litmus-rt.git - The LITMUS^RT kernel.

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author	Ingo Molnar <mingo@elte.hu>	2011-05-10 11:05:24 -0400
committer	Ingo Molnar <mingo@elte.hu>	2011-05-10 11:05:45 -0400
commit	932fed4e2e42c3d730c01bb63b1c4f812c533d5b (patch)
tree	11b1afac3a40d253cdb905c42901edfaae5e196e /kernel/mutex-debug.h
parent	57d524154ffe99d27fb55e0e30ddbad9f4c35806 (diff)
parent	693d92a1bbc9e42681c42ed190bd42b636ca876f (diff)

Merge commit 'v2.6.39-rc7' into perf/core

Merge reason: pull in the latest fixes. Signed-off-by: Ingo Molnar <mingo@elte.hu>

Diffstat (limited to 'kernel/mutex-debug.h')

0 files changed, 0 insertions, 0 deletions

/* * Copyright (c) 2012-2017, NVIDIA CORPORATION. All rights reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ /* * Function naming determines intended use: * * <x>_r(void) : Returns the offset for register <x>. * * <x>_o(void) : Returns the offset for element <x>. * * <x>_w(void) : Returns the word offset for word (4 byte) element <x>. * * <x>_<y>_s(void) : Returns size of field <y> of register <x> in bits. * * <x>_<y>_f(u32 v) : Returns a value based on 'v' which has been shifted * and masked to place it at field <y> of register <x>. This value * can be |'d with others to produce a full register value for * register <x>. * * <x>_<y>_m(void) : Returns a mask for field <y> of register <x>. This * value can be ~'d and then &'d to clear the value of field <y> for * register <x>. * * <x>_<y>_<z>_f(void) : Returns the constant value <z> after being shifted * to place it at field <y> of register <x>. This value can be |'d * with others to produce a full register value for <x>. * * <x>_<y>_v(u32 r) : Returns the value of field <y> from a full register * <x> value 'r' after being shifted to place its LSB at bit 0. * This value is suitable for direct comparison with other unshifted * values appropriate for use in field <y> of register <x>. * * <x>_<y>_<z>_v(void) : Returns the constant value for <z> defined for * field <y> of register <x>. This value is suitable for direct * comparison with unshifted values appropriate for use in field <y> * of register <x>. */ #ifndef _hw_therm_gk20a_h_ #define _hw_therm_gk20a_h_ static inline u32 therm_use_a_r(void) { return 0x00020798U; } static inline u32 therm_use_a_ext_therm_0_enable_f(void) { return 0x1U; } static inline u32 therm_use_a_ext_therm_1_enable_f(void) { return 0x2U; } static inline u32 therm_use_a_ext_therm_2_enable_f(void) { return 0x4U; } static inline u32 therm_evt_ext_therm_0_r(void) { return 0x00020700U; } static inline u32 therm_evt_ext_therm_0_slow_factor_f(u32 v) { return (v & 0x3fU) << 8U; } static inline u32 therm_evt_ext_therm_0_slow_factor_init_v(void) { return 0x00000000U; } static inline u32 therm_evt_ext_therm_0_priority_f(u32 v) { return (v & 0x1fU) << 24U; } static inline u32 therm_evt_ext_therm_1_r(void) { return 0x00020704U; } static inline u32 therm_evt_ext_therm_1_slow_factor_f(u32 v) { return (v & 0x3fU) << 8U; } static inline u32 therm_evt_ext_therm_1_slow_factor_init_v(void) { return 0x00000000U; } static inline u32 therm_evt_ext_therm_1_priority_f(u32 v) { return (v & 0x1fU) << 24U; } static inline u32 therm_evt_ext_therm_2_r(void) { return 0x00020708U; } static inline u32 therm_evt_ext_therm_2_slow_factor_f(u32 v) { return (v & 0x3fU) << 8U; } static inline u32 therm_evt_ext_therm_2_slow_factor_init_v(void) { return 0x00000000U; } static inline u32 therm_evt_ext_therm_2_priority_f(u32 v) { return (v & 0x1fU) << 24U; } static inline u32 therm_weight_1_r(void) { return 0x00020024U; } static inline u32 therm_config1_r(void) { return 0x00020050U; } static inline u32 therm_config2_r(void) { return 0x00020130U; } static inline u32 therm_config2_slowdown_factor_extended_f(u32 v) { return (v & 0x1U) << 24U; } static inline u32 therm_config2_grad_enable_f(u32 v) { return (v & 0x1U) << 31U; } static inline u32 therm_gate_ctrl_r(u32 i) { return 0x00020200U + i*4U; } static inline u32 therm_gate_ctrl_eng_clk_m(void) { return 0x3U << 0U; } static inline u32 therm_gate_ctrl_eng_clk_run_f(void) { return 0x0U; } static inline u32 therm_gate_ctrl_eng_clk_auto_f(void) { return 0x1U; } static inline u32 therm_gate_ctrl_eng_clk_stop_f(void) { return 0x2U; } static inline u32 therm_gate_ctrl_blk_clk_m(void) { return 0x3U << 2U; } static