1*4882a593Smuzhiyun /* 2*4882a593Smuzhiyun * Copyright (c) 2011 The Chromium OS Authors. 3*4882a593Smuzhiyun * 4*4882a593Smuzhiyun * SPDX-License-Identifier: GPL-2.0+ 5*4882a593Smuzhiyun */ 6*4882a593Smuzhiyun 7*4882a593Smuzhiyun /* Tegra clock control functions */ 8*4882a593Smuzhiyun 9*4882a593Smuzhiyun #ifndef _TEGRA_CLOCK_H_ 10*4882a593Smuzhiyun #define _TEGRA_CLOCK_H_ 11*4882a593Smuzhiyun 12*4882a593Smuzhiyun /* Set of oscillator frequencies supported in the internal API. */ 13*4882a593Smuzhiyun enum clock_osc_freq { 14*4882a593Smuzhiyun /* All in MHz, so 13_0 is 13.0MHz */ 15*4882a593Smuzhiyun CLOCK_OSC_FREQ_13_0, 16*4882a593Smuzhiyun CLOCK_OSC_FREQ_19_2, 17*4882a593Smuzhiyun CLOCK_OSC_FREQ_12_0, 18*4882a593Smuzhiyun CLOCK_OSC_FREQ_26_0, 19*4882a593Smuzhiyun CLOCK_OSC_FREQ_38_4, 20*4882a593Smuzhiyun CLOCK_OSC_FREQ_48_0, 21*4882a593Smuzhiyun 22*4882a593Smuzhiyun CLOCK_OSC_FREQ_COUNT, 23*4882a593Smuzhiyun }; 24*4882a593Smuzhiyun 25*4882a593Smuzhiyun /* 26*4882a593Smuzhiyun * Note that no Tegra clock register actually uses all of bits 31:28 as 27*4882a593Smuzhiyun * the mux field. Rather, bits 30:28, 29:28, or 28 are used. However, in 28*4882a593Smuzhiyun * those cases, nothing is stored in the bits about the mux field, so it's 29*4882a593Smuzhiyun * safe to pretend that the mux field extends all the way to the end of the 30*4882a593Smuzhiyun * register. As such, the U-Boot clock driver is currently a bit lazy, and 31*4882a593Smuzhiyun * doesn't distinguish between 31:28, 30:28, 29:28 and 28; it just lumps 32*4882a593Smuzhiyun * them all together and pretends they're all 31:28. 33*4882a593Smuzhiyun */ 34*4882a593Smuzhiyun enum { 35*4882a593Smuzhiyun MASK_BITS_31_30, 36*4882a593Smuzhiyun MASK_BITS_31_29, 37*4882a593Smuzhiyun MASK_BITS_31_28, 38*4882a593Smuzhiyun }; 39*4882a593Smuzhiyun 40*4882a593Smuzhiyun #include <asm/arch/clock-tables.h> 41*4882a593Smuzhiyun /* PLL stabilization delay in usec */ 42*4882a593Smuzhiyun #define CLOCK_PLL_STABLE_DELAY_US 300 43*4882a593Smuzhiyun 44*4882a593Smuzhiyun /* return the current oscillator clock frequency */ 45*4882a593Smuzhiyun enum clock_osc_freq clock_get_osc_freq(void); 46*4882a593Smuzhiyun 47*4882a593Smuzhiyun /* return the clk_m frequency */ 48*4882a593Smuzhiyun unsigned int clk_m_get_rate(unsigned int parent_rate); 49*4882a593Smuzhiyun 50*4882a593Smuzhiyun /** 51*4882a593Smuzhiyun * Start PLL using the provided configuration parameters. 52*4882a593Smuzhiyun * 53*4882a593Smuzhiyun * @param id clock id 54*4882a593Smuzhiyun * @param divm input divider 55*4882a593Smuzhiyun * @param divn feedback divider 56*4882a593Smuzhiyun * @param divp post divider 2^n 57*4882a593Smuzhiyun * @param cpcon charge pump setup control 58*4882a593Smuzhiyun * @param lfcon loop filter setup control 59*4882a593Smuzhiyun * 60*4882a593Smuzhiyun * @returns monotonic time in us that the PLL will be stable 61*4882a593Smuzhiyun */ 62*4882a593Smuzhiyun unsigned long clock_start_pll(enum clock_id id, u32 divm, u32 divn, 63*4882a593Smuzhiyun u32 divp, u32 cpcon, u32 lfcon); 64*4882a593Smuzhiyun 65*4882a593Smuzhiyun /** 66*4882a593Smuzhiyun * Set PLL output frequency 67*4882a593Smuzhiyun * 68*4882a593Smuzhiyun * @param clkid clock id 69*4882a593Smuzhiyun * @param pllout pll output id 70*4882a593Smuzhiyun * @param rate desired output rate 71*4882a593Smuzhiyun * 72*4882a593Smuzhiyun * @return 0 if ok, -1 on error (invalid clock id or no suitable divider) 73*4882a593Smuzhiyun */ 74*4882a593Smuzhiyun int clock_set_pllout(enum clock_id clkid, enum pll_out_id pllout, 75*4882a593Smuzhiyun unsigned rate); 76*4882a593Smuzhiyun 77*4882a593Smuzhiyun /** 78*4882a593Smuzhiyun * Read low-level parameters of a PLL. 79*4882a593Smuzhiyun * 80*4882a593Smuzhiyun * @param id clock id to read (note: USB is not supported) 81*4882a593Smuzhiyun * @param divm returns input divider 82*4882a593Smuzhiyun * @param divn returns feedback divider 83*4882a593Smuzhiyun * @param divp returns post divider 2^n 84*4882a593Smuzhiyun * @param cpcon returns charge pump setup control 85*4882a593Smuzhiyun * @param lfcon returns loop filter setup control 86*4882a593Smuzhiyun * 87*4882a593Smuzhiyun * @returns 0 if ok, -1 on error (invalid clock id) 88*4882a593Smuzhiyun */ 89*4882a593Smuzhiyun int clock_ll_read_pll(enum clock_id clkid, u32 *divm, u32 *divn, 90*4882a593Smuzhiyun u32 *divp, u32 *cpcon, u32 *lfcon); 91*4882a593Smuzhiyun 92*4882a593Smuzhiyun /* 93*4882a593Smuzhiyun * Enable a clock 94*4882a593Smuzhiyun * 95*4882a593Smuzhiyun * @param id clock id 96*4882a593Smuzhiyun */ 97*4882a593Smuzhiyun void clock_enable(enum periph_id clkid); 98*4882a593Smuzhiyun 99*4882a593Smuzhiyun /* 100*4882a593Smuzhiyun * Disable a clock 101*4882a593Smuzhiyun * 102*4882a593Smuzhiyun * @param id clock id 103*4882a593Smuzhiyun */ 104*4882a593Smuzhiyun void clock_disable(enum periph_id clkid); 105*4882a593Smuzhiyun 106*4882a593Smuzhiyun /* 107*4882a593Smuzhiyun * Set whether a clock is enabled or disabled. 108*4882a593Smuzhiyun * 109*4882a593Smuzhiyun * @param id clock id 110*4882a593Smuzhiyun * @param enable 1 to enable, 0 to disable 111*4882a593Smuzhiyun */ 112*4882a593Smuzhiyun void clock_set_enable(enum periph_id clkid, int enable); 113*4882a593Smuzhiyun 114*4882a593Smuzhiyun /** 115*4882a593Smuzhiyun * Reset a peripheral. This puts it in reset, waits for a delay, then takes 116*4882a593Smuzhiyun * it out of reset and waits for th delay again. 117*4882a593Smuzhiyun * 118*4882a593Smuzhiyun * @param periph_id peripheral to reset 119*4882a593Smuzhiyun * @param us_delay time to delay in microseconds 120*4882a593Smuzhiyun */ 121*4882a593Smuzhiyun void reset_periph(enum periph_id periph_id, int us_delay); 122*4882a593Smuzhiyun 123*4882a593Smuzhiyun /** 124*4882a593Smuzhiyun * Put a peripheral into or out of reset. 125*4882a593Smuzhiyun * 126*4882a593Smuzhiyun * @param periph_id peripheral to reset 127*4882a593Smuzhiyun * @param enable 1 to put into reset, 0 to take out of reset 128*4882a593Smuzhiyun */ 129*4882a593Smuzhiyun void reset_set_enable(enum periph_id periph_id, int enable); 130*4882a593Smuzhiyun 131*4882a593Smuzhiyun 132*4882a593Smuzhiyun /* CLK_RST_CONTROLLER_RST_CPU_CMPLX_SET/CLR_0 */ 133*4882a593Smuzhiyun enum crc_reset_id { 134*4882a593Smuzhiyun /* Things we can hold in reset for each CPU */ 135*4882a593Smuzhiyun crc_rst_cpu = 1, 136*4882a593Smuzhiyun crc_rst_de = 1 << 4, /* What is de? */ 137*4882a593Smuzhiyun crc_rst_watchdog = 1 << 8, 138*4882a593Smuzhiyun crc_rst_debug = 1 << 12, 139*4882a593Smuzhiyun }; 140*4882a593Smuzhiyun 141*4882a593Smuzhiyun /** 142*4882a593Smuzhiyun * Put parts of the CPU complex into or out of reset.