src/soc/intel/common/block/include/intelblocks/pcie_rp.h - coreboot - Gitiles

 /* SPDX-License-Identifier: GPL-2.0-only */

 #ifndef SOC_INTEL_COMMON_BLOCK_PCIE_RP_H
 #define SOC_INTEL_COMMON_BLOCK_PCIE_RP_H

 #include <stdint.h>

 /*
  * In schematic PCIe root port numbers are 1-based, but FSP use 0-based indexes for
  * the configuration arrays and so this macro subtracts 1 to convert RP# to array index.
  */
 #define PCIE_RP(x)      ((x) - 1)
 #define PCH_RP(x)       PCIE_RP(x)
 #define CPU_RP(x)       PCIE_RP(x)

 enum pcie_rp_flags {
 	PCIE_RP_HOTPLUG = (1 << 0),
 	/* PCIE RP Latency Tolerance Report */
 	PCIE_RP_LTR = (1 << 1),
 	/* PCIE RP Advanced Error Report */
 	PCIE_RP_AER = (1 << 2),
 	/* Clock source is not used by the root port. */
 	PCIE_RP_CLK_SRC_UNUSED = (1 << 3),
 	/*
 	 * Clock request signal requires probing before enabling CLKREQ# based power
 	 * management.
 	 */
 	PCIE_RP_CLK_REQ_DETECT = (1 << 4),
 	/* Clock request signal is not used by the root port. */
 	PCIE_RP_CLK_REQ_UNUSED = (1 << 5),
 	/* indicates that this root port is built-in. */
 	PCIE_RP_BUILT_IN = (1 << 6),
 };

 enum pcie_clk_src_flags {
 	PCIE_CLK_FREE_RUNNING = (1 << 0),
 	PCIE_CLK_LAN = (1 << 1),
 };

 /* This enum is for passing into an FSP UPD, typically PcieRpL1Substates */
 enum L1_substates_control {
 	L1_SS_FSP_DEFAULT,
 	L1_SS_DISABLED,
 	L1_SS_L1_1,
 	L1_SS_L1_2,
 };

 /* This enum is for passing into an FSP UPD, typically ASPM */
 enum ASPM_control {
 	ASPM_DEFAULT,
 	ASPM_DISABLE,
 	ASPM_L0S,
 	ASPM_L1,
 	ASPM_L0S_L1,
 	ASPM_AUTO,
 };

 /* PCIe Root Ports */
 struct pcie_rp_config {
 	/* CLKOUT_PCIE_P/N# used by this root port as per schematics. */
 	uint8_t clk_src;
 	/* SRCCLKREQ# used by this root port as per schematics. */
 	uint8_t clk_req;
 	enum pcie_rp_flags flags;
 	/* PCIe RP L1 substate */
 	enum L1_substates_control PcieRpL1Substates;
 	/* PCIe RP ASPM */
 	enum ASPM_control pcie_rp_aspm;
 	/* timeout for device detect */
 	uint32_t pcie_rp_detect_timeout_ms;
 };

 /*
  * The PCIe Root Ports usually come in groups of up to 8 PCI-device
  * functions.
  *
  * `slot` is the PCI device/slot number of such a group.
  * `start` is the initial PCI function number within the group. This is useful
  * in case the root port numbers are not contiguous within the slot.
  * `count` is the number of functions within the group starting with the `start`
  * function number.
  * `lcap_port_base` is the starting index of physical port as described in LCAP
  * register in PCIe config space. coreboot always uses 0 based indexing while
  * referring to the PCIe port but LCAP registers uses 1-based indexing in
  * most of the cases. Remapping logic needs to correctly map LCAP port number
  * (1-based or n-based) to coreboot indexing (0-based).
  */
 struct pcie_rp_group {
 	unsigned int slot;
 	unsigned int start;
 	unsigned int count;
 	unsigned int lcap_port_base;
 };

 static inline unsigned int rp_start_fn(const struct pcie_rp_group *group)
 {
 	return group->start;
 }

 static inline unsigned int rp_end_fn(const struct pcie_rp_group *group)
 {
 	return group->start + group->count - 1;
 }

