Global CNC Metal Cutting Machine Tools Market 2025 – 2034

Reports Description

As per the CNC Metal Cutting Machine Tools Market analysis conducted by the CMI Team, the global CNC Metal cutting machine tools Market is expected to record a CAGR of 10.2% from 2025 to 2034. In 2025, the market size is projected to reach a valuation of USD 107.09 Billion. By 2034, the valuation is anticipated to reach USD 252.67 Billion.

Overview

CNC-equipped metal cutting tool machines are a cornerstone of contemporary industries, as they provide unrivaled accuracy, consistency, and efficiency in the shaping of metallic components. These systems simultaneously automated computer-controlled milling, turning, drilling, and even grinding processes, as they are capable of producing intricately detailed parts at breakneck speeds and with very little human intervention. These sectors are ubiquitous in aerospace, automotive, healthcare, and defense industries, as they significantly minimize error and material waste.

Vital for precision machining and mass production, these systems can perform uninterrupted processes at peak output and with strict precision limits. Now, these machines are augmented with AI, CAD/CAM software, and IoT-based monitoring, enabling predictive maintenance and adaptive machining. Their contribution to manufacturing processes within Industry 4.0 is tremendous, as they facilitate responsive supply chains to changing demands for customization and precision while encouraging sustainable practices.

Key Trends & Drivers

The CNC Metal cutting machine tools Market Trends have tremendous growth opportunities due to several reasons:

• Increased Automation and Smart Manufacturing: The rapid adoption of CNC Metal cutting machine tools is implemented alongside the advancement of Industry 4.0 technologies. This has surged the precision and efficiency with which contemporary manufacturing systems operate. Smart and automated production systems not only enhance accuracy but also reduce waste during production, aligning with contemporary corporate sustainability goals. Smart factories fully utilize CNC machines with real-time monitoring and adaptive control systems. Predictive maintenance and process optimization are possible through the integration with sensors, PLCs, and ERP systems, adding to the automation. Enhanced throughput and quality control while lowering the margin of human error is achieved. The adoption of smart manufacturing technologies drives the widespread use of CNC metal cutting tools in the electronics, defense, and energy industries.

• Aerospace and automotive sectors have a growing demand: The fields of aerospace and automotive require the high precision components that are made from hard materials like titanium aluminum alloys and hardened steel. For producing the engine blocks, turbine blades and transmission systems, the exacting quality and vertical tolerances of CNC metal cutting machines are indispensable. With the increasing aircraft production and new innovations in automotive technology, especially the focus on lightweight structures and fuel efficient vehicles, the need for advanced machining is increasing. The utilization of CNC Tools in any industry guarantees the required speed and precision for mass production, as there is no compromise in accuracy. There is continuous sustained demand for air travel and the electrification of automobiles, which fuels these industries.

• Elevated Need for Metal Customization: The new construction and shipbuilding industries are growing on a global scale. This increases the need for CNC metal cutting machines. There is a constructive and continuous change in these markets as they go through urbanization and industrialization, which has a great need for structural steel, fabricated parts, and tailored metal items. CNC machines lower the material waste while producing complex parts, which makes these machines economical. Fabrication shops and OEMs are also expanding as a result of government-supported infrastructure projects such as transportation and energy systems. Such active industrial development guarantees strong CNC machining sales, especially for systems able to work with different metals and large volumes of parts.

Key Threats

The CNC Metal cutting machine tools Market has several primary threats that will influence its profitability and future development. Some of the threats are:

• Substantial Initial and Ongoing Costs: The acquisition of CNC metal cutting machines necessitates considerable investment in diagnostic and manual training. Moreover, sophisticated automated multi-axis machines can exceed a hundred thousand dollars, posing financial challenges for many small and medium-sized enterprises. Along with software maintenance and tool upgrading, the machines accrue routine maintenance, which further increases the overall cost of the machines. Due to operating in a financially constrained environment, local manufacturers in emerging economies struggle to adopt CNC-driven automation because of insufficient financing or leasing options. Well-capitalized firms that could rapidly take advantage of these technologies are severely restricted in other ways. Firms in emerging economies thus grapple to harness automation powered by CNC technologies.

