From 75ac63dbc3b0f4d3af67a5857790749e954e2ba6 Mon Sep 17 00:00:00 2001 From: Rex Zhu Date: Wed, 6 Jan 2016 16:38:48 +0800 Subject: [PATCH] drm/amd/powerplay: fix Smatch static checker warnings with indenting (v2) v2: AGD: rebase on upstream Signed-off-by: Rex Zhu Reviewed-by: Alex Deucher Reviewed-by: Ken Wang Signed-off-by: Alex Deucher --- drivers/gpu/drm/amd/amdgpu/amdgpu_pm.c | 2 +- .../gpu/drm/amd/powerplay/hwmgr/fiji_hwmgr.c | 51 +- .../drm/amd/powerplay/hwmgr/fiji_powertune.c | 12 +- .../drm/amd/powerplay/hwmgr/hardwaremanager.c | 1 - .../gpu/drm/amd/powerplay/hwmgr/ppevvmath.h | 555 +++++++++--------- .../drm/amd/powerplay/smumgr/fiji_smumgr.c | 8 +- 6 files changed, 312 insertions(+), 317 deletions(-) diff --git a/drivers/gpu/drm/amd/amdgpu/amdgpu_pm.c b/drivers/gpu/drm/amd/amdgpu/amdgpu_pm.c index 3b78982abaf1..4386cbac7f97 100644 --- a/drivers/gpu/drm/amd/amdgpu/amdgpu_pm.c +++ b/drivers/gpu/drm/amd/amdgpu/amdgpu_pm.c @@ -807,7 +807,7 @@ void amdgpu_pm_compute_clocks(struct amdgpu_device *adev) struct amdgpu_ring *ring = adev->rings[i]; if (ring && ring->ready) amdgpu_fence_wait_empty(ring); - } + } mutex_unlock(&adev->ring_lock); amdgpu_dpm_dispatch_task(adev, AMD_PP_EVENT_DISPLAY_CONFIG_CHANGE, NULL, NULL); diff --git a/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_hwmgr.c b/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_hwmgr.c index 94f404c121b7..6dba5bf73e52 100644 --- a/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_hwmgr.c +++ b/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_hwmgr.c @@ -941,8 +941,9 @@ static int fiji_trim_voltage_table(struct pp_hwmgr *hwmgr, memcpy(vol_table, table, sizeof(struct pp_atomctrl_voltage_table)); kfree(table); - return 0; + return 0; } + static int fiji_get_svi2_mvdd_voltage_table(struct pp_hwmgr *hwmgr, phm_ppt_v1_clock_voltage_dependency_table *dep_table) { @@ -1112,7 +1113,7 @@ static int fiji_construct_voltage_tables(struct pp_hwmgr *hwmgr) fiji_trim_voltage_table_to_fit_state_table(hwmgr, SMU73_MAX_LEVELS_MVDD, &(data->mvdd_voltage_table))); - return 0; + return 0; } static int fiji_initialize_mc_reg_table(struct pp_hwmgr *hwmgr) @@ -1158,7 +1159,7 @@ static int fiji_program_static_screen_threshold_parameters( CG_STATIC_SCREEN_PARAMETER, STATIC_SCREEN_THRESHOLD, data->static_screen_threshold); - return 0; + return 0; } /** @@ -1295,7 +1296,7 @@ static int fiji_process_firmware_header(struct pp_hwmgr *hwmgr) error |= (0 != result); - return error ? -1 : 0; + return error ? -1 : 0; } /* Copy one arb setting to another and then switch the active set. @@ -1339,12 +1340,12 @@ static int fiji_copy_and_switch_arb_sets(struct pp_hwmgr *hwmgr, return -EINVAL; } - mc_cg_config = cgs_read_register(hwmgr->device, mmMC_CG_CONFIG); - mc_cg_config |= 0x0000000F; - cgs_write_register(hwmgr->device, mmMC_CG_CONFIG, mc_cg_config); - PHM_WRITE_FIELD(hwmgr->device, MC_ARB_CG, CG_ARB_REQ, arb_dest); + mc_cg_config = cgs_read_register(hwmgr->device, mmMC_CG_CONFIG); + mc_cg_config |= 0x0000000F; + cgs_write_register(hwmgr->device, mmMC_CG_CONFIG, mc_cg_config); + PHM_WRITE_FIELD(hwmgr->device, MC_ARB_CG, CG_ARB_REQ, arb_dest); - return 0; + return 0; } /** @@ -1927,17 +1928,17 @@ static int fiji_populate_single_graphic_level(struct pp_hwmgr *hwmgr, threshold = clock * data->fast_watermark_threshold / 100; - /* - * TODO: get minimum clocks from dal configaration - * PECI_GetMinClockSettings(hwmgr->pPECI, &minClocks); - */ - /* data->DisplayTiming.minClockInSR = minClocks.engineClockInSR; */ + /* + * TODO: get minimum clocks from dal configaration + * PECI_GetMinClockSettings(hwmgr->pPECI, &minClocks); + */ + /* data->DisplayTiming.minClockInSR = minClocks.engineClockInSR; */ - /* get level->DeepSleepDivId - if (phm_cap_enabled(hwmgr->platformDescriptor.platformCaps, PHM_PlatformCaps_SclkDeepSleep)) - { - level->DeepSleepDivId = PhwFiji_GetSleepDividerIdFromClock(hwmgr, clock, minClocks.engineClockInSR); - } */ + /* get level->DeepSleepDivId + if (phm_cap_enabled(hwmgr->platformDescriptor.platformCaps, PHM_PlatformCaps_SclkDeepSleep)) + { + level->DeepSleepDivId = PhwFiji_GetSleepDividerIdFromClock(hwmgr, clock, minClocks.engineClockInSR); + } */ /* Default to slow, highest DPM level will be * set to PPSMC_DISPLAY_WATERMARK_LOW later. @@ -2756,7 +2757,7 @@ static int fiji_populate_clock_stretcher_data_table(struct pp_hwmgr *hwmgr) SclkFrequency) / 100); if (fiji_clock_stretcher_lookup_table[stretch_amount2][0] < clock_freq_u16 && - fiji_clock_stretcher_lookup_table[stretch_amount2][1] > + fiji_clock_stretcher_lookup_table[stretch_amount2][1] > clock_freq_u16) { /* Program PWR_CKS_CNTL. CKS_USE_FOR_LOW_FREQ */ value |= (fiji_clock_stretcher_lookup_table[stretch_amount2][3]) << 16; @@ -3172,9 +3173,9 @@ static int fiji_enable_sclk_mclk_dpm(struct pp_hwmgr *hwmgr) /* enable SCLK dpm */ if(!data->sclk_dpm_key_disabled) PP_ASSERT_WITH_CODE( - (0 == smum_send_msg_to_smc(hwmgr->smumgr, PPSMC_MSG_DPM_Enable)), - "Failed to enable SCLK DPM during DPM Start Function!", - return -1); + (0 == smum_send_msg_to_smc(hwmgr->smumgr, PPSMC_MSG_DPM_Enable)), + "Failed to enable SCLK DPM during DPM Start Function!", + return -1); /* enable MCLK dpm */ if(0 == data->mclk_dpm_key_disabled) { @@ -3320,7 +3321,7 @@ static int fiji_start_dpm(struct pp_hwmgr *hwmgr) return -1); } - return 0; + return 0; } static void fiji_set_dpm_event_sources(struct pp_hwmgr *hwmgr, @@ -3378,7 +3379,7 @@ static int fiji_enable_auto_throttle_source(struct pp_hwmgr *hwmgr, static int fiji_enable_thermal_auto_throttle(struct pp_hwmgr *hwmgr) { - return fiji_enable_auto_throttle_source(hwmgr, PHM_AutoThrottleSource_Thermal); + return fiji_enable_auto_throttle_source(hwmgr, PHM_AutoThrottleSource_Thermal); } static int fiji_enable_dpm_tasks(struct pp_hwmgr *hwmgr) diff --git a/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_powertune.c b/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_powertune.c index f89c98fd759e..6efcb2bac45f 100644 --- a/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_powertune.c +++ b/drivers/gpu/drm/amd/powerplay/hwmgr/fiji_powertune.c @@ -93,9 +93,9 @@ void fiji_initialize_power_tune_defaults(struct pp_hwmgr *hwmgr) */ static uint16_t scale_fan_gain_settings(uint16_t raw_setting) { - uint32_t tmp; - tmp = raw_setting * 4096 / 100; - return (uint16_t)tmp; + uint32_t tmp; + tmp = raw_setting * 4096 / 100; + return (uint16_t)tmp; } static void get_scl_sda_value(uint8_t line, uint8_t *scl, uint8_t* sda) @@ -546,8 +546,8 @@ int fiji_power_control_set_level(struct pp_hwmgr *hwmgr) * but message to be 8 bit fraction for messages */ target_tdp = ((100 + adjust_percent) * (int)(cac_table->usTDP * 256)) / 100; - result = fiji_set_overdriver_target_tdp(hwmgr, (uint32_t)target_tdp); - } + result = fiji_set_overdriver_target_tdp(hwmgr, (uint32_t)target_tdp); + } - return result; + return result; } diff --git a/drivers/gpu/drm/amd/powerplay/hwmgr/hardwaremanager.c b/drivers/gpu/drm/amd/powerplay/hwmgr/hardwaremanager.c index 001b8bb4143d..f9bf4fccbc79 100644 --- a/drivers/gpu/drm/amd/powerplay/hwmgr/hardwaremanager.c +++ b/drivers/gpu/drm/amd/powerplay/hwmgr/hardwaremanager.c @@ -317,4 +317,3 @@ int phm_set_cpu_power_state(struct pp_hwmgr *hwmgr) return 0; } - diff --git a/drivers/gpu/drm/amd/powerplay/hwmgr/ppevvmath.h b/drivers/gpu/drm/amd/powerplay/hwmgr/ppevvmath.h index 411cb0fcdf98..b7429a527828 100644 --- a/drivers/gpu/drm/amd/powerplay/hwmgr/ppevvmath.h +++ b/drivers/gpu/drm/amd/powerplay/hwmgr/ppevvmath.h @@ -117,379 +117,380 @@ int GetRoundedValue(fInt); /* Incomplete function - Usef */ fInt fExponential(fInt exponent) /*Can be used to calculate e^exponent*/ { - uint32_t i; - bool bNegated = false; + uint32_t i; + bool bNegated = false; - fInt fPositiveOne = ConvertToFraction(1); - fInt fZERO = ConvertToFraction(0); + fInt fPositiveOne = ConvertToFraction(1); + fInt fZERO = ConvertToFraction(0); - fInt lower_bound = Divide(78, 10000); - fInt solution = fPositiveOne; /*Starting off with baseline of 1 */ - fInt error_term; + fInt lower_bound = Divide(78, 10000); + fInt solution = fPositiveOne; /*Starting off with baseline of 1 */ + fInt error_term; - uint32_t k_array[11] = {55452, 27726, 13863, 6931, 4055, 2231, 1178, 606, 308, 155, 78}; - uint32_t expk_array[11] = {2560000, 160000, 40000, 20000, 15000, 12500, 11250, 10625, 10313, 10156, 10078}; + uint32_t k_array[11] = {55452, 27726, 13863, 6931, 4055, 2231, 1178, 606, 308, 155, 78}; + uint32_t expk_array[11] = {2560000, 160000, 40000, 20000, 15000, 12500, 11250, 10625, 10313, 10156, 10078}; - if (GreaterThan(fZERO, exponent)) { - exponent = fNegate(exponent); - bNegated = true; - } + if (GreaterThan(fZERO, exponent)) { + exponent = fNegate(exponent); + bNegated = true; + } - while (GreaterThan(exponent, lower_bound)) { - for (i = 0; i < 11; i++) { - if (GreaterThan(exponent, GetScaledFraction(k_array[i], 10000))) { - exponent = fSubtract(exponent, GetScaledFraction(k_array[i], 10000)); - solution = fMultiply(solution, GetScaledFraction(expk_array[i], 10000)); - } - } - } + while (GreaterThan(exponent, lower_bound)) { + for (i = 0; i < 11; i++) { + if (GreaterThan(exponent, GetScaledFraction(k_array[i], 10000))) { + exponent = fSubtract(exponent, GetScaledFraction(k_array[i], 10000)); + solution = fMultiply(solution, GetScaledFraction(expk_array[i], 10000)); + } + } + } - error_term = fAdd(fPositiveOne, exponent); + error_term = fAdd(fPositiveOne, exponent); - solution = fMultiply(solution, error_term); + solution = fMultiply(solution, error_term); - if (bNegated) - solution = fDivide(fPositiveOne, solution); + if (bNegated) + solution = fDivide(fPositiveOne, solution); - return solution; + return solution; } fInt fNaturalLog(fInt value) { - uint32_t i; - fInt upper_bound = Divide(8, 1000); - fInt fNegativeOne = ConvertToFraction(-1); - fInt solution = ConvertToFraction(0); /*Starting off with baseline of 0 */ - fInt error_term; - - uint32_t k_array[10] = {160000, 40000, 20000, 15000, 12500, 11250, 10625, 10313, 10156, 10078}; - uint32_t logk_array[10] = {27726, 13863, 6931, 4055, 2231, 1178, 606, 308, 155, 78}; - - while (GreaterThan(fAdd(value, fNegativeOne), upper_bound)) { - for (i = 0; i < 10; i++) { - if (GreaterThan(value, GetScaledFraction(k_array[i], 10000))) { - value = fDivide(value, GetScaledFraction(k_array[i], 10000)); - solution = fAdd(solution, GetScaledFraction(logk_array[i], 10000)); - } - } - } - - error_term = fAdd(fNegativeOne, value); - - return (fAdd(solution, error_term)); + uint32_t i; + fInt upper_bound = Divide(8, 1000); + fInt fNegativeOne = ConvertToFraction(-1); + fInt solution = ConvertToFraction(0); /*Starting off with baseline of 0 */ + fInt error_term; + + uint32_t k_array[10] = {160000, 40000, 20000, 15000, 12500, 11250, 10625, 10313, 10156, 10078}; + uint32_t logk_array[10] = {27726, 13863, 6931, 4055, 2231, 1178, 606, 308, 155, 78}; + + while (GreaterThan(fAdd(value, fNegativeOne), upper_bound)) { + for (i = 0; i < 10; i++) { + if (GreaterThan(value, GetScaledFraction(k_array[i], 10000))) { + value = fDivide(value, GetScaledFraction(k_array[i], 10000)); + solution = fAdd(solution, GetScaledFraction(logk_array[i], 10000)); + } + } + } + + error_term = fAdd(fNegativeOne, value); + + return (fAdd(solution, error_term)); } fInt fDecodeLinearFuse(uint32_t fuse_value, fInt f_min, fInt f_range, uint32_t bitlength) { - fInt f_fuse_value = Convert_ULONG_ToFraction(fuse_value); - fInt f_bit_max_value = Convert_ULONG_ToFraction((uPow(2, bitlength)) - 1); + fInt f_fuse_value = Convert_ULONG_ToFraction(fuse_value); + fInt f_bit_max_value = Convert_ULONG_ToFraction((uPow(2, bitlength)) - 1); - fInt f_decoded_value; + fInt f_decoded_value; - f_decoded_value = fDivide(f_fuse_value, f_bit_max_value); - f_decoded_value = fMultiply(f_decoded_value, f_range); - f_decoded_value = fAdd(f_decoded_value, f_min); + f_decoded_value = fDivide(f_fuse_value, f_bit_max_value); + f_decoded_value = fMultiply(f_decoded_value, f_range); + f_decoded_value = fAdd(f_decoded_value, f_min); - return f_decoded_value; + return f_decoded_value; } fInt fDecodeLogisticFuse(uint32_t fuse_value, fInt f_average, fInt f_range, uint32_t bitlength) { - fInt f_fuse_value = Convert_ULONG_ToFraction(fuse_value); - fInt f_bit_max_value = Convert_ULONG_ToFraction((uPow(2, bitlength)) - 1); + fInt f_fuse_value = Convert_ULONG_ToFraction(fuse_value); + fInt f_bit_max_value = Convert_ULONG_ToFraction((uPow(2, bitlength)) - 1); - fInt f_CONSTANT_NEG13 = ConvertToFraction(-13); - fInt f_CONSTANT1 = ConvertToFraction(1); + fInt f_CONSTANT_NEG13 = ConvertToFraction(-13); + fInt f_CONSTANT1 = ConvertToFraction(1); - fInt f_decoded_value; + fInt f_decoded_value; - f_decoded_value = fSubtract(fDivide(f_bit_max_value, f_fuse_value), f_CONSTANT1); - f_decoded_value = fNaturalLog(f_decoded_value); - f_decoded_value = fMultiply(f_decoded_value, fDivide(f_range, f_CONSTANT_NEG13)); - f_decoded_value = fAdd(f_decoded_value, f_average); + f_decoded_value = fSubtract(fDivide(f_bit_max_value, f_fuse_value), f_CONSTANT1); + f_decoded_value = fNaturalLog(f_decoded_value); + f_decoded_value = fMultiply(f_decoded_value, fDivide(f_range, f_CONSTANT_NEG13)); + f_decoded_value = fAdd(f_decoded_value, f_average); - return f_decoded_value; + return f_decoded_value; } fInt fDecodeLeakageID (uint32_t leakageID_fuse, fInt ln_max_div_min, fInt f_min, uint32_t bitlength) { - fInt fLeakage; - fInt f_bit_max_value = Convert_ULONG_ToFraction((uPow(2, bitlength)) - 1); + fInt fLeakage; + fInt f_bit_max_value = Convert_ULONG_ToFraction((uPow(2, bitlength)) - 1); - fLeakage = fMultiply(ln_max_div_min, Convert_ULONG_ToFraction(leakageID_fuse)); - fLeakage = fDivide(fLeakage, f_bit_max_value); - fLeakage = fExponential(fLeakage); - fLeakage = fMultiply(fLeakage, f_min); + fLeakage = fMultiply(ln_max_div_min, Convert_ULONG_ToFraction(leakageID_fuse)); + fLeakage = fDivide(fLeakage, f_bit_max_value); + fLeakage = fExponential(fLeakage); + fLeakage = fMultiply(fLeakage, f_min); - return fLeakage; + return fLeakage; } fInt ConvertToFraction(int X) /*Add all range checking here. Is it possible to make fInt a private declaration? */ { - fInt temp; + fInt temp; - if (X <= MAX) - temp.full = (X << SHIFT_AMOUNT); - else - temp.full = 0; + if (X <= MAX) + temp.full = (X << SHIFT_AMOUNT); + else + temp.full = 0; - return temp; + return temp; } fInt fNegate(fInt X) { - fInt CONSTANT_NEGONE = ConvertToFraction(-1); - return (fMultiply(X, CONSTANT_NEGONE)); + fInt CONSTANT_NEGONE = ConvertToFraction(-1); + return (fMultiply(X, CONSTANT_NEGONE)); } fInt Convert_ULONG_ToFraction(uint32_t X) { - fInt temp; + fInt temp; - if (X <= MAX) - temp.full = (X << SHIFT_AMOUNT); - else - temp.full = 0; + if (X <= MAX) + temp.full = (X << SHIFT_AMOUNT); + else + temp.full = 0; - return temp; + return temp; } fInt GetScaledFraction(int X, int factor) { - int times_shifted, factor_shifted; - bool bNEGATED; - fInt fValue; - - times_shifted = 