// Copyright (c) 2020 Intel Corporation // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #pragma once #include #include #include #include #include namespace cpu_info { namespace sst { /** * Initialize SST subsystem. * * This will schedule work to be done when the host is ready, in order to * retrieve all SST configuration info for all discoverable CPUs, and publish * the info on new D-Bus objects on the given bus connection. */ void init(); class PECIError : public std::runtime_error { using std::runtime_error::runtime_error; }; bool checkPECIStatus(EPECIStatus libStatus, uint8_t completionCode); constexpr int extendedModel(CPUModel model) { return (model >> 16) & 0xF; } /** * Construct a list of indexes of the set bits in the input value. * E.g. fn(0x7A) -> {1,3,4,5,6} * * @param[in] mask Bitmask to convert. * * @return List of bit indexes. */ std::vector convertMaskToList(std::bitset<64> mask); using TurboEntry = std::tuple; /** * Abstract interface that must be implemented by backends, allowing discovery * and control of a single CPU package. */ class SSTInterface { public: virtual ~SSTInterface() {} /** * Whether the interface is ready to be used, or we need to wait longer. The * backend may need to wait e.g. for the host BIOS to initialize the * interface. */ virtual bool ready() = 0; /** Whether the processor supports the control ("set") functions. */ virtual bool supportsControl() = 0; /** Whether SST-PP is enabled on the processor. */ virtual bool ppEnabled() = 0; /** Return the current SST-PP configuration level */ virtual unsigned int currentLevel() = 0; /** Return the maximum valid SST-PP configuration level */ virtual unsigned int maxLevel() = 0; /** * Whether the given level is supported. The level indices may be * discontinuous, so this function should be used before querying deeper * properties of a level. */ virtual bool levelSupported(unsigned int level) = 0; /** Whether SST-BF is supported in a given level. */ virtual bool bfSupported(unsigned int level) = 0; /** Whether SST-TF is supported in a given level. */ virtual bool tfSupported(unsigned int level) = 0; /** Whether SST-BF is enabled in a given level. */ virtual bool bfEnabled(unsigned int level) = 0; /** Whether SST-TF is enabled in a given level. */ virtual bool tfEnabled(unsigned int level) = 0; /** Return the package Thermal Design Power in Watts for a given level. */ virtual unsigned int tdp(unsigned int level) = 0; /** Return the number of cores enabled in a given level. */ virtual unsigned int coreCount(unsigned int level) = 0; /** Return the list of enabled logical core indices for a given level. */ virtual std::vector enabledCoreList(unsigned int level) = 0; /** * Return the list of TurboEntrys which define the SSE turbo profile for a * given level. */ virtual std::vector sseTurboProfile(unsigned int level) = 0; /** Return the base frequency (P1) for a given level. */ virtual unsigned int p1Freq(unsigned int level) = 0; /** Return the maximum single-core frequency (P0) for a given level. */ virtual unsigned int p0Freq(unsigned int level) = 0; /** * Return the DTS max or external Prochot temperature in degrees Celsius * for a given level. */ virtual unsigned int prochotTemp(unsigned int level) = 0; /** * Return the list of logical core indices which have high priority when * SST-BF is enabled for a given level. */ virtual std::vector bfHighPriorityCoreList(unsigned int level) = 0; /** Return the high priority base frequency for a given level. */ virtual unsigned int bfHighPriorityFreq(unsigned int level) = 0; /** Return the low priority base frequency for a given level. */ virtual unsigned int bfLowPriorityFreq(unsigned int level) = 0; /** Enable or disable SST-BF for the current configuration. */ virtual void setBfEnabled(bool enable) = 0; /** Enable or disable SST-TF for the current configuration. */ virtual void setTfEnabled(bool enable) = 0; /** Change the current configuration to the given level. */ virtual void setCurrentLevel(unsigned int level) = 0; }; /** * Policy for whether the SST interface should wake up an idle CPU to complete * requested operations. Waking should be used sparingly to avoid excess CPU * power draw, so the policy depends on the context. */ enum WakePolicy { /** * If CPU rejects the request due to being in a low-power state, enable * wake-on-PECI on the CPU and retry. Wake-on-PECI is disabled for the CPU * when the SST interface is destroyed. */ wakeAllowed, /** * If CPU rejects the request due to being in a low-power state, it results * in a PECIError exception. */ dontWake }; /** * BackendProvider represents a function which may create an SSTInterface given * a CPU PECI address, and the CPU Model information. Usually the CPUModel is * sufficient to determine if the backend is supported. * Backend should return nullptr to indicate it doesn't support a given CPU. * The SST upper layer will call the registered backend provider functions in * arbitrary order until one of them returns a non-null pointer. */ using BackendProvider = std::function(uint8_t, CPUModel, WakePolicy)>; /** * Backends should use 1 instance of the SSTProviderRegistration macro at file * scope to register their provider function. This static struct instance * register the backend before main() is run, and prevents the upper layer from * having to know about which backends exist. */ #define SSTProviderRegistration(fn) \ struct fn##Register \ { \ fn##Register() \ { \ std::cerr << "Registering SST Provider " #fn << std::endl; \ registerBackend(fn); \ } \ } fn##Instance; void registerBackend(BackendProvider); } // namespace sst } // namespace cpu_info