\ 143*4882a593Smuzhiyun * 144*4882a593Smuzhiyun * @param cpu cpu number (0 or 1 on Tegra2, 0-3 on Tegra3) 145*4882a593Smuzhiyun * @param which which parts of the complex to affect (OR of crc_reset_id) 146*4882a593Smuzhiyun * @param reset 1 to assert reset, 0 to de-assert 147*4882a593Smuzhiyun */ 148*4882a593Smuzhiyun void reset_cmplx_set_enable(int cpu, int which, int reset); 149*4882a593Smuzhiyun 150*4882a593Smuzhiyun /** 151*4882a593Smuzhiyun * Set the source for a peripheral clock. This plus the divisor sets the 152*4882a593Smuzhiyun * clock rate. You need to look up the datasheet to see the meaning of the 153*4882a593Smuzhiyun * source parameter as it changes for each peripheral. 154*4882a593Smuzhiyun * 155*4882a593Smuzhiyun * Warning: This function is only for use pre-relocation. Please use 156*4882a593Smuzhiyun * clock_start_periph_pll() instead. 157*4882a593Smuzhiyun * 158*4882a593Smuzhiyun * @param periph_id peripheral to adjust 159*4882a593Smuzhiyun * @param source source clock (0, 1, 2 or 3) 160*4882a593Smuzhiyun */ 161*4882a593Smuzhiyun void clock_ll_set_source(enum periph_id periph_id, unsigned source); 162*4882a593Smuzhiyun 163*4882a593Smuzhiyun /** 164*4882a593Smuzhiyun * This function is similar to clock_ll_set_source() except that it can be 165*4882a593Smuzhiyun * used for clocks with more than 2 mux bits. 166*4882a593Smuzhiyun * 167*4882a593Smuzhiyun * @param periph_id peripheral to adjust 168*4882a593Smuzhiyun * @param mux_bits number of mux bits for the clock 169*4882a593Smuzhiyun * @param source source clock (0-15 depending on mux_bits) 170*4882a593Smuzhiyun */ 171*4882a593Smuzhiyun int clock_ll_set_source_bits(enum periph_id periph_id, int mux_bits, 172*4882a593Smuzhiyun unsigned source); 173*4882a593Smuzhiyun 174*4882a593Smuzhiyun /** 175*4882a593Smuzhiyun * Set the source and divisor for a peripheral clock. This sets the 176*4882a593Smuzhiyun * clock rate. You need to look up the datasheet to see the meaning of the 177*4882a593Smuzhiyun * source parameter as it changes for each peripheral. 178*4882a593Smuzhiyun * 179*4882a593Smuzhiyun * Warning: This function is only for use pre-relocation. Please use 180*4882a593Smuzhiyun * clock_start_periph_pll() instead. 181*4882a593Smuzhiyun * 182*4882a593Smuzhiyun * @param periph_id peripheral to adjust 183*4882a593Smuzhiyun * @param source source clock (0, 1, 2 or 3) 184*4882a593Smuzhiyun * @param divisor divisor value to use 185*4882a593Smuzhiyun */ 186*4882a593Smuzhiyun void clock_ll_set_source_divisor(enum periph_id periph_id, unsigned source, 187*4882a593Smuzhiyun unsigned divisor); 188*4882a593Smuzhiyun 189*4882a593Smuzhiyun /** 190*4882a593Smuzhiyun * Returns the current parent clock ID of a given peripheral. This can be 191*4882a593Smuzhiyun * useful in order to call clock_*_periph_*() from generic code that has no 192*4882a593Smuzhiyun * specific knowledge of system-level clock tree structure. 