1 /* SPDX-License-Identifier: GPL-2.0 */ 2 /* 3 * S390 version 4 * Copyright IBM Corp. 1999 5 * 6 * Derived from "include/asm-i386/timex.h" 7 * Copyright (C) 1992, Linus Torvalds 8 */ 9 10 #ifndef _ASM_S390_TIMEX_H 11 #define _ASM_S390_TIMEX_H 12 13 #include <linux/preempt.h> 14 #include <linux/time64.h> 15 #include <asm/lowcore.h> 16 17 /* The value of the TOD clock for 1.1.1970. */ 18 #define TOD_UNIX_EPOCH 0x7d91048bca000000ULL 19 20 extern u64 clock_comparator_max; 21 22 union tod_clock { 23 __uint128_t val; 24 struct { 25 __uint128_t ei : 8; /* epoch index */ 26 __uint128_t tod : 64; /* bits 0-63 of tod clock */ 27 __uint128_t : 40; 28 __uint128_t pf : 16; /* programmable field */ 29 }; 30 struct { 31 __uint128_t eitod : 72; /* epoch index + bits 0-63 tod clock */ 32 __uint128_t : 56; 33 }; 34 struct { 35 __uint128_t us : 60; /* micro-seconds */ 36 __uint128_t sus : 12; /* sub-microseconds */ 37 __uint128_t : 56; 38 }; 39 } __packed; 40 41 /* Inline functions for clock register access. */ 42 static inline int set_tod_clock(__u64 time) 43 { 44 int cc; 45 46 asm volatile( 47 " sck %1\n" 48 " ipm %0\n" 49 " srl %0,28\n" 50 : "=d" (cc) : "Q" (time) : "cc"); 51 return cc; 52 } 53 54 static inline int store_tod_clock_ext_cc(union tod_clock *clk) 55 { 56 int cc; 57 58 asm volatile( 59 " stcke %1\n" 60 " ipm %0\n" 61 " srl %0,28\n" 62 : "=d" (cc), "=Q" (*clk) : : "cc"); 63 return cc; 64 } 65 66 static __always_inline void store_tod_clock_ext(union tod_clock *tod) 67 { 68 asm volatile("stcke %0" : "=Q" (*tod) : : "cc"); 69 } 70 71 static inline void set_clock_comparator(__u64 time) 72 { 73 asm volatile("sckc %0" : : "Q" (time)); 74 } 75 76 static inline void set_tod_programmable_field(u16 val) 77 { 78 asm volatile( 79 " lgr 0,%[val]\n" 80 " sckpf\n" 81 : 82 : [val] "d" ((unsigned long)val) 83 : "0"); 84 } 85 86 void clock_comparator_work(void); 87 88 void __init time_early_init(void); 89 90 extern unsigned char ptff_function_mask[16]; 91 92 /* Function codes for the ptff instruction. */ 93 #define PTFF_QAF 0x00 /* query available functions */ 94 #define PTFF_QTO 0x01 /* query tod offset */ 95 #define PTFF_QSI 0x02 /* query steering information */ 96 #define PTFF_QUI 0x04 /* query UTC information */ 97 #define PTFF_ATO 0x40 /* adjust tod offset */ 98 #define PTFF_STO 0x41 /* set tod offset */ 99 #define PTFF_SFS 0x42 /* set fine steering rate */ 100 #define PTFF_SGS 0x43 /* set gross steering rate */ 101 102 /* Query TOD offset result */ 103 struct ptff_qto { 104 unsigned long physical_clock; 105 unsigned long tod_offset; 106 unsigned long logical_tod_offset; 107 unsigned long tod_epoch_difference; 108 } __packed; 109 110 static inline int ptff_query(unsigned int nr) 111 { 112 unsigned char *ptr; 113 114 ptr = ptff_function_mask + (nr >> 3); 115 return (*ptr & (0x80 >> (nr & 7))) != 0; 116 } 117 118 /* Query UTC information result */ 119 struct ptff_qui { 120 unsigned int tm : 2; 121 unsigned int ts : 2; 122 unsigned int : 28; 123 unsigned int pad_0x04; 124 unsigned long leap_event; 125 short old_leap; 126 short new_leap; 127 unsigned int pad_0x14; 128 unsigned long prt[5]; 129 unsigned long cst[3]; 130 unsigned int skew; 131 unsigned int pad_0x5c[41]; 132 } __packed; 133 134 /* 135 * ptff - Perform timing facility function 136 * @ptff_block: Pointer to ptff parameter block 137 * @len: Length of parameter block 138 * @func: Function code 139 * Returns: Condition code (0 on success) 140 */ 141 #define ptff(ptff_block, len, func) \ 142 ({ \ 143 struct addrtype { char _[len]; }; \ 144 unsigned int reg0 = func; \ 145 unsigned long reg1 = (unsigned long)(ptff_block); \ 146 int rc; \ 