;
	} else if (pll_dev->pll_num == GP0_PLL) {
	// write config values
	hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL1, G12A_GP0_PLL_CNTL1);
	hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL2, G12A_GP0_PLL_CNTL2);
	hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL3, G12A_GP0_PLL_CNTL3);
	hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL4, G12A_GP0_PLL_CNTL4);
	hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL5, G12A_GP0_PLL_CNTL5);
	hiu_clk_set_reg(device, HHI_GP0_PLL_CNTL6, G12A_GP0_PLL_CNTL6);
	zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
	return ZX_OK;
	}
	return ZX_ERR_NOT_SUPPORTED;
	}

	void s905d2_pll_init_etc(aml_hiu_dev_t* device, aml_pll_dev_t* pll_dev, hhi_plls_t pll_num) {
	ZX_DEBUG_ASSERT(device);
	ZX_DEBUG_ASSERT(pll_dev);

	pll_dev->hiu = device;

	pll_dev->rate_table = s905d2_pll_get_rate_table(pll_num);
	pll_dev->rate_idx = 0;
	pll_dev->frequency = 0;
	pll_dev->pll_num = pll_num;
	pll_dev->rate_count = s905d2_get_rate_table_count(pll_num);

	ZX_DEBUG_ASSERT(pll_dev->rate_table);
	ZX_DEBUG_ASSERT(pll_dev->rate_count);
	}

	zx_status_t s905d2_pll_init(aml_hiu_dev_t* device, aml_pll_dev_t* pll_dev, hhi_plls_t pll_num) {
	ZX_DEBUG_ASSERT(device);
	ZX_DEBUG_ASSERT(pll_dev);

	s905d2_pll_init_etc(device, pll_dev, pll_num);

	// Disable and reset the pll
	s905d2_pll_disable(pll_dev);
	// Write configuration registers
	return s905d2_pll_init_regs(pll_dev);
	}

	bool s905d2_pll_disable(aml_pll_dev_t* pll_dev) {
	uint32_t offs = hiu_get_pll_offs(pll_dev);
	uint32_t ctl0 = hiu_clk_get_reg(pll_dev->hiu, offs);

	bool retval = ctl0 & HHI_PLL_CNTL0_EN;

	ctl0 = (ctl0 & ~HHI_PLL_CNTL0_EN) \| HHI_PLL_CNTL0_RESET;
	hiu_clk_set_reg(pll_dev->hiu, offs, ctl0);

	return retval;
	}

	zx_status_t s905d2_pll_ena(aml_pll_dev_t* pll_dev) {
	ZX_DEBUG_ASSERT(pll_dev);

	uint32_t offs = hiu_get_pll_offs(pll_dev);
	uint32_t reg_val = hiu_clk_get_reg(pll_dev->hiu, offs);

	// Set Enable bit
	reg_val \|= HHI_PLL_CNTL0_EN;
	hiu_clk_set_reg(pll_dev->hiu, offs, reg_val);
	zx_nanosleep(zx_deadline_after(ZX_USEC(50)));

	// Clear Reset bit
	reg_val &= ~HHI_PLL_CNTL0_RESET;
	hiu_clk_set_reg(pll_dev->hiu, offs, reg_val);

	uint32_t wait_count = 100;
	while (wait_count) {
	if (hiu_clk_get_reg(pll_dev->hiu, offs) & HHI_PLL_LOCK) {
	return ZX_OK;
	}
	zx_nanosleep(zx_deadline_after(ZX_USEC(10)));
	wait_count--;
	}

	return ZX_ERR_TIMED_OUT;
	}

	/* Notes:
	-VCO needs to be between 3-6GHz per the datasheet. It appears that if you
	provide values which would result in a VCO outside of this range, it will
	still oscillate, but at unknown (but likely close to target) frequency.
	*/
	zx_status_t s905d2_pll_set_rate(aml_pll_dev_t* pll_dev, uint64_t freq) {
	ZX_DEBUG_ASSERT(pll_dev);

	const hhi_pll_rate_t* pll_rate;

	zx_status_t status = s905d2_pll_fetch_rate(pll_dev, freq, &pll_rate);
	if (status != ZX_OK) {
	return status;
	}
	// Disable/reset the pll, save previous state
	bool ena = s905d2_pll_disable(pll_dev);

	// Initialize the registers to defaults (may not be retained after reset)
	s905d2_pll_init_regs(pll_dev);

	uint32_t offs = hiu_get_pll_offs(pll_dev);
	uint32_t ctl0 = hiu_clk_get_reg(pll_dev->hiu, offs);

	ctl0 &= ~HHI_PLL_CNTL0_M;
	ctl0 \|= pll_rate->m << HHI_PLL_CNTL0_M_SHIFT;

	ctl0 &= ~HHI_PLL_CNTL0_N;
	ctl0 \|= pll_rate->n << HHI_PLL_CNTL0_N_SHIFT;

	ctl0 &= ~HHI_PLL_CNTL0_OD;
	ctl0 \|= pll_rate->od << HHI_PLL_CNTL0_OD_SHIFT;

	hiu_clk_set_reg(pll_dev->hiu, offs, ctl0);

	hiu_clk_set_reg(pll_dev->hiu, offs + 4, pll_rate->frac);

	if (ena) {
	return s905d2_pll_ena(pll_dev);
	}

	return ZX_OK;
	}