#include #include #include "ddk750_reg.h" #include "ddk750_chip.h" #include "ddk750_power.h" #define MHz(x) ((x) * 1000000) static logical_chip_type_t chip; logical_chip_type_t sm750_get_chip_type(void) { return chip; } void sm750_set_chip_type(unsigned short devId, u8 revId) { if (devId == 0x718) { chip = SM718; } else if (devId == 0x750) { chip = SM750; /* SM750 and SM750LE are different in their revision ID only. */ if (revId == SM750LE_REVISION_ID) { chip = SM750LE; pr_info("found sm750le\n"); } } else { chip = SM_UNKNOWN; } } static unsigned int get_mxclk_freq(void) { unsigned int pll_reg; unsigned int M, N, OD, POD; if (sm750_get_chip_type() == SM750LE) return MHz(130); pll_reg = peek32(MXCLK_PLL_CTRL); M = (pll_reg & PLL_CTRL_M_MASK) >> PLL_CTRL_M_SHIFT; N = (pll_reg & PLL_CTRL_N_MASK) >> PLL_CTRL_N_SHIFT; OD = (pll_reg & PLL_CTRL_OD_MASK) >> PLL_CTRL_OD_SHIFT; POD = (pll_reg & PLL_CTRL_POD_MASK) >> PLL_CTRL_POD_SHIFT; return DEFAULT_INPUT_CLOCK * M / N / (1 << OD) / (1 << POD); } /* * This function set up the main chip clock. * * Input: Frequency to be set. */ static void set_chip_clock(unsigned int frequency) { struct pll_value pll; unsigned int ulActualMxClk; /* Cheok_0509: For SM750LE, the chip clock is fixed. Nothing to set. */ if (sm750_get_chip_type() == SM750LE) return; if (frequency) { /* * Set up PLL structure to hold the value to be set in clocks. */ pll.inputFreq = DEFAULT_INPUT_CLOCK; /* Defined in CLOCK.H */ pll.clockType = MXCLK_PLL; /* * Call sm750_calc_pll_value() to fill the other fields * of the PLL structure. Sometimes, the chip cannot set * up the exact clock required by the User. * Return value of sm750_calc_pll_value gives the actual * possible clock. */ ulActualMxClk = sm750_calc_pll_value(frequency, &pll); /* Master Clock Control: MXCLK_PLL */ poke32(MXCLK_PLL_CTRL, sm750_format_pll_reg(&pll)); } } static void set_memory_clock(unsigned int frequency) { unsigned int reg, divisor; /* * Cheok_0509: For SM750LE, the memory clock is fixed. * Nothing to set. */ if (sm750_get_chip_type() == SM750LE) return; if (frequency) { /* * Set the frequency to the maximum frequency * that the DDR Memory can take which is 336MHz. */ if (frequency > MHz(336)) frequency = MHz(336); /* Calculate the divisor */ divisor = DIV_ROUND_CLOSEST(get_mxclk_freq(), frequency); /* Set the corresponding divisor in the register. */ reg = peek32(CURRENT_GATE) & ~CURRENT_GATE_M2XCLK_MASK; switch (divisor) { default: case 1: reg |= CURRENT_GATE_M2XCLK_DIV_1; break; case 2: reg |= CURRENT_GATE_M2XCLK_DIV_2; break; case 3: reg |= CURRENT_GATE_M2XCLK_DIV_3; break; case 4: reg |= CURRENT_GATE_M2XCLK_DIV_4; break; } sm750_set_current_gate(reg); } } /* * This function set up the master clock (MCLK). * * Input: Frequency to be set. * * NOTE: * The maximum frequency the engine can run is 168MHz. */ static void set_master_clock(unsigned int frequency) { unsigned int reg, divisor; /* * Cheok_0509: For SM750LE, the memory clock is fixed. * Nothing to set. */ if (sm750_get_chip_type() == SM750LE) return; if (frequency) { /* * Set the frequency to the maximum frequency * that the SM750 engine can run, which is about 190 MHz. */ if (frequency > MHz(190)) frequency = MHz(190); /* Calculate the divisor */ divisor = DIV_ROUND_CLOSEST(get_mxclk_freq(), frequency); /* Set the corresponding divisor in the register. */ reg = peek32(CURRENT_GATE) & ~CURRENT_GATE_MCLK_MASK; switch (divisor) { default: case 3: reg |= CURRENT_GATE_MCLK_DIV_3; break; case 4: reg |= CURRENT_GATE_MCLK_DIV_4; break; case 6: reg |= CURRENT_GATE_MCLK_DIV_6; break; case 8: reg |= CURRENT_GATE_MCLK_DIV_8; break; } sm750_set_current_gate(reg); } } unsigned int ddk750_get_vm_size(void) { unsigned int reg; unsigned int data; /* sm750le only use 64 mb memory*/ if (sm750_get_chip_type() == SM750LE) return SZ_64M; /* for 750,always use power mode0*/ reg = peek32(MODE0_GATE); reg |= MODE0_GATE_GPIO; poke32(MODE0_GATE, reg); /* get frame buffer size from GPIO */ reg = peek32(MISC_CTRL) & MISC_CTRL_LOCALMEM_SIZE_MASK; switch (reg) { case MISC_CTRL_LOCALMEM_SIZE_8M: data = SZ_8M; break; /* 8 Mega byte */ case MISC_CTRL_LOCALMEM_SIZE_16M: data = SZ_16M; break; /* 16 Mega byte */ case MISC_CTRL_LOCALMEM_SIZE_32M: data = SZ_32M; break; /* 32 Mega byte */ case MISC_CTRL_LOCALMEM_SIZE_64M: data = SZ_64M; break; /* 64 Mega byte */ default: data = 0; break; } return data; } int ddk750_init_hw(struct initchip_param *pInitParam) { unsigned int reg; if (pInitParam->powerMode != 0) pInitParam->powerMode = 0; sm750_set_power_mode(pInitParam->powerMode); /* Enable display power gate & LOCALMEM power gate*/ reg = peek32(CURRENT_GATE); reg |= (CURRENT_GATE_DISPLAY | CURRENT_GATE_LOCALMEM); sm750_set_current_gate(reg); if (sm750_get_chip_type() != SM750LE) { /* set panel pll and graphic mode via mmio_88 */ reg = peek32(VGA_CONFIGURATION); reg |= (VGA_CONFIGURATION_PLL | VGA_CONFIGURATION_MODE); poke32(VGA_CONFIGURATION, reg); } else { #if defined(__i386__) || defined(__x86_64__) /* set graphic mode via IO method */ outb_p(0x88, 0x3d4); outb_p(0x06, 0x3d5); #endif } /* Set the Main Chip Clock */ set_chip_clock(MHz((unsigned int)pInitParam->chipClock)); /* Set up memory clock. */ set_memory_clock(MHz(pInitParam->memClock)); /* Set up master clock */ set_master_clock(MHz(pInitParam->masterClock)); /* * Reset the memory controller. * If the memory controller is not reset in SM750, * the system might hang when sw accesses the memory. * The memory should be resetted after changing the MXCLK. */ if (pInitParam->resetMemory == 1) { reg = peek32(MISC_CTRL); reg &= ~MISC_CTRL_LOCALMEM_RESET; poke32(MISC_CTRL, reg); reg |= MISC_CTRL_LOCALMEM_RESET; poke32(MISC_CTRL, reg); } if (pInitParam->setAllEngOff == 1) { sm750_enable_2d_engine(0); /* Disable Overlay, if a former application left it on */ reg = peek32(VIDEO_DISPLAY_CTRL); reg &= ~DISPLAY_CTRL_PLANE; poke32(VIDEO_DISPLAY_CTRL, reg); /* Disable video alpha, if a former application left it on */ reg = peek32(VIDEO_ALPHA_DISPLAY_CTRL); reg &= ~DISPLAY_CTRL_PLANE; poke32(VIDEO_ALPHA_DISPLAY_CTRL, reg); /* Disable