0; - factor_shifted = 0; - bNEGATED = false; - - if (X < 0) { - X = -1*X; - bNEGATED = true; - } - - if (factor < 0) { - factor = -1*factor; - - bNEGATED = !bNEGATED; /*If bNEGATED = true due to X < 0, this will cover the case of negative cancelling negative */ - } - - if ((X > MAX) || factor > MAX) { - if ((X/factor) <= MAX) { - while (X > MAX) { - X = X >> 1; - times_shifted++; - } - - while (factor > MAX) { - factor = factor >> 1; - factor_shifted++; - } - } else { - fValue.full = 0; - return fValue; - } - } - - if (factor == 1) - return (ConvertToFraction(X)); - - fValue = fDivide(ConvertToFraction(X * uPow(-1, bNEGATED)), ConvertToFraction(factor)); - - fValue.full = fValue.full << times_shifted; - fValue.full = fValue.full >> factor_shifted; - - return fValue; + int times_shifted, factor_shifted; + bool bNEGATED; + fInt fValue; + + times_shifted = 0; + factor_shifted = 0; + bNEGATED = false; + + if (X < 0) { + X = -1*X; + bNEGATED = true; + } + + if (factor < 0) { + factor = -1*factor; + bNEGATED = !bNEGATED; /*If bNEGATED = true due to X < 0, this will cover the case of negative cancelling negative */ + } + + if ((X > MAX) || factor > MAX) { + if ((X/factor) <= MAX) { + while (X > MAX) { + X = X >> 1; + times_shifted++; + } + + while (factor > MAX) { + factor = factor >> 1; + factor_shifted++; + } + } else { + fValue.full = 0; + return fValue; + } + } + + if (factor == 1) + return (ConvertToFraction(X)); + + fValue = fDivide(ConvertToFraction(X * uPow(-1, bNEGATED)), ConvertToFraction(factor)); + + fValue.full = fValue.full << times_shifted; + fValue.full = fValue.full >> factor_shifted; + + return fValue; } /* Addition using two fInts */ fInt fAdd (fInt X, fInt Y) { - fInt Sum; + fInt Sum; - Sum.full = X.full + Y.full; + Sum.full = X.full + Y.full; - return Sum; + return Sum; } /* Addition using two fInts */ fInt fSubtract (fInt X, fInt Y) { - fInt Difference; + fInt Difference; - Difference.full = X.full - Y.full; + Difference.full = X.full - Y.full; - return Difference; + return Difference; } bool Equal(fInt A, fInt B) { - if (A.full == B.full) - return true; - else - return false; + if (A.full == B.full) + return true; + else + return false; } bool GreaterThan(fInt A, fInt B) { - if (A.full > B.full) - return true; - else - return false; + if (A.full > B.full) + return true; + else + return false; } fInt fMultiply (fInt X, fInt Y) /* Uses 64-bit integers (int64_t) */ { - fInt Product; - int64_t tempProduct; - bool X_LessThanOne, Y_LessThanOne; + fInt Product; + int64_t tempProduct; + bool X_LessThanOne, Y_LessThanOne; - X_LessThanOne = (X.partial.real == 0 && X.partial.decimal != 0 && X.full >= 0); - Y_LessThanOne = (Y.partial.real == 0 && Y.partial.decimal != 0 && Y.full >= 0); + X_LessThanOne = (X.partial.real == 0 && X.partial.decimal != 0 && X.full >= 0); + Y_LessThanOne = (Y.partial.real == 0 && Y.partial.decimal != 0 && Y.full >= 0); - /*The following is for a very specific common case: Non-zero number with ONLY fractional portion*/ - /* TEMPORARILY DISABLED - CAN BE USED TO IMPROVE PRECISION + /*The following is for a very specific common case: Non-zero number with ONLY fractional portion*/ + /* TEMPORARILY DISABLED - CAN BE USED TO IMPROVE PRECISION - if (X_LessThanOne && Y_LessThanOne) { - Product.full = X.full * Y.full; - return Product - }*/ + if (X_LessThanOne && Y_LessThanOne) { + Product.full = X.full * Y.full; + return Product + }*/ - tempProduct = ((int64_t)X.full) * ((int64_t)Y.full); /*Q(16,16)*Q(16,16) = Q(32, 32) - Might become a negative number! */ - tempProduct = tempProduct >> 16; /*Remove lagging 16 bits - Will lose some precision from decimal; */ - Product.full = (int)tempProduct; /*The int64_t will lose the leading 16 bits that were part