193*4882a593Smuzhiyun * 194*4882a593Smuzhiyun * @param periph_id peripheral to query 195*4882a593Smuzhiyun * @return clock ID of the peripheral's current parent clock 196*4882a593Smuzhiyun */ 197*4882a593Smuzhiyun enum clock_id clock_get_periph_parent(enum periph_id periph_id); 198*4882a593Smuzhiyun 199*4882a593Smuzhiyun /** 200*4882a593Smuzhiyun * Start a peripheral PLL clock at the given rate. This also resets the 201*4882a593Smuzhiyun * peripheral. 202*4882a593Smuzhiyun * 203*4882a593Smuzhiyun * @param periph_id peripheral to start 204*4882a593Smuzhiyun * @param parent PLL id of required parent clock 205*4882a593Smuzhiyun * @param rate Required clock rate in Hz 206*4882a593Smuzhiyun * @return rate selected in Hz, or -1U if something went wrong 207*4882a593Smuzhiyun */ 208*4882a593Smuzhiyun unsigned clock_start_periph_pll(enum periph_id periph_id, 209*4882a593Smuzhiyun enum clock_id parent, unsigned rate); 210*4882a593Smuzhiyun 211*4882a593Smuzhiyun /** 212*4882a593Smuzhiyun * Returns the rate of a peripheral clock in Hz. Since the caller almost 213*4882a593Smuzhiyun * certainly knows the parent clock (having just set it) we require that 214*4882a593Smuzhiyun * this be passed in so we don't need to work it out. 215*4882a593Smuzhiyun * 216*4882a593Smuzhiyun * @param periph_id peripheral to start 217*4882a593Smuzhiyun * @param parent PLL id of parent clock (used to calculate rate, you 218*4882a593Smuzhiyun * must know this!) 219*4882a593Smuzhiyun * @return clock rate of peripheral in Hz 220*4882a593Smuzhiyun */ 221*4882a593Smuzhiyun unsigned long clock_get_periph_rate(enum periph_id periph_id, 222*4882a593Smuzhiyun enum clock_id parent); 223*4882a593Smuzhiyun 224*4882a593Smuzhiyun /** 225*4882a593Smuzhiyun * Adjust peripheral PLL clock to the given rate. This does not reset the 226*4882a593Smuzhiyun * peripheral. If a second stage divisor is not available, pass NULL for 227*4882a593Smuzhiyun * extra_div. If it is available, then this parameter will return the 228*4882a593Smuzhiyun * divisor selected (which will be a power of 2 from 1 to 256). 229*4882a593Smuzhiyun * 230*4882a593Smuzhiyun * @param periph_id peripheral to start 231*4882a593Smuzhiyun * @param parent PLL id of required parent clock 232*4882a593Smuzhiyun * @param rate Required clock rate in Hz 233*4882a593Smuzhiyun * @param extra_div value for the second-stage divisor (NULL if one is 234*4882a593Smuzhiyun not available) 235*4882a593Smuzhiyun * @return rate selected in Hz, or -1U if something went wrong 236*4882a593Smuzhiyun */ 237*4882a593Smuzhiyun unsigned clock_adjust_periph_pll_div(enum periph_id periph_id, 238*4882a593Smuzhiyun enum clock_id parent, unsigned rate, int *extra_div); 239*4882a593Smuzhiyun 240*4882a593Smuzhiyun /** 241*4882a593Smuzhiyun * Returns the clock rate of a specified clock, in Hz. 242*4882a593Smuzhiyun * 243*4882a593Smuzhiyun * @param parent PLL id of clock to check 244*4882a593Smuzhiyun * @return rate of clock in Hz 245*4882a593Smuzhiyun */ 246*4882a593Smuzhiyun unsigned clock_get_rate(enum clock_id clkid); 