 /*
  * Update PCI paths of the root ports in the devicetree.
  *
  * Depending on the board layout and physical presence of downstream
  * devices, individual root-port functions can be hidden and reordered.
  * If we have device nodes for root ports in the static `devicetree.cb`,
  * we need to update their PCI paths, so the nodes still control the
  * correct root port. Device nodes for disabled root ports will be
  * unlinked from the bus, to not interfere with PCI enumeration.
  *
  * Call this once, after root ports have been reordered, but before PCI
  * enumeration.
  *
  * `groups` points to a list of groups terminated by an entry with `count == 0`.
  * It is assumed that the first group includes the RPs 1 to the first group's
  * `count` and that adjacent groups follow without gaps in the numbering.
  */
 void pcie_rp_update_devicetree(const struct pcie_rp_group *groups);

 /*
  * Return mask of PCIe root ports that are enabled by mainboard. Mask is set in
  * the same order as the root ports in pcie_rp_group groups table.
  *
  * Thus, the status of first root port in the groups table is indicated by bit 0
  * in the returned mask, second root port by bit 1 and so on.

  * 1 in the bit position indicates root port is enabled, whereas 0 indicates root
  * port is disabled. This function assumes that the maximum count of root ports
  * in the groups table is <= 32.
  */
 uint32_t pcie_rp_enable_mask(const struct pcie_rp_group *groups);

 /* Get PCH root port groups */
 const struct pcie_rp_group *soc_get_pch_rp_groups(void);

 enum pcie_rp_type {
 	PCIE_RP_UNKNOWN,
 	PCIE_RP_CPU,
 	PCIE_RP_PCH,
 };

 /* For PCIe RTD3 support, each SoC that uses it must implement this function. */
 struct device; /* Not necessary to include all of device/device.h */
 enum pcie_rp_type soc_get_pcie_rp_type(const struct device *dev);

 /* Return the virtual wire index that represents CPU-side PCIe root ports */
 int soc_get_cpu_rp_vw_idx(const struct device *dev);

 #endif /* SOC_INTEL_COMMON_BLOCK_PCIE_RP_H */
	/* SPDX-License-Identifier: GPL-2.0-only */

	#ifndef SOC_INTEL_COMMON_BLOCK_PCIE_RP_H
	#define SOC_INTEL_COMMON_BLOCK_PCIE_RP_H

	#include <stdint.h>

	/*
	* In schematic PCIe root port numbers are 1-based, but FSP use 0-based indexes for
	* the configuration arrays and so this macro subtracts 1 to convert RP# to array index.
	*/
	#define PCIE_RP(x) ((x) - 1)
	#define PCH_RP(x) PCIE_RP(x)
	#define CPU_RP(x) PCIE_RP(x)

	enum pcie_rp_flags {
	PCIE_RP_HOTPLUG = (1 << 0),
	/* PCIE RP Latency Tolerance Report */
	PCIE_RP_LTR = (1 << 1),
	/* PCIE RP Advanced Error Report */
	PCIE_RP_AER = (1 << 2),
	/* Clock source is not used by the root port. */
	PCIE_RP_CLK_SRC_UNUSED = (1 << 3),
	/*
	* Clock request signal requires probing before enabling CLKREQ# based power
	* management.
	*/
	PCIE_RP_CLK_REQ_DETECT = (1 << 4),
	/* Clock request signal is not used by the root port. */
	PCIE_RP_CLK_REQ_UNUSED = (1 << 5),
	/* indicates that this root port is built-in. */
	PCIE_RP_BUILT_IN = (1 << 6),
	};

	enum pcie_clk_src_flags {
	PCIE_CLK_FREE_RUNNING = (1 << 0),
	PCIE_CLK_LAN = (1 << 1),
	};

	/* This enum is for passing into an FSP UPD, typically PcieRpL1Substates */
	enum L1_substates_control {
	L1_SS_FSP_DEFAULT,
	L1_SS_DISABLED,
	L1_SS_L1_1,
	L1_SS_L1_2,
	};

