#ifndef DEVICE_PNP_H #define DEVICE_PNP_H #include #include /* When is needed, it supposed to provide */ #include #include #include #if !ENV_PNP_SIMPLE_DEVICE /* Primitive PNP resource manipulation */ void pnp_write_config(struct device *dev, u8 reg, u8 value); u8 pnp_read_config(struct device *dev, u8 reg); void pnp_unset_and_set_config(struct device *dev, u8 reg, u8 unset, u8 set); void pnp_set_logical_device(struct device *dev); void pnp_set_enable(struct device *dev, int enable); int pnp_read_enable(struct device *dev); void pnp_set_iobase(struct device *dev, u8 index, u16 iobase); void pnp_set_irq(struct device *dev, u8 index, u8 irq); void pnp_set_drq(struct device *dev, u8 index, u8 drq); #endif /* PNP device operations */ void pnp_read_resources(struct device *dev); void pnp_set_resources(struct device *dev); void pnp_enable_resources(struct device *dev); void pnp_enable(struct device *dev); void pnp_alt_enable(struct device *dev); extern struct device_operations pnp_ops; /* PNP helper operations */ struct pnp_info { struct device_operations *ops; /* LDN-specific ops override */ #define PNP_SKIP_FUNCTION 0xffff u16 function; /* Must be at least 16 bits (virtual LDNs)! */ unsigned int flags; #define PNP_IO0 0x0000001 #define PNP_IO1 0x0000002 #define PNP_IO2 0x0000004 #define PNP_IO3 0x0000008 #define PNP_IO4 0x0000010 #define PNP_IRQ0 0x0000020 #define PNP_IRQ1 0x0000040 #define PNP_DRQ0 0x0000080 #define PNP_DRQ1 0x0000100 #define PNP_EN 0x0000200 #define PNP_MSC0 0x0000400 #define PNP_MSC1 0x0000800 #define PNP_MSC2 0x0001000 #define PNP_MSC3 0x0002000 #define PNP_MSC4 0x0004000 #define PNP_MSC5 0x0008000 #define PNP_MSC6 0x0010000 #define PNP_MSC7 0x0020000 #define PNP_MSC8 0x0040000 #define PNP_MSC9 0x0080000 #define PNP_MSCA 0x0100000 #define PNP_MSCB 0x0200000 #define PNP_MSCC 0x0400000 #define PNP_MSCD 0x0800000 #define PNP_MSCE 0x1000000 u16 io0, io1, io2, io3, io4; }; struct resource *pnp_get_resource(struct device *dev, unsigned int index); void pnp_enable_devices(struct device *dev, struct device_operations *ops, unsigned int functions, struct pnp_info *info); struct pnp_mode_ops { void (*enter_conf_mode)(struct device *dev); void (*exit_conf_mode)(struct device *dev); #if CONFIG(HAVE_ACPI_TABLES) /* * Generates ASL code to enter/exit config mode. * * @param idx The ACPI name of the SuperIO index port register. eg. 'INDX'. * @param data The ACPI name of the SuperIO data port register. eg. 'DATA'. */ void (*ssdt_enter_conf_mode)(struct device *dev, const char *idx, const char *data); void (*ssdt_exit_conf_mode)(struct device *dev, const char *idx, const char *data); #endif }; void pnp_enter_conf_mode(struct device *dev); void pnp_exit_conf_mode(struct device *dev); #if CONFIG(HAVE_ACPI_TABLES) /* * Generates ASL code to enter/exit config mode if supported. * The calling code has to place this within an ASL MethodOP. * * @param idx The ACPI name of the SuperIO index port register. eg. 'INDX'. * @param data The ACPI name of the SuperIO data port register. eg. 'DATA'. */ void pnp_ssdt_enter_conf_mode(struct device *dev, const char *idx, const char *data); void pnp_ssdt_exit_conf_mode(struct device *dev, const char *idx, const char *data); #endif /* PNP indexed I/O operations */ /* * u8 pnp_read_index(u16 port, u8 reg) * Description: * This routine reads indexed I/O registers. The reg byte is written * to the index register at I/O address = port. The result is then * read from the data register at I/O address = port + 1. * * Parameters: * @param[in] u16 port = The I/O address of the port index register. * @param[in] u8 reg = The offset within the indexed space. * @param[out] u8 result = The value read back from the data register. */ static inline u8 pnp_read_index(u16 port, u8 reg) { outb(reg, port); return inb(port + 1); } /* * void pnp_write_index(u16 port, u8 reg, u8 value) * Description: * This routine writes indexed I/O registers. The reg byte is written * to the index register at I/O address = port. The value byte is then * written to the data register at I/O address = port + 1. * * Parameters: * @param[in] u16 port = The address of the port index register. * @param[in] u8 reg = The offset within the indexed space. * @param[in] u8 value = The value to be written to the data register. */ static inline void pnp_write_index(u16 port, u8 reg, u8 value) { outb(reg, port); outb(value, port + 1); } /* * void pnp_unset_and_set_index(u16 port, u8 reg, u8 unset, u8 set) * Description: * This routine unsets and sets bits from indexed I/O registers. The * reg byte is written to the index register at I/O address = port. * The value byte to update is data register at I/O address = port + 1. * * Unlike and-then-or style operations, no bitwise negation is necessary * to specify the bits to unset. Because the bitwise negation implicitly * promotes operands to int before operating, one may have to explicitly * downcast the result if the data width is smaller than that of an int. * Since warnings are errors in coreboot, explicit casting is necessary. * * Performing said negation inside this routine alleviates this problem, * while allowing the compiler to warn if the input parameters overflow. * Casting outside this function would silence valid compiler warnings. * * Parameters: * @param[in] u16 port = The address of the port index register. * @param[in] u8 reg = The offset within the indexed space. * @param[in] u8 unset = Bitmask with ones to the bits to unset from the data register. * @param[in] u8 set = Bitmask with ones to the bits to set from the data register. */ static inline void pnp_unset_and_set_index(u16 port, u8 reg, u8 unset, u8 set) { outb(reg, port); u8 value = inb(port + 1); value &= (u8)~unset; value |= set; outb(value, port + 1); } #endif /* DEVICE_PNP_H */