of the integer portion */ + tempProduct = ((int64_t)X.full) * ((int64_t)Y.full); /*Q(16,16)*Q(16,16) = Q(32, 32) - Might become a negative number! */ + tempProduct = tempProduct >> 16; /*Remove lagging 16 bits - Will lose some precision from decimal; */ + Product.full = (int)tempProduct; /*The int64_t will lose the leading 16 bits that were part of the integer portion */ - return Product; + return Product; } fInt fDivide (fInt X, fInt Y) { - fInt fZERO, fQuotient; - int64_t longlongX, longlongY; + fInt fZERO, fQuotient; + int64_t longlongX, longlongY; - fZERO = ConvertToFraction(0); + fZERO = ConvertToFraction(0); - if (Equal(Y, fZERO)) - return fZERO; + if (Equal(Y, fZERO)) + return fZERO; - longlongX = (int64_t)X.full; - longlongY = (int64_t)Y.full; + longlongX = (int64_t)X.full; + longlongY = (int64_t)Y.full; - longlongX = longlongX << 16; /*Q(16,16) -> Q(32,32) */ + longlongX = longlongX << 16; /*Q(16,16) -> Q(32,32) */ - div64_s64(longlongX, longlongY); /*Q(32,32) divided by Q(16,16) = Q(16,16) Back to original format */ + div64_s64(longlongX, longlongY); /*Q(32,32) divided by Q(16,16) = Q(16,16) Back to original format */ - fQuotient.full = (int)longlongX; - return fQuotient; + fQuotient.full = (int)longlongX; + return fQuotient; } int ConvertBackToInteger (fInt A) /*THIS is the function that will be used to check with the Golden settings table*/ { - fInt fullNumber, scaledDecimal, scaledReal; + fInt fullNumber, scaledDecimal, scaledReal; - scaledReal.full = GetReal(A) * uPow(10, PRECISION-1); /* DOUBLE CHECK THISSSS!!! */ + scaledReal.full = GetReal(A) * uPow(10, PRECISION-1); /* DOUBLE CHECK THISSSS!!! */ - scaledDecimal.full = uGetScaledDecimal(A); + scaledDecimal.full = uGetScaledDecimal(A); - fullNumber = fAdd(scaledDecimal,scaledReal); + fullNumber = fAdd(scaledDecimal,scaledReal); - return fullNumber.full; + return fullNumber.full; } fInt fGetSquare(fInt A) { - return fMultiply(A,A); + return fMultiply(A,A); } /* x_new = x_old - (x_old^2 - C) / (2 * x_old) */ fInt fSqrt(fInt num) { - fInt F_divide_Fprime, Fprime; - fInt test; - fInt twoShifted; - int seed, counter, error; - fInt x_new, x_old, C, y; + fInt F_divide_Fprime, Fprime; + fInt test; + fInt twoShifted; + int seed, counter, error; + fInt x_new, x_old, C, y; - fInt fZERO = ConvertToFraction(0); - /* (0 > num) is the same as (num < 0), i.e., num is negative */ - if (GreaterThan(fZERO, num) || Equal(fZERO, num)) - return fZERO; + fInt fZERO = ConvertToFraction(0); - C = num; + /* (0 > num) is the same as (num < 0), i.e., num is negative */ - if (num.partial.real > 3000) - seed = 60; - else if (num.partial.real > 1000) - seed = 30; - else if (num.partial.real > 100) - seed = 10; - else - seed = 2; + if (GreaterThan(fZERO, num) || Equal(fZERO, num)) + return fZERO; - counter = 0; + C = num; - if (Equal(num, fZERO)) /*Square Root of Zero is zero */ - return fZERO; + if (num.partial.real > 3000) + seed = 60; + else if (num.partial.real > 1000) + seed = 30; + else if (num.partial.real > 100) + seed = 10; + else + seed = 2; + + counter = 0; - twoShifted = ConvertToFraction(2); - x_new = ConvertToFraction(seed); + if (Equal(num, fZERO)) /*Square Root of Zero is zero */ + return fZERO; - do { - counter++; + twoShifted = ConvertToFraction(2); + x_new = ConvertToFraction(seed); - x_old.full = x_new.full; + do { + counter++; - test = fGetSquare(x_old); /*1.75*1.75 is reverting back to 1 when shifted down */ - y = fSubtract(test, C); /*y = f(x) = x^2 - C; */ + x_old.full = x_new.full; - Fprime = fMultiply(twoShifted, x_old); - F_divide_Fprime = fDivide(y, Fprime); + test = fGetSquare(x_old); /*1.75*1.75 is reverting back to 1 when shifted down */ + y = fSubtract(test, C); /*y = f(x) = x^2 - C; */ - x_new = fSubtract(x_old, F_divide_Fprime); + Fprime = fMultiply(twoShifted, x_old); + F_divide_Fprime = fDivide(y, Fprime); - error = ConvertBackToInteger(x_new) - ConvertBackToInteger(x_old); + x_new = fSubtract(x_old, F_divide_Fprime); - if (counter > 20) /*20 is already way too many iterations. If we dont have an answer by then, we never will*/ - return x_new; + error = ConvertBackToInteger(x_new) - ConvertBackToInteger(x_old); - } while (uAbs(error) > 0); + if (counter > 20) /*20 is already way too many iterations. If we dont have an answer by then, we never will*/ + return x_new; - return (x_new); + } while (uAbs(error) > 0); + + return (x_new); } void SolveQuadracticEqn(fInt A, fInt B, fInt C, fInt Roots[]) { - fInt* pRoots = &Roots[0]; - fInt temp, root_first, root_second; - fInt f_CONSTANT10, f_CONSTANT100; + fInt *pRoots = &Roots[0]; + fInt temp, root_first, root_second; + fInt f_CONSTANT10, f_CONSTANT100; - f_CONSTANT100 = ConvertToFraction(100); - f_CONSTANT10 = ConvertToFraction(10); + f_CONSTANT100 = ConvertToFraction(100); + f_CONSTANT10 = ConvertToFraction(10); - while(GreaterThan(A, f_CONSTANT100) || GreaterThan(B, f_CONSTANT100) || GreaterThan(C, f_CONSTANT100)) { - A = fDivide(A, f_CONSTANT10); - B = fDivide(B, f_CONSTANT10); - C = fDivide(C, f_CONSTANT10); - } + while(GreaterThan(A, f_CONSTANT100) || GreaterThan(B, f_CONSTANT100) || GreaterThan(C, f_CONSTANT100)) { + A = fDivide(A, f_CONSTANT10); + B = fDivide(B, f_CONSTANT10); + C = fDivide(C, f_CONSTANT10); + } - temp = fMultiply(ConvertToFraction(4), A); /* root = 4*A */ - temp = fMultiply(temp, C); /* root = 4*A*C */ - temp = fSubtract(fGetSquare(B), temp); /* root = b^2 - 4AC */ - temp = fSqrt(temp); /*root = Sqrt (b^2 - 4AC); */ + temp = fMultiply(ConvertToFraction(4), A); /* root = 4*A */ + temp = fMultiply(temp, C); /* root = 4*A*C */ + temp = fSubtract(fGetSquare(B), temp); /* root = b^2 - 4AC */ + temp = fSqrt(temp); /*root = Sqrt (b^2 - 4AC); */ - root_first = fSubtract(fNegate(B), temp); /* b - Sqrt(b^2 - 4AC) */ - root_second = fAdd(fNegate(B), temp); /* b + Sqrt(b^2 - 4AC) */ + root_first = fSubtract(fNegate(B), temp); /* b - Sqrt(b^2 - 4AC) */ + root_second = fAdd(fNegate(B), temp); /* b + Sqrt(b^2 - 4AC) */ - root_first = fDivide(root_first, ConvertToFraction(2)); /* [b +- Sqrt(b^2 - 4AC)]/[2] */ - root_first = fDivide(root_first, A); /*[b +- Sqrt(b^2 - 4AC)]/[2*A] */ + root_first = fDivide(root_first, ConvertToFraction(2)); /* [b +- Sqrt(b^2 - 4AC)]/[2] */ + root_first = fDivide(root_first, A); /*[b +- Sqrt(b^2 - 4AC)]/[2*A] */ - root_second = fDivide(root_second, ConvertToFraction(2)); /* [b +- Sqrt(b^2 - 4AC)]/[2] */ - root_second = fDivide(root_second, A); /*[b +- Sqrt(b^2 - 4AC)]/[2*A] */ + root_second = fDivide(root_second, ConvertToFraction(2)); /* [b +- Sqrt(b^2 - 4AC)]/[2] */ + root_second = fDivide(root_second, A); /*[b +- Sqrt(b^2 - 4AC)]/[2*A] */ - *(pRoots + 0) = root_first; - *(pRoots + 1) = root_second; + *(pRoots + 0) = root_first; + *(pRoots + 1) = root_second; } /* ----------------------------------------------------------------------------- @@ -500,61 +501,58 @@ void SolveQuadracticEqn(fInt A, fInt B, fInt C, fInt Roots[]) /* Addition using two normal ints - Temporary - Use only for testing purposes?. */ fInt Add (int X, int Y) { - fInt A, B, Sum; + fInt A, B, Sum; - A.full = (X << SHIFT_AMOUNT); - B.full = (Y << SHIFT_AMOUNT); + A.full = (X << SHIFT_AMOUNT); + B.full = (Y << SHIFT_AMOUNT); - Sum.full = A.full + B.full; + Sum.full = A.full + B.full; - return Sum; + return Sum; } /* Conversion Functions */ int GetReal (fInt A) { - return (A.full >> SHIFT_AMOUNT); + return (A.full >> SHIFT_AMOUNT); } /* Temporarily Disabled */ int GetRoundedValue(fInt A) /*For now, round the 3rd