• Shortage of Skilled Operators and Programmers: The operation of CNC metal cutting machines is coupled with programming, maintenance, and troubleshooting, which creates a shortage of competent operators for these complex machines. There is a critical lack of CNC programmers, CAD/CAM professionals, and multi-axis machinists in the manufacturing field. Failing to keep pace with technological advancements has created a shortage of properly trained instructors, exacerbating the problem of unqualified operators. This shortage impacts productivity, utilization rates, and error margins. Investments in advanced CNC machinery go to waste for companies suffering from a lack of skilled workers because of the sophisticated training needed to maximize their functionality. Practically every segment of vocational education, industry training, and reskilling needs to be provided for in order to close the skills gap.

Opportunities

• Adoption in Emerging Markets: The Asia Pacific, Africa, and Latin America regions embrace New Industrialized Countries with their vast opportunities for trade on CNC metal cutting machine tools. Countries like India and Indonesia, Brazil, Germany, and Vietnam greatly require precision metalworking machinery to utilize in their manufacturing sectors and in infrastructures, along with a need for additional scaffolding metalworking tools. There is also an emergence of small to medium enterprises within the region that require economical and price efficient CNC solutions. Public manufacturing parks along with tax breaks and systems of subsidies all encourage the adoption of CNC machine tools. The greatest opportunities appear to be for the manufacturers who offer local servicing of competitively priced machinery, provide training for operators, and have more affordable machines.

• The Construction of Electric Vehicles (EVs) and Their Parts: Importance of Precision-Machined Components: The manufacturing of EVs, alongside the global adoption of electric vehicles, is contributing to a growing need for precision-machined components. EV parts such as motor housings, batteries, and structural frames require CNC machining. The integration of compact shapes and specialized materials as a thermal regulation component has optimized workflows and manufacturing processes further from automation. This is motivated by government policies promoting EV adoption, along with OEM (Original Equipment Manufacturer) automotive industry expansion. There is a substantially growing niche within the automotive industry, which will be explored by CNC manufacturers customizing their machines for specific materials and requirements associated with EVs.

• Integration with Digital Twin and Predictive Analytics: The integration of digital twin technologies alongside CNC machine tools and Predictive Analytics can greatly enhance their value. A digital twin allows a manufacturer to create an actual virtual replica of the machine or a part, which permits simulation of strategies, testing of tolerances, and detection of inefficiencies prior to production. With artificial intelligence (AI) and predictive analytics, machine data can also be leveraged to estimate tool wear, make cutting parameter adjustments, and avert breakdowns. Forecasting, in this case, helps eliminate interruptions, enhance quality, and minimize costs related to operations. Companies providing CNC systems that can interface with these technologies stand to capitalize on the growing demand for intelligent, data-centric, and automated manufacturing systems.

Category Wise Insights

By Type

• Metal Cutting: Within the CNC machine tool industry, metal cutting remains the leader in market share and includes milling, turning, and drilling. These CNC machines are critical for precision parts manufacturing in the automotive, aerospace, and general engineering industries. The advantages of CNC metal cutting tools include consistency, complex geometrical capability, and minimal material waste. Recent advancements in multi-axis machining and high-speed spindle integration have significantly improved throughput while maintaining tight tolerance capabilities. IoT and AI technologies also boost machine optimization and uptime. Continuous growth in this segment stems from the prolonged need for custom, long-lasting, and intricately designed metal components.

• Metal Forming: Activities performed by metal forming machines in the CNC sector include the non-extractive processes of shaping, bending, stamping, forging, or rolling. These tools are indispensable in the automotive and construction industries, which demand precision in metal parts shaping and consistent structural strength. Metal forming processes that are CNC controlled offer enhanced precision, streamlined production, and greater ease of automation. The shift towards lighter and stronger materials is increasing the adoption of advanced forming methods, for example, servo-pressing or hydroforming. Although they are still less prevalent than cutting tools, innovations in metalworking technology, software integration, and eco-friendly processes are advancing the use of metal forming equipment, making manufacturing more energy-efficient and sustainable.

By Application

• Automotive: The automotive industry has been one of the largest consumers of CNC machine tools in the metalworking industry, applying these tools for fabricating engine blocks, transmission systems, brake parts, and even body frames. The move to electric vehicles (EVs) has further increased the need for precision lightweight parts that are manufactured with lean technologies. CNC tools maintain the need for speed, flexibility, accuracy, and complexity in design functions while meeting the automotive industry’s high demands during bulk production. CNC automation enhances productivity while reducing labor costs within automotive parts manufacturing. As cost-effective material use, strict compliance to regulations, and zero waste become central to automakers, innovation and productivity in the automotive industry continue to hinge on CNC technologies.