247*4882a593Smuzhiyun 248*4882a593Smuzhiyun /** 249*4882a593Smuzhiyun * Start up a UART using low-level calls 250*4882a593Smuzhiyun * 251*4882a593Smuzhiyun * Prior to relocation clock_start_periph_pll() cannot be called. This 252*4882a593Smuzhiyun * function provides a way to set up a UART using low-level calls which 253*4882a593Smuzhiyun * do not require BSS. 254*4882a593Smuzhiyun * 255*4882a593Smuzhiyun * @param periph_id Peripheral ID of UART to enable (e,g, PERIPH_ID_UART1) 256*4882a593Smuzhiyun */ 257*4882a593Smuzhiyun void clock_ll_start_uart(enum periph_id periph_id); 258*4882a593Smuzhiyun 259*4882a593Smuzhiyun /** 260*4882a593Smuzhiyun * Decode a peripheral ID from a device tree node. 261*4882a593Smuzhiyun * 262*4882a593Smuzhiyun * This works by looking up the peripheral's 'clocks' node and reading out 263*4882a593Smuzhiyun * the second cell, which is the clock number / peripheral ID. 264*4882a593Smuzhiyun * 265*4882a593Smuzhiyun * @param blob FDT blob to use 266*4882a593Smuzhiyun * @param node Node to look at 267*4882a593Smuzhiyun * @return peripheral ID, or PERIPH_ID_NONE if none 268*4882a593Smuzhiyun */ 269*4882a593Smuzhiyun int clock_decode_periph_id(struct udevice *dev); 270*4882a593Smuzhiyun 271*4882a593Smuzhiyun /** 272*4882a593Smuzhiyun * Checks if the oscillator bypass is enabled (XOBP bit) 273*4882a593Smuzhiyun * 274*4882a593Smuzhiyun * @return 1 if bypass is enabled, 0 if not 275*4882a593Smuzhiyun */ 276*4882a593Smuzhiyun int clock_get_osc_bypass(void); 277*4882a593Smuzhiyun 278*4882a593Smuzhiyun /* 279*4882a593Smuzhiyun * Checks that clocks are valid and prints a warning if not 280*4882a593Smuzhiyun * 281*4882a593Smuzhiyun * @return 0 if ok, -1 on error 282*4882a593Smuzhiyun */ 283*4882a593Smuzhiyun int clock_verify(void); 284*4882a593Smuzhiyun 285*4882a593Smuzhiyun /* Initialize the clocks */ 286*4882a593Smuzhiyun void clock_init(void); 287*4882a593Smuzhiyun 288*4882a593Smuzhiyun /* Initialize the PLLs */ 289*4882a593Smuzhiyun void clock_early_init(void); 290*4882a593Smuzhiyun 291*4882a593Smuzhiyun /* @return true if hardware indicates that clock_early_init() was called */ 292*4882a593Smuzhiyun bool clock_early_init_done(void); 293*4882a593Smuzhiyun 294*4882a593Smuzhiyun /* Returns a pointer to the clock source register for a peripheral */ 295*4882a593Smuzhiyun u32 *get_periph_source_reg(enum periph_id periph_id); 296*4882a593Smuzhiyun 297*4882a593Smuzhiyun /* Returns a pointer to the given 'simple' PLL */ 298*4882a593Smuzhiyun struct clk_pll_simple *clock_get_simple_pll(enum clock_id clkid); 299*4882a593Smuzhiyun 300*4882a593Smuzhiyun /* 301*4882a593Smuzhiyun * Given a peripheral ID, determine where the mux bits are in the peripheral 302*4882a593Smuzhiyun * clock's register, the number of divider bits the clock has, and the SoC- 303*4882a593Smuzhiyun * specific clock type. 304*4882a593Smuzhiyun * 305*4882a593Smuzhiyun * This is an internal API between the core Tegra clock code and the SoC- 306*4882a593Smuzhiyun * specific clock code. 307*4882a593Smuzhiyun * 308*4882a593Smuzhiyun * @param periph_id peripheral to query 309*4882a593Smuzhiyun * @param mux_bits Set to number