147 \ 148 asm volatile( \ 149 " lgr 0,%[reg0]\n" \ 150 " lgr 1,%[reg1]\n" \ 151 " ptff\n" \ 152 " ipm %[rc]\n" \ 153 " srl %[rc],28\n" \ 154 : [rc] "=&d" (rc), "+m" (*(struct addrtype *)reg1) \ 155 : [reg0] "d" (reg0), [reg1] "d" (reg1) \ 156 : "cc", "0", "1"); \ 157 rc; \ 158 }) 159 160 static inline unsigned long local_tick_disable(void) 161 { 162 unsigned long old; 163 164 old = get_lowcore()->clock_comparator; 165 get_lowcore()->clock_comparator = clock_comparator_max; 166 set_clock_comparator(get_lowcore()->clock_comparator); 167 return old; 168 } 169 170 static inline void local_tick_enable(unsigned long comp) 171 { 172 get_lowcore()->clock_comparator = comp; 173 set_clock_comparator(get_lowcore()->clock_comparator); 174 } 175 176 #define CLOCK_TICK_RATE 1193180 /* Underlying HZ */ 177 178 typedef unsigned long cycles_t; 179 180 static __always_inline unsigned long get_tod_clock(void) 181 { 182 union tod_clock clk; 183 184 store_tod_clock_ext(&clk); 185 return clk.tod; 186 } 187 188 static inline unsigned long get_tod_clock_fast(void) 189 { 190 unsigned long clk; 191 192 asm volatile("stckf %0" : "=Q" (clk) : : "cc"); 193 return clk; 194 } 195 196 static inline cycles_t get_cycles(void) 197 { 198 return (cycles_t) get_tod_clock() >> 2; 199 } 200 #define get_cycles get_cycles 201 202 int get_phys_clock(unsigned long *clock); 203 void init_cpu_timer(void); 204 205 extern union tod_clock tod_clock_base; 206 207 static __always_inline unsigned long __get_tod_clock_monotonic(void) 208 { 209 return get_tod_clock() - tod_clock_base.tod; 210 } 211 212 /** 213 * get_clock_monotonic - returns current time in clock rate units 214 * 215 * The clock and tod_clock_base get changed via stop_machine. 216 * Therefore preemption must be disabled, otherwise the returned 217 * value is not guaranteed to be monotonic. 218 */ 219 static inline unsigned long get_tod_clock_monotonic(void) 220 { 221 unsigned long tod; 222 223 preempt_disable_notrace(); 224 tod = __get_tod_clock_monotonic(); 225 preempt_enable_notrace(); 226 return tod; 227 } 228 229 /** 230 * tod_to_ns - convert a TOD format value to nanoseconds 231 * @todval: to be converted TOD format value 232 * Returns: number of nanoseconds that correspond to the TOD format value 233 * 234 * Converting a 64 Bit TOD format value to nanoseconds means that the value 235 * must be divided by 4.096. In order to achieve that we multiply with 125 236 * and divide by 512: 237 * 238 * ns = (todval * 125) >> 9; 239 * 240 * In order to avoid an overflow with the multiplication we can rewrite this. 241 * With a split todval == 2^9 * th + tl (th upper 55 bits, tl lower 9 bits) 242 * we end up with 243 * 244 * ns = ((2^9 * th + tl) * 125 ) >> 9; 245 * -> ns = (th * 125) + ((tl * 125) >> 9); 246 * 247 */ 248 static __always_inline unsigned long tod_to_ns(unsigned long todval) 249 { 250 return ((todval >> 9) * 125) + (((todval & 0x1ff) * 125) >> 9); 251 } 252 253 /** 254 * tod_after - compare two 64 bit TOD values 255 * @a: first 64 bit TOD timestamp 256 * @b: second 64 bit TOD timestamp 257 * 258 * Returns: true if a is later than b 259 */ 260 static inline int tod_after(unsigned long a, unsigned long b) 261 { 262 if (MACHINE_HAS_SCC) 263 return (long) a > (long) b; 264 return a > b; 265 } 266 267 /** 268 * tod_after_eq - compare two 64 bit TOD values 269 * @a: first 64 bit TOD timestamp 270 * @b: second 64 bit TOD timestamp 271 * 272 * Returns: true if a is later than b 273 */ 274 static inline int tod_after_eq(unsigned long a, unsigned long b) 275 { 276 if (MACHINE_HAS_SCC) 277 return (long) a >= (long) b; 278 return a >= b; 279 } 280 281 #endif 282