alpha plane, if a former application left it on */ reg = peek32(ALPHA_DISPLAY_CTRL); reg &= ~DISPLAY_CTRL_PLANE; poke32(ALPHA_DISPLAY_CTRL, reg); /* Disable DMA Channel, if a former application left it on */ reg = peek32(DMA_ABORT_INTERRUPT); reg |= DMA_ABORT_INTERRUPT_ABORT_1; poke32(DMA_ABORT_INTERRUPT, reg); /* Disable DMA Power, if a former application left it on */ sm750_enable_dma(0); } /* We can add more initialization as needed. */ return 0; } /* * monk liu @ 4/6/2011: * re-write the calculatePLL function of ddk750. * the original version function does not use * some mathematics tricks and shortcut * when it doing the calculation of the best N,M,D combination * I think this version gives a little upgrade in speed * * 750 pll clock formular: * Request Clock = (Input Clock * M )/(N * X) * * Input Clock = 14318181 hz * X = 2 power D * D ={0,1,2,3,4,5,6} * M = {1,...,255} * N = {2,...,15} */ unsigned int sm750_calc_pll_value(unsigned int request_orig, struct pll_value *pll) { /* * as sm750 register definition, * N located in 2,15 and M located in 1,255 */ int N, M, X, d; int mini_diff; unsigned int RN, quo, rem, fl_quo; unsigned int input, request; unsigned int tmpClock, ret; const int max_OD = 3; int max_d = 6; if (sm750_get_chip_type() == SM750LE) { /* * SM750LE don't have * programmable PLL and M/N values to work on. * Just return the requested clock. */ return request_orig; } ret = 0; mini_diff = ~0; request = request_orig / 1000; input = pll->inputFreq / 1000; /* * for MXCLK register, * no POD provided, so need be treated differently */ if (pll->clockType == MXCLK_PLL) max_d = 3; for (N = 15; N > 1; N--) { /* * RN will not exceed maximum long * if @request <= 285 MHZ (for 32bit cpu) */ RN = N * request; quo = RN / input; rem = RN % input;/* rem always small than 14318181 */ fl_quo = rem * 10000 / input; for (d = max_d; d >= 0; d--) { X = BIT(d); M = quo * X; M += fl_quo * X / 10000; /* round step */ M += (fl_quo * X % 10000) > 5000 ? 1 : 0; if (M < 256 && M > 0) { unsigned int diff; tmpClock = pll->inputFreq * M / N / X; diff = abs(tmpClock - request_orig); if (diff < mini_diff) { pll->M = M; pll->N = N; pll->POD = 0; if (d > max_OD) pll->POD = d - max_OD; pll->OD = d - pll->POD; mini_diff = diff; ret = tmpClock; } } } } return ret; } unsigned int sm750_format_pll_reg(struct pll_value *pPLL) { #ifndef VALIDATION_CHIP unsigned int POD = pPLL->POD; #endif unsigned int OD = pPLL->OD; unsigned int M = pPLL->M; unsigned int N = pPLL->N; unsigned int reg = 0; /* * Note that all PLL's have the same format. Here, we just use * Panel PLL parameter to work out the bit fields in the * register. On returning a 32 bit number, the value can be * applied to any PLL in the calling function. */ reg = PLL_CTRL_POWER | #ifndef VALIDATION_CHIP ((POD << PLL_CTRL_POD_SHIFT) & PLL_CTRL_POD_MASK) | #endif ((OD << PLL_CTRL_OD_SHIFT) & PLL_CTRL_OD_MASK) | ((N << PLL_CTRL_N_SHIFT) & PLL_CTRL_N_MASK) | ((M << PLL_CTRL_M_SHIFT) & PLL_CTRL_M_MASK); return reg; }