• General Machining: The broad category of general machining covers items such as industrial tools and equipment, power tools, agricultural instruments, and construction machinery. As prototyping adaptation and material become fast-tracked in production, demand for CNC metal cutting tools rises. Innovations brought forth new standards of improved quality, lowered costs, and accelerated timelines, proving further in demand. Custom CNCs, which tailor to needs support mass production while enabling rapid alterations to the design. Moreover, there is growing sophistication in smart machines that are required to be more efficient. As such, custom crafted CNC components are required to be manufactured ultra-lite yet intricately detailed. Advancements in multifunctional and modular technologies have also spurred the development of machine tools to improve in this segment.

• Precision Engineering: The fabrication of distinctive optical devices, scientific instruments, and surgical and defense machinery requires the utmost precision where CNC metal cutting machines are integral, thus placing demands on surface finish quality and exacting tolerances. Ultraprecise micro machining and nano positioning integrates technologies such as CNC, spindles, modern CAM software, real-time monitoring systems and rigid benchmarks, which increase high standards efficiency. Timely marked and rigid technologies enable industries like healthcare and electronics to meet the perpetual demand for miniaturized sophisticated components.

• Transport Machinery: The sphere of transport machinery includes railways, marine transport, spacecrafts, and articulated vehicles. For making structural mechanical components such as gear housings, chassis frames, and engine parts, the structural and mechanical components require precision CNC metal cutting. With high-performance materials, accuracy, and durability needed, CNC systems answer all requirements. Transport engineering is dictated by legislation focused on weight reduction, fuel economy, and vehicle electrification. In these domains, CNC machining makes it possible to utilize complex alloys and composites. CNC tools are also used by manufacturers for refurbishing and retrofitting, which helps in improving the equipment lifecycle. The segment benefits from 5-axis multitasking machine advances for complex transport applications.

• Others: Renewable energy focuses on the machining of components such as wind turbine parts, solar mounts, and battery housings. In construction, precision CNC machinery assists with the fabrication of rebar connectors, metal frameworks, and support brackets. Moreover, the CNC manufacture of flanges, valves, and pump parts from resistant alloys is applied in oil and gas. This segment encompasses industries like construction, electronics, and oil and gas as well as renewable energy. Electronics makes use of precision CNC for the fabrication of semiconductor components and enclosures. The need for faster prototyping as well as adaptability in materials and high-volume production greatly increases the demand for CNC metal cutting tools. As the need arises, these tools continue to prove their worth in improving quality, reducing costs, and accelerating timelines across industries.

By class

• General Class: General-class CNC machining centres are purposely designed for economical material removal within job-shop and low-to-medium volume production scenarios. These platforms offer a balanced trade-off between initial investment and sustained throughput, positioning them as reliable tools in jobbing and small-to-medium enterprise settings. The operational intent is a rapid production cycle combined with minimal cutting-tool consumption, while exact final geometry is tolerated within broad limits. They accommodate a wide range of ferrous and non-ferrous alloys, habitually producing parts that meet moderate tolerances. Their pervasiveness in cost-sensitive manufacturing and in regions with developing infrastructure confirms their fit within lean and value-focused production lines.

• High-End Class: Premium CNC metal-cutting platforms are characterised by their ultra-rigid frames, rapid axis acceleration profiles, and tightly controlled thermal behaviour, enabling dimensional stability within low-single-micrometre tolerances. Advanced spindle architecture—integrated with multi-axis contouring—extends the operational envelope. Key industries, including aerospace, automotive, and high-precision medical-device manufacturing, require the concurrent generation of flawless surface finish and complex geometries within low-volume batches. Completely digitised control, augmented by predictive maintenance and autonomous machining capability, yields a quantifiable uplift in productive uptime. Although the initial capital commitment is significant, the corresponding gains in dimensional fidelity, shortened cycle times, and greater availability of the entire value chain provide a compelling economic case for manufacturers pursuing advanced production paradigms.

