src/soc/sifive/fu540/ux00ddr.h - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /* SPDX-License-Identifier: Apache-2.0 */
 /* SPDX-License-Identifier: GPL-2.0-or-later */
 /* See the file LICENSE for further information */

 #ifndef _SIFIVE_UX00DDR_H
 #define _SIFIVE_UX00DDR_H

 #ifndef __ASSEMBLER__

 #include <stdint.h>
 #include <stddef.h>

 #define _REG32(p, i) (*(volatile uint32_t *)((p) + (i)))

 #define DRAM_CLASS_OFFSET                   8
 #define DRAM_CLASS_DDR4                     0xA
 #define OPTIMAL_RMODW_EN_OFFSET             0
 #define DISABLE_RD_INTERLEAVE_OFFSET        16
 #define OUT_OF_RANGE_OFFSET                 1
 #define MULTIPLE_OUT_OF_RANGE_OFFSET        2
 #define PORT_COMMAND_CHANNEL_ERROR_OFFSET   7
 #define MC_INIT_COMPLETE_OFFSET             8
 #define LEVELING_OPERATION_COMPLETED_OFFSET 22
 #define DFI_PHY_WRLELV_MODE_OFFSET          24
 #define DFI_PHY_RDLVL_MODE_OFFSET           24
 #define DFI_PHY_RDLVL_GATE_MODE_OFFSET      0
 #define VREF_EN_OFFSET                      24
 #define PORT_ADDR_PROTECTION_EN_OFFSET      0
 #define AXI0_ADDRESS_RANGE_ENABLE           8
 #define AXI0_RANGE_PROT_BITS_0_OFFSET       24
 #define RDLVL_EN_OFFSET                     16
 #define RDLVL_GATE_EN_OFFSET                24
 #define WRLVL_EN_OFFSET                     0

 #define PHY_RX_CAL_DQ0_0_OFFSET             0
 #define PHY_RX_CAL_DQ1_0_OFFSET             16

 static inline void phy_reset(volatile uint32_t *ddrphyreg, const uint32_t *physettings) {
   unsigned int i;
   for (i=1152;i<=1214;i++) {
     uint32_t physet = physettings[i];
     /*if (physet!=0)*/ ddrphyreg[i] = physet;
   }
   for (i=0;i<=1151;i++) {
     uint32_t physet = physettings[i];
     /*if (physet!=0)*/ ddrphyreg[i] = physet;
   }
 }

 static inline void ux00ddr_writeregmap(size_t ahbregaddr, const uint32_t *ctlsettings, const uint32_t *physettings) {
   volatile uint32_t *ddrctlreg = (volatile uint32_t *)ahbregaddr;
   volatile uint32_t *ddrphyreg = ((volatile uint32_t *)ahbregaddr) + (0x2000 / sizeof(uint32_t));

   unsigned int i;
   for (i=0;i<=264;i++) {
     uint32_t ctlset = ctlsettings[i];
     /*if (ctlset!=0)*/ ddrctlreg[i] = ctlset;
   }

   phy_reset(ddrphyreg, physettings);
 }

 static inline void ux00ddr_start(size_t ahbregaddr, size_t filteraddr, size_t ddrend) {
   // START register at ddrctl register base offset 0
   uint32_t regdata = _REG32(0<<2, ahbregaddr);
   regdata |= 0x1;
   _REG32(0<<2, ahbregaddr) = regdata;
   // WAIT for initialization complete : bit 8 of INT_STATUS (DENALI_CTL_132) 0x210
   while ((_REG32(132<<2, ahbregaddr) & (1<<MC_INIT_COMPLETE_OFFSET)) == 0) {}