of bits in mux register 310*4882a593Smuzhiyun * @param divider_bits Set to the relevant MASK_BITS_* value 311*4882a593Smuzhiyun * @param type Set to the SoC-specific clock type 312*4882a593Smuzhiyun * @return 0 on success, -1 on error 313*4882a593Smuzhiyun */ 314*4882a593Smuzhiyun int get_periph_clock_info(enum periph_id periph_id, int *mux_bits, 315*4882a593Smuzhiyun int *divider_bits, int *type); 316*4882a593Smuzhiyun 317*4882a593Smuzhiyun /* 318*4882a593Smuzhiyun * Given a peripheral ID and clock source mux value, determine the clock_id 319*4882a593Smuzhiyun * of that peripheral's parent. 320*4882a593Smuzhiyun * 321*4882a593Smuzhiyun * This is an internal API between the core Tegra clock code and the SoC- 322*4882a593Smuzhiyun * specific clock code. 323*4882a593Smuzhiyun * 324*4882a593Smuzhiyun * @param periph_id peripheral to query 325*4882a593Smuzhiyun * @param source raw clock source mux value 326*4882a593Smuzhiyun * @return the CLOCK_ID_* value @source represents 327*4882a593Smuzhiyun */ 328*4882a593Smuzhiyun enum clock_id get_periph_clock_id(enum periph_id periph_id, int source); 329*4882a593Smuzhiyun 330*4882a593Smuzhiyun /** 331*4882a593Smuzhiyun * Given a peripheral ID and the required source clock, this returns which 332*4882a593Smuzhiyun * value should be programmed into the source mux for that peripheral. 333*4882a593Smuzhiyun * 334*4882a593Smuzhiyun * There is special code here to handle the one source type with 5 sources. 335*4882a593Smuzhiyun * 336*4882a593Smuzhiyun * @param periph_id peripheral to start 337*4882a593Smuzhiyun * @param source PLL id of required parent clock 338*4882a593Smuzhiyun * @param mux_bits Set to number of bits in mux register: 2 or 4 339*4882a593Smuzhiyun * @param divider_bits Set to number of divider bits (8 or 16) 340*4882a593Smuzhiyun * @return mux value (0-4, or -1 if not found) 341*4882a593Smuzhiyun */ 342*4882a593Smuzhiyun int get_periph_clock_source(enum periph_id periph_id, 343*4882a593Smuzhiyun enum clock_id parent, int *mux_bits, int *divider_bits); 344*4882a593Smuzhiyun 345*4882a593Smuzhiyun /* 346*4882a593Smuzhiyun * Convert a device tree clock ID to our peripheral ID. They are mostly 347*4882a593Smuzhiyun * the same but we are very cautious so we check that a valid clock ID is 348*4882a593Smuzhiyun * provided. 349*4882a593Smuzhiyun * 350*4882a593Smuzhiyun * @param clk_id Clock ID according to tegra30 device tree binding 351*4882a593Smuzhiyun * @return peripheral ID, or PERIPH_ID_NONE if the clock ID is invalid 352*4882a593Smuzhiyun */ 353*4882a593Smuzhiyun enum periph_id clk_id_to_periph_id(int clk_id); 354*4882a593Smuzhiyun 355*4882a593Smuzhiyun /** 356*4882a593Smuzhiyun * Set the output frequency you want for each PLL clock. 357*4882a593Smuzhiyun * PLL output frequencies are programmed by setting their N, M and P values. 