inline u32 therm_gate_ctrl_blk_clk_run_f(void) { return 0x0U; } static inline u32 therm_gate_ctrl_blk_clk_auto_f(void) { return 0x4U; } static inline u32 therm_gate_ctrl_eng_pwr_m(void) { return 0x3U << 4U; } static inline u32 therm_gate_ctrl_eng_pwr_auto_f(void) { return 0x10U; } static inline u32 therm_gate_ctrl_eng_pwr_off_v(void) { return 0x00000002U; } static inline u32 therm_gate_ctrl_eng_pwr_off_f(void) { return 0x20U; } static inline u32 therm_gate_ctrl_eng_idle_filt_exp_f(u32 v) { return (v & 0x1fU) << 8U; } static inline u32 therm_gate_ctrl_eng_idle_filt_exp_m(void) { return 0x1fU << 8U; } static inline u32 therm_gate_ctrl_eng_idle_filt_mant_f(u32 v) { return (v & 0x7U) << 13U; } static inline u32 therm_gate_ctrl_eng_idle_filt_mant_m(void) { return 0x7U << 13U; } static inline u32 therm_gate_ctrl_eng_delay_before_f(u32 v) { return (v & 0xfU) << 16U; } static inline u32 therm_gate_ctrl_eng_delay_before_m(void) { return 0xfU << 16U; } static inline u32 therm_gate_ctrl_eng_delay_after_f(u32 v) { return (v & 0xfU) << 20U; } static inline u32 therm_gate_ctrl_eng_delay_after_m(void) { return 0xfU << 20U; } static inline u32 therm_fecs_idle_filter_r(void) { return 0x00020288U; } static inline u32 therm_fecs_idle_filter_value_m(void) { return 0xffffffffU << 0U; } static inline u32 therm_hubmmu_idle_filter_r(void) { return 0x0002028cU; } static inline u32 therm_hubmmu_idle_filter_value_m(void) { return 0xffffffffU << 0U; } static inline u32 therm_clk_slowdown_r(u32 i) { return 0x00020160U + i*4U; } static inline u32 therm_clk_slowdown_idle_factor_f(u32 v) { return (v & 0x3fU) << 16U; } static inline u32 therm_clk_slowdown_idle_factor_m(void) { return 0x3fU << 16U; } static inline u32 therm_clk_slowdown_idle_factor_v(u32 r) { return (r >> 16U) & 0x3fU; } static inline u32 therm_clk_slowdown_idle_factor_disabled_f(void) { return 0x0U; } static inline u32 therm_grad_stepping_table_r(u32 i) { return 0x000202c8U + i*4U; } static inline u32 therm_grad_stepping_table_slowdown_factor0_f(u32 v) { return (v & 0x3fU) << 0U; } static inline u32 therm_grad_stepping_table_slowdown_factor0_m(void) { return 0x3fU << 0U; } static inline u32 therm_grad_stepping_table_slowdown_factor0_fpdiv_by1p5_f(void) { return 0x1U; } static inline u32 therm_grad_stepping_table_slowdown_factor0_fpdiv_by2_f(void) { return 0x2U; } static inline u32 therm_grad_stepping_table_slowdown_factor0_fpdiv_by4_f(void) { return 0x6U; } static inline u32 therm_grad_stepping_table_slowdown_factor0_fpdiv_by8_f(void) { return 0xeU; } static inline u32 therm_grad_stepping_table_slowdown_factor1_f(u32 v) { return (v & 0x3fU) << 6U; } static inline u32 therm_grad_stepping_table_slowdown_factor1_m(void) { return 0x3fU << 6U; } static inline u32 therm_grad_stepping_table_slowdown_factor2_f(u32 v) { return (v & 0x3fU) << 12U; } static inline u32 therm_grad_stepping_table_slowdown_factor2_m(void) { return 0x3fU << 12U; } static inline u32 therm_grad_stepping_table_slowdown_factor3_f(u32 v) { return (v & 0x3fU) << 18U; } static inline u32 therm_grad_stepping_table_slowdown_factor3_m(void) { return 0x3fU << 18U; } static inline u32 therm_grad_stepping_table_slowdown_factor4_f(u32 v) { return (v & 0x3fU) << 24U; } static inline u32 therm_grad_stepping_table_slowdown_factor4_m(void) { return 0x3fU << 24U; } static inline u32 therm_grad_stepping0_r(void) { return 0x000202c0U; } static inline u32 therm_grad_stepping0_feature_s(void) { return 1U; } static inline u32 therm_grad_stepping0_feature_f(u32 v) { return (v & 0x1U) << 0U; } static inline u32 therm_grad_stepping0_feature_m(void) { return 0x1U << 0U; } static inline u32 therm_grad_stepping0_feature_v(u32 r) { return (r >> 0U) & 0x1U; } static inline u32 therm_grad_stepping0_feature_enable_f(void) { return 0x1U; } static inline u32 therm_grad_stepping1_r(void) { return 0x000202c4U; } static inline u32 therm_grad_stepping1_pdiv_duration_f(u32 v) { return (v & 0x1ffffU) << 0U; } static inline u32 therm_clk_timing_r(u32 i) { return 0x000203c0U + i*4U; } static inline u32 therm_clk_timing_grad_slowdown_f(u32 v) { return (v & 0x1U) << 16U; } static inline u32 therm_clk_timing_grad_slowdown_m(void) { return 0x1U << 16U; } static inline u32 therm_clk_timing_grad_slowdown_enabled_f(void) { return 0x10000U; } #endif


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