   // Disable the BusBlocker in front of the controller AXI slave ports
   volatile uint64_t *filterreg = (volatile uint64_t *)filteraddr;
   filterreg[0] = 0x0f00000000000000UL | (ddrend >> 2);
   //                ^^ RWX + TOR
 }

 static inline void ux00ddr_mask_mc_init_complete_interrupt(size_t ahbregaddr) {
   // Mask off Bit 8 of Interrupt Status
   // Bit [8] The MC initialization has been completed
   _REG32(136<<2, ahbregaddr) |= (1<<MC_INIT_COMPLETE_OFFSET);
 }

 static inline void ux00ddr_mask_outofrange_interrupts(size_t ahbregaddr) {
   // Mask off Bit 8, Bit 2 and Bit 1 of Interrupt Status
   // Bit [2] Multiple accesses outside the defined PHYSICAL memory space have occurred
   // Bit [1] A memory access outside the defined PHYSICAL memory space has occurred
   _REG32(136<<2, ahbregaddr) |= ((1<<OUT_OF_RANGE_OFFSET) | (1<<MULTIPLE_OUT_OF_RANGE_OFFSET));
 }

 static inline void ux00ddr_mask_port_command_error_interrupt(size_t ahbregaddr) {
   // Mask off Bit 7 of Interrupt Status
   // Bit [7] An error occurred on the port command channel
   _REG32(136<<2, ahbregaddr) |= (1<<PORT_COMMAND_CHANNEL_ERROR_OFFSET);
 }

 static inline void ux00ddr_mask_leveling_completed_interrupt(size_t ahbregaddr) {
   // Mask off Bit 22 of Interrupt Status
   // Bit [22] The leveling operation has completed
   _REG32(136<<2, ahbregaddr) |= (1<<LEVELING_OPERATION_COMPLETED_OFFSET);
 }

 static inline void ux00ddr_setuprangeprotection(size_t ahbregaddr, size_t end_addr) {
   _REG32(209<<2, ahbregaddr) = 0x0;
   size_t end_addr_16Kblocks = ((end_addr >> 14) & 0x7FFFFF)-1;
   _REG32(210<<2, ahbregaddr) = ((uint32_t)end_addr_16Kblocks);
   _REG32(212<<2, ahbregaddr) = 0x0;
   _REG32(214<<2, ahbregaddr) = 0x0;
   _REG32(216<<2, ahbregaddr) = 0x0;
   _REG32(224<<2, ahbregaddr) |= (0x3 << AXI0_RANGE_PROT_BITS_0_OFFSET);
   _REG32(225<<2, ahbregaddr) = 0xFFFFFFFF;
   _REG32(208<<2, ahbregaddr) |= (1 << AXI0_ADDRESS_RANGE_ENABLE);
   _REG32(208<<2, ahbregaddr) |= (1 << PORT_ADDR_PROTECTION_EN_OFFSET);

 }

 static inline void ux00ddr_disableaxireadinterleave(size_t ahbregaddr) {
   _REG32(120<<2, ahbregaddr) |= (1<<DISABLE_RD_INTERLEAVE_OFFSET);
 }

 static inline void ux00ddr_disableoptimalrmodw(size_t ahbregaddr) {
   _REG32(21<<2, ahbregaddr) &= (~(1<<OPTIMAL_RMODW_EN_OFFSET));
 }

 static inline void ux00ddr_enablewriteleveling(size_t ahbregaddr) {
   _REG32(170<<2, ahbregaddr) |= ((1<<WRLVL_EN_OFFSET) | (1<<DFI_PHY_WRLELV_MODE_OFFSET));
 }

 static inline void ux00ddr_enablereadleveling(size_t ahbregaddr) {
   _REG32(181<<2, ahbregaddr) |= (1<<DFI_PHY_RDLVL_MODE_OFFSET);
   _REG32(260<<2, ahbregaddr) |= (1<<RDLVL_EN_OFFSET);
 }

 static inline void ux00ddr_enablereadlevelinggate(size_t ahbregaddr) {
   _REG32(260<<2, ahbregaddr) |= (1<<RDLVL_GATE_EN_OFFSET);
   _REG32(182<<2, ahbregaddr) |= (1<<DFI_PHY_RDLVL_GATE_MODE_OFFSET);
 }

 static inline void ux00ddr_enablevreftraining(size_t ahbregaddr) {
   _REG32(184<<2, ahbregaddr) |= (1<<VREF_EN_OFFSET);
 }

 static inline uint32_t ux00ddr_getdramclass(size_t ahbregaddr) {
   return ((_REG32(0, ahbregaddr) >> DRAM_CLASS_OFFSET) & 0xF);
 }

 static inline uint64_t ux00ddr_phy_fixup(size_t ahbregaddr) {
   // return bitmask of failed lanes

   size_t ddrphyreg = ahbregaddr + 0x2000;