358*4882a593Smuzhiyun * The governing equations are: 359*4882a593Smuzhiyun * VCO = (Fi / m) * n, Fo = VCO / (2^p) 360*4882a593Smuzhiyun * where Fo is the output frequency from the PLL. 361*4882a593Smuzhiyun * Example: Set the output frequency to 216Mhz(Fo) with 12Mhz OSC(Fi) 362*4882a593Smuzhiyun * 216Mhz = ((12Mhz / m) * n) / (2^p) so n=432,m=12,p=1 363*4882a593Smuzhiyun * Please see Tegra TRM section 5.3 to get the detail for PLL Programming 364*4882a593Smuzhiyun * 365*4882a593Smuzhiyun * @param n PLL feedback divider(DIVN) 366*4882a593Smuzhiyun * @param m PLL input divider(DIVN) 367*4882a593Smuzhiyun * @param p post divider(DIVP) 368*4882a593Smuzhiyun * @param cpcon base PLL charge pump(CPCON) 369*4882a593Smuzhiyun * @return 0 if ok, -1 on error (the requested PLL is incorrect and cannot 370*4882a593Smuzhiyun * be overridden), 1 if PLL is already correct 371*4882a593Smuzhiyun */ 372*4882a593Smuzhiyun int clock_set_rate(enum clock_id clkid, u32 n, u32 m, u32 p, u32 cpcon); 373*4882a593Smuzhiyun 374*4882a593Smuzhiyun /* return 1 if a peripheral ID is in range */ 375*4882a593Smuzhiyun #define clock_type_id_isvalid(id) ((id) >= 0 && \ 376*4882a593Smuzhiyun (id) < CLOCK_TYPE_COUNT) 377*4882a593Smuzhiyun 378*4882a593Smuzhiyun /* return 1 if a periphc_internal_id is in range */ 379*4882a593Smuzhiyun #define periphc_internal_id_isvalid(id) ((id) >= 0 && \ 380*4882a593Smuzhiyun (id) < PERIPHC_COUNT) 381*4882a593Smuzhiyun 382*4882a593Smuzhiyun /* SoC-specific TSC init */ 383*4882a593Smuzhiyun void arch_timer_init(void); 384*4882a593Smuzhiyun 385*4882a593Smuzhiyun void tegra30_set_up_pllp(void); 386*4882a593Smuzhiyun 387*4882a593Smuzhiyun /* Number of PLL-based clocks (i.e. not OSC, MCLK or 32KHz) */ 388*4882a593Smuzhiyun #define CLOCK_ID_PLL_COUNT (CLOCK_ID_COUNT - 3) 389*4882a593Smuzhiyun 390*4882a593Smuzhiyun struct clk_pll_info { 391*4882a593Smuzhiyun u32 m_shift:5; /* DIVM_SHIFT */ 392*4882a593Smuzhiyun u32 n_shift:5; /* DIVN_SHIFT */ 393*4882a593Smuzhiyun u32 p_shift:5; /* DIVP_SHIFT */ 394*4882a593Smuzhiyun u32 kcp_shift:5; /* KCP/cpcon SHIFT */ 395*4882a593Smuzhiyun u32 kvco_shift:5; /* KVCO/lfcon SHIFT */ 396*4882a593Smuzhiyun u32 lock_ena:6; /* LOCK_ENABLE/EN_LOCKDET shift */ 397*4882a593Smuzhiyun u32 rsvd:1; 398*4882a593Smuzhiyun u32 m_mask:10; /* DIVM_MASK */ 399*4882a593Smuzhiyun u32 n_mask:12; /* DIVN_MASK */ 400*4882a593Smuzhiyun u32 p_mask:10; /* DIVP_MASK or VCO_MASK */ 401*4882a593Smuzhiyun u32 kcp_mask:10; /* KCP/CPCON MASK */ 402*4882a593Smuzhiyun u32 kvco_mask:10; /* KVCO/LFCON MASK */ 403*4882a593Smuzhiyun u32 lock_det:6; /* LOCK_DETECT/LOCKED shift */ 404*4882a593Smuzhiyun u32 rsvd2:6; 405*4882a593Smuzhiyun }; 406*4882a593Smuzhiyun extern struct clk_pll_info tegra_pll_info_table[CLOCK_ID_PLL_COUNT]; 407*4882a593Smuzhiyun 408*4882a593Smuzhiyun struct periph_clk_init { 409*4882a593Smuzhiyun enum periph_id periph_id; 410*4882a593Smuzhiyun enum clock_id parent_clock_id; 411*4882a593Smuzhiyun }; 412*4882a593Smuzhiyun extern struct periph_clk_init periph_clk_init_table[]; 413*4882a593Smuzhiyun 414*4882a593Smuzhiyun /** 415*4882a593Smuzhiyun * Enable output clock for external peripherals 416*4882a593Smuzhiyun * 417*4882a593Smuzhiyun * @param clk_id Clock ID to output (1, 2 or 3) 418*4882a593Smuzhiyun * @return 0 if OK. -ve on error 419*4882a593Smuzhiyun */ 420*4882a593Smuzhiyun int clock_external_output(int clk_id); 421*4882a593Smuzhiyun 422*4882a593Smuzhiyun #endif /* _TEGRA_CLOCK_H_ */ 423