• Special-Class: These ultra-precision CNC systems are meticulously crafted for narrowly specified applications, often employing exotic alloys, micro-scale geometries, or features demanding tolerances in the sub-micron regime. Their primary deployment occurs in defence, nuclear, and advanced research-and-development environments, where they accommodate bespoke tooling, custom fixturing, and programmable adaptability to fulfil unique project specifications. These machines are custom-engineered and may integrate auxiliary capabilities such as in-process measurement or co-located finishing stages. While their share of the overall market is limited, requirements are growing alongside enhanced precision manufacturing, the arrival of new material classes, and an expanding emphasis on prototyping.

By Product

• 5-Axis CNC Machines: The 5-axis CNC machine embodies the pinnacle of machining flexibility by permitting concurrent motion across five distinct axes. Consequently, it can produce geometrically intricate components in a single workholding, thereby minimizing setup time and enhancing dimensional accuracy. This capability has secured its adoption in aerospace, automotive, and die-and-mold sectors, where it consistently achieves outstanding surface finishes, elaborate detail, and a diminished need for dedicated fixtures. Although the capital investment is substantial, the resultant gains in cycle speed and error reduction justify the expenditure, rendering it essential for the manufacture of high-value, precision components.

• 4-Axis CNC Machines: The integration of a rotational axis into the traditional three-axis CNC architecture significantly enhances the manipulatory capacity of the machining spindle by permitting a controlled rotational displacement about a fixed axis. This advancement allows for the uninterrupted machining of cylindrical profiles and angular geometries, thereby eliminating the need for multiple repositioning and clamping operations. The result is a marked gain in productivity and process reliability, particularly for components with complex curvature or multiple reference faces. The technology has gained traction in mold fabrication and the production of orthopedic implants precisely because it reconciles a moderate capital cost with expanded directional machining capability. While current 5-axis systems provide superior flexibility, the 4-axis architecture maintains a strong cost-performance balance for medium-complexity geometries, especially in low- to moderate-production-volume scenarios typical of small- and mid-sized enterprises.

• 3-axis CNC machines: 3-axis CNC machines remain the cornerstone of contemporary numerical control, translating tool movement along the linear X, Y, and Z axes in a Cartesian framework. Engineered for the production of flat and prismatic workpieces, these machines have found broad adoption in general machining, automotive component production, and the fabrication of industrial assemblies. Although lacking multi-angular capability, these devices remain economically attractive, offer an intuitive programming environment, and are designed for long-term dependable operation, making them ideal for basic, high-volume production streams. As a result, three-axis CNC platforms occupy the majority of shop-floor real estate in contract manufacturing environments and are the standard introductory choice for enterprises adopting CNC automation for the first time.

• 2-axis CNC: 2-axis CNC systems are structurally optimized for turning operations, where a fixed cutting tool moves along two linear axes while the part rotates about its longitudinal centerline. This arrangement dominates lathing and threading tasks and is well suited for creating cylindrical forms. Typical parts machined on this class of hardware are bushings, shafts, and washers, with a machining emphasis limited to outer and inner profiles. Although the range of applications is narrow, two-axis lathes deliver robust cost effectiveness by shortening cycle times on large, repetitive lot sizes, a need particularly acute in the automotive sector and in general metalworking. Simple control interfaces and consistent output in batch scenarios ensure their ongoing deployment in these industries.

• Others: The broader category embraces purpose-built configurations such as multi-axis platforms with six degrees of freedom and hybrid machines integrating additive and subtractive techniques. It also includes bespoke CNC systems engineered for research laboratories and low-volume, niche production. These systems facilitate sophisticated machining sequences and are typically integrated with AI-driven process monitoring for in-process adjustment. Despite their single share of the global CNC market being relatively small, adoption is accelerating in parallel with the rise of smart-manufacturing strategies and the growing imperative for flexible, multifunctional machining capabilities.

By Machine Type

• Conventional CNC Machines: Standard CNC platforms typically begin as conventional lathes, milling machines, or drill presses retrofitted with numerical-control capability. These machines excel at achieving high-precision tolerances, especially for two-dimensional profiles and relatively simple three-dimensional features. Their economical purchase price and straightforward maintenance have made them popular choices for small- and medium-sized enterprises, as well as for educational and research laboratories. Although they do not accommodate dynamic workpiece geometries or adaptive tool paths, they remain integral to job shops and are particularly effective for high-volume runs or maintenance work where repeatability is paramount.