   // uint64_t fails=0;
   uint32_t slicebase = 0;
   // uint32_t dq = 0;

   // check errata condition
   for (uint32_t slice = 0; slice < 8; slice++) {
     uint32_t regbase = slicebase + 34;
     for (uint32_t reg = 0 ; reg < 4; reg++) {
       uint32_t updownreg = _REG32((regbase+reg)<<2, ddrphyreg);
       for (uint32_t bit = 0; bit < 2; bit++) {
         uint32_t phy_rx_cal_dqn_0_offset;

         if (bit==0) {
           phy_rx_cal_dqn_0_offset = PHY_RX_CAL_DQ0_0_OFFSET;
         }else{
           phy_rx_cal_dqn_0_offset = PHY_RX_CAL_DQ1_0_OFFSET;
         }

         uint32_t down = (updownreg >> phy_rx_cal_dqn_0_offset) & 0x3F;
         uint32_t up = (updownreg >> (phy_rx_cal_dqn_0_offset+6)) & 0x3F;

         uint8_t failc0 = ((down == 0) && (up == 0x3F));
         uint8_t failc1 = ((up == 0) && (down == 0x3F));

         // print error message on failure
         if (failc0 || failc1) {
           //if (fails==0) uart_puts((void*) UART0_CTRL_ADDR, "DDR error in fixing up \n");
           //fails |= (1<<dq);
           /* char slicelsc = '0'; */
           /* char slicemsc = '0'; */
           /* slicelsc += (dq % 10); */
           /* slicemsc += (dq / 10); */
           //uart_puts((void*) UART0_CTRL_ADDR, "S ");
           //uart_puts((void*) UART0_CTRL_ADDR, &slicemsc);
           //uart_puts((void*) UART0_CTRL_ADDR, &slicelsc);
           //if (failc0) uart_puts((void*) UART0_CTRL_ADDR, "U");
           //else uart_puts((void*) UART0_CTRL_ADDR, "D");
           //uart_puts((void*) UART0_CTRL_ADDR, "\n");
         }
         //dq++;
       }
     }
     slicebase+=128;
   }
   return (0);
 }

 #endif

 #endif
	/* SPDX-License-Identifier: Apache-2.0 */
	/* SPDX-License-Identifier: GPL-2.0-or-later */
	/* See the file LICENSE for further information */

	#ifndef _SIFIVE_UX00DDR_H
	#define _SIFIVE_UX00DDR_H

	#ifndef __ASSEMBLER__

	#include <stdint.h>
	#include <stddef.h>

	#define _REG32(p, i) ((volatile uint32_t )((p) + (i)))

	#define DRAM_CLASS_OFFSET 8
	#define DRAM_CLASS_DDR4 0xA
	#define OPTIMAL_RMODW_EN_OFFSET 0
	#define DISABLE_RD_INTERLEAVE_OFFSET 16
	#define OUT_OF_RANGE_OFFSET 1
	#define MULTIPLE_OUT_OF_RANGE_OFFSET 2
	#define PORT_COMMAND_CHANNEL_ERROR_OFFSET 7
	#define MC_INIT_COMPLETE_OFFSET 8
	#define LEVELING_OPERATION_COMPLETED_OFFSET 22
	#define DFI_PHY_WRLELV_MODE_OFFSET 24
	#define DFI_PHY_RDLVL_MODE_OFFSET 24
	#define DFI_PHY_RDLVL_GATE_MODE_OFFSET 0
	#define VREF_EN_OFFSET 24
	#define PORT_ADDR_PROTECTION_EN_OFFSET 0
	#define AXI0_ADDRESS_RANGE_ENABLE 8
	#define AXI0_RANGE_PROT_BITS_0_OFFSET 24
	#define RDLVL_EN_OFFSET 16
	#define RDLVL_GATE_EN_OFFSET 24
	#define WRLVL_EN_OFFSET 0