decimal place */ { - /* ROUNDING TEMPORARLY DISABLED - int temp = A.full; - - int decimal_cutoff, decimal_mask = 0x000001FF; - - decimal_cutoff = temp & decimal_mask; - - - if (decimal_cutoff > 0x147) { - temp += 673; - }*/ - - return ConvertBackToInteger(A)/10000; /*Temporary - in case this was used somewhere else */ + /* ROUNDING TEMPORARLY DISABLED + int temp = A.full; + int decimal_cutoff, decimal_mask = 0x000001FF; + decimal_cutoff = temp & decimal_mask; + if (decimal_cutoff > 0x147) { + temp += 673; + }*/ + + return ConvertBackToInteger(A)/10000; /*Temporary - in case this was used somewhere else */ } fInt Multiply (int X, int Y) { - fInt A, B, Product; + fInt A, B, Product; - A.full = X << SHIFT_AMOUNT; - B.full = Y << SHIFT_AMOUNT; + A.full = X << SHIFT_AMOUNT; + B.full = Y << SHIFT_AMOUNT; - Product = fMultiply(A, B); + Product = fMultiply(A, B); - return Product; + return Product; } + fInt Divide (int X, int Y) { - fInt A, B, Quotient; + fInt A, B, Quotient; - A.full = X << SHIFT_AMOUNT; - B.full = Y << SHIFT_AMOUNT; + A.full = X << SHIFT_AMOUNT; + B.full = Y << SHIFT_AMOUNT; - Quotient = fDivide(A, B); + Quotient = fDivide(A, B); - return Quotient; + return Quotient; } int uGetScaledDecimal (fInt A) /*Converts the fractional portion to whole integers - Costly function */ @@ -563,16 +561,13 @@ int uGetScaledDecimal (fInt A) /*Converts the fractional portion to whole intege int i, scaledDecimal = 0, tmp = A.partial.decimal; for (i = 0; i < PRECISION; i++) { - dec[i] = tmp / (1 << SHIFT_AMOUNT); - - tmp = tmp - ((1 << SHIFT_AMOUNT)*dec[i]); - - tmp *= 10; - - scaledDecimal = scaledDecimal + dec[i]*uPow(10, PRECISION - 1 -i); - } + dec[i] = tmp / (1 << SHIFT_AMOUNT); + tmp = tmp - ((1 << SHIFT_AMOUNT)*dec[i]); + tmp *= 10; + scaledDecimal = scaledDecimal + dec[i]*uPow(10, PRECISION - 1 -i); + } - return scaledDecimal; + return scaledDecimal; } int uPow(int base, int power) @@ -601,17 +596,17 @@ int uAbs(int X) fInt fRoundUpByStepSize(fInt A, fInt fStepSize, bool error_term) { - fInt solution; + fInt solution; - solution = fDivide(A, fStepSize); - solution.partial.decimal = 0; /*All fractional digits changes to 0 */ + solution = fDivide(A, fStepSize); + solution.partial.decimal = 0; /*All fractional digits changes to 0 */ - if (error_term) - solution.partial.real += 1; /*Error term of 1 added */ + if (error_term) + solution.partial.real += 1; /*Error term of 1 added */ - solution = fMultiply(solution, fStepSize); - solution = fAdd(solution, fStepSize); + solution = fMultiply(solution, fStepSize); + solution = fAdd(solution, fStepSize); - return solution; + return solution; } diff --git a/drivers/gpu/drm/amd/powerplay/smumgr/fiji_smumgr.c b/drivers/gpu/drm/amd/powerplay/smumgr/fiji_smumgr.c index 45997e609fd6..21c31db0df26 100644 --- a/drivers/gpu/drm/amd/powerplay/smumgr/fiji_smumgr.c +++ b/drivers/gpu/drm/amd/powerplay/smumgr/fiji_smumgr.c @@ -228,9 +228,9 @@ int fiji_send_msg_to_smc(struct pp_smumgr *smumgr, uint16_t msg) } cgs_write_register(smumgr->device, mmSMC_MESSAGE_0, msg); - SMUM_WAIT_FIELD_UNEQUAL(smumgr, SMC_RESP_0, SMC_RESP, 0); + SMUM_WAIT_FIELD_UNEQUAL(smumgr, SMC_RESP_0, SMC_RESP, 0); - return 0; + return 0; } /** @@ -557,7 +557,7 @@ static int fiji_request_smu_specific_fw_load(struct pp_smumgr *smumgr, uint32_t /* For non-virtualization cases, * SMU loads all FWs at once in fiji_request_smu_load_fw. */ - return 0; + return 0; } static int fiji_start_smu_in_protection_mode(struct pp_smumgr *smumgr) @@ -723,7 +723,7 @@ static int fiji_start_avfs_btc(struct pp_smumgr *smumgr) /* clear reset */ cgs_write_register(smumgr->device, mmGRBM_SOFT_RESET, 0); - return result; + return result; } int fiji_setup_pm_fuse_for_avfs(struct pp_smumgr *smumgr) -- 2.20.1