• Machining Centres: Machining centres consolidate milling, drilling, and tapping functions within a single, flexible platform. The available configurations—vertical, horizontal, and universal—commonly incorporate automated tool changers, optional high-speed spindle assemblies, and expansive travel distances. Such layouts support aerospace, automotive, and high-precision engineering applications, where complex geometries must be produced while minimizing manual setup and handling. Rapid cycle times, integrated probing systems, and pallet-handling modules accelerate throughput while ensuring consistent accuracy, thus embedding such machining centres in automated manufacturing cells and digital-thread-driven smart factories.

• Turning centres: Turning centres evolve from advanced CNC lathes engineered for peak throughput in the rapid manufacture of rotary parts. Each system incorporates live tooling and robotic loading, ensuring continuous, unbroken material flow. Optimised exclusively for cylindrical geometries—pistons, shafts, and housings—the platforms enable simultaneous axial drilling, milling, and finishing operations, all performed within a single work-holding arrangement. Twin-spindle configurations permit continuous operation, making them central to automotive and heavy-equipment lines where tight tolerances and reduced cycle times are imperative.

• Mill-turn centres: Mill-turn centres combine milling and turning functions within a single work envelope, capable of handling geometrically intricate, multi-face components. The hybrid architecture reduces the number of work-holding index changes, thereby limiting cumulative positional drift and shortening overall cycle times. Coupled with bar feeders, autonomous tool changers, and live data analytics, these workcells meet the exacting standards of aerospace, defence, and medical-device manufacturing. While initial capital is significant, the resultant gains in productivity justify deployment in varied high-mix environments.

• Other: This category comprises Swiss-type lathes, laser-assisted machining, and machines that merge electrical discharge machining with additive processes. Specified for micro-manufacturing, medical devices, and miniaturised electronics, they address particularised demands. Though they operate in narrower niches, adoption is increasing as manufacturers pivot towards flexible production of custom geometries, exotic materials, and abbreviated lead times in advanced-manufacturing paradigms.

Impact of Latest Tariff Policies

The recent tariff increases by the U.S. on China and certain Asian and European countries have significantly impacted the market for CNC metal cutting machine tools. Other sourced key parts, such as motors, servo drives, and control units, now incur additional tariffs, which increase production and procurement expenditures. This presents a problem for firms that purchase semi-finished goods or operatejust-in-time inventory systems. To alleviate these issues, many manufacturers are beginning to increase component inventories by sourcing some parts from domestic suppliers or stockpiling crucial components to circumvent these tariffs.

While these strategies resolve the major problems, they also lead to expensive reconstructions with increased lead times. Firms with regional assembly plants and vertically integrated corporate structures will benefit notably from lower cost exposure, enhanced control over expenses, improved cost structure due to reduced tariff exposure and greater control of costs, and thus strengthen their competitive advantage.

Joint research and development projects, as well as global collaborations and partnerships, are on hold as a result of geopolitical instability, which impacts all other sectors, including new venture startups. These younger firms are the most impacted by these changes, suffering from shrinking margins and longer project timelines.

Report Scope

Regional Perspective

The CNC Metal cutting machine tools Market can be divided across different regions such as North America, Europe, Asia-Pacific, and LAMEA. This is a cursory overview of each region:

• North America: North America continues to be the leading region for CNC metal cutting machine tools due to advanced manufacturing in aerospace, defense, and automotive sectors. The U.S. has strong automation and smart factory investment, which propels the market. Innovative technology and well-trained personnel, along with supportive government policies, drive further expansion. Precision and tailor-made metal parts are in great demand due to growing EV manufacturing and defense sectors.

• Europe: Europe has one of the strongest shares in the CNC machine tools market, with Germany, Italy, and Switzerland leading because of their strong engineering reputation. Sustainability and energy-efficient machines are a focus for this region due to EU policies, boosting the global market. Adoption of Industry 4.0 and automation in precision engineering, automotive, and aerospace industries is widespread, driving Europe’s growth. Europe continues to lead in advanced machining with collaborative research, high R&D investments, and production-oriented globalization.

• Asia-Pacific: The Asia-Pacific region leads the world CNC market for metal cutting tools owing to industrialization, mass production, and increasing automation in China, Japan, South Korea, and India. Government-sponsored programs such as “Make in India” and “Made in China 2025” are accelerating spending in CNC technologies. The region enjoys low-cost manufacturing and a growing need in the automotive, electronics, and heavy engineering sectors as skilled labor which makes it the fastest growing regional market.