	#define PHY_RX_CAL_DQ0_0_OFFSET 0
	#define PHY_RX_CAL_DQ1_0_OFFSET 16

	static inline void phy_reset(volatile uint32_t ddrphyreg, const uint32_t physettings) {
	unsigned int i;
	for (i=1152;i<=1214;i++) {
	uint32_t physet = physettings[i];
	/if (physet!=0)/ ddrphyreg[i] = physet;
	}
	for (i=0;i<=1151;i++) {
	uint32_t physet = physettings[i];
	/if (physet!=0)/ ddrphyreg[i] = physet;
	}
	}

	static inline void ux00ddr_writeregmap(size_t ahbregaddr, const uint32_t ctlsettings, const uint32_t physettings) {
	volatile uint32_t ddrctlreg = (volatile uint32_t )ahbregaddr;
	volatile uint32_t ddrphyreg = ((volatile uint32_t )ahbregaddr) + (0x2000 / sizeof(uint32_t));

	unsigned int i;
	for (i=0;i<=264;i++) {
	uint32_t ctlset = ctlsettings[i];
	/if (ctlset!=0)/ ddrctlreg[i] = ctlset;
	}

	phy_reset(ddrphyreg, physettings);
	}

	static inline void ux00ddr_start(size_t ahbregaddr, size_t filteraddr, size_t ddrend) {
	// START register at ddrctl register base offset 0
	uint32_t regdata = _REG32(0<<2, ahbregaddr);
	regdata \|= 0x1;
	_REG32(0<<2, ahbregaddr) = regdata;
	// WAIT for initialization complete : bit 8 of INT_STATUS (DENALI_CTL_132) 0x210
	while ((_REG32(132<<2, ahbregaddr) & (1<<MC_INIT_COMPLETE_OFFSET)) == 0) {}

	// Disable the BusBlocker in front of the controller AXI slave ports
	volatile uint64_t filterreg = (volatile uint64_t )filteraddr;
	filterreg[0] = 0x0f00000000000000UL \| (ddrend >> 2);
	// ^^ RWX + TOR
	}

	static inline void ux00ddr_mask_mc_init_complete_interrupt(size_t ahbregaddr) {
	// Mask off Bit 8 of Interrupt Status
	// Bit [8] The MC initialization has been completed
	_REG32(136<<2, ahbregaddr) \|= (1<<MC_INIT_COMPLETE_OFFSET);
	}

	static inline void ux00ddr_mask_outofrange_interrupts(size_t ahbregaddr) {
	// Mask off Bit 8, Bit 2 and Bit 1 of Interrupt Status
	// Bit [2] Multiple accesses outside the defined PHYSICAL memory space have occurred
	// Bit [1] A memory access outside the defined PHYSICAL memory space has occurred
	_REG32(136<<2, ahbregaddr) \|= ((1<<OUT_OF_RANGE_OFFSET) \| (1<<MULTIPLE_OUT_OF_RANGE_OFFSET));
	}

	static inline void ux00ddr_mask_port_command_error_interrupt(size_t ahbregaddr) {
	// Mask off Bit 7 of Interrupt Status
	// Bit [7] An error occurred on the port command channel
	_REG32(136<<2, ahbregaddr) \|= (1<<PORT_COMMAND_CHANNEL_ERROR_OFFSET);
	}

	static inline void ux00ddr_mask_leveling_completed_interrupt(size_t ahbregaddr) {
	// Mask off Bit 22 of Interrupt Status
	// Bit [22] The leveling operation has completed
	_REG32(136<<2, ahbregaddr) \|= (1<<LEVELING_OPERATION_COMPLETED_OFFSET);
	}

	static inline void ux00ddr_setuprangeprotection(size_t ahbregaddr, size_t end_addr) {
	_REG32(209<<2, ahbregaddr) = 0x0;
	size_t end_addr_16Kblocks = ((end_addr >> 14) & 0x7FFFFF)-1;
	_REG32(210<<2, ahbregaddr) = ((uint32_t)end_addr_16Kblocks);
	_REG32(212<<2, ahbregaddr) = 0x0;
	_REG32(214<<2, ahbregaddr) = 0x0;
	_REG32(216<<2, ahbregaddr) = 0x0;
	_REG32(224<<2, ahbregaddr) \|= (0x3 << AXI0_RANGE_PROT_BITS_0_OFFSET);
	_REG32(225<<2, ahbregaddr) = 0xFFFFFFFF;
	_REG32(208<<2, ahbregaddr) \|= (1 << AXI0_ADDRESS_RANGE_ENABLE);
	_REG32(208<<2, ahbregaddr) \|= (1 << PORT_ADDR_PROTECTION_EN_OFFSET);