	/* This enum is for passing into an FSP UPD, typically ASPM */
	enum ASPM_control {
	ASPM_DEFAULT,
	ASPM_DISABLE,
	ASPM_L0S,
	ASPM_L1,
	ASPM_L0S_L1,
	ASPM_AUTO,
	};

	/* PCIe Root Ports */
	struct pcie_rp_config {
	/* CLKOUT_PCIE_P/N# used by this root port as per schematics. */
	uint8_t clk_src;
	/* SRCCLKREQ# used by this root port as per schematics. */
	uint8_t clk_req;
	enum pcie_rp_flags flags;
	/* PCIe RP L1 substate */
	enum L1_substates_control PcieRpL1Substates;
	/* PCIe RP ASPM */
	enum ASPM_control pcie_rp_aspm;
	/* timeout for device detect */
	uint32_t pcie_rp_detect_timeout_ms;
	};

	/*
	* The PCIe Root Ports usually come in groups of up to 8 PCI-device
	* functions.
	*
	* `slot` is the PCI device/slot number of such a group.
	* `start` is the initial PCI function number within the group. This is useful
	* in case the root port numbers are not contiguous within the slot.
	* `count` is the number of functions within the group starting with the `start`
	* function number.
	* `lcap_port_base` is the starting index of physical port as described in LCAP
	* register in PCIe config space. coreboot always uses 0 based indexing while
	* referring to the PCIe port but LCAP registers uses 1-based indexing in
	* most of the cases. Remapping logic needs to correctly map LCAP port number
	* (1-based or n-based) to coreboot indexing (0-based).
	*/
	struct pcie_rp_group {
	unsigned int slot;
	unsigned int start;
	unsigned int count;
	unsigned int lcap_port_base;
	};

	static inline unsigned int rp_start_fn(const struct pcie_rp_group *group)
	{
	return group->start;
	}

	static inline unsigned int rp_end_fn(const struct pcie_rp_group *group)
	{
	return group->start + group->count - 1;
	}

	/*
	* Update PCI paths of the root ports in the devicetree.
	*
	* Depending on the board layout and physical presence of downstream
	* devices, individual root-port functions can be hidden and reordered.
	* If we have device nodes for root ports in the static `devicetree.cb`,
	* we need to update their PCI paths, so the nodes still control the
	* correct root port. Device nodes for disabled root ports will be
	* unlinked from the bus, to not interfere with PCI enumeration.
	*
	* Call this once, after root ports have been reordered, but before PCI
	* enumeration.
	*
	* `groups` points to a list of groups terminated by an entry with `count == 0`.
	* It is assumed that the first group includes the RPs 1 to the first group's
	* `count` and that adjacent groups follow without gaps in the numbering.
	*/
	void pcie_rp_update_devicetree(const struct pcie_rp_group *groups);

	/*
	* Return mask of PCIe root ports that are enabled by mainboard. Mask is set in
	* the same order as the root ports in pcie_rp_group groups table.
	*
	* Thus, the status of first root port in the groups table is indicated by bit 0
	* in the returned mask, second root port by bit 1 and so on.

	* 1 in the bit position indicates root port is enabled, whereas 0 indicates root
	* port is disabled. This function assumes that the maximum count of root ports
	* in the groups table is <= 32.
	*/
	uint32_t pcie_rp_enable_mask(const struct pcie_rp_group *groups);

	/* Get PCH root port groups */
	const struct pcie_rp_group *soc_get_pch_rp_groups(void);

	enum pcie_rp_type {
	PCIE_RP_UNKNOWN,
	PCIE_RP_CPU,
	PCIE_RP_PCH,
	};

	/* For PCIe RTD3 support, each SoC that uses it must implement this function. */
	struct device; /* Not necessary to include all of device/device.h */
	enum pcie_rp_type soc_get_pcie_rp_type(const struct device *dev);

	/* Return the virtual wire index that represents CPU-side PCIe root ports */
	int soc_get_cpu_rp_vw_idx(const struct device *dev);

	#endif /* SOC_INTEL_COMMON_BLOCK_PCIE_RP_H */