• LAMEA: The LAMEA region is exhibiting the most emergent promise alongside South Africa, Brazil and the UAE where industrialization is intensifying the demand for CNC machine tools. Infrastructure development and energy projects, as well as localization of manufacturing, are the primary drivers of growth. The market is restricted, however, due to lack of specialized knowledge, high capital expenditure, and inconsistent laws. Those aside, increased foreign direct investment and regional manufacturing incentives are likely to stimulate gradual adoption.

Key Developments

In recent years, the CNC Metal cutting machine tools Market has experienced several crucial changes as the players in the market strive to grow their geographical footprint and improve their product line and profits by using synergies.

• In September 2023, DMG MORI unveiled its new model, the INH 63, at the EMO trade fair. This robust 5-axis horizontal machining center is engineered for long-term precision in producing complex components with workpiece weights up to 1,000 kg. It features a generous working area of ø1,070 x 1,000 mm and supports pallet sizes up to 630 x 630 mm. Designed for seamless integration into automated production environments, the INH 63 supports the next generation of smart manufacturing. Additionally, its advanced coolant supply system enhances operational efficiency and promotes sustainability, aligning with modern industry demands for environmentally responsible machining solutions.

Leading players in the CNC Metal Cutting Machine Tools Market—such as Mazak, DMG MORI, Okuma, and Makino—are accelerating innovation through the integration of smart automation, AI-powered process control, and multi-axis machining technologies. These companies are investing in advanced digital platforms, real-time analytics, and energy-efficient systems to boost productivity, reduce waste, and ensure high-precision outcomes across industries. Their focus on modular design, predictive maintenance, and seamless integration with Industry 4.0 infrastructure supports customized manufacturing and rapid prototyping. By enabling greater efficiency, flexibility, and sustainability, these firms are redefining the future of intelligent machining and competitive industrial production on a global scale.

Leading Players

The CNC Metal cutting machine tools Market is highly competitive, with a large number of product providers globally. Some of the key players in the market include:

• Mazak Corporation
• Doosan Machine Tools Co. Ltd.
• Trumpf
• Amada Machine Tools Co. Ltd.
• JTEKT Corporation
• MAG IAS GmbH
• Schuler AG
• Makino
• Hyundai WIA
• Komatsu Ltd.
• Okuma Corporation
• FANUC Corporation
• XYZ Machine Tools
• Mitsubishi Heavy Industries Machine Tool Co. Ltd.
• General Technology Group Dalian Machine Tool Corporation
• ANCA Group
• Others

These companies pursue strategies such as R&D investment, digital transformation, strategic acquisitions, and technology licensing to strengthen global presence. Several are focusing on integrating AI, digital twins, and predictive analytics to align with Industry 4.0 manufacturing trends.

The global CNC Metal Cutting Machine Tools Market is evolving rapidly, with top manufacturers like Mazak, DMG MORI, Okuma, and Makino leading technological innovations. These firms are developing intelligent machining systems equipped with IoT-enabled monitoring, adaptive control software, and real-time data feedback. Mazak is pioneering digital twin-enabled automation, Makino is advancing multi-axis capabilities for aerospace applications, Okuma emphasizes smart factory integration, and Trumpf continues to innovate in laser-based cutting tools. These advancements are transforming production efficiency, operational sustainability, and machining precision.

The CNC Metal Cutting Machine Tools Market is segmented as follows:

By Type

• Metal Cutting
• Metal Forming

By Application

• Automotive
• General Machinery
• Precision Engineering
• Transport Machinery
• Others

By Class

• General
• High End
• Special

By Product

• 5- Axis
• 4- Axis
• 3-Axis
• 2-Axis
• Others

 By Machine Type

• Conventional
• Machining Centre
• Turning Centre
• Mill-Turn
• Other

Regional Coverage:

North America

• U.S.
• Canada
• Mexico
• Rest of North America

Europe

• Germany
• France
• U.K.
• Russia
• Italy
• Spain
• Netherlands
• Rest of Europe

Asia Pacific

• China
• Japan
• India
• New Zealand
• Australia
• South Korea
• Taiwan
• Rest of Asia Pacific

The Middle East & Africa

• Saudi Arabia
• UAE
• Egypt
• Kuwait
• South Africa
• Rest of the Middle East & Africa

Latin America

• Brazil
• Argentina
• Rest of Latin America