	}

	static inline void ux00ddr_disableaxireadinterleave(size_t ahbregaddr) {
	_REG32(120<<2, ahbregaddr) \|= (1<<DISABLE_RD_INTERLEAVE_OFFSET);
	}

	static inline void ux00ddr_disableoptimalrmodw(size_t ahbregaddr) {
	_REG32(21<<2, ahbregaddr) &= (~(1<<OPTIMAL_RMODW_EN_OFFSET));
	}

	static inline void ux00ddr_enablewriteleveling(size_t ahbregaddr) {
	_REG32(170<<2, ahbregaddr) \|= ((1<<WRLVL_EN_OFFSET) \| (1<<DFI_PHY_WRLELV_MODE_OFFSET));
	}

	static inline void ux00ddr_enablereadleveling(size_t ahbregaddr) {
	_REG32(181<<2, ahbregaddr) \|= (1<<DFI_PHY_RDLVL_MODE_OFFSET);
	_REG32(260<<2, ahbregaddr) \|= (1<<RDLVL_EN_OFFSET);
	}

	static inline void ux00ddr_enablereadlevelinggate(size_t ahbregaddr) {
	_REG32(260<<2, ahbregaddr) \|= (1<<RDLVL_GATE_EN_OFFSET);
	_REG32(182<<2, ahbregaddr) \|= (1<<DFI_PHY_RDLVL_GATE_MODE_OFFSET);
	}

	static inline void ux00ddr_enablevreftraining(size_t ahbregaddr) {
	_REG32(184<<2, ahbregaddr) \|= (1<<VREF_EN_OFFSET);
	}

	static inline uint32_t ux00ddr_getdramclass(size_t ahbregaddr) {
	return ((_REG32(0, ahbregaddr) >> DRAM_CLASS_OFFSET) & 0xF);
	}

	static inline uint64_t ux00ddr_phy_fixup(size_t ahbregaddr) {
	// return bitmask of failed lanes

	size_t ddrphyreg = ahbregaddr + 0x2000;

	// uint64_t fails=0;
	uint32_t slicebase = 0;
	// uint32_t dq = 0;

	// check errata condition
	for (uint32_t slice = 0; slice < 8; slice++) {
	uint32_t regbase = slicebase + 34;
	for (uint32_t reg = 0 ; reg < 4; reg++) {
	uint32_t updownreg = _REG32((regbase+reg)<<2, ddrphyreg);
	for (uint32_t bit = 0; bit < 2; bit++) {
	uint32_t phy_rx_cal_dqn_0_offset;

	if (bit==0) {
	phy_rx_cal_dqn_0_offset = PHY_RX_CAL_DQ0_0_OFFSET;
	}else{
	phy_rx_cal_dqn_0_offset = PHY_RX_CAL_DQ1_0_OFFSET;
	}

	uint32_t down = (updownreg >> phy_rx_cal_dqn_0_offset) & 0x3F;
	uint32_t up = (updownreg >> (phy_rx_cal_dqn_0_offset+6)) & 0x3F;

	uint8_t failc0 = ((down == 0) && (up == 0x3F));
	uint8_t failc1 = ((up == 0) && (down == 0x3F));

	// print error message on failure
	if (failc0 \|\| failc1) {
	//if (fails==0) uart_puts((void*) UART0_CTRL_ADDR, "DDR error in fixing up \n");
	//fails \|= (1<<dq);
	/* char slicelsc = '0'; */
	/* char slicemsc = '0'; */
	/* slicelsc += (dq % 10); */
	/* slicemsc += (dq / 10); */
	//uart_puts((void*) UART0_CTRL_ADDR, "S ");
	//uart_puts((void*) UART0_CTRL_ADDR, &slicemsc);
	//uart_puts((void*) UART0_CTRL_ADDR, &slicelsc);
	//if (failc0) uart_puts((void*) UART0_CTRL_ADDR, "U");
	//else uart_puts((void*) UART0_CTRL_ADDR, "D");
	//uart_puts((void*) UART0_CTRL_ADDR, "\n");
	}
	//dq++;
	}
	}
	slicebase+=128;
	}
	return (0);
	}

	#endif

	#endif